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linux-stable/arch/powerpc/kvm/book3s_xive.c
Jordan Niethe dfcaacc8f9 KVM: PPC: Book3s HV: Hold LPIDs in an unsigned long 
The LPID register is 32 bits long. The host keeps the lpids for each
guest in an unsigned word struct kvm_arch. Currently, LPIDs are already
limited by mmu_lpid_bits and KVM_MAX_NESTED_GUESTS_SHIFT.

The nestedv2 API returns a 64 bit "Guest ID" to be used be the L1 host
for each L2 guest. This value is used as an lpid, e.g. it is the
parameter used by H_RPT_INVALIDATE. To minimize needless special casing
it makes sense to keep this "Guest ID" in struct kvm_arch::lpid.

This means that struct kvm_arch::lpid is too small so prepare for this
and make it an unsigned long. This is not a problem for the KVM-HV and
nestedv1 cases as their lpid values are already limited to valid ranges
so in those contexts the lpid can be used as an unsigned word safely as
needed.

In the PAPR, the H_RPT_INVALIDATE pid/lpid parameter is already
specified as an unsigned long so change pseries_rpt_invalidate() to
match that.  Update the callers of pseries_rpt_invalidate() to also take
an unsigned long if they take an lpid value.

Signed-off-by: Jordan Niethe <jniethe5@gmail.com>
Signed-off-by: Michael Ellerman <mpe@ellerman.id.au>
Link: https://msgid.link/20230914030600.16993-10-jniethe5@gmail.com
2023-09-14 22:04:24 +10:00

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// SPDX-License-Identifier: GPL-2.0-only
/*
* Copyright 2017 Benjamin Herrenschmidt, IBM Corporation.
*/
#define pr_fmt(fmt) "xive-kvm: " fmt
#include <linux/kernel.h>
#include <linux/kvm_host.h>
#include <linux/err.h>
#include <linux/gfp.h>
#include <linux/spinlock.h>
#include <linux/delay.h>
#include <linux/percpu.h>
#include <linux/cpumask.h>
#include <linux/uaccess.h>
#include <linux/irqdomain.h>
#include <asm/kvm_book3s.h>
#include <asm/kvm_ppc.h>
#include <asm/hvcall.h>
#include <asm/xics.h>
#include <asm/xive.h>
#include <asm/xive-regs.h>
#include <asm/debug.h>
#include <asm/time.h>
#include <asm/opal.h>
#include <linux/debugfs.h>
#include <linux/seq_file.h>
#include "book3s_xive.h"
#define __x_eoi_page(xd) ((void __iomem *)((xd)->eoi_mmio))
#define __x_trig_page(xd) ((void __iomem *)((xd)->trig_mmio))
/* Dummy interrupt used when taking interrupts out of a queue in H_CPPR */
#define XICS_DUMMY 1
static void xive_vm_ack_pending(struct kvmppc_xive_vcpu *xc)
{
u8 cppr;
u16 ack;
/*
* Ensure any previous store to CPPR is ordered vs.
* the subsequent loads from PIPR or ACK.
*/
eieio();
/* Perform the acknowledge OS to register cycle. */
ack = be16_to_cpu(__raw_readw(xive_tima + TM_SPC_ACK_OS_REG));
/* Synchronize subsequent queue accesses */
mb();
/* XXX Check grouping level */
/* Anything ? */
if (!((ack >> 8) & TM_QW1_NSR_EO))
return;
/* Grab CPPR of the most favored pending interrupt */
cppr = ack & 0xff;
if (cppr < 8)
xc->pending |= 1 << cppr;
/* Check consistency */
if (cppr >= xc->hw_cppr)
pr_warn("KVM-XIVE: CPU %d odd ack CPPR, got %d at %d\n",
smp_processor_id(), cppr, xc->hw_cppr);
/*
* Update our image of the HW CPPR. We don't yet modify
* xc->cppr, this will be done as we scan for interrupts
* in the queues.
*/
xc->hw_cppr = cppr;
}
static u8 xive_vm_esb_load(struct xive_irq_data *xd, u32 offset)
{
u64 val;
if (offset == XIVE_ESB_SET_PQ_10 && xd->flags & XIVE_IRQ_FLAG_STORE_EOI)
offset |= XIVE_ESB_LD_ST_MO;
val = __raw_readq(__x_eoi_page(xd) + offset);
#ifdef __LITTLE_ENDIAN__
val >>= 64-8;
#endif
return (u8)val;
}
static void xive_vm_source_eoi(u32 hw_irq, struct xive_irq_data *xd)
{
/* If the XIVE supports the new "store EOI facility, use it */
if (xd->flags & XIVE_IRQ_FLAG_STORE_EOI)
__raw_writeq(0, __x_eoi_page(xd) + XIVE_ESB_STORE_EOI);
else if (xd->flags & XIVE_IRQ_FLAG_LSI) {
/*
* For LSIs the HW EOI cycle is used rather than PQ bits,
* as they are automatically re-triggred in HW when still
* pending.
