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/*
* ARM Generic Interrupt Controller v3 (emulation)
*
* Copyright (c) 2015 Huawei.
* Copyright (c) 2016 Linaro Limited
* Written by Shlomo Pongratz, Peter Maydell
*
* This code is licensed under the GPL, version 2 or (at your option)
* any later version.
*/
/* This file contains implementation code for an interrupt controller
* which implements the GICv3 architecture. Specifically this is where
* the device class itself and the functions for handling interrupts
* coming in and going out live.
*/
#include "qemu/osdep.h"
#include "qapi/error.h"
#include "qemu/module.h"
#include "hw/intc/arm_gicv3.h"
#include "gicv3_internal.h"
static bool irqbetter(GICv3CPUState *cs, int irq, uint8_t prio)
{
/* Return true if this IRQ at this priority should take
* precedence over the current recorded highest priority
* pending interrupt for this CPU. We also return true if
* the current recorded highest priority pending interrupt
* is the same as this one (a property which the calling code
* relies on).
*/
if (prio < cs->hppi.prio) {
return true;
}
/* If multiple pending interrupts have the same priority then it is an
* IMPDEF choice which of them to signal to the CPU. We choose to
* signal the one with the lowest interrupt number.
*/
if (prio == cs->hppi.prio && irq <= cs->hppi.irq) {
return true;
}
return false;
}
static uint32_t gicd_int_pending(GICv3State *s, int irq)
{
/* Recalculate which distributor interrupts are actually pending
* in the group of 32 interrupts starting at irq (which should be a multiple
* of 32), and return a 32-bit integer which has a bit set for each
* interrupt that is eligible to be signaled to the CPU interface.
*
* An interrupt is pending if:
* + the PENDING latch is set OR it is level triggered and the input is 1
* + its ENABLE bit is set
* + the GICD enable bit for its group is set
* + its ACTIVE bit is not set (otherwise it would be Active+Pending)
* Conveniently we can bulk-calculate this with bitwise operations.
*/
uint32_t pend, grpmask;
uint32_t pending = *gic_bmp_ptr32(s->pending, irq);
uint32_t edge_trigger = *gic_bmp_ptr32(s->edge_trigger, irq);
uint32_t level = *gic_bmp_ptr32(s->level, irq);
uint32_t group = *gic_bmp_ptr32(s->group, irq);
uint32_t grpmod = *gic_bmp_ptr32(s->grpmod, irq);
uint32_t enable = *gic_bmp_ptr32(s->enabled, irq);
uint32_t active = *gic_bmp_ptr32(s->active, irq);
pend = pending | (~edge_trigger & level);
pend &= enable;
pend &= ~active;
if (s->gicd_ctlr & GICD_CTLR_DS) {
grpmod = 0;
}
grpmask = 0;
if (s->gicd_ctlr & GICD_CTLR_EN_GRP1NS) {
grpmask |= group;
}
if (s->gicd_ctlr & GICD_CTLR_EN_GRP1S) {
grpmask |= (~group & grpmod);
}
if (s->gicd_ctlr & GICD_CTLR_EN_GRP0) {
grpmask |= (~group & ~grpmod);
}
pend &= grpmask;
return pend;
}
static uint32_t gicr_int_pending(GICv3CPUState *cs)
{
/* Recalculate which redistributor interrupts are actually pending,
* and return a 32-bit integer which has a bit set for each interrupt
* that is eligible to be signaled to the CPU interface.
*
* An interrupt is pending if:
* + the PENDING latch is set OR it is level triggered and the input is 1
* + its ENABLE bit is set
* + the GICD enable bit for its group is set
* + its ACTIVE bit is not set (otherwise it would be Active+Pending)
* Conveniently we can bulk-calculate this with bitwise operations.
*/
uint32_t pend, grpmask, grpmod;
pend = cs->gicr_ipendr0 | (~cs->edge_trigger & cs->level);
pend &= cs->gicr_ienabler0;
pend &= ~cs->gicr_iactiver0;
if (cs->gic->gicd_ctlr & GICD_CTLR_DS) {
grpmod = 0;
} else {
grpmod = cs->gicr_igrpmodr0;
}
grpmask = 0;
if (cs->gic->gicd_ctlr & GICD_CTLR_EN_GRP1NS) {
grpmask |= cs->gicr_igroupr0;
}
if (cs->gic->gicd_ctlr & GICD_CTLR_EN_GRP1S) {
grpmask |= (~cs->gicr_igroupr0 & grpmod);
}
if (cs->gic->gicd_ctlr & GICD_CTLR_EN_GRP0) {
grpmask |= (~cs->gicr_igroupr0 & ~grpmod);
}
pend &= grpmask;
return pend;
}
/* Update the interrupt status after state in a redistributor
* or CPU interface has changed, but don't tell the CPU i/f.
