2 * ITS emulation for a GICv3-based system
4 * Copyright Linaro.org 2021
7 * Shashi Mallela <shashi.mallela@linaro.org>
9 * This work is licensed under the terms of the GNU GPL, version 2 or (at your
10 * option) any later version. See the COPYING file in the top-level directory.
14 #include "qemu/osdep.h"
17 #include "hw/qdev-properties.h"
18 #include "hw/intc/arm_gicv3_its_common.h"
19 #include "gicv3_internal.h"
20 #include "qom/object.h"
21 #include "qapi/error.h"
23 typedef struct GICv3ITSClass GICv3ITSClass
;
24 /* This is reusing the GICv3ITSState typedef from ARM_GICV3_ITS_COMMON */
25 DECLARE_OBJ_CHECKERS(GICv3ITSState
, GICv3ITSClass
,
26 ARM_GICV3_ITS
, TYPE_ARM_GICV3_ITS
)
28 struct GICv3ITSClass
{
29 GICv3ITSCommonClass parent_class
;
30 ResettablePhases parent_phases
;
34 * This is an internal enum used to distinguish between LPI triggered
35 * via command queue and LPI triggered via gits_translater write.
37 typedef enum ItsCmdType
{
38 NONE
= 0, /* internal indication for GITS_TRANSLATER write */
44 typedef struct DTEntry
{
50 typedef struct CTEntry
{
55 typedef struct ITEntry
{
64 typedef struct VTEntry
{
72 * The ITS spec permits a range of CONSTRAINED UNPREDICTABLE options
73 * if a command parameter is not correct. These include both "stall
74 * processing of the command queue" and "ignore this command, and
75 * keep processing the queue". In our implementation we choose that
76 * memory transaction errors reading the command packet provoke a
77 * stall, but errors in parameters cause us to ignore the command
78 * and continue processing.
79 * The process_* functions which handle individual ITS commands all
80 * return an ItsCmdResult which tells process_cmdq() whether it should
81 * stall, keep going because of an error, or keep going because the
82 * command was a success.
84 typedef enum ItsCmdResult
{
90 /* True if the ITS supports the GICv4 virtual LPI feature */
91 static bool its_feature_virtual(GICv3ITSState
*s
)
93 return s
->typer
& R_GITS_TYPER_VIRTUAL_MASK
;
96 static inline bool intid_in_lpi_range(uint32_t id
)
98 return id
>= GICV3_LPI_INTID_START
&&
99 id
< (1 << (GICD_TYPER_IDBITS
+ 1));
102 static inline bool valid_doorbell(uint32_t id
)
104 /* Doorbell fields may be an LPI, or 1023 to mean "no doorbell" */
105 return id
== INTID_SPURIOUS
|| intid_in_lpi_range(id
);
108 static uint64_t baser_base_addr(uint64_t value
, uint32_t page_sz
)
113 case GITS_PAGE_SIZE_4K
:
114 case GITS_PAGE_SIZE_16K
:
115 result
= FIELD_EX64(value
, GITS_BASER
, PHYADDR
) << 12;
118 case GITS_PAGE_SIZE_64K
:
119 result
= FIELD_EX64(value
, GITS_BASER
, PHYADDRL_64K
) << 16;
120 result
|= FIELD_EX64(value
, GITS_BASER
, PHYADDRH_64K
) << 48;
129 static uint64_t table_entry_addr(GICv3ITSState
*s
, TableDesc
*td
,
130 uint32_t idx
, MemTxResult
*res
)
133 * Given a TableDesc describing one of the ITS in-guest-memory
134 * tables and an index into it, return the guest address
135 * corresponding to that table entry.
136 * If there was a memory error reading the L1 table of an
137 * indirect table, *res is set accordingly, and we return -1.
138 * If the L1 table entry is marked not valid, we return -1 with
139 * *res set to MEMTX_OK.
141 * The specification defines the format of level 1 entries of a
142 * 2-level table, but the format of level 2 entries and the format
143 * of flat-mapped tables is IMPDEF.
145 AddressSpace
*as
= &s
->gicv3
->dma_as
;
148 uint32_t num_l2_entries
;
153 /* Single level table */
154 return td
->base_addr
+ idx
* td
->entry_sz
;
157 /* Two level table */
158 l2idx
= idx
/ (td
->page_sz
/ L1TABLE_ENTRY_SIZE
);
160 l2
= address_space_ldq_le(as
,
161 td
->base_addr
+ (l2idx
* L1TABLE_ENTRY_SIZE
),
162 MEMTXATTRS_UNSPECIFIED
, res
);
163 if (*res
!= MEMTX_OK
) {
166 if (!(l2
& L2_TABLE_VALID_MASK
)) {
170 num_l2_entries
= td
->page_sz
/ td
->entry_sz
;
171 return (l2
& ((1ULL << 51) - 1)) + (idx
% num_l2_entries
) * td
->entry_sz
;
175 * Read the Collection Table entry at index @icid. On success (including
176 * successfully determining that there is no valid CTE for this index),
177 * we return MEMTX_OK and populate the CTEntry struct @cte accordingly.
178 * If there is an error reading memory then we return the error code.
180 static MemTxResult
get_cte(GICv3ITSState
*s
, uint16_t icid
, CTEntry
*cte
)
182 AddressSpace
*as
= &s
->gicv3
->dma_as
;
183 MemTxResult res
= MEMTX_OK
;
184 uint64_t entry_addr
= table_entry_addr(s
, &s
->ct
, icid
, &res
);
187 if (entry_addr
== -1) {
188 /* No L2 table entry, i.e. no valid CTE, or a memory error */
193 cteval
= address_space_ldq_le(as
, entry_addr
, MEMTXATTRS_UNSPECIFIED
, &res
);
194 if (res
!= MEMTX_OK
) {
197 cte
->valid
= FIELD_EX64(cteval
, CTE
, VALID
);
198 cte
->rdbase
= FIELD_EX64(cteval
, CTE
, RDBASE
);
200 if (res
!= MEMTX_OK
) {
201 trace_gicv3_its_cte_read_fault(icid
);
203 trace_gicv3_its_cte_read(icid
, cte
->valid
, cte
->rdbase
);
209 * Update the Interrupt Table entry at index @evinted in the table specified
210 * by the dte @dte. Returns true on success, false if there was a memory
213 static bool update_ite(GICv3ITSState
*s
, uint32_t eventid
, const DTEntry
*dte
,
216 AddressSpace
*as
= &s
->gicv3
->dma_as
;
217 MemTxResult res
= MEMTX_OK
;
218 hwaddr iteaddr
= dte
->ittaddr
+ eventid
* ITS_ITT_ENTRY_SIZE
;
222 trace_gicv3_its_ite_write(dte
->ittaddr
, eventid
, ite
->valid
,
223 ite
->inttype
, ite
->intid
, ite
->icid
,
224 ite
->vpeid
, ite
->doorbell
);
227 itel
= FIELD_DP64(itel
, ITE_L
, VALID
, 1);
228 itel
= FIELD_DP64(itel
, ITE_L
, INTTYPE
, ite
->inttype
);
229 itel
= FIELD_DP64(itel
, ITE_L
, INTID
, ite
->intid
);
230 itel
= FIELD_DP64(itel
, ITE_L
, ICID
, ite
->icid
);
231 itel
= FIELD_DP64(itel
, ITE_L
, VPEID
, ite
->vpeid
);
232 iteh
= FIELD_DP32(iteh
, ITE_H
, DOORBELL
, ite
->doorbell
);
235 address_space_stq_le(as
, iteaddr
, itel
, MEMTXATTRS_UNSPECIFIED
, &res
);
236 if (res
!= MEMTX_OK
) {
239 address_space_stl_le(as
, iteaddr
+ 8, iteh
, MEMTXATTRS_UNSPECIFIED
, &res
);
240 return res
== MEMTX_OK
;
244 * Read the Interrupt Table entry at index @eventid from the table specified
245 * by the DTE @dte. On success, we return MEMTX_OK and populate the ITEntry
246 * struct @ite accordingly. If there is an error reading memory then we return
249 static MemTxResult
get_ite(GICv3ITSState
*s
, uint32_t eventid
,
250 const DTEntry
*dte
, ITEntry
*ite
)
252 AddressSpace
*as
= &s
->gicv3
->dma_as
;
253 MemTxResult res
= MEMTX_OK
;
256 hwaddr iteaddr
= dte
->ittaddr
+ eventid
* ITS_ITT_ENTRY_SIZE
;
258 itel
= address_space_ldq_le(as
, iteaddr
, MEMTXATTRS_UNSPECIFIED
, &res
);
259 if (res
!= MEMTX_OK
) {
260 trace_gicv3_its_ite_read_fault(dte
->ittaddr
, eventid
);
264 iteh
= address_space_ldl_le(as
, iteaddr
+ 8, MEMTXATTRS_UNSPECIFIED
, &res
);
265 if (res
!= MEMTX_OK
) {
266 trace_gicv3_its_ite_read_fault(dte
->ittaddr
, eventid
);
270 ite
->valid
= FIELD_EX64(itel
, ITE_L
, VALID
);
271 ite
->inttype
= FIELD_EX64(itel
, ITE_L
, INTTYPE
);
272 ite
->intid
= FIELD_EX64(itel
, ITE_L
, INTID
);
273 ite
->icid
= FIELD_EX64(itel
, ITE_L
, ICID
);
274 ite
->vpeid
= FIELD_EX64(itel
, ITE_L
, VPEID
);
275 ite
->doorbell
= FIELD_EX64(iteh
, ITE_H
, DOORBELL
);
276 trace_gicv3_its_ite_read(dte
->ittaddr
, eventid
, ite
->valid
,
277 ite
->inttype
, ite
->intid
, ite
->icid
,
278 ite
->vpeid
, ite
->doorbell
);
283 * Read the Device Table entry at index @devid. On success (including
284 * successfully determining that there is no valid DTE for this index),
285 * we return MEMTX_OK and populate the DTEntry struct accordingly.
