Merge tag 'pull-loongarch-20241016' of https://gitlab.com/gaosong/qemu into staging
[qemu/armbru.git] / hw / intc / arm_gic.c
blob2a48f0da2fe18eca06d45d0de81713174b787f84
1 /*
2 * ARM Generic/Distributed Interrupt Controller
4 * Copyright (c) 2006-2007 CodeSourcery.
5 * Written by Paul Brook
7 * This code is licensed under the GPL.
8 */
10 /* This file contains implementation code for the RealView EB interrupt
11 * controller, MPCore distributed interrupt controller and ARMv7-M
12 * Nested Vectored Interrupt Controller.
13 * It is compiled in two ways:
14 * (1) as a standalone file to produce a sysbus device which is a GIC
15 * that can be used on the realview board and as one of the builtin
16 * private peripherals for the ARM MP CPUs (11MPCore, A9, etc)
17 * (2) by being directly #included into armv7m_nvic.c to produce the
18 * armv7m_nvic device.
21 #include "qemu/osdep.h"
22 #include "hw/irq.h"
23 #include "hw/sysbus.h"
24 #include "gic_internal.h"
25 #include "qapi/error.h"
26 #include "hw/core/cpu.h"
27 #include "qemu/log.h"
28 #include "qemu/module.h"
29 #include "trace.h"
30 #include "sysemu/kvm.h"
31 #include "sysemu/qtest.h"
33 /* #define DEBUG_GIC */
35 #ifdef DEBUG_GIC
36 #define DEBUG_GIC_GATE 1
37 #else
38 #define DEBUG_GIC_GATE 0
39 #endif
41 #define DPRINTF(fmt, ...) do { \
42 if (DEBUG_GIC_GATE) { \
43 fprintf(stderr, "%s: " fmt, __func__, ## __VA_ARGS__); \
44 } \
45 } while (0)
47 static const uint8_t gic_id_11mpcore[] = {
48 0x00, 0x00, 0x00, 0x00, 0x90, 0x13, 0x04, 0x00, 0x0d, 0xf0, 0x05, 0xb1
51 static const uint8_t gic_id_gicv1[] = {
52 0x04, 0x00, 0x00, 0x00, 0x90, 0xb3, 0x1b, 0x00, 0x0d, 0xf0, 0x05, 0xb1
55 static const uint8_t gic_id_gicv2[] = {
56 0x04, 0x00, 0x00, 0x00, 0x90, 0xb4, 0x2b, 0x00, 0x0d, 0xf0, 0x05, 0xb1
59 static inline int gic_get_current_cpu(GICState *s)
61 if (!qtest_enabled() && s->num_cpu > 1) {
62 return current_cpu->cpu_index;
64 return 0;
67 static inline int gic_get_current_vcpu(GICState *s)
69 return gic_get_current_cpu(s) + GIC_NCPU;
72 /* Return true if this GIC config has interrupt groups, which is
73 * true if we're a GICv2, or a GICv1 with the security extensions.
75 static inline bool gic_has_groups(GICState *s)
77 return s->revision == 2 || s->security_extn;
80 static inline bool gic_cpu_ns_access(GICState *s, int cpu, MemTxAttrs attrs)
82 return !gic_is_vcpu(cpu) && s->security_extn && !attrs.secure;
85 static inline void gic_get_best_irq(GICState *s, int cpu,
86 int *best_irq, int *best_prio, int *group)
88 int irq;
89 int cm = 1 << cpu;
91 *best_irq = 1023;
92 *best_prio = 0x100;
94 for (irq = 0; irq < s->num_irq; irq++) {
95 if (GIC_DIST_TEST_ENABLED(irq, cm) && gic_test_pending(s, irq, cm) &&
96 (!GIC_DIST_TEST_ACTIVE(irq, cm)) &&
97 (irq < GIC_INTERNAL || GIC_DIST_TARGET(irq) & cm)) {
98 if (GIC_DIST_GET_PRIORITY(irq, cpu) < *best_prio) {
99 *best_prio = GIC_DIST_GET_PRIORITY(irq, cpu);
100 *best_irq = irq;
105 if (*best_irq < 1023) {
106 *group = GIC_DIST_TEST_GROUP(*best_irq, cm);
110 static inline void gic_get_best_virq(GICState *s, int cpu,
111 int *best_irq, int *best_prio, int *group)
113 int lr_idx = 0;
115 *best_irq = 1023;
116 *best_prio = 0x100;
118 for (lr_idx = 0; lr_idx < s->num_lrs; lr_idx++) {
119 uint32_t lr_entry = s->h_lr[lr_idx][cpu];
120 int state = GICH_LR_STATE(lr_entry);
122 if (state == GICH_LR_STATE_PENDING) {
123 int prio = GICH_LR_PRIORITY(lr_entry);
125 if (prio < *best_prio) {
126 *best_prio = prio;
127 *best_irq = GICH_LR_VIRT_ID(lr_entry);
128 *group = GICH_LR_GROUP(lr_entry);
134 /* Return true if IRQ signaling is enabled for the given cpu and at least one
135 * of the given groups:
136 * - in the non-virt case, the distributor must be enabled for one of the
137 * given groups
138 * - in the virt case, the virtual interface must be enabled.
139 * - in all cases, the (v)CPU interface must be enabled for one of the given
140 * groups.
142 static inline bool gic_irq_signaling_enabled(GICState *s, int cpu, bool virt,
143 int group_mask)
145 int cpu_iface = virt ? (cpu + GIC_NCPU) : cpu;
147 if (!virt && !(s->ctlr & group_mask)) {
148 return false;
151 if (virt && !(s->h_hcr[cpu] & R_GICH_HCR_EN_MASK)) {
152 return false;
155 if (!(s->cpu_ctlr[cpu_iface] & group_mask)) {
156 return false;
159 return true;
162 /* TODO: Many places that call this routine could be optimized. */
163 /* Update interrupt status after enabled or pending bits have been changed. */
164 static inline void gic_update_internal(GICState *s, bool virt)
166 int best_irq;
167 int best_prio;
168 int irq_level, fiq_level;
169 int cpu, cpu_iface;
170 int group = 0;
171 qemu_irq *irq_lines = virt ? s->parent_virq : s->parent_irq;
172 qemu_irq *fiq_lines = virt ? s->parent_vfiq : s->parent_fiq;
174 for (cpu = 0; cpu < s->num_cpu; cpu++) {
175 cpu_iface = virt ? (cpu + GIC_NCPU) : cpu;
177 s->current_pending[cpu_iface] = 1023;
178 if (!gic_irq_signaling_enabled(s, cpu, virt,
179 GICD_CTLR_EN_GRP0 | GICD_CTLR_EN_GRP1)) {
180 qemu_irq_lower(irq_lines[cpu]);
181 qemu_irq_lower(fiq_lines[cpu]);
182 continue;
185 if (virt) {
186 gic_get_best_virq(s, cpu, &best_irq, &best_prio, &group);
187 } else {
188 gic_get_best_irq(s, cpu, &best_irq, &best_prio, &group);
191 if (best_irq != 1023) {
192 trace_gic_update_bestirq(virt ? "vcpu" : "cpu", cpu,
193 best_irq, best_prio,
194 s->priority_mask[cpu_iface],
195 s->running_priority[cpu_iface]);
198 irq_level = fiq_level = 0;
200 if (best_prio < s->priority_mask[cpu_iface]) {
201 s->current_pending[cpu_iface] = best_irq;
202 if (best_prio < s->running_priority[cpu_iface]) {
203 if (gic_irq_signaling_enabled(s, cpu, virt, 1 << group)) {
204 if (group == 0 &&
205 s->cpu_ctlr[cpu_iface] & GICC_CTLR_FIQ_EN) {
206 DPRINTF("Raised pending FIQ %d (cpu %d)\n",
207 best_irq, cpu_iface);
208 fiq_level = 1;
209 trace_gic_update_set_irq(cpu, virt ? "vfiq" : "fiq",
210 fiq_level);
211 } else {
212 DPRINTF("Raised pending IRQ %d (cpu %d)\n",
213 best_irq, cpu_iface);
214 irq_level = 1;
215 trace_gic_update_set_irq(cpu, virt ? "virq" : "irq",
216 irq_level);
222 qemu_set_irq(irq_lines[cpu], irq_level);
223 qemu_set_irq(fiq_lines[cpu], fiq_level);
227 static void gic_update(GICState *s)
229 gic_update_internal(s, false);
232 /* Return true if this LR is empty, i.e. the corresponding bit
233 * in ELRSR is set.
235 static inline bool gic_lr_entry_is_free(uint32_t entry)
237 return (GICH_LR_STATE(entry) == GICH_LR_STATE_INVALID)
238 && (GICH_LR_HW(entry) || !GICH_LR_EOI(entry));
241 /* Return true if this LR should trigger an EOI maintenance interrupt, i.e. the
242 * corresponding bit in EISR is set.