*/
static void gicv3_redist_update_noirqset(GICv3CPUState *cs)
{
/* Find the highest priority pending interrupt among the
* redistributor interrupts (SGIs and PPIs).
*/
bool seenbetter = false;
uint8_t prio;
int i;
uint32_t pend;
/* Find out which redistributor interrupts are eligible to be
* signaled to the CPU interface.
*/
pend = gicr_int_pending(cs);
if (pend) {
for (i = 0; i < GIC_INTERNAL; i++) {
if (!(pend & (1 << i))) {
continue;
}
prio = cs->gicr_ipriorityr[i];
if (irqbetter(cs, i, prio)) {
cs->hppi.irq = i;
cs->hppi.prio = prio;
seenbetter = true;
}
}
}
if (seenbetter) {
cs->hppi.grp = gicv3_irq_group(cs->gic, cs, cs->hppi.irq);
}
if ((cs->gicr_ctlr & GICR_CTLR_ENABLE_LPIS) && cs->gic->lpi_enable &&
(cs->gic->gicd_ctlr & GICD_CTLR_EN_GRP1NS) &&
(cs->hpplpi.prio != 0xff)) {
if (irqbetter(cs, cs->hpplpi.irq, cs->hpplpi.prio)) {
cs->hppi.irq = cs->hpplpi.irq;
cs->hppi.prio = cs->hpplpi.prio;
cs->hppi.grp = cs->hpplpi.grp;
seenbetter = true;
}
}
/* If the best interrupt we just found would preempt whatever
* was the previous best interrupt before this update, then
* we know it's definitely the best one now.
* If we didn't find an interrupt that would preempt the previous
* best, and the previous best is outside our range (or there was no
* previous pending interrupt at all), then that is still valid, and
* we leave it as the best.
* Otherwise, we need to do a full update (because the previous best
* interrupt has reduced in priority and any other interrupt could
* now be the new best one).
*/
if (!seenbetter && cs->hppi.prio != 0xff &&
(cs->hppi.irq < GIC_INTERNAL ||
cs->hppi.irq >= GICV3_LPI_INTID_START)) {
gicv3_full_update_noirqset(cs->gic);
}
}
/* Update the GIC status after state in a redistributor or
* CPU interface has changed, and inform the CPU i/f of
* its new highest priority pending interrupt.
*/
void gicv3_redist_update(GICv3CPUState *cs)
{
gicv3_redist_update_noirqset(cs);
gicv3_cpuif_update(cs);
}
/* Update the GIC status after state in the distributor has
* changed affecting @len interrupts starting at @start,
* but don't tell the CPU i/f.
*/
static void gicv3_update_noirqset(GICv3State *s, int start, int len)
{
int i;
uint8_t prio;
uint32_t pend = 0;
assert(start >= GIC_INTERNAL);
assert(len > 0);
for (i = 0; i < s->num_cpu; i++) {
s->cpu[i].seenbetter = false;
}
/* Find the highest priority pending interrupt in this range. */
for (i = start; i < start + len; i++) {
GICv3CPUState *cs;
if (i == start || (i & 0x1f) == 0) {
/* Calculate the next 32 bits worth of pending status */
pend = gicd_int_pending(s, i & ~0x1f);
}
if (!(pend & (1 << (i & 0x1f)))) {
continue;
}
cs = s->gicd_irouter_target[i];
if (!cs) {
/* Interrupts targeting no implemented CPU should remain pending
* and not be forwarded to any CPU.
*/
continue;
}
prio = s->gicd_ipriority[i];
if (irqbetter(cs, i, prio)) {
cs->hppi.irq = i;
cs->hppi.prio = prio;
cs->seenbetter = true;
}
}
/* If the best interrupt we just found would preempt whatever
* was the previous best interrupt before this update, then
* we know it's definitely the best one now.
* If we didn't find an interrupt that would preempt the previous
* best, and the previous best is outside our range (or there was
* no previous pending interrupt at all), then that
* is still valid, and we leave it as the best.
* Otherwise, we need to do a full update (because the previous best
* interrupt has reduced in priority and any other interrupt could
* now be the new best one).
*/
for (i = 0; i < s->num_cpu; i++) {
GICv3CPUState *cs = &s->cpu[i];
if (cs->seenbetter) {
cs->hppi.grp = gicv3_irq_group(cs->gic, cs, cs->hppi.irq);
}
if (!cs->seenbetter && cs->hppi.prio != 0xff &&
cs->hppi.irq >= start && cs->hppi.irq < start + len) {
gicv3_full_update_noirqset(s);
break;
}
}
}
void gicv3_update(GICv3State *s, int start, int len)
{
int i;
gicv3_update_noirqset(s, start, len);
for (i = 0; i < s->num_cpu; i++) {
gicv3_cpuif_update(&s->cpu[i]);
}
}
void gicv3_full_update_noirqset(GICv3State *s)
{
/* Completely recalculate the GIC status from scratch, but
* don't update any outbound IRQ lines.