286 * If there is an error reading memory then we return the error code.
288 static MemTxResult
get_dte(GICv3ITSState
*s
, uint32_t devid
, DTEntry
*dte
)
290 MemTxResult res
= MEMTX_OK
;
291 AddressSpace
*as
= &s
->gicv3
->dma_as
;
292 uint64_t entry_addr
= table_entry_addr(s
, &s
->dt
, devid
, &res
);
295 if (entry_addr
== -1) {
296 /* No L2 table entry, i.e. no valid DTE, or a memory error */
300 dteval
= address_space_ldq_le(as
, entry_addr
, MEMTXATTRS_UNSPECIFIED
, &res
);
301 if (res
!= MEMTX_OK
) {
304 dte
->valid
= FIELD_EX64(dteval
, DTE
, VALID
);
305 dte
->size
= FIELD_EX64(dteval
, DTE
, SIZE
);
306 /* DTE word field stores bits [51:8] of the ITT address */
307 dte
->ittaddr
= FIELD_EX64(dteval
, DTE
, ITTADDR
) << ITTADDR_SHIFT
;
309 if (res
!= MEMTX_OK
) {
310 trace_gicv3_its_dte_read_fault(devid
);
312 trace_gicv3_its_dte_read(devid
, dte
->valid
, dte
->size
, dte
->ittaddr
);
318 * Read the vPE Table entry at index @vpeid. On success (including
319 * successfully determining that there is no valid entry for this index),
320 * we return MEMTX_OK and populate the VTEntry struct accordingly.
321 * If there is an error reading memory then we return the error code.
323 static MemTxResult
get_vte(GICv3ITSState
*s
, uint32_t vpeid
, VTEntry
*vte
)
325 MemTxResult res
= MEMTX_OK
;
326 AddressSpace
*as
= &s
->gicv3
->dma_as
;
327 uint64_t entry_addr
= table_entry_addr(s
, &s
->vpet
, vpeid
, &res
);
330 if (entry_addr
== -1) {
331 /* No L2 table entry, i.e. no valid VTE, or a memory error */
335 vteval
= address_space_ldq_le(as
, entry_addr
, MEMTXATTRS_UNSPECIFIED
, &res
);
336 if (res
!= MEMTX_OK
) {
339 vte
->valid
= FIELD_EX64(vteval
, VTE
, VALID
);
340 vte
->vptsize
= FIELD_EX64(vteval
, VTE
, VPTSIZE
);
341 vte
->vptaddr
= FIELD_EX64(vteval
, VTE
, VPTADDR
);
342 vte
->rdbase
= FIELD_EX64(vteval
, VTE
, RDBASE
);
344 if (res
!= MEMTX_OK
) {
345 trace_gicv3_its_vte_read_fault(vpeid
);
347 trace_gicv3_its_vte_read(vpeid
, vte
->valid
, vte
->vptsize
,
348 vte
->vptaddr
, vte
->rdbase
);
354 * Given a (DeviceID, EventID), look up the corresponding ITE, including
355 * checking for the various invalid-value cases. If we find a valid ITE,
356 * fill in @ite and @dte and return CMD_CONTINUE_OK. Otherwise return
357 * CMD_STALL or CMD_CONTINUE as appropriate (and the contents of @ite
358 * should not be relied on).
360 * The string @who is purely for the LOG_GUEST_ERROR messages,
361 * and should indicate the name of the calling function or similar.
363 static ItsCmdResult
lookup_ite(GICv3ITSState
*s
, const char *who
,
364 uint32_t devid
, uint32_t eventid
, ITEntry
*ite
,
367 uint64_t num_eventids
;
369 if (devid
>= s
->dt
.num_entries
) {
370 qemu_log_mask(LOG_GUEST_ERROR
,
371 "%s: invalid command attributes: devid %d>=%d",
372 who
, devid
, s
->dt
.num_entries
);
376 if (get_dte(s
, devid
, dte
) != MEMTX_OK
) {
380 qemu_log_mask(LOG_GUEST_ERROR
,
381 "%s: invalid command attributes: "
382 "invalid dte for %d\n", who
, devid
);
386 num_eventids
= 1ULL << (dte
->size
+ 1);
387 if (eventid
>= num_eventids
) {
388 qemu_log_mask(LOG_GUEST_ERROR
,
389 "%s: invalid command attributes: eventid %d >= %"
390 PRId64
"\n", who
, eventid
, num_eventids
);
394 if (get_ite(s
, eventid
, dte
, ite
) != MEMTX_OK
) {
399 qemu_log_mask(LOG_GUEST_ERROR
,
400 "%s: invalid command attributes: invalid ITE\n", who
);
404 return CMD_CONTINUE_OK
;
408 * Given an ICID, look up the corresponding CTE, including checking for various
409 * invalid-value cases. If we find a valid CTE, fill in @cte and return
410 * CMD_CONTINUE_OK; otherwise return CMD_STALL or CMD_CONTINUE (and the
411 * contents of @cte should not be relied on).
413 * The string @who is purely for the LOG_GUEST_ERROR messages,
414 * and should indicate the name of the calling function or similar.
416 static ItsCmdResult
lookup_cte(GICv3ITSState
*s
, const char *who
,
417 uint32_t icid
, CTEntry
*cte
)
419 if (icid
>= s
->ct
.num_entries
) {
420 qemu_log_mask(LOG_GUEST_ERROR
, "%s: invalid ICID 0x%x\n", who
, icid
);
423 if (get_cte(s
, icid
, cte
) != MEMTX_OK
) {
427 qemu_log_mask(LOG_GUEST_ERROR
, "%s: invalid CTE\n", who
);
430 if (cte
->rdbase
>= s
->gicv3
->num_cpu
) {
433 return CMD_CONTINUE_OK
;
437 * Given a VPEID, look up the corresponding VTE, including checking
438 * for various invalid-value cases. if we find a valid VTE, fill in @vte
439 * and return CMD_CONTINUE_OK; otherwise return CMD_STALL or CMD_CONTINUE
440 * (and the contents of @vte should not be relied on).
442 * The string @who is purely for the LOG_GUEST_ERROR messages,
443 * and should indicate the name of the calling function or similar.