244 static inline bool gic_lr_entry_is_eoi(uint32_t entry)
246 return (GICH_LR_STATE(entry) == GICH_LR_STATE_INVALID)
247 && !GICH_LR_HW(entry) && GICH_LR_EOI(entry);
250 static inline void gic_extract_lr_info(GICState *s, int cpu,
251 int *num_eoi, int *num_valid, int *num_pending)
253 int lr_idx;
255 *num_eoi = 0;
256 *num_valid = 0;
257 *num_pending = 0;
259 for (lr_idx = 0; lr_idx < s->num_lrs; lr_idx++) {
260 uint32_t *entry = &s->h_lr[lr_idx][cpu];
262 if (gic_lr_entry_is_eoi(*entry)) {
263 (*num_eoi)++;
266 if (GICH_LR_STATE(*entry) != GICH_LR_STATE_INVALID) {
267 (*num_valid)++;
270 if (GICH_LR_STATE(*entry) == GICH_LR_STATE_PENDING) {
271 (*num_pending)++;
276 static void gic_compute_misr(GICState *s, int cpu)
278 uint32_t value = 0;
279 int vcpu = cpu + GIC_NCPU;
281 int num_eoi, num_valid, num_pending;
283 gic_extract_lr_info(s, cpu, &num_eoi, &num_valid, &num_pending);
285 /* EOI */
286 if (num_eoi) {
287 value |= R_GICH_MISR_EOI_MASK;
290 /* U: true if only 0 or 1 LR entry is valid */
291 if ((s->h_hcr[cpu] & R_GICH_HCR_UIE_MASK) && (num_valid < 2)) {
292 value |= R_GICH_MISR_U_MASK;
295 /* LRENP: EOICount is not 0 */
296 if ((s->h_hcr[cpu] & R_GICH_HCR_LRENPIE_MASK) &&
297 ((s->h_hcr[cpu] & R_GICH_HCR_EOICount_MASK) != 0)) {
298 value |= R_GICH_MISR_LRENP_MASK;
301 /* NP: no pending interrupts */
302 if ((s->h_hcr[cpu] & R_GICH_HCR_NPIE_MASK) && (num_pending == 0)) {
303 value |= R_GICH_MISR_NP_MASK;
306 /* VGrp0E: group0 virq signaling enabled */
307 if ((s->h_hcr[cpu] & R_GICH_HCR_VGRP0EIE_MASK) &&
308 (s->cpu_ctlr[vcpu] & GICC_CTLR_EN_GRP0)) {
309 value |= R_GICH_MISR_VGrp0E_MASK;
312 /* VGrp0D: group0 virq signaling disabled */
313 if ((s->h_hcr[cpu] & R_GICH_HCR_VGRP0DIE_MASK) &&
314 !(s->cpu_ctlr[vcpu] & GICC_CTLR_EN_GRP0)) {
315 value |= R_GICH_MISR_VGrp0D_MASK;
318 /* VGrp1E: group1 virq signaling enabled */
319 if ((s->h_hcr[cpu] & R_GICH_HCR_VGRP1EIE_MASK) &&
320 (s->cpu_ctlr[vcpu] & GICC_CTLR_EN_GRP1)) {
321 value |= R_GICH_MISR_VGrp1E_MASK;
324 /* VGrp1D: group1 virq signaling disabled */
325 if ((s->h_hcr[cpu] & R_GICH_HCR_VGRP1DIE_MASK) &&
326 !(s->cpu_ctlr[vcpu] & GICC_CTLR_EN_GRP1)) {
327 value |= R_GICH_MISR_VGrp1D_MASK;
330 s->h_misr[cpu] = value;
333 static void gic_update_maintenance(GICState *s)
335 int cpu = 0;
336 int maint_level;
338 for (cpu = 0; cpu < s->num_cpu; cpu++) {
339 gic_compute_misr(s, cpu);
340 maint_level = (s->h_hcr[cpu] & R_GICH_HCR_EN_MASK) && s->h_misr[cpu];
342 trace_gic_update_maintenance_irq(cpu, maint_level);
343 qemu_set_irq(s->maintenance_irq[cpu], maint_level);
347 static void gic_update_virt(GICState *s)
349 gic_update_internal(s, true);
350 gic_update_maintenance(s);
353 static void gic_set_irq_11mpcore(GICState *s, int irq, int level,
354 int cm, int target)
356 if (level) {
357 GIC_DIST_SET_LEVEL(irq, cm);
358 if (GIC_DIST_TEST_EDGE_TRIGGER(irq) || GIC_DIST_TEST_ENABLED(irq, cm)) {
359 DPRINTF("Set %d pending mask %x\n", irq, target);
360 GIC_DIST_SET_PENDING(irq, target);
362 } else {
363 GIC_DIST_CLEAR_LEVEL(irq, cm);
367 static void gic_set_irq_generic(GICState *s, int irq, int level,
368 int cm, int target)
370 if (level) {
371 GIC_DIST_SET_LEVEL(irq, cm);
372 DPRINTF("Set %d pending mask %x\n", irq, target);
373 if (GIC_DIST_TEST_EDGE_TRIGGER(irq)) {
374 GIC_DIST_SET_PENDING(irq, target);
376 } else {
377 GIC_DIST_CLEAR_LEVEL(irq, cm);
381 /* Process a change in an external IRQ input. */
382 static void gic_set_irq(void *opaque, int irq, int level)
384 /* Meaning of the 'irq' parameter:
385 * [0..N-1] : external interrupts
386 * [N..N+31] : PPI (internal) interrupts for CPU 0
387 * [N+32..N+63] : PPI (internal interrupts for CPU 1
388 * ...
390 GICState *s = (GICState *)opaque;
391 int cm, target;
392 if (irq < (s->num_irq - GIC_INTERNAL)) {
393 /* The first external input line is internal interrupt 32. */
394 cm = ALL_CPU_MASK;
395 irq += GIC_INTERNAL;
396 target = GIC_DIST_TARGET(irq);
397 } else {
398 int cpu;
399 irq -= (s->num_irq - GIC_INTERNAL);
400 cpu = irq / GIC_INTERNAL;
401 irq %= GIC_INTERNAL;
402 cm = 1 << cpu;
403 target = cm;
406 assert(irq >= GIC_NR_SGIS);
408 if (level == GIC_DIST_TEST_LEVEL(irq, cm)) {
409 return;
412 if (s->revision == REV_11MPCORE) {
413 gic_set_irq_11mpcore(s, irq, level, cm, target);
414 } else {
415 gic_set_irq_generic(s, irq, level, cm, target);
417 trace_gic_set_irq(irq, level, cm, target);
419 gic_update(s);
422 static uint16_t gic_get_current_pending_irq(GICState *s, int cpu,
423 MemTxAttrs attrs)
425 uint16_t pending_irq = s->current_pending[cpu];
427 if (pending_irq < GIC_MAXIRQ && gic_has_groups(s)) {
428 int group = gic_test_group(s, pending_irq, cpu);
430 /* On a GIC without the security extensions, reading this register
431 * behaves in the same way as a secure access to a GIC with them.
433 bool secure = !gic_cpu_ns_access(s, cpu, attrs);
435 if (group == 0 && !secure) {
436 /* Group0 interrupts hidden from Non-secure access */
437 return 1023;
439 if (group == 1 && secure && !(s->cpu_ctlr[cpu] & GICC_CTLR_ACK_CTL)) {
440 /* Group1 interrupts only seen by Secure access if
441 * AckCtl bit set.
443 return 1022;
446 return pending_irq;
449 static int gic_get_group_priority(GICState *s, int cpu, int irq)
451 /* Return the group priority of the specified interrupt
452 * (which is the top bits of its priority, with the number
453 * of bits masked determined by the applicable binary point register).
455 int bpr;
456 uint32_t mask;
458 if (gic_has_groups(s) &&
459 !(s->cpu_ctlr[cpu] & GICC_CTLR_CBPR) &&
460 gic_test_group(s, irq, cpu)) {
461 bpr = s->abpr[cpu] - 1;
462 assert(bpr >= 0);
463 } else {
464 bpr = s->bpr[cpu];
467 /* a BPR of 0 means the group priority bits are [7:1];
468 * a BPR of 1 means they are [7:2], and so on down to
469 * a BPR of 7 meaning no group priority bits at all.
471 mask = ~0U << ((bpr & 7) + 1);
473 return gic_get_priority(s, irq, cpu) & mask;
476 static void gic_activate_irq(GICState *s, int cpu, int irq)
478 /* Set the appropriate Active Priority Register bit for this IRQ,
479 * and update the running priority.
481 int prio = gic_get_group_priority(s, cpu, irq);
482 int min_bpr = gic_is_vcpu(cpu) ? GIC_VIRT_MIN_BPR : GIC_MIN_BPR;
483 int preemption_level = prio >> (min_bpr + 1);
484 int regno = preemption_level / 32;
485 int bitno = preemption_level % 32;
486 uint32_t *papr = NULL;
488 if (gic_is_vcpu(cpu)) {
489 assert(regno == 0);
490 papr = &s->h_apr[gic_get_vcpu_real_id(cpu)];
491 } else if (gic_has_groups(s) && gic_test_group(s, irq, cpu)) {
492 papr = &s->nsapr[regno][cpu];
493 } else {
494 papr = &s->apr[regno][cpu];
497 *papr |= (1 << bitno);
499 s->running_priority[cpu] = prio;
500 gic_set_active(s, irq, cpu);
503 static int gic_get_prio_from_apr_bits(GICState *s, int cpu)
505 /* Recalculate the current running priority for this CPU based
506 * on the set bits in the Active Priority Registers.
508 int i;
510 if (gic_is_vcpu(cpu)) {
511 uint32_t apr = s->h_apr[gic_get_vcpu_real_id(cpu)];
512 if (apr) {
513 return ctz32(apr) << (GIC_VIRT_MIN_BPR + 1);
514 } else {
515 return 0x100;
519 for (i = 0; i < GIC_NR_APRS; i++) {
520 uint32_t apr = s->apr[i][cpu] | s->nsapr[i][cpu];
521 if (!apr) {
522 continue;
524 return (i * 32 + ctz32(apr)) << (GIC_MIN_BPR + 1);
526 return 0x100;
529 static void gic_drop_prio(GICState *s, int cpu, int group)
531 /* Drop the priority of the currently active interrupt in the
532 * specified group.
534 * Note that we can guarantee (because of the requirement to nest
535 * GICC_IAR reads [which activate an interrupt and raise priority]
536 * with GICC_EOIR writes [which drop the priority for the interrupt])
537 * that the interrupt we're being called for is the highest priority
538 * active interrupt, meaning that it has the lowest set bit in the
539 * APR registers.
541 * If the guest does not honour the ordering constraints then the
542 * behaviour of the GIC is UNPREDICTABLE, which for us means that
543 * the values of the APR registers might become incorrect and the
544 * running priority will be wrong, so interrupts that should preempt
545 * might not do so, and interrupts that should not preempt might do so.
547 if (gic_is_vcpu(cpu)) {
548 int rcpu = gic_get_vcpu_real_id(cpu);
550 if (s->h_apr[rcpu]) {
551 /* Clear lowest set bit */
552 s->h_apr[rcpu] &= s->h_apr[rcpu] - 1;
554 } else {
555 int i;
557 for (i = 0; i < GIC_NR_APRS; i++) {
558 uint32_t *papr = group ? &s->nsapr[i][cpu] : &s->apr[i][cpu];
559 if (!*papr) {
560 continue;
562 /* Clear lowest set bit */
563 *papr &= *papr - 1;
564 break;
568 s->running_priority[cpu] = gic_get_prio_from_apr_bits(s, cpu);
571 static inline uint32_t gic_clear_pending_sgi(GICState *s, int irq, int cpu)
573 int src;
574 uint32_t ret;
576 if (!gic_is_vcpu(cpu)) {
577 /* Lookup the source CPU for the SGI and clear this in the
578 * sgi_pending map. Return the src and clear the overall pending
579 * state on this CPU if the SGI is not pending from any CPUs.