*/
int i;
for (i = 0; i < s->num_cpu; i++) {
s->cpu[i].hppi.prio = 0xff;
}
/* Note that we can guarantee that these functions will not
* recursively call back into gicv3_full_update(), because
* at each point the "previous best" is always outside the
* range we ask them to update.
*/
gicv3_update_noirqset(s, GIC_INTERNAL, s->num_irq - GIC_INTERNAL);
for (i = 0; i < s->num_cpu; i++) {
gicv3_redist_update_noirqset(&s->cpu[i]);
}
}
void gicv3_full_update(GICv3State *s)
{
/* Completely recalculate the GIC status from scratch, including
* updating outbound IRQ lines.
*/
int i;
gicv3_full_update_noirqset(s);
for (i = 0; i < s->num_cpu; i++) {
gicv3_cpuif_update(&s->cpu[i]);
}
}
/* Process a change in an external IRQ input. */
static void gicv3_set_irq(void *opaque, int irq, int level)
{
/* Meaning of the 'irq' parameter:
* [0..N-1] : external interrupts
* [N..N+31] : PPI (internal) interrupts for CPU 0
* [N+32..N+63] : PPI (internal interrupts for CPU 1
* ...
*/
GICv3State *s = opaque;
if (irq < (s->num_irq - GIC_INTERNAL)) {
/* external interrupt (SPI) */
gicv3_dist_set_irq(s, irq + GIC_INTERNAL, level);
} else {
/* per-cpu interrupt (PPI) */
int cpu;
irq -= (s->num_irq - GIC_INTERNAL);
cpu = irq / GIC_INTERNAL;
irq %= GIC_INTERNAL;
assert(cpu < s->num_cpu);
/* Raising SGIs via this function would be a bug in how the board
* model wires up interrupts.
*/
assert(irq >= GIC_NR_SGIS);
gicv3_redist_set_irq(&s->cpu[cpu], irq, level);
}
}
static void arm_gicv3_post_load(GICv3State *s)
{
int i;
/* Recalculate our cached idea of the current highest priority
* pending interrupt, but don't set IRQ or FIQ lines.
*/
for (i = 0; i < s->num_cpu; i++) {
gicv3_redist_update_lpi_only(&s->cpu[i]);
}
gicv3_full_update_noirqset(s);
/* Repopulate the cache of GICv3CPUState pointers for target CPUs */
gicv3_cache_all_target_cpustates(s);
}
static const MemoryRegionOps gic_ops[] = {
{
.read_with_attrs = gicv3_dist_read,
.write_with_attrs = gicv3_dist_write,
.endianness = DEVICE_NATIVE_ENDIAN,
.valid.min_access_size = 1,
.valid.max_access_size = 8,
.impl.min_access_size = 1,
.impl.max_access_size = 8,
},
{
.read_with_attrs = gicv3_redist_read,
.write_with_attrs = gicv3_redist_write,
.endianness = DEVICE_NATIVE_ENDIAN,
.valid.min_access_size = 1,
.valid.max_access_size = 8,
.impl.min_access_size = 1,
.impl.max_access_size = 8,
}
};
static void arm_gic_realize(DeviceState *dev, Error **errp)
{
/* Device instance realize function for the GIC sysbus device */
GICv3State *s = ARM_GICV3(dev);
ARMGICv3Class *agc = ARM_GICV3_GET_CLASS(s);
Error *local_err = NULL;
agc->parent_realize(dev, &local_err);
if (local_err) {
error_propagate(errp, local_err);
return;
}
gicv3_init_irqs_and_mmio(s, gicv3_set_irq, gic_ops);
gicv3_init_cpuif(s);
}
static void arm_gicv3_class_init(ObjectClass *klass, void *data)
{
DeviceClass *dc = DEVICE_CLASS(klass);
ARMGICv3CommonClass *agcc = ARM_GICV3_COMMON_CLASS(klass);
ARMGICv3Class *agc = ARM_GICV3_CLASS(klass);
agcc->post_load = arm_gicv3_post_load;
device_class_set_parent_realize(dc, arm_gic_realize, &agc->parent_realize);
}
static const TypeInfo arm_gicv3_info = {
.name = TYPE_ARM_GICV3,
.parent = TYPE_ARM_GICV3_COMMON,
.instance_size = sizeof(GICv3State),
.class_init = arm_gicv3_class_init,
.class_size = sizeof(ARMGICv3Class),
};
static void arm_gicv3_register_types(void)
{
type_register_static(&arm_gicv3_info);
}
type_init(arm_gicv3_register_types)
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