*/
__raw_readq(__x_eoi_page(xd) + XIVE_ESB_LOAD_EOI);
} else {
uint64_t eoi_val;
/*
* Otherwise for EOI, we use the special MMIO that does
* a clear of both P and Q and returns the old Q,
* except for LSIs where we use the "EOI cycle" special
* load.
*
* This allows us to then do a re-trigger if Q was set
* rather than synthetizing an interrupt in software
*/
eoi_val = xive_vm_esb_load(xd, XIVE_ESB_SET_PQ_00);
/* Re-trigger if needed */
if ((eoi_val & 1) && __x_trig_page(xd))
__raw_writeq(0, __x_trig_page(xd));
}
}
enum {
scan_fetch,
scan_poll,
scan_eoi,
};
static u32 xive_vm_scan_interrupts(struct kvmppc_xive_vcpu *xc,
u8 pending, int scan_type)
{
u32 hirq = 0;
u8 prio = 0xff;
/* Find highest pending priority */
while ((xc->mfrr != 0xff || pending != 0) && hirq == 0) {
struct xive_q *q;
u32 idx, toggle;
__be32 *qpage;
/*
* If pending is 0 this will return 0xff which is what
* we want
*/
prio = ffs(pending) - 1;
/* Don't scan past the guest cppr */
if (prio >= xc->cppr || prio > 7) {
if (xc->mfrr < xc->cppr) {
prio = xc->mfrr;
hirq = XICS_IPI;
}
break;
}
/* Grab queue and pointers */
q = &xc->queues[prio];
idx = q->idx;
toggle = q->toggle;
/*
* Snapshot the queue page. The test further down for EOI
* must use the same "copy" that was used by __xive_read_eq
* since qpage can be set concurrently and we don't want
* to miss an EOI.
*/
qpage = READ_ONCE(q->qpage);
skip_ipi:
/*
* Try to fetch from the queue. Will return 0 for a
* non-queueing priority (ie, qpage = 0).
*/
hirq = __xive_read_eq(qpage, q->msk, &idx, &toggle);
/*
* If this was a signal for an MFFR change done by
* H_IPI we skip it. Additionally, if we were fetching
* we EOI it now, thus re-enabling reception of a new
* such signal.
*
* We also need to do that if prio is 0 and we had no
* page for the queue. In this case, we have non-queued
* IPI that needs to be EOId.
*
* This is safe because if we have another pending MFRR
* change that wasn't observed above, the Q bit will have
* been set and another occurrence of the IPI will trigger.
*/
if (hirq == XICS_IPI || (prio == 0 && !qpage)) {
if (scan_type == scan_fetch) {
xive_vm_source_eoi(xc->vp_ipi,
&xc->vp_ipi_data);
q->idx = idx;
q->toggle = toggle;
}
/* Loop back on same queue with updated idx/toggle */
WARN_ON(hirq && hirq != XICS_IPI);
if (hirq)
goto skip_ipi;
}
/* If it's the dummy interrupt, continue searching */
if (hirq == XICS_DUMMY)
goto skip_ipi;
/* Clear the pending bit if the queue is now empty */
if (!hirq) {
pending &= ~(1 << prio);
/*
* Check if the queue count needs adjusting due to
* interrupts being moved away.
*/
if (atomic_read(&q->pending_count)) {
int p = atomic_xchg(&q->pending_count, 0);
if (p) {
WARN_ON(p > atomic_read(&q->count));
atomic_sub(p, &q->count);
}
}
}
/*
* If the most favoured prio we found pending is less
* favored (or equal) than a pending IPI, we return
* the IPI instead.
*/
if (prio >= xc->mfrr && xc->mfrr < xc->cppr) {
prio = xc->mfrr;
hirq = XICS_IPI;
break;
}
/* If fetching, update queue pointers */
if (scan_type == scan_fetch) {
q->idx = idx;
q->toggle = toggle;
}
}
/* If we are just taking a "peek", do nothing else */
if (scan_type == scan_poll)
return hirq;
/* Update the pending bits */
xc->pending = pending;
/*
* If this is an EOI that's it, no CPPR adjustment done here,
* all we needed was cleanup the stale pending bits and check
* if there's anything left.
*/
if (scan_type == scan_eoi)
return hirq;
/*
* If we found an interrupt, adjust what the guest CPPR should
* be as if we had just fetched that interrupt from HW.