581 assert(s->sgi_pending[irq][cpu] != 0);
582 src = ctz32(s->sgi_pending[irq][cpu]);
583 s->sgi_pending[irq][cpu] &= ~(1 << src);
584 if (s->sgi_pending[irq][cpu] == 0) {
585 gic_clear_pending(s, irq, cpu);
587 ret = irq | ((src & 0x7) << 10);
588 } else {
589 uint32_t *lr_entry = gic_get_lr_entry(s, irq, cpu);
590 src = GICH_LR_CPUID(*lr_entry);
592 gic_clear_pending(s, irq, cpu);
593 ret = irq | (src << 10);
596 return ret;
599 uint32_t gic_acknowledge_irq(GICState *s, int cpu, MemTxAttrs attrs)
601 int ret, irq;
603 /* gic_get_current_pending_irq() will return 1022 or 1023 appropriately
604 * for the case where this GIC supports grouping and the pending interrupt
605 * is in the wrong group.
607 irq = gic_get_current_pending_irq(s, cpu, attrs);
608 trace_gic_acknowledge_irq(gic_is_vcpu(cpu) ? "vcpu" : "cpu",
609 gic_get_vcpu_real_id(cpu), irq);
611 if (irq >= GIC_MAXIRQ) {
612 DPRINTF("ACK, no pending interrupt or it is hidden: %d\n", irq);
613 return irq;
616 if (gic_get_priority(s, irq, cpu) >= s->running_priority[cpu]) {
617 DPRINTF("ACK, pending interrupt (%d) has insufficient priority\n", irq);
618 return 1023;
621 gic_activate_irq(s, cpu, irq);
623 if (s->revision == REV_11MPCORE) {
624 /* Clear pending flags for both level and edge triggered interrupts.
625 * Level triggered IRQs will be reasserted once they become inactive.
627 gic_clear_pending(s, irq, cpu);
628 ret = irq;
629 } else {
630 if (irq < GIC_NR_SGIS) {
631 ret = gic_clear_pending_sgi(s, irq, cpu);
632 } else {
633 gic_clear_pending(s, irq, cpu);
634 ret = irq;
638 if (gic_is_vcpu(cpu)) {
639 gic_update_virt(s);
640 } else {
641 gic_update(s);
643 DPRINTF("ACK %d\n", irq);
644 return ret;
647 static uint32_t gic_fullprio_mask(GICState *s, int cpu)
650 * Return a mask word which clears the unimplemented priority
651 * bits from a priority value for an interrupt. (Not to be
652 * confused with the group priority, whose mask depends on BPR.)
654 int priBits;
656 if (gic_is_vcpu(cpu)) {
657 priBits = GIC_VIRT_MAX_GROUP_PRIO_BITS;
658 } else {
659 priBits = s->n_prio_bits;
661 return ~0U << (8 - priBits);
664 void gic_dist_set_priority(GICState *s, int cpu, int irq, uint8_t val,
665 MemTxAttrs attrs)
667 if (s->security_extn && !attrs.secure) {
668 if (!GIC_DIST_TEST_GROUP(irq, (1 << cpu))) {
669 return; /* Ignore Non-secure access of Group0 IRQ */
671 val = 0x80 | (val >> 1); /* Non-secure view */
674 val &= gic_fullprio_mask(s, cpu);
676 if (irq < GIC_INTERNAL) {
677 s->priority1[irq][cpu] = val;
678 } else {
679 s->priority2[(irq) - GIC_INTERNAL] = val;
683 static uint32_t gic_dist_get_priority(GICState *s, int cpu, int irq,
684 MemTxAttrs attrs)
686 uint32_t prio = GIC_DIST_GET_PRIORITY(irq, cpu);
688 if (s->security_extn && !attrs.secure) {
689 if (!GIC_DIST_TEST_GROUP(irq, (1 << cpu))) {
690 return 0; /* Non-secure access cannot read priority of Group0 IRQ */
692 prio = (prio << 1) & 0xff; /* Non-secure view */
694 return prio & gic_fullprio_mask(s, cpu);
697 static void gic_set_priority_mask(GICState *s, int cpu, uint8_t pmask,
698 MemTxAttrs attrs)
700 if (gic_cpu_ns_access(s, cpu, attrs)) {
701 if (s->priority_mask[cpu] & 0x80) {
702 /* Priority Mask in upper half */
703 pmask = 0x80 | (pmask >> 1);
704 } else {
705 /* Non-secure write ignored if priority mask is in lower half */
706 return;
709 s->priority_mask[cpu] = pmask & gic_fullprio_mask(s, cpu);
712 static uint32_t gic_get_priority_mask(GICState *s, int cpu, MemTxAttrs attrs)
714 uint32_t pmask = s->priority_mask[cpu];
716 if (gic_cpu_ns_access(s, cpu, attrs)) {
717 if (pmask & 0x80) {
718 /* Priority Mask in upper half, return Non-secure view */
719 pmask = (pmask << 1) & 0xff;
720 } else {
721 /* Priority Mask in lower half, RAZ */
722 pmask = 0;
725 return pmask;
728 static uint32_t gic_get_cpu_control(GICState *s, int cpu, MemTxAttrs attrs)
730 uint32_t ret = s->cpu_ctlr[cpu];
732 if (gic_cpu_ns_access(s, cpu, attrs)) {
733 /* Construct the NS banked view of GICC_CTLR from the correct
734 * bits of the S banked view. We don't need to move the bypass
735 * control bits because we don't implement that (IMPDEF) part
736 * of the GIC architecture.
738 ret = (ret & (GICC_CTLR_EN_GRP1 | GICC_CTLR_EOIMODE_NS)) >> 1;
740 return ret;
743 static void gic_set_cpu_control(GICState *s, int cpu, uint32_t value,
744 MemTxAttrs attrs)
746 uint32_t mask;
748 if (gic_cpu_ns_access(s, cpu, attrs)) {
749 /* The NS view can only write certain bits in the register;
750 * the rest are unchanged
752 mask = GICC_CTLR_EN_GRP1;
753 if (s->revision == 2) {
754 mask |= GICC_CTLR_EOIMODE_NS;
756 s->cpu_ctlr[cpu] &= ~mask;
757 s->cpu_ctlr[cpu] |= (value << 1) & mask;
758 } else {
759 if (s->revision == 2) {
760 mask = s->security_extn ? GICC_CTLR_V2_S_MASK : GICC_CTLR_V2_MASK;
761 } else {
762 mask = s->security_extn ? GICC_CTLR_V1_S_MASK : GICC_CTLR_V1_MASK;
764 s->cpu_ctlr[cpu] = value & mask;
766 DPRINTF("CPU Interface %d: Group0 Interrupts %sabled, "
767 "Group1 Interrupts %sabled\n", cpu,
768 (s->cpu_ctlr[cpu] & GICC_CTLR_EN_GRP0) ? "En" : "Dis",
769 (s->cpu_ctlr[cpu] & GICC_CTLR_EN_GRP1) ? "En" : "Dis");
772 static uint8_t gic_get_running_priority(GICState *s, int cpu, MemTxAttrs attrs)
774 if ((s->revision != REV_11MPCORE) && (s->running_priority[cpu] > 0xff)) {
775 /* Idle priority */
776 return 0xff;
779 if (gic_cpu_ns_access(s, cpu, attrs)) {
780 if (s->running_priority[cpu] & 0x80) {
781 /* Running priority in upper half of range: return the Non-secure
782 * view of the priority.
784 return s->running_priority[cpu] << 1;
785 } else {
786 /* Running priority in lower half of range: RAZ */
787 return 0;
789 } else {
790 return s->running_priority[cpu];
794 /* Return true if we should split priority drop and interrupt deactivation,
795 * ie whether the relevant EOIMode bit is set.
797 static bool gic_eoi_split(GICState *s, int cpu, MemTxAttrs attrs)
799 if (s->revision != 2) {
800 /* Before GICv2 prio-drop and deactivate are not separable */
801 return false;
803 if (gic_cpu_ns_access(s, cpu, attrs)) {
804 return s->cpu_ctlr[cpu] & GICC_CTLR_EOIMODE_NS;
806 return s->cpu_ctlr[cpu] & GICC_CTLR_EOIMODE;
809 static void gic_deactivate_irq(GICState *s, int cpu, int irq, MemTxAttrs attrs)
811 int group;
813 if (irq >= GIC_MAXIRQ || (!gic_is_vcpu(cpu) && irq >= s->num_irq)) {
815 * This handles two cases:
816 * 1. If software writes the ID of a spurious interrupt [ie 1023]
817 * to the GICC_DIR, the GIC ignores that write.
818 * 2. If software writes the number of a non-existent interrupt
819 * this must be a subcase of "value written is not an active interrupt"
820 * and so this is UNPREDICTABLE. We choose to ignore it. For vCPUs,
821 * all IRQs potentially exist, so this limit does not apply.
823 return;
826 if (!gic_eoi_split(s, cpu, attrs)) {
827 /* This is UNPREDICTABLE; we choose to ignore it */
828 qemu_log_mask(LOG_GUEST_ERROR,
829 "gic_deactivate_irq: GICC_DIR write when EOIMode clear");
830 return;
833 if (gic_is_vcpu(cpu) && !gic_virq_is_valid(s, irq, cpu)) {
834 /* This vIRQ does not have an LR entry which is either active or
835 * pending and active. Increment EOICount and ignore the write.
837 int rcpu = gic_get_vcpu_real_id(cpu);
838 s->h_hcr[rcpu] += 1 << R_GICH_HCR_EOICount_SHIFT;
840 /* Update the virtual interface in case a maintenance interrupt should
841 * be raised.