445 static ItsCmdResult
lookup_vte(GICv3ITSState
*s
, const char *who
,
446 uint32_t vpeid
, VTEntry
*vte
)
448 if (vpeid
>= s
->vpet
.num_entries
) {
449 qemu_log_mask(LOG_GUEST_ERROR
, "%s: invalid VPEID 0x%x\n", who
, vpeid
);
453 if (get_vte(s
, vpeid
, vte
) != MEMTX_OK
) {
457 qemu_log_mask(LOG_GUEST_ERROR
,
458 "%s: invalid VTE for VPEID 0x%x\n", who
, vpeid
);
462 if (vte
->rdbase
>= s
->gicv3
->num_cpu
) {
465 return CMD_CONTINUE_OK
;
468 static ItsCmdResult
process_its_cmd_phys(GICv3ITSState
*s
, const ITEntry
*ite
,
474 cmdres
= lookup_cte(s
, __func__
, ite
->icid
, &cte
);
475 if (cmdres
!= CMD_CONTINUE_OK
) {
478 gicv3_redist_process_lpi(&s
->gicv3
->cpu
[cte
.rdbase
], ite
->intid
, irqlevel
);
479 return CMD_CONTINUE_OK
;
482 static ItsCmdResult
process_its_cmd_virt(GICv3ITSState
*s
, const ITEntry
*ite
,
488 cmdres
= lookup_vte(s
, __func__
, ite
->vpeid
, &vte
);
489 if (cmdres
!= CMD_CONTINUE_OK
) {
493 if (!intid_in_lpi_range(ite
->intid
) ||
494 ite
->intid
>= (1ULL << (vte
.vptsize
+ 1))) {
495 qemu_log_mask(LOG_GUEST_ERROR
, "%s: intid 0x%x out of range\n",
496 __func__
, ite
->intid
);
501 * For QEMU the actual pending of the vLPI is handled in the
504 gicv3_redist_process_vlpi(&s
->gicv3
->cpu
[vte
.rdbase
], ite
->intid
,
505 vte
.vptaddr
<< 16, ite
->doorbell
, irqlevel
);
506 return CMD_CONTINUE_OK
;
510 * This function handles the processing of following commands based on
511 * the ItsCmdType parameter passed:-
512 * 1. triggering of lpi interrupt translation via ITS INT command
513 * 2. triggering of lpi interrupt translation via gits_translater register
514 * 3. handling of ITS CLEAR command
515 * 4. handling of ITS DISCARD command
517 static ItsCmdResult
do_process_its_cmd(GICv3ITSState
*s
, uint32_t devid
,
518 uint32_t eventid
, ItsCmdType cmd
)
525 cmdres
= lookup_ite(s
, __func__
, devid
, eventid
, &ite
, &dte
);
526 if (cmdres
!= CMD_CONTINUE_OK
) {
530 irqlevel
= (cmd
== CLEAR
|| cmd
== DISCARD
) ? 0 : 1;
532 switch (ite
.inttype
) {
533 case ITE_INTTYPE_PHYSICAL
:
534 cmdres
= process_its_cmd_phys(s
, &ite
, irqlevel
);
536 case ITE_INTTYPE_VIRTUAL
:
537 if (!its_feature_virtual(s
)) {
538 /* Can't happen unless guest is illegally writing to table memory */
539 qemu_log_mask(LOG_GUEST_ERROR
,
540 "%s: invalid type %d in ITE (table corrupted?)\n",
541 __func__
, ite
.inttype
);
544 cmdres
= process_its_cmd_virt(s
, &ite
, irqlevel
);
547 g_assert_not_reached();
550 if (cmdres
== CMD_CONTINUE_OK
&& cmd
== DISCARD
) {
552 /* remove mapping from interrupt translation table */
554 return update_ite(s
, eventid
, &dte
, &ite
) ? CMD_CONTINUE_OK
: CMD_STALL
;
556 return CMD_CONTINUE_OK
;
559 static ItsCmdResult
process_its_cmd(GICv3ITSState
*s
, const uint64_t *cmdpkt
,
562 uint32_t devid
, eventid
;
564 devid
= (cmdpkt
[0] & DEVID_MASK
) >> DEVID_SHIFT
;
565 eventid
= cmdpkt
[1] & EVENTID_MASK
;
568 trace_gicv3_its_cmd_int(devid
, eventid
);
571 trace_gicv3_its_cmd_clear(devid
, eventid
);
574 trace_gicv3_its_cmd_discard(devid
, eventid
);
577 g_assert_not_reached();
579 return do_process_its_cmd(s
, devid
, eventid
, cmd
);
582 static ItsCmdResult
process_mapti(GICv3ITSState
*s
, const uint64_t *cmdpkt
,
585 uint32_t devid
, eventid
;
587 uint64_t num_eventids
;
592 devid
= (cmdpkt
[0] & DEVID_MASK
) >> DEVID_SHIFT
;
593 eventid
= cmdpkt
[1] & EVENTID_MASK
;
594 icid
= cmdpkt
[2] & ICID_MASK
;
598 trace_gicv3_its_cmd_mapi(devid
, eventid
, icid
);
600 pIntid
= (cmdpkt
[1] & pINTID_MASK
) >> pINTID_SHIFT
;
601 trace_gicv3_its_cmd_mapti(devid
, eventid
, icid
, pIntid
);
604 if (devid
>= s
->dt
.num_entries
) {
605 qemu_log_mask(LOG_GUEST_ERROR
,
606 "%s: invalid command attributes: devid %d>=%d",
607 __func__
, devid
, s
->dt
.num_entries
);
611 if (get_dte(s
, devid
, &dte
) != MEMTX_OK
) {
614 num_eventids
= 1ULL << (dte
.size
+ 1);
616 if (icid
>= s
->ct
.num_entries
) {
617 qemu_log_mask(LOG_GUEST_ERROR
,
618 "%s: invalid ICID 0x%x >= 0x%x\n",
619 __func__
, icid
, s
->ct
.num_entries
);
624 qemu_log_mask(LOG_GUEST_ERROR
,
625 "%s: no valid DTE for devid 0x%x\n", __func__
, devid
);
629 if (eventid
>= num_eventids
) {
630 qemu_log_mask(LOG_GUEST_ERROR
,
631 "%s: invalid event ID 0x%x >= 0x%" PRIx64
"\n",
632 __func__
, eventid
, num_eventids
);
636 if (!intid_in_lpi_range(pIntid
)) {
637 qemu_log_mask(LOG_GUEST_ERROR
,
638 "%s: invalid interrupt ID 0x%x\n", __func__
, pIntid
);
642 /* add ite entry to interrupt translation table */
644 ite
.inttype
= ITE_INTTYPE_PHYSICAL
;
647 ite
.doorbell
= INTID_SPURIOUS
;
649 return update_ite(s
, eventid
, &dte
, &ite
) ? CMD_CONTINUE_OK
: CMD_STALL
;
652 static ItsCmdResult
process_vmapti(GICv3ITSState
*s
, const uint64_t *cmdpkt
,
655 uint32_t devid
, eventid
, vintid
, doorbell
, vpeid
;
656 uint32_t num_eventids
;
660 if (!its_feature_virtual(s
)) {
664 devid
= FIELD_EX64(cmdpkt
[0], VMAPTI_0
, DEVICEID
);
665 eventid
= FIELD_EX64(cmdpkt
[1], VMAPTI_1
, EVENTID
);
666 vpeid
= FIELD_EX64(cmdpkt
[1], VMAPTI_1
, VPEID
);
667 doorbell
= FIELD_EX64(cmdpkt
[2], VMAPTI_2
, DOORBELL
);
670 trace_gicv3_its_cmd_vmapi(devid
, eventid
, vpeid
, doorbell
);
672 vintid
= FIELD_EX64(cmdpkt
[2], VMAPTI_2
, VINTID
);
673 trace_gicv3_its_cmd_vmapti(devid
, eventid
, vpeid
, vintid
, doorbell
);
676 if (devid
>= s
->dt
.num_entries
) {
677 qemu_log_mask(LOG_GUEST_ERROR
,
678 "%s: invalid DeviceID 0x%x (must be less than 0x%x)\n",
679 __func__
, devid
, s
->dt
.num_entries
);
683 if (get_dte(s
, devid
, &dte
) != MEMTX_OK
) {
688 qemu_log_mask(LOG_GUEST_ERROR
,
689 "%s: no entry in device table for DeviceID 0x%x\n",
694 num_eventids
= 1ULL << (dte
.size
+ 1);
696 if (eventid
>= num_eventids
) {
697 qemu_log_mask(LOG_GUEST_ERROR
,
698 "%s: EventID 0x%x too large for DeviceID 0x%x "
699 "(must be less than 0x%x)\n",
700 __func__
, eventid
, devid
, num_eventids
);
703 if (!intid_in_lpi_range(vintid
)) {
704 qemu_log_mask(LOG_GUEST_ERROR
,
705 "%s: VIntID 0x%x not a valid LPI\n",
709 if (!valid_doorbell(doorbell
)) {
710 qemu_log_mask(LOG_GUEST_ERROR
,
711 "%s: Doorbell %d not 1023 and not a valid LPI\n",
715 if (vpeid
>= s
->vpet
.num_entries
) {
716 qemu_log_mask(LOG_GUEST_ERROR
,
717 "%s: VPEID 0x%x out of range (must be less than 0x%x)\n",
718 __func__
, vpeid
, s
->vpet
.num_entries
);
721 /* add ite entry to interrupt translation table */
723 ite
.inttype
= ITE_INTTYPE_VIRTUAL
;
726 ite
.doorbell
= doorbell
;
728 return update_ite(s
, eventid
, &dte
, &ite
) ? CMD_CONTINUE_OK
: CMD_STALL
;
732 * Update the Collection Table entry for @icid to @cte. Returns true
733 * on success, false if there was a memory access error.
735 static bool update_cte(GICv3ITSState
*s
, uint16_t icid
, const CTEntry
*cte
)
737 AddressSpace
*as
= &s
->gicv3
->dma_as
;
740 MemTxResult res
= MEMTX_OK
;
742 trace_gicv3_its_cte_write(icid
, cte
->valid
, cte
->rdbase
);
745 /* add mapping entry to collection table */
746 cteval
= FIELD_DP64(cteval
, CTE
, VALID
, 1);
747 cteval
= FIELD_DP64(cteval
, CTE
, RDBASE
, cte
->rdbase
);
750 entry_addr
= table_entry_addr(s
, &s
->ct
, icid
, &res
);
751 if (res
!= MEMTX_OK
) {
752 /* memory access error: stall */
755 if (entry_addr
== -1) {
756 /* No L2 table for this index: discard write and continue */
760 address_space_stq_le(as
, entry_addr
, cteval
, MEMTXATTRS_UNSPECIFIED
, &res
);
761 return res
== MEMTX_OK
;
764 static ItsCmdResult
process_mapc(GICv3ITSState
*s
, const uint64_t *cmdpkt
)
769 icid
= cmdpkt
[2] & ICID_MASK
;
770 cte
.valid
= cmdpkt
[2] & CMD_FIELD_VALID_MASK
;
772 cte
.rdbase
= (cmdpkt
[2] & R_MAPC_RDBASE_MASK
) >> R_MAPC_RDBASE_SHIFT
;
773 cte
.rdbase
&= RDBASE_PROCNUM_MASK
;
777 trace_gicv3_its_cmd_mapc(icid
, cte
.rdbase
, cte
.valid
);
779 if (icid
>= s
->ct
.num_entries
) {
780 qemu_log_mask(LOG_GUEST_ERROR
, "ITS MAPC: invalid ICID 0x%x\n", icid
);
783 if (cte
.valid
&& cte
.rdbase
>= s
->gicv3
->num_cpu
) {
784 qemu_log_mask(LOG_GUEST_ERROR
,
785 "ITS MAPC: invalid RDBASE %u\n", cte
.rdbase
);
789 return update_cte(s
, icid
, &cte
) ? CMD_CONTINUE_OK
: CMD_STALL
;
793 * Update the Device Table entry for @devid to @dte. Returns true
794 * on success, false if there was a memory access error.