*
* Note: This can only make xc->cppr smaller as the previous
* loop will only exit with hirq != 0 if prio is lower than
* the current xc->cppr. Thus we don't need to re-check xc->mfrr
* for pending IPIs.
*/
if (hirq)
xc->cppr = prio;
/*
* If it was an IPI the HW CPPR might have been lowered too much
* as the HW interrupt we use for IPIs is routed to priority 0.
*
* We re-sync it here.
*/
if (xc->cppr != xc->hw_cppr) {
xc->hw_cppr = xc->cppr;
__raw_writeb(xc->cppr, xive_tima + TM_QW1_OS + TM_CPPR);
}
return hirq;
}
static unsigned long xive_vm_h_xirr(struct kvm_vcpu *vcpu)
{
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
u8 old_cppr;
u32 hirq;
pr_devel("H_XIRR\n");
xc->stat_vm_h_xirr++;
/* First collect pending bits from HW */
xive_vm_ack_pending(xc);
pr_devel(" new pending=0x%02x hw_cppr=%d cppr=%d\n",
xc->pending, xc->hw_cppr, xc->cppr);
/* Grab previous CPPR and reverse map it */
old_cppr = xive_prio_to_guest(xc->cppr);
/* Scan for actual interrupts */
hirq = xive_vm_scan_interrupts(xc, xc->pending, scan_fetch);
pr_devel(" got hirq=0x%x hw_cppr=%d cppr=%d\n",
hirq, xc->hw_cppr, xc->cppr);
/* That should never hit */
if (hirq & 0xff000000)
pr_warn("XIVE: Weird guest interrupt number 0x%08x\n", hirq);
/*
* XXX We could check if the interrupt is masked here and
* filter it. If we chose to do so, we would need to do:
*
* if (masked) {
* lock();
* if (masked) {
* old_Q = true;
* hirq = 0;
* }
* unlock();
* }
*/
/* Return interrupt and old CPPR in GPR4 */
kvmppc_set_gpr(vcpu, 4, hirq | (old_cppr << 24));
return H_SUCCESS;
}
static unsigned long xive_vm_h_ipoll(struct kvm_vcpu *vcpu, unsigned long server)
{
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
u8 pending = xc->pending;
u32 hirq;
pr_devel("H_IPOLL(server=%ld)\n", server);
xc->stat_vm_h_ipoll++;
/* Grab the target VCPU if not the current one */
if (xc->server_num != server) {
vcpu = kvmppc_xive_find_server(vcpu->kvm, server);
if (!vcpu)
return H_PARAMETER;
xc = vcpu->arch.xive_vcpu;
/* Scan all priorities */
pending = 0xff;
} else {
/* Grab pending interrupt if any */
__be64 qw1 = __raw_readq(xive_tima + TM_QW1_OS);
u8 pipr = be64_to_cpu(qw1) & 0xff;
if (pipr < 8)
pending |= 1 << pipr;
}
hirq = xive_vm_scan_interrupts(xc, pending, scan_poll);
/* Return interrupt and old CPPR in GPR4 */
kvmppc_set_gpr(vcpu, 4, hirq | (xc->cppr << 24));
return H_SUCCESS;
}
static void xive_vm_push_pending_to_hw(struct kvmppc_xive_vcpu *xc)
{
u8 pending, prio;
pending = xc->pending;
if (xc->mfrr != 0xff) {
if (xc->mfrr < 8)
pending |= 1 << xc->mfrr;
else
pending |= 0x80;
}
if (!pending)
return;
prio = ffs(pending) - 1;
__raw_writeb(prio, xive_tima + TM_SPC_SET_OS_PENDING);
}
static void xive_vm_scan_for_rerouted_irqs(struct kvmppc_xive *xive,
struct kvmppc_xive_vcpu *xc)
{
unsigned int prio;
/* For each priority that is now masked */
for (prio = xc->cppr; prio < KVMPPC_XIVE_Q_COUNT; prio++) {
struct xive_q *q = &xc->queues[prio];
struct kvmppc_xive_irq_state *state;
struct kvmppc_xive_src_block *sb;
u32 idx, toggle, entry, irq, hw_num;
struct xive_irq_data *xd;
__be32 *qpage;
u16 src;
idx = q->idx;
toggle = q->toggle;
qpage = READ_ONCE(q->qpage);
if (!qpage)
continue;
/* For each interrupt in the queue */
for (;;) {
entry = be32_to_cpup(qpage + idx);
/* No more ? */
if ((entry >> 31) == toggle)
break;
irq = entry & 0x7fffffff;
/* Skip dummies and IPIs */
if (irq == XICS_DUMMY || irq == XICS_IPI)
goto next;
sb = kvmppc_xive_find_source(xive, irq, &src);
if (!sb)
goto next;
state = &sb->irq_state[src];
/* Has it been rerouted ? */
if (xc->server_num == state->act_server)
goto next;
/*
* Allright, it *has* been re-routed, kill it from
* the queue.