843 gic_update_virt(s);
844 return;
847 group = gic_has_groups(s) && gic_test_group(s, irq, cpu);
849 if (gic_cpu_ns_access(s, cpu, attrs) && !group) {
850 DPRINTF("Non-secure DI for Group0 interrupt %d ignored\n", irq);
851 return;
854 gic_clear_active(s, irq, cpu);
857 static void gic_complete_irq(GICState *s, int cpu, int irq, MemTxAttrs attrs)
859 int cm = 1 << cpu;
860 int group;
862 DPRINTF("EOI %d\n", irq);
863 if (gic_is_vcpu(cpu)) {
864 /* The call to gic_prio_drop() will clear a bit in GICH_APR iff the
865 * running prio is < 0x100.
867 bool prio_drop = s->running_priority[cpu] < 0x100;
869 if (irq >= GIC_MAXIRQ) {
870 /* Ignore spurious interrupt */
871 return;
874 gic_drop_prio(s, cpu, 0);
876 if (!gic_eoi_split(s, cpu, attrs)) {
877 bool valid = gic_virq_is_valid(s, irq, cpu);
878 if (prio_drop && !valid) {
879 /* We are in a situation where:
880 * - V_CTRL.EOIMode is false (no EOI split),
881 * - The call to gic_drop_prio() cleared a bit in GICH_APR,
882 * - This vIRQ does not have an LR entry which is either
883 * active or pending and active.
884 * In that case, we must increment EOICount.
886 int rcpu = gic_get_vcpu_real_id(cpu);
887 s->h_hcr[rcpu] += 1 << R_GICH_HCR_EOICount_SHIFT;
888 } else if (valid) {
889 gic_clear_active(s, irq, cpu);
893 gic_update_virt(s);
894 return;
897 if (irq >= s->num_irq) {
898 /* This handles two cases:
899 * 1. If software writes the ID of a spurious interrupt [ie 1023]
900 * to the GICC_EOIR, the GIC ignores that write.
901 * 2. If software writes the number of a non-existent interrupt
902 * this must be a subcase of "value written does not match the last
903 * valid interrupt value read from the Interrupt Acknowledge
904 * register" and so this is UNPREDICTABLE. We choose to ignore it.
906 return;
908 if (s->running_priority[cpu] == 0x100) {
909 return; /* No active IRQ. */
912 if (s->revision == REV_11MPCORE) {
913 /* Mark level triggered interrupts as pending if they are still
914 raised. */
915 if (!GIC_DIST_TEST_EDGE_TRIGGER(irq) && GIC_DIST_TEST_ENABLED(irq, cm)
916 && GIC_DIST_TEST_LEVEL(irq, cm)
917 && (GIC_DIST_TARGET(irq) & cm) != 0) {
918 DPRINTF("Set %d pending mask %x\n", irq, cm);
919 GIC_DIST_SET_PENDING(irq, cm);
923 group = gic_has_groups(s) && gic_test_group(s, irq, cpu);
925 if (gic_cpu_ns_access(s, cpu, attrs) && !group) {
926 DPRINTF("Non-secure EOI for Group0 interrupt %d ignored\n", irq);
927 return;
930 /* Secure EOI with GICC_CTLR.AckCtl == 0 when the IRQ is a Group 1
931 * interrupt is UNPREDICTABLE. We choose to handle it as if AckCtl == 1,
932 * i.e. go ahead and complete the irq anyway.
935 gic_drop_prio(s, cpu, group);
937 /* In GICv2 the guest can choose to split priority-drop and deactivate */
938 if (!gic_eoi_split(s, cpu, attrs)) {
939 gic_clear_active(s, irq, cpu);
941 gic_update(s);
944 static uint8_t gic_dist_readb(void *opaque, hwaddr offset, MemTxAttrs attrs)
946 GICState *s = (GICState *)opaque;
947 uint32_t res;
948 int irq;
949 int i;
950 int cpu;
951 int cm;
952 int mask;
954 cpu = gic_get_current_cpu(s);
955 cm = 1 << cpu;
956 if (offset < 0x100) {
957 if (offset == 0) { /* GICD_CTLR */
958 /* We rely here on the only non-zero bits being in byte 0 */
959 if (s->security_extn && !attrs.secure) {
960 /* The NS bank of this register is just an alias of the
961 * EnableGrp1 bit in the S bank version.
963 return extract32(s->ctlr, 1, 1);
964 } else {
965 return s->ctlr;
968 if (offset == 4) {
969 /* GICD_TYPER byte 0 */
970 return ((s->num_irq / 32) - 1) | ((s->num_cpu - 1) << 5);
972 if (offset == 5) {
973 /* GICD_TYPER byte 1 */
974 return (s->security_extn << 2);
976 if (offset == 8) {
977 /* GICD_IIDR byte 0 */
978 return 0x3b; /* Arm JEP106 identity */
980 if (offset == 9) {
981 /* GICD_IIDR byte 1 */
982 return 0x04; /* Arm JEP106 identity */
984 if (offset < 0x0c) {
985 /* All other bytes in this range are RAZ */
986 return 0;
988 if (offset >= 0x80) {
989 /* Interrupt Group Registers: these RAZ/WI if this is an NS
990 * access to a GIC with the security extensions, or if the GIC
991 * doesn't have groups at all.
993 res = 0;
994 if (!(s->security_extn && !attrs.secure) && gic_has_groups(s)) {
995 /* Every byte offset holds 8 group status bits */
996 irq = (offset - 0x080) * 8;
997 if (irq >= s->num_irq) {
998 goto bad_reg;
1000 for (i = 0; i < 8; i++) {
1001 if (GIC_DIST_TEST_GROUP(irq + i, cm)) {
1002 res |= (1 << i);
1006 return res;
1008 goto bad_reg;
1009 } else if (offset < 0x200) {
1010 /* Interrupt Set/Clear Enable. */
1011 if (offset < 0x180)
1012 irq = (offset - 0x100) * 8;
1013 else
1014 irq = (offset - 0x180) * 8;
1015 if (irq >= s->num_irq)
1016 goto bad_reg;
1017 res = 0;
1018 for (i = 0; i < 8; i++) {
1019 if (s->security_extn && !attrs.secure &&
1020 !GIC_DIST_TEST_GROUP(irq + i, 1 << cpu)) {
1021 continue; /* Ignore Non-secure access of Group0 IRQ */
1024 if (GIC_DIST_TEST_ENABLED(irq + i, cm)) {
1025 res |= (1 << i);
1028 } else if (offset < 0x300) {
1029 /* Interrupt Set/Clear Pending. */
1030 if (offset < 0x280)
1031 irq = (offset - 0x200) * 8;
1032 else
1033 irq = (offset - 0x280) * 8;
1034 if (irq >= s->num_irq)
1035 goto bad_reg;
1036 res = 0;
1037 mask = (irq < GIC_INTERNAL) ? cm : ALL_CPU_MASK;
1038 for (i = 0; i < 8; i++) {
1039 if (s->security_extn && !attrs.secure &&
1040 !GIC_DIST_TEST_GROUP(irq + i, 1 << cpu)) {
1041 continue; /* Ignore Non-secure access of Group0 IRQ */
1044 if (gic_test_pending(s, irq + i, mask)) {
1045 res |= (1 << i);
1048 } else if (offset < 0x400) {
1049 /* Interrupt Set/Clear Active. */
1050 if (offset < 0x380) {
1051 irq = (offset - 0x300) * 8;
1052 } else if (s->revision == 2) {
1053 irq = (offset - 0x380) * 8;
1054 } else {
1055 goto bad_reg;
1058 if (irq >= s->num_irq)
1059 goto bad_reg;
1060 res = 0;
1061 mask = (irq < GIC_INTERNAL) ? cm : ALL_CPU_MASK;
1062 for (i = 0; i < 8; i++) {
1063 if (s->security_extn && !attrs.secure &&
1064 !GIC_DIST_TEST_GROUP(irq + i, 1 << cpu)) {
1065 continue; /* Ignore Non-secure access of Group0 IRQ */
1068 if (GIC_DIST_TEST_ACTIVE(irq + i, mask)) {
1069 res |= (1 << i);
1072 } else if (offset < 0x800) {
1073 /* Interrupt Priority. */
1074 irq = (offset - 0x400);
1075 if (irq >= s->num_irq)
1076 goto bad_reg;
1077 res = gic_dist_get_priority(s, cpu, irq, attrs);
1078 } else if (offset < 0xc00) {
1079 /* Interrupt CPU Target. */
1080 if (s->num_cpu == 1 && s->revision != REV_11MPCORE) {
1081 /* For uniprocessor GICs these RAZ/WI */
1082 res = 0;
1083 } else {
1084 irq = (offset - 0x800);
1085 if (irq >= s->num_irq) {
1086 goto bad_reg;
1088 if (irq < 29 && s->revision == REV_11MPCORE) {
1089 res = 0;
1090 } else if (irq < GIC_INTERNAL) {
1091 res = cm;
1092 } else {
1093 res = GIC_DIST_TARGET(irq);
1096 } else if (offset < 0xf00) {
1097 /* Interrupt Configuration. */
1098 irq = (offset - 0xc00) * 4;
1099 if (irq >= s->num_irq)
1100 goto bad_reg;
1101 res = 0;
1102 for (i = 0; i < 4; i++) {
1103 if (s->security_extn && !attrs.secure &&
1104 !GIC_DIST_TEST_GROUP(irq + i, 1 << cpu)) {
1105 continue; /* Ignore Non-secure access of Group0 IRQ */
1108 if (GIC_DIST_TEST_MODEL(irq + i)) {
1109 res |= (1 << (i * 2));
1111 if (GIC_DIST_TEST_EDGE_TRIGGER(irq + i)) {
1112 res |= (2 << (i * 2));
1115 } else if (offset < 0xf10) {
1116 goto bad_reg;
1117 } else if (offset < 0xf30) {
1118 if (s->revision == REV_11MPCORE) {
1119 goto bad_reg;
1122 if (offset < 0xf20) {
1123 /* GICD_CPENDSGIRn */
1124 irq = (offset - 0xf10);
1125 } else {
1126 irq = (offset - 0xf20);
1127 /* GICD_SPENDSGIRn */