796 static bool update_dte(GICv3ITSState
*s
, uint32_t devid
, const DTEntry
*dte
)
798 AddressSpace
*as
= &s
->gicv3
->dma_as
;
801 MemTxResult res
= MEMTX_OK
;
803 trace_gicv3_its_dte_write(devid
, dte
->valid
, dte
->size
, dte
->ittaddr
);
806 /* add mapping entry to device table */
807 dteval
= FIELD_DP64(dteval
, DTE
, VALID
, 1);
808 dteval
= FIELD_DP64(dteval
, DTE
, SIZE
, dte
->size
);
809 dteval
= FIELD_DP64(dteval
, DTE
, ITTADDR
, dte
->ittaddr
);
812 entry_addr
= table_entry_addr(s
, &s
->dt
, devid
, &res
);
813 if (res
!= MEMTX_OK
) {
814 /* memory access error: stall */
817 if (entry_addr
== -1) {
818 /* No L2 table for this index: discard write and continue */
821 address_space_stq_le(as
, entry_addr
, dteval
, MEMTXATTRS_UNSPECIFIED
, &res
);
822 return res
== MEMTX_OK
;
825 static ItsCmdResult
process_mapd(GICv3ITSState
*s
, const uint64_t *cmdpkt
)
830 devid
= (cmdpkt
[0] & DEVID_MASK
) >> DEVID_SHIFT
;
831 dte
.size
= cmdpkt
[1] & SIZE_MASK
;
832 dte
.ittaddr
= (cmdpkt
[2] & ITTADDR_MASK
) >> ITTADDR_SHIFT
;
833 dte
.valid
= cmdpkt
[2] & CMD_FIELD_VALID_MASK
;
835 trace_gicv3_its_cmd_mapd(devid
, dte
.size
, dte
.ittaddr
, dte
.valid
);
837 if (devid
>= s
->dt
.num_entries
) {
838 qemu_log_mask(LOG_GUEST_ERROR
,
839 "ITS MAPD: invalid device ID field 0x%x >= 0x%x\n",
840 devid
, s
->dt
.num_entries
);
844 if (dte
.size
> FIELD_EX64(s
->typer
, GITS_TYPER
, IDBITS
)) {
845 qemu_log_mask(LOG_GUEST_ERROR
,
846 "ITS MAPD: invalid size %d\n", dte
.size
);
850 return update_dte(s
, devid
, &dte
) ? CMD_CONTINUE_OK
: CMD_STALL
;
853 static ItsCmdResult
process_movall(GICv3ITSState
*s
, const uint64_t *cmdpkt
)
857 rd1
= FIELD_EX64(cmdpkt
[2], MOVALL_2
, RDBASE1
);
858 rd2
= FIELD_EX64(cmdpkt
[3], MOVALL_3
, RDBASE2
);
860 trace_gicv3_its_cmd_movall(rd1
, rd2
);
862 if (rd1
>= s
->gicv3
->num_cpu
) {
863 qemu_log_mask(LOG_GUEST_ERROR
,
864 "%s: RDBASE1 %" PRId64
865 " out of range (must be less than %d)\n",
866 __func__
, rd1
, s
->gicv3
->num_cpu
);
869 if (rd2
>= s
->gicv3
->num_cpu
) {
870 qemu_log_mask(LOG_GUEST_ERROR
,
871 "%s: RDBASE2 %" PRId64
872 " out of range (must be less than %d)\n",
873 __func__
, rd2
, s
->gicv3
->num_cpu
);
878 /* Move to same target must succeed as a no-op */
879 return CMD_CONTINUE_OK
;
882 /* Move all pending LPIs from redistributor 1 to redistributor 2 */
883 gicv3_redist_movall_lpis(&s
->gicv3
->cpu
[rd1
], &s
->gicv3
->cpu
[rd2
]);
885 return CMD_CONTINUE_OK
;
888 static ItsCmdResult
process_movi(GICv3ITSState
*s
, const uint64_t *cmdpkt
)
890 uint32_t devid
, eventid
;
893 CTEntry old_cte
, new_cte
;
897 devid
= FIELD_EX64(cmdpkt
[0], MOVI_0
, DEVICEID
);
898 eventid
= FIELD_EX64(cmdpkt
[1], MOVI_1
, EVENTID
);
899 new_icid
= FIELD_EX64(cmdpkt
[2], MOVI_2
, ICID
);
901 trace_gicv3_its_cmd_movi(devid
, eventid
, new_icid
);
903 cmdres
= lookup_ite(s
, __func__
, devid
, eventid
, &old_ite
, &dte
);
904 if (cmdres
!= CMD_CONTINUE_OK
) {
908 if (old_ite
.inttype
!= ITE_INTTYPE_PHYSICAL
) {
909 qemu_log_mask(LOG_GUEST_ERROR
,
910 "%s: invalid command attributes: invalid ITE\n",
915 cmdres
= lookup_cte(s
, __func__
, old_ite
.icid
, &old_cte
);
916 if (cmdres
!= CMD_CONTINUE_OK
) {
919 cmdres
= lookup_cte(s
, __func__
, new_icid
, &new_cte
);
920 if (cmdres
!= CMD_CONTINUE_OK
) {
924 if (old_cte
.rdbase
!= new_cte
.rdbase
) {
925 /* Move the LPI from the old redistributor to the new one */
926 gicv3_redist_mov_lpi(&s
->gicv3
->cpu
[old_cte
.rdbase
],
927 &s
->gicv3
->cpu
[new_cte
.rdbase
],
931 /* Update the ICID field in the interrupt translation table entry */
932 old_ite
.icid
= new_icid
;
933 return update_ite(s
, eventid
, &dte
, &old_ite
) ? CMD_CONTINUE_OK
: CMD_STALL
;
937 * Update the vPE Table entry at index @vpeid with the entry @vte.
938 * Returns true on success, false if there was a memory access error.
940 static bool update_vte(GICv3ITSState
*s
, uint32_t vpeid
, const VTEntry
*vte
)
942 AddressSpace
*as
= &s
->gicv3
->dma_as
;
945 MemTxResult res
= MEMTX_OK
;
947 trace_gicv3_its_vte_write(vpeid
, vte
->valid
, vte
->vptsize
, vte
->vptaddr
,
951 vteval
= FIELD_DP64(vteval
, VTE
, VALID
, 1);
952 vteval
= FIELD_DP64(vteval
, VTE
, VPTSIZE
, vte
->vptsize
);
953 vteval
= FIELD_DP64(vteval
, VTE
, VPTADDR
, vte
->vptaddr
);
954 vteval
= FIELD_DP64(vteval
, VTE
, RDBASE
, vte
->rdbase
);
957 entry_addr
= table_entry_addr(s
, &s
->vpet
, vpeid
, &res
);
958 if (res
!= MEMTX_OK
) {
961 if (entry_addr
== -1) {
962 /* No L2 table for this index: discard write and continue */
965 address_space_stq_le(as
, entry_addr
, vteval
, MEMTXATTRS_UNSPECIFIED
, &res
);
966 return res
== MEMTX_OK
;
969 static ItsCmdResult
process_vmapp(GICv3ITSState
*s
, const uint64_t *cmdpkt
)
974 if (!its_feature_virtual(s
)) {
978 vpeid
= FIELD_EX64(cmdpkt
[1], VMAPP_1
, VPEID
);
979 vte
.rdbase
= FIELD_EX64(cmdpkt
[2], VMAPP_2
, RDBASE
);
980 vte
.valid
= FIELD_EX64(cmdpkt
[2], VMAPP_2
, V
);
981 vte
.vptsize
= FIELD_EX64(cmdpkt
[3], VMAPP_3
, VPTSIZE
);
982 vte
.vptaddr
= FIELD_EX64(cmdpkt
[3], VMAPP_3
, VPTADDR
);
984 trace_gicv3_its_cmd_vmapp(vpeid
, vte
.rdbase
, vte
.valid
,
985 vte
.vptaddr
, vte
.vptsize
);
988 * For GICv4.0 the VPT_size field is only 5 bits, whereas we
989 * define our field macros to include the full GICv4.1 8 bits.
990 * The range check on VPT_size will catch the cases where
991 * the guest set the RES0-in-GICv4.0 bits [7:6].