1130 if (s->security_extn && !attrs.secure &&
1131 !GIC_DIST_TEST_GROUP(irq, 1 << cpu)) {
1132 res = 0; /* Ignore Non-secure access of Group0 IRQ */
1133 } else {
1134 res = s->sgi_pending[irq][cpu];
1136 } else if (offset < 0xfd0) {
1137 goto bad_reg;
1138 } else if (offset < 0x1000) {
1139 if (offset & 3) {
1140 res = 0;
1141 } else {
1142 switch (s->revision) {
1143 case REV_11MPCORE:
1144 res = gic_id_11mpcore[(offset - 0xfd0) >> 2];
1145 break;
1146 case 1:
1147 res = gic_id_gicv1[(offset - 0xfd0) >> 2];
1148 break;
1149 case 2:
1150 res = gic_id_gicv2[(offset - 0xfd0) >> 2];
1151 break;
1152 default:
1153 res = 0;
1156 } else {
1157 g_assert_not_reached();
1159 return res;
1160 bad_reg:
1161 qemu_log_mask(LOG_GUEST_ERROR,
1162 "gic_dist_readb: Bad offset %x\n", (int)offset);
1163 return 0;
1166 static MemTxResult gic_dist_read(void *opaque, hwaddr offset, uint64_t *data,
1167 unsigned size, MemTxAttrs attrs)
1169 switch (size) {
1170 case 1:
1171 *data = gic_dist_readb(opaque, offset, attrs);
1172 break;
1173 case 2:
1174 *data = gic_dist_readb(opaque, offset, attrs);
1175 *data |= gic_dist_readb(opaque, offset + 1, attrs) << 8;
1176 break;
1177 case 4:
1178 *data = gic_dist_readb(opaque, offset, attrs);
1179 *data |= gic_dist_readb(opaque, offset + 1, attrs) << 8;
1180 *data |= gic_dist_readb(opaque, offset + 2, attrs) << 16;
1181 *data |= gic_dist_readb(opaque, offset + 3, attrs) << 24;
1182 break;
1183 default:
1184 return MEMTX_ERROR;
1187 trace_gic_dist_read(offset, size, *data);
1188 return MEMTX_OK;
1191 static void gic_dist_writeb(void *opaque, hwaddr offset,
1192 uint32_t value, MemTxAttrs attrs)
1194 GICState *s = (GICState *)opaque;
1195 int irq;
1196 int i;
1197 int cpu;
1199 cpu = gic_get_current_cpu(s);
1200 if (offset < 0x100) {
1201 if (offset == 0) {
1202 if (s->security_extn && !attrs.secure) {
1203 /* NS version is just an alias of the S version's bit 1 */
1204 s->ctlr = deposit32(s->ctlr, 1, 1, value);
1205 } else if (gic_has_groups(s)) {
1206 s->ctlr = value & (GICD_CTLR_EN_GRP0 | GICD_CTLR_EN_GRP1);
1207 } else {
1208 s->ctlr = value & GICD_CTLR_EN_GRP0;
1210 DPRINTF("Distributor: Group0 %sabled; Group 1 %sabled\n",
1211 s->ctlr & GICD_CTLR_EN_GRP0 ? "En" : "Dis",
1212 s->ctlr & GICD_CTLR_EN_GRP1 ? "En" : "Dis");
1213 } else if (offset < 4) {
1214 /* ignored. */
1215 } else if (offset >= 0x80) {
1216 /* Interrupt Group Registers: RAZ/WI for NS access to secure
1217 * GIC, or for GICs without groups.
1219 if (!(s->security_extn && !attrs.secure) && gic_has_groups(s)) {
1220 /* Every byte offset holds 8 group status bits */
1221 irq = (offset - 0x80) * 8;
1222 if (irq >= s->num_irq) {
1223 goto bad_reg;
1225 for (i = 0; i < 8; i++) {
1226 /* Group bits are banked for private interrupts */
1227 int cm = (irq < GIC_INTERNAL) ? (1 << cpu) : ALL_CPU_MASK;
1228 if (value & (1 << i)) {
1229 /* Group1 (Non-secure) */
1230 GIC_DIST_SET_GROUP(irq + i, cm);
1231 } else {
1232 /* Group0 (Secure) */
1233 GIC_DIST_CLEAR_GROUP(irq + i, cm);
1237 } else {
1238 goto bad_reg;
1240 } else if (offset < 0x180) {
1241 /* Interrupt Set Enable. */
1242 irq = (offset - 0x100) * 8;
1243 if (irq >= s->num_irq)
1244 goto bad_reg;
1245 if (irq < GIC_NR_SGIS) {
1246 value = 0xff;
1249 for (i = 0; i < 8; i++) {
1250 if (value & (1 << i)) {
1251 int mask =
1252 (irq < GIC_INTERNAL) ? (1 << cpu)
1253 : GIC_DIST_TARGET(irq + i);
1254 int cm = (irq < GIC_INTERNAL) ? (1 << cpu) : ALL_CPU_MASK;
1256 if (s->security_extn && !attrs.secure &&
1257 !GIC_DIST_TEST_GROUP(irq + i, 1 << cpu)) {
1258 continue; /* Ignore Non-secure access of Group0 IRQ */
1261 if (!GIC_DIST_TEST_ENABLED(irq + i, cm)) {
1262 DPRINTF("Enabled IRQ %d\n", irq + i);
1263 trace_gic_enable_irq(irq + i);
1265 GIC_DIST_SET_ENABLED(irq + i, cm);
1267 * If a raised level triggered IRQ enabled then mark
1268 * it as pending on 11MPCore. For other GIC revisions we
1269 * handle the "level triggered and line asserted" check
1270 * at the other end in gic_test_pending().
1272 if (s->revision == REV_11MPCORE
1273 && GIC_DIST_TEST_LEVEL(irq + i, mask)
1274 && !GIC_DIST_TEST_EDGE_TRIGGER(irq + i)) {
1275 DPRINTF("Set %d pending mask %x\n", irq + i, mask);
1276 GIC_DIST_SET_PENDING(irq + i, mask);
1280 } else if (offset < 0x200) {
1281 /* Interrupt Clear Enable. */
1282 irq = (offset - 0x180) * 8;
1283 if (irq >= s->num_irq)
1284 goto bad_reg;
1285 if (irq < GIC_NR_SGIS) {
1286 value = 0;
1289 for (i = 0; i < 8; i++) {
1290 if (value & (1 << i)) {
1291 int cm = (irq < GIC_INTERNAL) ? (1 << cpu) : ALL_CPU_MASK;
1293 if (s->security_extn && !attrs.secure &&
1294 !GIC_DIST_TEST_GROUP(irq + i, 1 << cpu)) {
1295 continue; /* Ignore Non-secure access of Group0 IRQ */
1298 if (GIC_DIST_TEST_ENABLED(irq + i, cm)) {
1299 DPRINTF("Disabled IRQ %d\n", irq + i);
1300 trace_gic_disable_irq(irq + i);
1302 GIC_DIST_CLEAR_ENABLED(irq + i, cm);
1305 } else if (offset < 0x280) {
1306 /* Interrupt Set Pending. */
1307 irq = (offset - 0x200) * 8;
1308 if (irq >= s->num_irq)
1309 goto bad_reg;
1310 if (irq < GIC_NR_SGIS) {
1311 value = 0;
1314 for (i = 0; i < 8; i++) {
1315 if (value & (1 << i)) {
1316 int mask = (irq < GIC_INTERNAL) ? (1 << cpu)
1317 : GIC_DIST_TARGET(irq + i);
1319 if (s->security_extn && !attrs.secure &&
1320 !GIC_DIST_TEST_GROUP(irq + i, 1 << cpu)) {
1321 continue; /* Ignore Non-secure access of Group0 IRQ */
1324 GIC_DIST_SET_PENDING(irq + i, mask);
1327 } else if (offset < 0x300) {
1328 /* Interrupt Clear Pending. */
1329 irq = (offset - 0x280) * 8;
1330 if (irq >= s->num_irq)
1331 goto bad_reg;
1332 if (irq < GIC_NR_SGIS) {
1333 value = 0;
1336 for (i = 0; i < 8; i++) {
1337 if (s->security_extn && !attrs.secure &&
1338 !GIC_DIST_TEST_GROUP(irq + i, 1 << cpu)) {
1339 continue; /* Ignore Non-secure access of Group0 IRQ */
1342 /* ??? This currently clears the pending bit for all CPUs, even
1343 for per-CPU interrupts. It's unclear whether this is the
1344 correct behavior. */
1345 if (value & (1 << i)) {
1346 GIC_DIST_CLEAR_PENDING(irq + i, ALL_CPU_MASK);
1349 } else if (offset < 0x380) {
1350 /* Interrupt Set Active. */
1351 if (s->revision != 2) {
1352 goto bad_reg;
1355 irq = (offset - 0x300) * 8;
1356 if (irq >= s->num_irq) {
1357 goto bad_reg;
1360 /* This register is banked per-cpu for PPIs */
1361 int cm = irq < GIC_INTERNAL ? (1 << cpu) : ALL_CPU_MASK;
1363 for (i = 0; i < 8; i++) {
1364 if (s->security_extn && !attrs.secure &&
1365 !GIC_DIST_TEST_GROUP(irq + i, 1 << cpu)) {
1366 continue; /* Ignore Non-secure access of Group0 IRQ */
1369 if (value & (1 << i)) {
1370 GIC_DIST_SET_ACTIVE(irq + i, cm);
1373 } else if (offset < 0x400) {
1374 /* Interrupt Clear Active. */
1375 if (s->revision != 2) {
1376 goto bad_reg;
1379 irq = (offset - 0x380) * 8;
1380 if (irq >= s->num_irq) {
1381 goto bad_reg;
1384 /* This register is banked per-cpu for PPIs */
1385 int cm = irq < GIC_INTERNAL ? (1 << cpu) : ALL_CPU_MASK;
1387 for (i = 0; i < 8; i++) {
1388 if (s->security_extn && !attrs.secure &&
1389 !GIC_DIST_TEST_GROUP(irq + i, 1 << cpu)) {
1390 continue; /* Ignore Non-secure access of Group0 IRQ */
1393 if (value & (1 << i)) {
1394 GIC_DIST_CLEAR_ACTIVE(irq + i, cm);
1397 } else if (offset < 0x800) {
1398 /* Interrupt Priority. */
1399 irq = (offset - 0x400);
1400 if (irq >= s->num_irq)
1401 goto bad_reg;
1402 gic_dist_set_priority(s, cpu, irq, value, attrs);
1403 } else if (offset < 0xc00) {
1404 /* Interrupt CPU Target. RAZ/WI on uniprocessor GICs, with the
1405 * annoying exception of the 11MPCore's GIC.