993 if (vte
.vptsize
> FIELD_EX64(s
->typer
, GITS_TYPER
, IDBITS
)) {
994 qemu_log_mask(LOG_GUEST_ERROR
,
995 "%s: invalid VPT_size 0x%x\n", __func__
, vte
.vptsize
);
999 if (vte
.valid
&& vte
.rdbase
>= s
->gicv3
->num_cpu
) {
1000 qemu_log_mask(LOG_GUEST_ERROR
,
1001 "%s: invalid rdbase 0x%x\n", __func__
, vte
.rdbase
);
1002 return CMD_CONTINUE
;
1005 if (vpeid
>= s
->vpet
.num_entries
) {
1006 qemu_log_mask(LOG_GUEST_ERROR
,
1007 "%s: VPEID 0x%x out of range (must be less than 0x%x)\n",
1008 __func__
, vpeid
, s
->vpet
.num_entries
);
1009 return CMD_CONTINUE
;
1012 return update_vte(s
, vpeid
, &vte
) ? CMD_CONTINUE_OK
: CMD_STALL
;
1015 typedef struct VmovpCallbackData
{
1019 * Overall command result. If more than one callback finds an
1020 * error, STALL beats CONTINUE.
1022 ItsCmdResult result
;
1023 } VmovpCallbackData
;
1025 static void vmovp_callback(gpointer data
, gpointer opaque
)
1028 * This function is called to update the VPEID field in a VPE
1029 * table entry for this ITS. This might be because of a VMOVP
1030 * command executed on any ITS that is connected to the same GIC
1031 * as this ITS. We need to read the VPE table entry for the VPEID
1032 * and update its RDBASE field.
1034 GICv3ITSState
*s
= data
;
1035 VmovpCallbackData
*cbdata
= opaque
;
1037 ItsCmdResult cmdres
;
1039 cmdres
= lookup_vte(s
, __func__
, cbdata
->vpeid
, &vte
);
1042 cbdata
->result
= CMD_STALL
;
1045 if (cbdata
->result
!= CMD_STALL
) {
1046 cbdata
->result
= CMD_CONTINUE
;
1049 case CMD_CONTINUE_OK
:
1053 vte
.rdbase
= cbdata
->rdbase
;
1054 if (!update_vte(s
, cbdata
->vpeid
, &vte
)) {
1055 cbdata
->result
= CMD_STALL
;
1059 static ItsCmdResult
process_vmovp(GICv3ITSState
*s
, const uint64_t *cmdpkt
)
1061 VmovpCallbackData cbdata
;
1063 if (!its_feature_virtual(s
)) {
1064 return CMD_CONTINUE
;
1067 cbdata
.vpeid
= FIELD_EX64(cmdpkt
[1], VMOVP_1
, VPEID
);
1068 cbdata
.rdbase
= FIELD_EX64(cmdpkt
[2], VMOVP_2
, RDBASE
);
1070 trace_gicv3_its_cmd_vmovp(cbdata
.vpeid
, cbdata
.rdbase
);
1072 if (cbdata
.rdbase
>= s
->gicv3
->num_cpu
) {
1073 return CMD_CONTINUE
;
1077 * Our ITS implementation reports GITS_TYPER.VMOVP == 1, which means
1078 * that when the VMOVP command is executed on an ITS to change the
1079 * VPEID field in a VPE table entry the change must be propagated
1080 * to all the ITSes connected to the same GIC.
1082 cbdata
.result
= CMD_CONTINUE_OK
;
1083 gicv3_foreach_its(s
->gicv3
, vmovp_callback
, &cbdata
);
1084 return cbdata
.result
;
1087 static ItsCmdResult
process_vmovi(GICv3ITSState
*s
, const uint64_t *cmdpkt
)
1089 uint32_t devid
, eventid
, vpeid
, doorbell
;
1090 bool doorbell_valid
;
1093 VTEntry old_vte
, new_vte
;
1094 ItsCmdResult cmdres
;
1096 if (!its_feature_virtual(s
)) {
1097 return CMD_CONTINUE
;
1100 devid
= FIELD_EX64(cmdpkt
[0], VMOVI_0
, DEVICEID
);
1101 eventid
= FIELD_EX64(cmdpkt
[1], VMOVI_1
, EVENTID
);
1102 vpeid
= FIELD_EX64(cmdpkt
[1], VMOVI_1
, VPEID
);
1103 doorbell_valid
= FIELD_EX64(cmdpkt
[2], VMOVI_2
, D
);
1104 doorbell
= FIELD_EX64(cmdpkt
[2], VMOVI_2
, DOORBELL
);
1106 trace_gicv3_its_cmd_vmovi(devid
, eventid
, vpeid
, doorbell_valid
, doorbell
);
1108 if (doorbell_valid
&& !valid_doorbell(doorbell
)) {
1109 qemu_log_mask(LOG_GUEST_ERROR
,
1110 "%s: invalid doorbell 0x%x\n", __func__
, doorbell
);
1111 return CMD_CONTINUE
;
1114 cmdres
= lookup_ite(s
, __func__
, devid
, eventid
, &ite
, &dte
);
1115 if (cmdres
!= CMD_CONTINUE_OK
) {
1119 if (ite
.inttype
!= ITE_INTTYPE_VIRTUAL
) {
1120 qemu_log_mask(LOG_GUEST_ERROR
, "%s: ITE is not for virtual interrupt\n",
1122 return CMD_CONTINUE
;
1125 cmdres
= lookup_vte(s
, __func__
, ite
.vpeid
, &old_vte
);
1126 if (cmdres
!= CMD_CONTINUE_OK
) {
1129 cmdres
= lookup_vte(s
, __func__
, vpeid
, &new_vte
);
1130 if (cmdres
!= CMD_CONTINUE_OK
) {
1134 if (!intid_in_lpi_range(ite
.intid
) ||
1135 ite
.intid
>= (1ULL << (old_vte
.vptsize
+ 1)) ||
1136 ite
.intid
>= (1ULL << (new_vte
.vptsize
+ 1))) {
1137 qemu_log_mask(LOG_GUEST_ERROR
,
1138 "%s: ITE intid 0x%x out of range\n",
1139 __func__
, ite
.intid
);
1140 return CMD_CONTINUE
;
1144 if (doorbell_valid
) {
1145 ite
.doorbell
= doorbell
;
1149 * Move the LPI from the old redistributor to the new one. We don't
1150 * need to do anything if the guest somehow specified the
1151 * same pending table for source and destination.
1153 if (old_vte
.vptaddr
!= new_vte
.vptaddr
) {
1154 gicv3_redist_mov_vlpi(&s
->gicv3
->cpu
[old_vte
.rdbase
],
1155 old_vte
.vptaddr
<< 16,
1156 &s
->gicv3
->cpu
[new_vte
.rdbase
],
1157 new_vte
.vptaddr
<< 16,
1162 /* Update the ITE to the new VPEID and possibly doorbell values */
1163 return update_ite(s
, eventid
, &dte
, &ite
) ? CMD_CONTINUE_OK
: CMD_STALL
;
1166 static ItsCmdResult
process_vinvall(GICv3ITSState
*s
, const uint64_t *cmdpkt
)
1170 ItsCmdResult cmdres
;
1172 if (!its_feature_virtual(s
)) {
1173 return CMD_CONTINUE
;
1176 vpeid
= FIELD_EX64(cmdpkt
[1], VINVALL_1
, VPEID
);
1178 trace_gicv3_its_cmd_vinvall(vpeid
);
1180 cmdres
= lookup_vte(s
, __func__
, vpeid
, &vte
);
1181 if (cmdres
!= CMD_CONTINUE_OK
) {
1185 gicv3_redist_vinvall(&s
->gicv3
->cpu
[vte
.rdbase
], vte
.vptaddr
<< 16);
1186 return CMD_CONTINUE_OK
;
1189 static ItsCmdResult
process_inv(GICv3ITSState
*s
, const uint64_t *cmdpkt
)
1191 uint32_t devid
, eventid
;
1196 ItsCmdResult cmdres
;
1198 devid
= FIELD_EX64(cmdpkt
[0], INV_0
, DEVICEID
);
1199 eventid
= FIELD_EX64(cmdpkt
[1], INV_1
, EVENTID
);
1201 trace_gicv3_its_cmd_inv(devid
, eventid
);
1203 cmdres
= lookup_ite(s
, __func__
, devid
, eventid
, &ite
, &dte
);
1204 if (cmdres
!= CMD_CONTINUE_OK
) {
1208 switch (ite
.inttype
) {
1209 case ITE_INTTYPE_PHYSICAL
:
1210 cmdres
= lookup_cte(s
, __func__
, ite
.icid
, &cte
);
1211 if (cmdres
!= CMD_CONTINUE_OK
) {
1214 gicv3_redist_inv_lpi(&s
->gicv3
->cpu
[cte
.rdbase
], ite
.intid
);
1216 case ITE_INTTYPE_VIRTUAL
:
1217 if (!its_feature_virtual(s
)) {
1218 /* Can't happen unless guest is illegally writing to table memory */
1219 qemu_log_mask(LOG_GUEST_ERROR
,
1220 "%s: invalid type %d in ITE (table corrupted?)\n",
1221 __func__
, ite
.inttype
);
1222 return CMD_CONTINUE
;
1225 cmdres
= lookup_vte(s
, __func__
, ite
.vpeid
, &vte
);
1226 if (cmdres
!= CMD_CONTINUE_OK
) {
1229 if (!intid_in_lpi_range(ite
.intid
) ||
1230 ite
.intid
>= (1ULL << (vte
.vptsize
+ 1))) {
1231 qemu_log_mask(LOG_GUEST_ERROR
, "%s: intid 0x%x out of range\n",
1232 __func__
, ite
.intid
);
1233 return CMD_CONTINUE
;
1235 gicv3_redist_inv_vlpi(&s