1407 if (s->num_cpu != 1 || s->revision == REV_11MPCORE) {
1408 irq = (offset - 0x800);
1409 if (irq >= s->num_irq) {
1410 goto bad_reg;
1412 if (irq < 29 && s->revision == REV_11MPCORE) {
1413 value = 0;
1414 } else if (irq < GIC_INTERNAL) {
1415 value = ALL_CPU_MASK;
1417 s->irq_target[irq] = value & ALL_CPU_MASK;
1418 if (irq >= GIC_INTERNAL && s->irq_state[irq].pending) {
1420 * Changing the target of an interrupt that is currently
1421 * pending updates the set of CPUs it is pending on.
1423 s->irq_state[irq].pending = value & ALL_CPU_MASK;
1426 } else if (offset < 0xf00) {
1427 /* Interrupt Configuration. */
1428 irq = (offset - 0xc00) * 4;
1429 if (irq >= s->num_irq)
1430 goto bad_reg;
1431 if (irq < GIC_NR_SGIS)
1432 value |= 0xaa;
1433 for (i = 0; i < 4; i++) {
1434 if (s->security_extn && !attrs.secure &&
1435 !GIC_DIST_TEST_GROUP(irq + i, 1 << cpu)) {
1436 continue; /* Ignore Non-secure access of Group0 IRQ */
1439 if (s->revision == REV_11MPCORE) {
1440 if (value & (1 << (i * 2))) {
1441 GIC_DIST_SET_MODEL(irq + i);
1442 } else {
1443 GIC_DIST_CLEAR_MODEL(irq + i);
1446 if (value & (2 << (i * 2))) {
1447 GIC_DIST_SET_EDGE_TRIGGER(irq + i);
1448 } else {
1449 GIC_DIST_CLEAR_EDGE_TRIGGER(irq + i);
1452 } else if (offset < 0xf10) {
1453 /* 0xf00 is only handled for 32-bit writes. */
1454 goto bad_reg;
1455 } else if (offset < 0xf20) {
1456 /* GICD_CPENDSGIRn */
1457 if (s->revision == REV_11MPCORE) {
1458 goto bad_reg;
1460 irq = (offset - 0xf10);
1462 if (!s->security_extn || attrs.secure ||
1463 GIC_DIST_TEST_GROUP(irq, 1 << cpu)) {
1464 s->sgi_pending[irq][cpu] &= ~value;
1465 if (s->sgi_pending[irq][cpu] == 0) {
1466 GIC_DIST_CLEAR_PENDING(irq, 1 << cpu);
1469 } else if (offset < 0xf30) {
1470 /* GICD_SPENDSGIRn */
1471 if (s->revision == REV_11MPCORE) {
1472 goto bad_reg;
1474 irq = (offset - 0xf20);
1476 if (!s->security_extn || attrs.secure ||
1477 GIC_DIST_TEST_GROUP(irq, 1 << cpu)) {
1478 GIC_DIST_SET_PENDING(irq, 1 << cpu);
1479 s->sgi_pending[irq][cpu] |= value;
1481 } else {
1482 goto bad_reg;
1484 gic_update(s);
1485 return;
1486 bad_reg:
1487 qemu_log_mask(LOG_GUEST_ERROR,
1488 "gic_dist_writeb: Bad offset %x\n", (int)offset);
1491 static void gic_dist_writew(void *opaque, hwaddr offset,
1492 uint32_t value, MemTxAttrs attrs)
1494 gic_dist_writeb(opaque, offset, value & 0xff, attrs);
1495 gic_dist_writeb(opaque, offset + 1, value >> 8, attrs);
1498 static void gic_dist_writel(void *opaque, hwaddr offset,
1499 uint32_t value, MemTxAttrs attrs)
1501 GICState *s = (GICState *)opaque;
1502 if (offset == 0xf00) {
1503 int cpu;
1504 int irq;
1505 int mask;
1506 int target_cpu;
1508 cpu = gic_get_current_cpu(s);
1509 irq = value & 0xf;
1510 switch ((value >> 24) & 3) {
1511 case 0:
1512 mask = (value >> 16) & ALL_CPU_MASK;
1513 break;
1514 case 1:
1515 mask = ALL_CPU_MASK ^ (1 << cpu);
1516 break;
1517 case 2:
1518 mask = 1 << cpu;
1519 break;
1520 default:
1521 DPRINTF("Bad Soft Int target filter\n");
1522 mask = ALL_CPU_MASK;
1523 break;
1525 GIC_DIST_SET_PENDING(irq, mask);
1526 target_cpu = ctz32(mask);
1527 while (target_cpu < GIC_NCPU) {
1528 s->sgi_pending[irq][target_cpu] |= (1 << cpu);
1529 mask &= ~(1 << target_cpu);
1530 target_cpu = ctz32(mask);
1532 gic_update(s);
1533 return;
1535 gic_dist_writew(opaque, offset, value & 0xffff, attrs);
1536 gic_dist_writew(opaque, offset + 2, value >> 16, attrs);
1539 static MemTxResult gic_dist_write(void *opaque, hwaddr offset, uint64_t data,
1540 unsigned size, MemTxAttrs attrs)
1542 trace_gic_dist_write(offset, size, data);
1544 switch (size) {
1545 case 1:
1546 gic_dist_writeb(opaque, offset, data, attrs);
1547 return MEMTX_OK;
1548 case 2:
1549 gic_dist_writew(opaque, offset, data, attrs);
1550 return MEMTX_OK;
1551 case 4:
1552 gic_dist_writel(opaque, offset, data, attrs);
1553 return MEMTX_OK;
1554 default:
1555 return MEMTX_ERROR;
1559 static inline uint32_t gic_apr_ns_view(GICState *s, int cpu, int regno)
1561 /* Return the Nonsecure view of GICC_APR<regno>. This is the
1562 * second half of GICC_NSAPR.
1564 switch (GIC_MIN_BPR) {
1565 case 0:
1566 if (regno < 2) {
1567 return s->nsapr[regno + 2][cpu];
1569 break;
1570 case 1:
1571 if (regno == 0) {
1572 return s->nsapr[regno + 1][cpu];
1574 break;
1575 case 2:
1576 if (regno == 0) {
1577 return extract32(s->nsapr[0][cpu], 16, 16);
1579 break;
1580 case 3:
1581 if (regno == 0) {
1582 return extract32(s->nsapr[0][cpu], 8, 8);
1584 break;
1585 default:
1586 g_assert_not_reached();
1588 return 0;
1591 static inline void gic_apr_write_ns_view(GICState *s, int cpu, int regno,
1592 uint32_t value)
1594 /* Write the Nonsecure view of GICC_APR<regno>. */
1595 switch (GIC_MIN_BPR) {
1596 case 0:
1597 if (regno < 2) {
1598 s->nsapr[regno + 2][cpu] = value;
1600 break;
1601 case 1:
1602 if (regno == 0) {
1603 s->nsapr[regno + 1][cpu] = value;
1605 break;
1606 case 2:
1607 if (regno == 0) {
1608 s->nsapr[0][cpu] = deposit32(s->nsapr[0][cpu], 16, 16, value);
1610 break;
1611 case 3:
1612 if (regno == 0) {
1613 s->nsapr[0][cpu] = deposit32(s->nsapr[0][cpu], 8, 8, value);
1615 break;
1616 default:
1617 g_assert_not_reached();
1621 static MemTxResult gic_cpu_read(GICState *s, int cpu, int offset,
1622 uint64_t *data, MemTxAttrs attrs)
1624 switch (offset) {
1625 case 0x00: /* Control */
1626 *data = gic_get_cpu_control(s, cpu, attrs);
1627 break;
1628 case 0x04: /* Priority mask */
1629 *data = gic_get_priority_mask(s, cpu, attrs);
1630 break;
1631 case 0x08: /* Binary Point */
1632 if (gic_cpu_ns_access(s, cpu, attrs)) {
1633 if (s->cpu_ctlr[cpu] & GICC_CTLR_CBPR) {
1634 /* NS view of BPR when CBPR is 1 */
1635 *data = MIN(s->bpr[cpu] + 1, 7);
1636 } else {
1637 /* BPR is banked. Non-secure copy stored in ABPR. */
1638 *data = s->abpr[cpu];
1640 } else {
1641 *data = s->bpr[cpu];
1643 break;
1644 case 0x0c: /* Acknowledge */
1645 *data = gic_acknowledge_irq(s, cpu, attrs);
1646 break;
1647 case 0x14: /* Running Priority */
1648 *data = gic_get_running_priority(s, cpu, attrs);
1649 break;
1650 case 0x18: /* Highest Pending Interrupt */
1651 *data = gic_get_current_pending_irq(s, cpu, attrs);
1652 break;
1653 case 0x1c: /* Aliased Binary Point */
1654 /* GIC v2, no security: ABPR
1655 * GIC v1, no security: not implemented (RAZ/WI)
1656 * With security extensions, secure access: ABPR (alias of NS BPR)
1657 * With security extensions, nonsecure access: RAZ/WI
1659 if (!gic_has_groups(s) || (gic_cpu_ns_access(s, cpu, attrs))) {
1660 *data = 0;
1661 } else {
1662 *data = s->abpr[cpu];
1664 break;
1665 case 0xd0: case 0xd4: case 0xd8: case 0xdc:
1667 int regno = (offset - 0xd0) / 4;
1668 int nr_aprs = gic_is_vcpu(cpu) ? GIC_VIRT_NR_APRS : GIC_NR_APRS;
1670 if (regno >= nr_aprs || s->revision != 2) {
1671 *data = 0;
1672 } else if (gic_is_vcpu(cpu)) {
1673 *data = s->h_apr[gic_get_vcpu_real_id(cpu)];
1674 } else if (gic_cpu_ns_access(s, cpu, attrs)) {
1675 /* NS view of GICC_APR<n> is the top half of GIC_NSAPR<n> */
1676 *data = gic_apr_ns_view(s, cpu, regno);
1677 } else {
1678 *data = s->apr[regno][cpu];
1680 break;
1682 case 0xe0: case 0xe4: case 0xe8: case 0xec:
1684 int regno = (offset - 0xe0) / 4;
1686 if (regno >= GIC_NR_APRS || s->revision != 2 || !gic_has_groups(s) ||
1687 gic_cpu_ns_access(s, cpu, attrs) || gic_is_vcpu(cpu)) {
1688 *data = 0;
1689 } else {
1690 *data = s->nsapr[regno][cpu];
1692 break;
1694 case 0xfc:
1695 if (s->revision == REV_11MPCORE) {
1696 /* Reserved on 11MPCore */
1697 *data = 0;
1698 } else {
1699 /* GICv1 or v2; Arm implementation */
1700 *data = (s->revision << 16) | 0x43b;
1702 break;
1703 default:
1704 qemu_log_mask(LOG_GUEST_ERROR,
1705 "gic_cpu_read: Bad offset %x\n", (int)offset);
1706 *data = 0;
1707 break;
1710 trace_gic_cpu_read(gic_is_vcpu(cpu) ? "vcpu" : "cpu",
1711 gic_get_vcpu_real_id(cpu), offset, *data);
1712 return MEMTX_OK;
1715 static MemTxResult gic_cpu_write(GICState *s, int cpu, int offset,
1716 uint32_t value, MemTxAttrs attrs)
1718 trace_gic_cpu_write(gic_is_vcpu(cpu) ? "vcpu" : "cpu",
1719 gic_get_vcpu_real_id(cpu), offset, value);
1721 switch (offset) {
1722 case 0x00: /* Control */
1723 gic_set_cpu_control(s, cpu, value, attrs);
1724 break;
1725 case 0x04: /* Priority mask */
1726 gic_set_priority_mask(s, cpu, value, attrs);
1727 break;
1728 case 0x08: /* Binary Point */
1729 if (gic_cpu_ns_access(s, cpu, attrs)) {
1730 if (s->cpu_ctlr[cpu] & GICC_CTLR_CBPR) {
1731 /* WI when CBPR is 1 */
1732 return MEMTX_OK;
1733 } else {
1734 s->abpr[cpu] = MAX(value & 0x7, GIC_MIN_ABPR);
1736 } else {
1737 int min_bpr = gic_is_vcpu(cpu) ? GIC_VIRT_MIN_BPR : GIC_MIN_BPR;
1738 s->bpr[cpu] = MAX(value & 0x7, min_bpr);
1740 break;
1741 case 0x10: /* End Of Interrupt */
1742 gic_complete_irq(s, cpu, value & 0x3ff, attrs);
1743 return MEMTX_OK;
1744 case 0x1c: /* Aliased Binary Point */
1745 if (!gic_has_groups(s) || (gic_cpu_ns_access(s, cpu, attrs))) {
1746 /* unimplemented, or NS access: RAZ/WI */
1747 return MEMTX_OK;
1748 } else {
1749 s->abpr[cpu] = MAX(value & 0x7, GIC_MIN_ABPR);
1751 break;
1752 case 0xd0: case 0xd4: case 0xd8: case 0xdc:
1754 int regno = (offset - 0xd0) / 4;
1755 int nr_aprs = gic_is_vcpu(cpu) ? GIC_VIRT_NR_APRS : GIC_NR_APRS;
1757 if (regno >= nr_aprs || s->revision != 2) {
1758 return MEMTX_OK;
1760 if (gic_is_vcpu(cpu)) {
1761 s->h_apr[gic_get_vcpu_real_id(cpu)] = value;
1762 } else if (gic_cpu_ns_access(s, cpu, attrs)) {
1763 /* NS view of GICC_APR<n> is the top half of GIC_NSAPR<n> */
1764 gic_apr_write_ns_view(s, cpu, regno, value);
1765 } else {
1766 s->apr[regno][cpu] = value;
1768 s->running_priority[cpu] = gic_get_prio_from_apr_bits(s, cpu);
1769 break;
1771 case 0xe0: case 0xe4: case 0xe8: case 0xec:
1773 int regno = (offset - 0xe0) / 4;
1775 if (regno >= GIC_NR_APRS || s->revision != 2) {
1776 return MEMTX_OK;
1778 if (gic_is_vcpu(cpu)) {
1779 return MEMTX_OK;
1781 if (!gic_has_groups(s) || (gic_cpu_ns_access(s, cpu, attrs))) {
1782 return MEMTX_OK;
1784 s->nsapr[regno][cpu] = value;
1785 s->running_priority[cpu] = gic_get_prio_from_apr_bits(s, cpu);
1786 break;
1788 case 0x1000:
1789 /* GICC_DIR */
1790 gic_deactivate_irq(s, cpu, value & 0x3ff, attrs);
1791 break;
1792 default:
1793 qemu_log_mask(LOG_GUEST_ERROR,
1794 "gic_cpu_write: Bad offset %x\n", (int)offset);
1795 return MEMTX_OK;
1798 if (gic_is_vcpu(cpu)) {
1799 gic_update_virt(s);
1800 } else {
1801 gic_update(s);
1804 return MEMTX_OK;
1807 /* Wrappers to read/write the GIC CPU interface for the current CPU */
1808 static MemTxResult gic_thiscpu_read(void *opaque, hwaddr addr, uint64_t *data,
1809 unsigned size, MemTxAttrs attrs)
1811 GICState *s = (GICState *)opaque;
1812 return gic_cpu_read(s, gic_get_current_cpu(s), addr, data, attrs);
1815 static MemTxResult gic_thiscpu_write(void *opaque, hwaddr addr,
1816 uint64_t value, unsigned size,
1817 MemTxAttrs attrs)
1819 GICState *s = (GICState *)opaque;
1820 return gic_cpu_write(s, gic_get_current_cpu(s), addr, value, attrs);
1823 /* Wrappers to read/write the GIC CPU interface for a specific CPU.
1824 * These just decode the opaque pointer into GICState* + cpu id.
1826 static MemTxResult gic_do_cpu_read(void *opaque, hwaddr addr, uint64_t *data,
1827 unsigned size, MemTxAttrs attrs)
1829 GICState **backref = (GICState **)opaque;
1830 GICState *s = *backref;
1831 int id = (backref - s->backref);
1832 return gic_cpu_read(s, id, addr, data, attrs);
1835 static MemTxResult gic_do_cpu_write(void *opaque, hwaddr addr,
1836 uint64_t value, unsigned size,
1837 MemTxAttrs attrs)
1839 GICState **backref = (GICState **)opaque;
1840 GICState *s = *backref;
1841 int id = (backref - s->backref);
1842 return gic_cpu_write(s, id, addr, value, attrs);
1845 static MemTxResult gic_thisvcpu_read(void *opaque, hwaddr addr, uint64_t *data,
1846 unsigned size, MemTxAttrs attrs)
1848 GICState *s = (GICState *)opaque;
1850 return gic_cpu_read(s, gic_get_current_vcpu(s), addr, data, attrs);
1853 static MemTxResult gic_thisvcpu_write(void *opaque, hwaddr addr,
1854 uint64_t value, unsigned size,
1855 MemTxAttrs attrs)
1857 GICState *s = (GICState *)opaque;
1859 return gic_cpu_write(s, gic_get_current_vcpu(s), addr, value, attrs);
1862 static uint32_t gic_compute_eisr(GICState *s, int cpu, int lr_start)
1864 int lr_idx;
1865 uint32_t ret = 0;
1867 for (lr_idx = lr_start; lr_idx < s->num_lrs; lr_idx++) {
1868 uint32_t *entry = &s->h_lr[lr_idx][cpu];
1869 ret = deposit32(ret, lr_idx - lr_start, 1,
1870 gic_lr_entry_is_eoi(*entry));
1873 return ret;
1876 static uint32_t gic_compute_elrsr(GICState *s, int cpu, int lr_start)
1878 int lr_idx;
1879 uint32_t ret = 0;
1881 for (lr_idx = lr_start; lr_idx < s->num_lrs; lr_idx++) {
1882 uint32_t *entry = &s->h_lr[lr_idx][cpu];
1883 ret = deposit32(ret, lr_idx - lr_start, 1,
1884 gic_lr_entry_is_free(*entry));
1887 return ret;
1890 static void gic_vmcr_write(GICState *s, uint32_t value, MemTxAttrs attrs)
1892 int vcpu = gic_get_current_vcpu(s);
1893 uint32_t ctlr;
1894 uint32_t abpr;
1895 uint32_t bpr;
1896 uint32_t prio_mask;
1898 ctlr = FIELD_EX32(value, GICH_VMCR, VMCCtlr);
1899 abpr = FIELD_EX32(value, GICH_VMCR, VMABP);
1900 bpr = FIELD_EX32(value, GICH_VMCR, VMBP);
1901 prio_mask = FIELD_EX32(value, GICH_VMCR, VMPriMask) << 3;
1903 gic_set_cpu_control(s, vcpu, ctlr, attrs);
1904 s->abpr[vcpu] = MAX(abpr, GIC_VIRT_MIN_ABPR);
1905 s->bpr[vcpu] = MAX(bpr, GIC_VIRT_MIN_BPR);
1906 gic_set_priority_mask(s, vcpu, prio_mask, attrs);
1909 static MemTxResult gic_hyp_read(void *opaque, int cpu, hwaddr addr,
1910 uint64_t *data, MemTxAttrs attrs)
1912 GICState *s = ARM_GIC(opaque);
1913 int vcpu = cpu + GIC_NCPU;
1915 switch (addr) {
1916 case A_GICH_HCR: /* Hypervisor Control */
1917 *data = s->h_hcr[cpu];
1918 break;
1920 case A_GICH_VTR: /* VGIC Type */
1921 *data = FIELD_DP32(0, GICH_VTR, ListRegs, s->num_lrs - 1);
1922 *data = FIELD_DP32(*data, GICH_VTR, PREbits,
1923 GIC_VIRT_MAX_GROUP_PRIO_BITS - 1);
1924 *data = FIELD_DP32(*data, GICH_VTR, PRIbits,
1925 (7 - GIC_VIRT_MIN_BPR) - 1);
1926 break;
1928 case A_GICH_VMCR: /* Virtual Machine Control */
1929 *data = FIELD_DP32(0, GICH_VMCR, VMCCtlr,
1930 extract32(s->cpu_ctlr[vcpu], 0, 10));