->gicv3
->cpu
[vte
.rdbase
], ite
.intid
,
1239 g_assert_not_reached();
1242 return CMD_CONTINUE_OK
;
1246 * Current implementation blocks until all
1247 * commands are processed
1249 static void process_cmdq(GICv3ITSState
*s
)
1251 uint32_t wr_offset
= 0;
1252 uint32_t rd_offset
= 0;
1253 uint32_t cq_offset
= 0;
1254 AddressSpace
*as
= &s
->gicv3
->dma_as
;
1258 if (!(s
->ctlr
& R_GITS_CTLR_ENABLED_MASK
)) {
1262 wr_offset
= FIELD_EX64(s
->cwriter
, GITS_CWRITER
, OFFSET
);
1264 if (wr_offset
>= s
->cq
.num_entries
) {
1265 qemu_log_mask(LOG_GUEST_ERROR
,
1266 "%s: invalid write offset "
1267 "%d\n", __func__
, wr_offset
);
1271 rd_offset
= FIELD_EX64(s
->creadr
, GITS_CREADR
, OFFSET
);
1273 if (rd_offset
>= s
->cq
.num_entries
) {
1274 qemu_log_mask(LOG_GUEST_ERROR
,
1275 "%s: invalid read offset "
1276 "%d\n", __func__
, rd_offset
);
1280 while (wr_offset
!= rd_offset
) {
1281 ItsCmdResult result
= CMD_CONTINUE_OK
;
1284 uint64_t cmdpkt
[GITS_CMDQ_ENTRY_WORDS
];
1286 cq_offset
= (rd_offset
* GITS_CMDQ_ENTRY_SIZE
);
1288 buflen
= GITS_CMDQ_ENTRY_SIZE
;
1289 hostmem
= address_space_map(as
, s
->cq
.base_addr
+ cq_offset
,
1290 &buflen
, false, MEMTXATTRS_UNSPECIFIED
);
1291 if (!hostmem
|| buflen
!= GITS_CMDQ_ENTRY_SIZE
) {
1293 address_space_unmap(as
, hostmem
, buflen
, false, 0);
1295 s
->creadr
= FIELD_DP64(s
->creadr
, GITS_CREADR
, STALLED
, 1);
1296 qemu_log_mask(LOG_GUEST_ERROR
,
1297 "%s: could not read command at 0x%" PRIx64
"\n",
1298 __func__
, s
->cq
.base_addr
+ cq_offset
);
1301 for (i
= 0; i
< ARRAY_SIZE(cmdpkt
); i
++) {
1302 cmdpkt
[i
] = ldq_le_p(hostmem
+ i
* sizeof(uint64_t));
1304 address_space_unmap(as
, hostmem
, buflen
, false, 0);
1306 cmd
= cmdpkt
[0] & CMD_MASK
;
1308 trace_gicv3_its_process_command(rd_offset
, cmd
);
1312 result
= process_its_cmd(s
, cmdpkt
, INTERRUPT
);
1314 case GITS_CMD_CLEAR
:
1315 result
= process_its_cmd(s
, cmdpkt
, CLEAR
);
1319 * Current implementation makes a blocking synchronous call
1320 * for every command issued earlier, hence the internal state
1321 * is already consistent by the time SYNC command is executed.
1322 * Hence no further processing is required for SYNC command.
1324 trace_gicv3_its_cmd_sync();
1326 case GITS_CMD_VSYNC
:
1328 * VSYNC also is a nop, because our implementation is always
1331 if (!its_feature_virtual(s
)) {
1332 result
= CMD_CONTINUE
;
1335 trace_gicv3_its_cmd_vsync();
1338 result
= process_mapd(s
, cmdpkt
);
1341 result
= process_mapc(s
, cmdpkt
);
1343 case GITS_CMD_MAPTI
:
1344 result
= process_mapti(s
, cmdpkt
, false);
1347 result
= process_mapti(s
, cmdpkt
, true);
1349 case GITS_CMD_DISCARD
:
1350 result
= process_its_cmd(s
, cmdpkt
, DISCARD
);
1353 result
= process_inv(s
, cmdpkt
);
1355 case GITS_CMD_INVALL
:
1357 * Current implementation doesn't cache any ITS tables,
1358 * but the calculated lpi priority information. We only
1359 * need to trigger lpi priority re-calculation to be in
1360 * sync with LPI config table or pending table changes.
1361 * INVALL operates on a collection specified by ICID so
1362 * it only affects physical LPIs.
1364 trace_gicv3_its_cmd_invall();
1365 for (i
= 0; i
< s
->gicv3
->num_cpu
; i
++) {
1366 gicv3_redist_update_lpi(&s
->gicv3
->cpu
[i
]);
1370 result
= process_movi(s
, cmdpkt
);
1372 case GITS_CMD_MOVALL
:
1373 result
= process_movall(s
, cmdpkt
);
1375 case GITS_CMD_VMAPTI
:
1376 result
= process_vmapti(s
, cmdpkt
, false);
1378 case GITS_CMD_VMAPI
:
1379 result
= process_vmapti(s
, cmdpkt
, true);
1381 case GITS_CMD_VMAPP
:
1382 result
= process_vmapp(s
, cmdpkt
);
1384 case GITS_CMD_VMOVP
:
1385 result
= process_vmovp(s
, cmdpkt
);
1387 case GITS_CMD_VMOVI
:
1388 result
= process_vmovi(s
, cmdpkt
);
1390 case GITS_CMD_VINVALL
:
1391 result
= process_vinvall(s
, cmdpkt
);
1394 trace_gicv3_its_cmd_unknown(cmd
);
1397 if (result
!= CMD_STALL
) {
1398 /* CMD_CONTINUE or CMD_CONTINUE_OK */
1400 rd_offset
%= s
->cq
.num_entries
;
1401 s
->creadr
= FIELD_DP64(s
->creadr
, GITS_CREADR
, OFFSET
, rd_offset
);
1404 s
->creadr
= FIELD_DP64(s
->creadr
, GITS_CREADR
, STALLED
, 1);
1405 qemu_log_mask(LOG_GUEST_ERROR
,
1406 "%s: 0x%x cmd processing failed, stalling\n",
1414 * This function extracts the ITS Device and Collection table specific
1415 * parameters (like base_addr, size etc) from GITS_BASER register.
1416 * It is called during ITS enable and also during post_load migration
1418 static void extract_table_params(GICv3ITSState
*s
)
1420 uint16_t num_pages
= 0;
1421 uint8_t page_sz_type
;
1423 uint32_t page_sz
= 0;
1426 for (int i
= 0; i
< 8; i
++) {
1430 value
= s
->baser
[i
];
1436 page_sz_type
= FIELD_EX64(value
, GITS_BASER
, PAGESIZE
);
1438 switch (page_sz_type
) {
1440 page_sz
= GITS_PAGE_SIZE_4K
;
1444 page_sz
= GITS_PAGE_SIZE_16K
;
1449 page_sz
= GITS_PAGE_SIZE_64K
;
1453 g_assert_not_reached();
1456 num_pages
= FIELD_EX64(value
, GITS_BASER
, SIZE
) + 1;
1458 type
= FIELD_EX64(value
, GITS_BASER
, TYPE
);
1461 case GITS_BASER_TYPE_DEVICE
:
1463 idbits
= FIELD_EX64(s
->typer
, GITS_TYPER
, DEVBITS
) + 1;
1465 case GITS_BASER_TYPE_COLLECTION
:
1467 if (FIELD_EX64(s
->typer
, GITS_TYPER
, CIL
)) {
1468 idbits
= FIELD_EX64(s
->typer
, GITS_TYPER
, CIDBITS
) + 1;
1470 /* 16-bit CollectionId supported when CIL == 0 */
1474 case GITS_BASER_TYPE_VPE
:
1477 * For QEMU vPEIDs are always 16 bits. (GICv4.1 allows an
1478 * implementation to implement fewer bits and report this
1485 * GITS_BASER<n>.TYPE is read-only, so GITS_BASER_RO_MASK
1486 * ensures we will only see type values corresponding to
1487 * the values set up in gicv3_its_reset().
1489 g_assert_not_reached();
1492 memset(td
, 0, sizeof(*td
));
1494 * If GITS_BASER<n>.Valid is 0 for any <n> then we will not process
1495 * interrupts. (GITS_TYPER.HCC is 0 for this implementation, so we
1496 * do not have a special case where the GITS_BASER<n>.Valid bit is 0
1497 * for the register corresponding to the Collection table but we
1498 * still have to process interrupts using non-memory-backed
1499 * Collection table entries.)
1500 * The specification makes it UNPREDICTABLE to enable the ITS without
1501 * marking each BASER<n> as valid. We choose to handle these as if
1502 * the table was zero-sized, so commands using the table will fail
1503 * and interrupts requested via GITS_TRANSLATER writes will be ignored.
1504 * This happens automatically by leaving the num_entries field at
1505 * zero, which will be caught by the bounds checks we have before
1506 * every table lookup anyway.