1931 *data = FIELD_DP32(*data, GICH_VMCR, VMABP, s->abpr[vcpu]);
1932 *data = FIELD_DP32(*data, GICH_VMCR, VMBP, s->bpr[vcpu]);
1933 *data = FIELD_DP32(*data, GICH_VMCR, VMPriMask,
1934 extract32(s->priority_mask[vcpu], 3, 5));
1935 break;
1937 case A_GICH_MISR: /* Maintenance Interrupt Status */
1938 *data = s->h_misr[cpu];
1939 break;
1941 case A_GICH_EISR0: /* End of Interrupt Status 0 and 1 */
1942 case A_GICH_EISR1:
1943 *data = gic_compute_eisr(s, cpu, (addr - A_GICH_EISR0) * 8);
1944 break;
1946 case A_GICH_ELRSR0: /* Empty List Status 0 and 1 */
1947 case A_GICH_ELRSR1:
1948 *data = gic_compute_elrsr(s, cpu, (addr - A_GICH_ELRSR0) * 8);
1949 break;
1951 case A_GICH_APR: /* Active Priorities */
1952 *data = s->h_apr[cpu];
1953 break;
1955 case A_GICH_LR0 ... A_GICH_LR63: /* List Registers */
1957 int lr_idx = (addr - A_GICH_LR0) / 4;
1959 if (lr_idx > s->num_lrs) {
1960 *data = 0;
1961 } else {
1962 *data = s->h_lr[lr_idx][cpu];
1964 break;
1967 default:
1968 qemu_log_mask(LOG_GUEST_ERROR,
1969 "gic_hyp_read: Bad offset %" HWADDR_PRIx "\n", addr);
1970 return MEMTX_OK;
1973 trace_gic_hyp_read(addr, *data);
1974 return MEMTX_OK;
1977 static MemTxResult gic_hyp_write(void *opaque, int cpu, hwaddr addr,
1978 uint64_t value, MemTxAttrs attrs)
1980 GICState *s = ARM_GIC(opaque);
1981 int vcpu = cpu + GIC_NCPU;
1983 trace_gic_hyp_write(addr, value);
1985 switch (addr) {
1986 case A_GICH_HCR: /* Hypervisor Control */
1987 s->h_hcr[cpu] = value & GICH_HCR_MASK;
1988 break;
1990 case A_GICH_VMCR: /* Virtual Machine Control */
1991 gic_vmcr_write(s, value, attrs);
1992 break;
1994 case A_GICH_APR: /* Active Priorities */
1995 s->h_apr[cpu] = value;
1996 s->running_priority[vcpu] = gic_get_prio_from_apr_bits(s, vcpu);
1997 break;
1999 case A_GICH_LR0 ... A_GICH_LR63: /* List Registers */
2001 int lr_idx = (addr - A_GICH_LR0) / 4;
2003 if (lr_idx > s->num_lrs) {
2004 return MEMTX_OK;
2007 s->h_lr[lr_idx][cpu] = value & GICH_LR_MASK;
2008 trace_gic_lr_entry(cpu, lr_idx, s->h_lr[lr_idx][cpu]);
2009 break;
2012 default:
2013 qemu_log_mask(LOG_GUEST_ERROR,
2014 "gic_hyp_write: Bad offset %" HWADDR_PRIx "\n", addr);
2015 return MEMTX_OK;
2018 gic_update_virt(s);
2019 return MEMTX_OK;
2022 static MemTxResult gic_thiscpu_hyp_read(void *opaque, hwaddr addr, uint64_t *data,
2023 unsigned size, MemTxAttrs attrs)
2025 GICState *s = (GICState *)opaque;
2027 return gic_hyp_read(s, gic_get_current_cpu(s), addr, data, attrs);
2030 static MemTxResult gic_thiscpu_hyp_write(void *opaque, hwaddr addr,
2031 uint64_t value, unsigned size,
2032 MemTxAttrs attrs)
2034 GICState *s = (GICState *)opaque;
2036 return gic_hyp_write(s, gic_get_current_cpu(s), addr, value, attrs);
2039 static MemTxResult gic_do_hyp_read(void *opaque, hwaddr addr, uint64_t *data,
2040 unsigned size, MemTxAttrs attrs)
2042 GICState **backref = (GICState **)opaque;
2043 GICState *s = *backref;
2044 int id = (backref - s->backref);
2046 return gic_hyp_read(s, id, addr, data, attrs);
2049 static MemTxResult gic_do_hyp_write(void *opaque, hwaddr addr,
2050 uint64_t value, unsigned size,
2051 MemTxAttrs attrs)
2053 GICState **backref = (GICState **)opaque;
2054 GICState *s = *backref;
2055 int id = (backref - s->backref);
2057 return gic_hyp_write(s, id + GIC_NCPU, addr, value, attrs);
2061 static const MemoryRegionOps gic_ops[2] = {
2063 .read_with_attrs = gic_dist_read,
2064 .write_with_attrs = gic_dist_write,
2065 .endianness = DEVICE_NATIVE_ENDIAN,
2068 .read_with_attrs = gic_thiscpu_read,
2069 .write_with_attrs = gic_thiscpu_write,
2070 .endianness = DEVICE_NATIVE_ENDIAN,
2074 static const MemoryRegionOps gic_cpu_ops = {
2075 .read_with_attrs = gic_do_cpu_read,
2076 .write_with_attrs = gic_do_cpu_write,
2077 .endianness = DEVICE_NATIVE_ENDIAN,
2080 static const MemoryRegionOps gic_virt_ops[2] = {
2082 .read_with_attrs = gic_thiscpu_hyp_read,
2083 .write_with_attrs = gic_thiscpu_hyp_write,
2084 .endianness = DEVICE_NATIVE_ENDIAN,
2087 .read_with_attrs = gic_thisvcpu_read,
2088 .write_with_attrs = gic_thisvcpu_write,
2089 .endianness = DEVICE_NATIVE_ENDIAN,
2093 static const MemoryRegionOps gic_viface_ops = {
2094 .read_with_attrs = gic_do_hyp_read,
2095 .write_with_attrs = gic_do_hyp_write,
2096 .endianness = DEVICE_NATIVE_ENDIAN,
2099 static void arm_gic_realize(DeviceState *dev, Error **errp)
2101 /* Device instance realize function for the GIC sysbus device */
2102 int i;
2103 GICState *s = ARM_GIC(dev);
2104 SysBusDevice *sbd = SYS_BUS_DEVICE(dev);
2105 ARMGICClass *agc = ARM_GIC_GET_CLASS(s);
2106 Error *local_err = NULL;
2108 agc->parent_realize(dev, &local_err);
2109 if (local_err) {
2110 error_propagate(errp, local_err);
2111 return;
2114 if (kvm_enabled() && !kvm_arm_supports_user_irq()) {
2115 error_setg(errp, "KVM with user space irqchip only works when the "
2116 "host kernel supports KVM_CAP_ARM_USER_IRQ");
2117 return;
2120 if (s->n_prio_bits > GIC_MAX_PRIORITY_BITS ||
2121 (s->virt_extn ? s->n_prio_bits < GIC_VIRT_MAX_GROUP_PRIO_BITS :
2122 s->n_prio_bits < GIC_MIN_PRIORITY_BITS)) {
2123 error_setg(errp, "num-priority-bits cannot be greater than %d"
2124 " or less than %d", GIC_MAX_PRIORITY_BITS,
2125 s->virt_extn ? GIC_VIRT_MAX_GROUP_PRIO_BITS :
2126 GIC_MIN_PRIORITY_BITS);
2127 return;
2130 /* This creates distributor, main CPU interface (s->cpuiomem[0]) and if
2131 * enabled, virtualization extensions related interfaces (main virtual
2132 * interface (s->vifaceiomem[0]) and virtual CPU interface).
2134 gic_init_irqs_and_mmio(s, gic_set_irq, gic_ops, gic_virt_ops);
2136 /* Extra core-specific regions for the CPU interfaces. This is
2137 * necessary for "franken-GIC" implementations, for example on
2138 * Exynos 4.
2139 * NB that the memory region size of 0x100 applies for the 11MPCore
2140 * and also cores following the GIC v1 spec (ie A9).
2141 * GIC v2 defines a larger memory region (0x1000) so this will need
2142 * to be extended when we implement A15.
2144 for (i = 0; i < s->num_cpu; i++) {
2145 s->backref[i] = s;
2146 memory_region_init_io(&s->cpuiomem[i+1], OBJECT(s), &gic_cpu_ops,
2147 &s->backref[i], "gic_cpu", 0x100);
2148 sysbus_init_mmio(sbd, &s->cpuiomem[i+1]);
2151 /* Extra core-specific regions for virtual interfaces. This is required by
2152 * the GICv2 specification.
2154 if (s->virt_extn) {
2155 for (i = 0; i < s->num_cpu; i++) {
2156 memory_region_init_io(&s->vifaceiomem[i + 1], OBJECT(s),
2157 &gic_viface_ops, &s->backref[i],
2158 "gic_viface", 0x200);
2159 sysbus_init_mmio(sbd, &s->vifaceiomem[i + 1]);
2165 static void arm_gic_class_init(ObjectClass *klass, void *data)
2167 DeviceClass *dc = DEVICE_CLASS(klass);
2168 ARMGICClass *agc = ARM_GIC_CLASS(klass);
2170 device_class_set_parent_realize(dc, arm_gic_realize, &agc->parent_realize);
2173 static const TypeInfo arm_gic_info = {
2174 .name = TYPE_ARM_GIC,
2175 .parent = TYPE_ARM_GIC_COMMON,
2176 .instance_size = sizeof(GICState),
2177 .class_init = arm_gic_class_init,
2178 .class_size = sizeof(ARMGICClass),
2181 static void arm_gic_register_types(void)
2183 type_register_static(&arm_gic_info);
2186 type_init(arm_gic_register_types)