1508 if (!FIELD_EX64(value
, GITS_BASER
, VALID
)) {
1511 td
->page_sz
= page_sz
;
1512 td
->indirect
= FIELD_EX64(value
, GITS_BASER
, INDIRECT
);
1513 td
->entry_sz
= FIELD_EX64(value
, GITS_BASER
, ENTRYSIZE
) + 1;
1514 td
->base_addr
= baser_base_addr(value
, page_sz
);
1515 if (!td
->indirect
) {
1516 td
->num_entries
= (num_pages
* page_sz
) / td
->entry_sz
;
1518 td
->num_entries
= (((num_pages
* page_sz
) /
1519 L1TABLE_ENTRY_SIZE
) *
1520 (page_sz
/ td
->entry_sz
));
1522 td
->num_entries
= MIN(td
->num_entries
, 1ULL << idbits
);
1526 static void extract_cmdq_params(GICv3ITSState
*s
)
1528 uint16_t num_pages
= 0;
1529 uint64_t value
= s
->cbaser
;
1531 num_pages
= FIELD_EX64(value
, GITS_CBASER
, SIZE
) + 1;
1533 memset(&s
->cq
, 0 , sizeof(s
->cq
));
1535 if (FIELD_EX64(value
, GITS_CBASER
, VALID
)) {
1536 s
->cq
.num_entries
= (num_pages
* GITS_PAGE_SIZE_4K
) /
1537 GITS_CMDQ_ENTRY_SIZE
;
1538 s
->cq
.base_addr
= FIELD_EX64(value
, GITS_CBASER
, PHYADDR
);
1539 s
->cq
.base_addr
<<= R_GITS_CBASER_PHYADDR_SHIFT
;
1543 static MemTxResult
gicv3_its_translation_read(void *opaque
, hwaddr offset
,
1544 uint64_t *data
, unsigned size
,
1548 * GITS_TRANSLATER is write-only, and all other addresses
1549 * in the interrupt translation space frame are RES0.
1555 static MemTxResult
gicv3_its_translation_write(void *opaque
, hwaddr offset
,
1556 uint64_t data
, unsigned size
,
1559 GICv3ITSState
*s
= (GICv3ITSState
*)opaque
;
1562 trace_gicv3_its_translation_write(offset
, data
, size
, attrs
.requester_id
);
1565 case GITS_TRANSLATER
:
1566 if (s
->ctlr
& R_GITS_CTLR_ENABLED_MASK
) {
1567 result
= do_process_its_cmd(s
, attrs
.requester_id
, data
, NONE
);
1581 static bool its_writel(GICv3ITSState
*s
, hwaddr offset
,
1582 uint64_t value
, MemTxAttrs attrs
)
1589 if (value
& R_GITS_CTLR_ENABLED_MASK
) {
1590 s
->ctlr
|= R_GITS_CTLR_ENABLED_MASK
;
1591 extract_table_params(s
);
1592 extract_cmdq_params(s
);
1595 s
->ctlr
&= ~R_GITS_CTLR_ENABLED_MASK
;
1600 * IMPDEF choice:- GITS_CBASER register becomes RO if ITS is
1603 if (!(s
->ctlr
& R_GITS_CTLR_ENABLED_MASK
)) {
1604 s
->cbaser
= deposit64(s
->cbaser
, 0, 32, value
);
1608 case GITS_CBASER
+ 4:
1610 * IMPDEF choice:- GITS_CBASER register becomes RO if ITS is
1613 if (!(s
->ctlr
& R_GITS_CTLR_ENABLED_MASK
)) {
1614 s
->cbaser
= deposit64(s
->cbaser
, 32, 32, value
);
1619 s
->cwriter
= deposit64(s
->cwriter
, 0, 32,
1620 (value
& ~R_GITS_CWRITER_RETRY_MASK
));
1621 if (s
->cwriter
!= s
->creadr
) {
1625 case GITS_CWRITER
+ 4:
1626 s
->cwriter
= deposit64(s
->cwriter
, 32, 32, value
);
1629 if (s
->gicv3
->gicd_ctlr
& GICD_CTLR_DS
) {
1630 s
->creadr
= deposit64(s
->creadr
, 0, 32,
1631 (value
& ~R_GITS_CREADR_STALLED_MASK
));
1633 /* RO register, ignore the write */
1634 qemu_log_mask(LOG_GUEST_ERROR
,
1635 "%s: invalid guest write to RO register at offset "
1636 HWADDR_FMT_plx
"\n", __func__
, offset
);
1639 case GITS_CREADR
+ 4:
1640 if (s
->gicv3
->gicd_ctlr
& GICD_CTLR_DS
) {
1641 s
->creadr
= deposit64(s
->creadr
, 32, 32, value
);
1643 /* RO register, ignore the write */
1644 qemu_log_mask(LOG_GUEST_ERROR
,
1645 "%s: invalid guest write to RO register at offset "
1646 HWADDR_FMT_plx
"\n", __func__
, offset
);
1649 case GITS_BASER
... GITS_BASER
+ 0x3f:
1651 * IMPDEF choice:- GITS_BASERn register becomes RO if ITS is
1654 if (!(s
->ctlr
& R_GITS_CTLR_ENABLED_MASK
)) {
1655 index
= (offset
- GITS_BASER
) / 8;
1657 if (s
->baser
[index
] == 0) {
1658 /* Unimplemented GITS_BASERn: RAZ/WI */
1663 value
&= ~GITS_BASER_RO_MASK
;
1664 s
->baser
[index
] &= GITS_BASER_RO_MASK
| MAKE_64BIT_MASK(0, 32);
1665 s
->baser
[index
] |= value
;
1667 value
&= ~GITS_BASER_RO_MASK
;
1668 s
->baser
[index
] &= GITS_BASER_RO_MASK
| MAKE_64BIT_MASK(32, 32);
1669 s
->baser
[index
] |= value
;
1674 case GITS_IDREGS
... GITS_IDREGS
+ 0x2f:
1675 /* RO registers, ignore the write */
1676 qemu_log_mask(LOG_GUEST_ERROR
,
1677 "%s: invalid guest write to RO register at offset "
1678 HWADDR_FMT_plx
"\n", __func__
, offset
);
1687 static bool its_readl(GICv3ITSState
*s
, hwaddr offset
,
1688 uint64_t *data
, MemTxAttrs attrs
)
1698 *data
= gicv3_iidr();
1700 case GITS_IDREGS
... GITS_IDREGS
+ 0x2f:
1702 *data
= gicv3_idreg(s
->gicv3
, offset
- GITS_IDREGS
, GICV3_PIDR0_ITS
);
1705 *data
= extract64(s
->typer
, 0, 32);
1707 case GITS_TYPER
+ 4:
1708 *data
= extract64(s
->typer
, 32, 32);
1711 *data
= extract64(s
->cbaser
, 0, 32);
1713 case GITS_CBASER
+ 4:
1714 *data
= extract64(s
->cbaser
, 32, 32);
1717 *data
= extract64(s
->creadr
, 0, 32);
1719 case GITS_CREADR
+ 4:
1720 *data
= extract64(s
->creadr
, 32, 32);
1723 *data
= extract64(s
->cwriter
, 0, 32);
1725 case GITS_CWRITER
+ 4:
1726 *data
= extract64(s
->cwriter
, 32, 32);
1728 case GITS_BASER
... GITS_BASER
+ 0x3f:
1729 index
= (offset
- GITS_BASER
) / 8;
1731 *data
= extract64(s
->baser
[index
], 32, 32);
1733 *data
= extract64(s
->baser
[index
], 0, 32);
1743 static bool its_writell(GICv3ITSState
*s
, hwaddr offset
,
1744 uint64_t value
, MemTxAttrs attrs
)
1750 case GITS_BASER
... GITS_BASER
+ 0x3f:
1752 * IMPDEF choice:- GITS_BASERn register becomes RO if ITS is
1755 if (!(s
->ctlr
& R_GITS_CTLR_ENABLED_MASK
)) {
1756 index
= (offset
- GITS_BASER
) / 8;
1757 if (s
->baser
[index
] == 0) {
1758 /* Unimplemented GITS_BASERn: RAZ/WI */
1761 s
->baser
[index
] &= GITS_BASER_RO_MASK
;
1762 s
->baser
[index
] |= (value
& ~GITS_BASER_RO_MASK
);
1767 * IMPDEF choice:- GITS_CBASER register becomes RO if ITS is
1770 if (!(s
->ctlr
& R_GITS_CTLR_ENABLED_MASK
)) {
1776 s
->cwriter
= value
& ~R_GITS_CWRITER_RETRY_MASK
;
1777 if (s
->cwriter
!= s
->creadr
) {
1782 if (s
->gicv3
->gicd_ctlr
& GICD_CTLR_DS
) {
1783 s
->creadr
= value
& ~R_GITS_CREADR_STALLED_MASK
;
1785 /* RO register, ignore the write */
1786 qemu_log_mask(LOG_GUEST_ERROR
,
1787 "%s: invalid guest write to RO register at offset "
1788 HWADDR_FMT_plx
"\n", __func__
, offset
);
1792 /* RO registers, ignore the write */
1793 qemu_log_mask(LOG_GUEST_ERROR
,
1794 "%s: invalid guest write to RO register at offset "
1795 HWADDR_FMT_plx
"\n", __func__
, offset
);
1804 static bool its_readll(GICv3ITSState
*s
, hwaddr offset
,
1805 uint64_t *data
, MemTxAttrs attrs
)
1814 case GITS_BASER
... GITS_BASER
+ 0x3f:
1815 index
= (offset
- GITS_BASER
) / 8;
1816 *data
= s
->baser
[index
];
1834 static MemTxResult
gicv3_its_read(void *opaque
, hwaddr offset
, uint64_t *data
,
1835 unsigned size
, MemTxAttrs attrs
)
1837 GICv3ITSState
*s
= (GICv3ITSState
*)opaque
;
1842 result
= its_readl(s
, offset
, data
, attrs
);
1845 result
= its_readll(s
, offset
, data
, attrs
);
1853 qemu_log_mask(LOG_GUEST_ERROR
,
1854 "%s: invalid guest read at offset " HWADDR_FMT_plx
1855 " size %u\n", __func__
, offset
, size
);
1856 trace_gicv3_its_badread(offset
, size
);
1858 * The spec requires that reserved registers are RAZ/WI;
1859 * so use false returns from leaf functions as a way to
1860 * trigger the guest-error logging but don't return it to
1861 * the caller, or we'll cause a spurious guest data abort.
1865 trace_gicv3_its_read(offset
, *data
, size
);
1870 static MemTxResult
gicv3_its_write(void *opaque
, hwaddr offset
, uint64_t data
,
1871 unsigned size
, MemTxAttrs attrs
)
1873 GICv3ITSState
*s
= (GICv3ITSState
*)opaque
;
1878 result
= its_writel(s
, offset
, data
, attrs
);
1881 result
= its_writell(s
, offset
, data
, attrs
);
1889 qemu_log_mask(LOG_GUEST_ERROR
,
1890 "%s: invalid guest write at offset " HWADDR_FMT_plx
1891 " size %u\n", __func__
, offset
, size
);
1892 trace_gicv3_its_badwrite(offset
, data
, size
);
1894 * The spec requires that reserved registers are RAZ/WI;
1895 * so use false returns from leaf functions as a way to
1896 * trigger the guest-error logging but don't return it to
1897 * the caller, or we'll cause a spurious guest data abort.
1900 trace_gicv3_its_write(offset
, data
, size
);
1905 static const MemoryRegionOps gicv3_its_control_ops
= {
1906 .read_with_attrs
= gicv3_its_read
,
1907 .write_with_attrs
= gicv3_its_write
,
1908 .valid
.min_access_size
= 4,
1909 .valid
.max_access_size
= 8,
1910 .impl
.min_access_size
= 4,
1911 .impl
.max_access_size
= 8,
1912 .endianness
= DEVICE_NATIVE_ENDIAN
,
1915 static const MemoryRegionOps gicv3_its_translation_ops
= {
1916 .read_with_attrs
= gicv3_its_translation_read
,
1917 .write_with_attrs
= gicv3_its_translation_write
,
1918 .valid
.min_access_size
= 2,
1919 .valid
.max_access_size
= 4,
1920 .impl
.min_access_size
= 2,
1921 .impl
.max_access_size
= 4,
1922 .endianness
= DEVICE_NATIVE_ENDIAN
,
1925 static void gicv3_arm_its_realize(DeviceState
*dev
, Error
**errp
)
1927 GICv3ITSState
*s
= ARM_GICV3_ITS_COMMON(dev
);
1930 for (i
= 0; i
< s
->gicv3
->num_cpu
; i
++) {
1931 if (!(s
->gicv3
->cpu
[i
].gicr_typer
& GICR_TYPER_PLPIS
)) {
1932 error_setg(errp
, "Physical LPI not supported by CPU %d", i
);
1937 gicv3_add_its(s
->gicv3
, dev
);
1939 gicv3_its_init_mmio(s
, &gicv3_its_control_ops
, &gicv3_its_translation_ops
);
1941 /* set the ITS default features supported */
1942 s
->typer
= FIELD_DP64(s
->typer
, GITS_TYPER
, PHYSICAL
, 1);
1943 s
->typer
= FIELD_DP64(s
->typer
, GITS_TYPER
, ITT_ENTRY_SIZE
,
1944 ITS_ITT_ENTRY_SIZE
- 1);
1945 s
->typer
= FIELD_DP64(s
->typer
, GITS_TYPER
, IDBITS
, ITS_IDBITS
);
1946 s
->typer
= FIELD_DP64(s
->typer
, GITS_TYPER
, DEVBITS
, ITS_DEVBITS
);
1947 s
->typer
= FIELD_DP64(s
->typer
, GITS_TYPER
, CIL
, 1);
1948 s
->typer
= FIELD_DP64(s
->typer
, GITS_TYPER
, CIDBITS
, ITS_CIDBITS
);
1949 if (s
->gicv3
->revision
>= 4) {
1950 /* Our VMOVP handles cross-ITS synchronization itself */
1951 s
->typer
= FIELD_DP64(s
->typer
, GITS_TYPER
, VMOVP
, 1);
1952 s
->typer
= FIELD_DP64(s
->typer
, GITS_TYPER
, VIRTUAL
, 1);
1956 static void gicv3_its_reset_hold(Object
*obj
)
1958 GICv3ITSState
*s
= ARM_GICV3_ITS_COMMON(obj
);
1959 GICv3ITSClass
*c
= ARM_GICV3_ITS_GET_CLASS(s
);
1961 if (c
->parent_phases
.hold
) {
1962 c
->parent_phases
.hold(obj
);
1965 /* Quiescent bit reset to 1 */
1966 s
->ctlr
= FIELD_DP32(s
->ctlr
, GITS_CTLR
, QUIESCENT
, 1);
1969 * setting GITS_BASER0.Type = 0b001 (Device)
1970 * GITS_BASER1.Type = 0b100 (Collection Table)
1971 * GITS_BASER2.Type = 0b010 (vPE) for GICv4 and later
1972 * GITS_BASER<n>.Type,where n = 3 to 7 are 0b00 (Unimplemented)
1973 * GITS_BASER<0,1>.Page_Size = 64KB
1974 * and default translation table entry size to 16 bytes
1976 s
->baser
[0] = FIELD_DP64(s
->baser
[0], GITS_BASER
, TYPE
,
1977 GITS_BASER_TYPE_DEVICE
);
1978 s
->baser
[0] = FIELD_DP64(s
->baser
[0], GITS_BASER
, PAGESIZE
,
1979 GITS_BASER_PAGESIZE_64K
);
1980 s
->baser
[0] = FIELD_DP64(s
->baser
[0], GITS_BASER
, ENTRYSIZE
,
1983 s
->baser
[1] = FIELD_DP64(s
->baser
[1], GITS_BASER
, TYPE
,
1984 GITS_BASER_TYPE_COLLECTION
);
1985 s
->baser
[1] = FIELD_DP64(s
->baser
[1], GITS_BASER
, PAGESIZE
,
1986 GITS_BASER_PAGESIZE_64K
);
1987 s
->baser
[1] = FIELD_DP64(s
->baser
[1], GITS_BASER
, ENTRYSIZE
,
1990 if (its_feature_virtual(s
)) {
1991 s
->baser
[2] = FIELD_DP64(s
->baser
[2], GITS_BASER
, TYPE
,
1992 GITS_BASER_TYPE_VPE
);
1993 s
->baser
[2] = FIELD_DP64(s
->baser
[2], GITS_BASER
, PAGESIZE
,
1994 GITS_BASER_PAGESIZE_64K
);
1995 s
->baser
[2] = FIELD_DP64(s
->baser
[2], GITS_BASER
, ENTRYSIZE
,
2000 static void gicv3_its_post_load(GICv3ITSState
*s
)
2002 if (s
->ctlr
& R_GITS_CTLR_ENABLED_MASK
) {
2003 extract_table_params(s
);
2004 extract_cmdq_params(s
);
2008 static Property gicv3_its_props
[] = {
2009 DEFINE_PROP_LINK("parent-gicv3", GICv3ITSState
, gicv3
, "arm-gicv3",
2011 DEFINE_PROP_END_OF_LIST(),
2014 static void gicv3_its_class_init(ObjectClass
*klass
, void *data
)
2016 DeviceClass
*dc
= DEVICE_CLASS(klass
);
2017 ResettableClass
*rc
= RESETTABLE_CLASS(klass
);
2018 GICv3ITSClass
*ic
= ARM_GICV3_ITS_CLASS(klass
);
2019 GICv3ITSCommonClass
*icc
= ARM_GICV3_ITS_COMMON_CLASS(klass
);
2021 dc
->realize
= gicv3_arm_its_realize
;
2022 device_class_set_props(dc
, gicv3_its_props
);
2023 resettable_class_set_parent_phases(rc
, NULL
, gicv3_its_reset_hold
, NULL
,
2024 &ic
->parent_phases
);
2025 icc
->post_load
= gicv3_its_post_load
;
2028 static const TypeInfo gicv3_its_info
= {
2029 .name
= TYPE_ARM_GICV3_ITS
,
2030 .parent
= TYPE_ARM_GICV3_ITS_COMMON
,
2031 .instance_size
= sizeof(GICv3ITSState
),
2032 .class_init
= gicv3_its_class_init
,
2033 .class_size
= sizeof(GICv3ITSClass
),
2036 static void gicv3_its_register_types(void)
2038 type_register_static(&gicv3_its_info
);
2041 type_init(gicv3_its_register_types
)