*/
qpage[idx] = cpu_to_be32((entry & 0x80000000) | XICS_DUMMY);
/* Find the HW interrupt */
kvmppc_xive_select_irq(state, &hw_num, &xd);
/* If it's not an LSI, set PQ to 11 the EOI will force a resend */
if (!(xd->flags & XIVE_IRQ_FLAG_LSI))
xive_vm_esb_load(xd, XIVE_ESB_SET_PQ_11);
/* EOI the source */
xive_vm_source_eoi(hw_num, xd);
next:
idx = (idx + 1) & q->msk;
if (idx == 0)
toggle ^= 1;
}
}
}
static int xive_vm_h_cppr(struct kvm_vcpu *vcpu, unsigned long cppr)
{
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
struct kvmppc_xive *xive = vcpu->kvm->arch.xive;
u8 old_cppr;
pr_devel("H_CPPR(cppr=%ld)\n", cppr);
xc->stat_vm_h_cppr++;
/* Map CPPR */
cppr = xive_prio_from_guest(cppr);
/* Remember old and update SW state */
old_cppr = xc->cppr;
xc->cppr = cppr;
/*
* Order the above update of xc->cppr with the subsequent
* read of xc->mfrr inside push_pending_to_hw()
*/
smp_mb();
if (cppr > old_cppr) {
/*
* We are masking less, we need to look for pending things
* to deliver and set VP pending bits accordingly to trigger
* a new interrupt otherwise we might miss MFRR changes for
* which we have optimized out sending an IPI signal.
*/
xive_vm_push_pending_to_hw(xc);
} else {
/*
* We are masking more, we need to check the queue for any
* interrupt that has been routed to another CPU, take
* it out (replace it with the dummy) and retrigger it.
*
* This is necessary since those interrupts may otherwise
* never be processed, at least not until this CPU restores
* its CPPR.
*
* This is in theory racy vs. HW adding new interrupts to
* the queue. In practice this works because the interesting
* cases are when the guest has done a set_xive() to move the
* interrupt away, which flushes the xive, followed by the
* target CPU doing a H_CPPR. So any new interrupt coming into
* the queue must still be routed to us and isn't a source
* of concern.
*/
xive_vm_scan_for_rerouted_irqs(xive, xc);
}
/* Apply new CPPR */
xc->hw_cppr = cppr;
__raw_writeb(cppr, xive_tima + TM_QW1_OS + TM_CPPR);
return H_SUCCESS;
}
static int xive_vm_h_eoi(struct kvm_vcpu *vcpu, unsigned long xirr)
{
struct kvmppc_xive *xive = vcpu->kvm->arch.xive;
struct kvmppc_xive_src_block *sb;
struct kvmppc_xive_irq_state *state;
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
struct xive_irq_data *xd;
u8 new_cppr = xirr >> 24;
u32 irq = xirr & 0x00ffffff, hw_num;
u16 src;
int rc = 0;
pr_devel("H_EOI(xirr=%08lx)\n", xirr);
xc->stat_vm_h_eoi++;
xc->cppr = xive_prio_from_guest(new_cppr);
/*
* IPIs are synthetized from MFRR and thus don't need
* any special EOI handling. The underlying interrupt
* used to signal MFRR changes is EOId when fetched from
* the queue.
*/
if (irq == XICS_IPI || irq == 0) {
/*
* This barrier orders the setting of xc->cppr vs.
* subsequent test of xc->mfrr done inside
* scan_interrupts and push_pending_to_hw
*/
smp_mb();
goto bail;
}
/* Find interrupt source */
sb = kvmppc_xive_find_source(xive, irq, &src);
if (!sb) {
pr_devel(" source not found !\n");
rc = H_PARAMETER;
/* Same as above */
smp_mb();
goto bail;
}
state = &sb->irq_state[src];
kvmppc_xive_select_irq(state, &hw_num, &xd);
state->in_eoi = true;
/*
* This barrier orders both setting of in_eoi above vs,
* subsequent test of guest_priority, and the setting
* of xc->cppr vs. subsequent test of xc->mfrr done inside
* scan_interrupts and push_pending_to_hw
*/
smp_mb();
again:
if (state->guest_priority == MASKED) {
arch_spin_lock(&sb->lock);
if (state->guest_priority != MASKED) {
arch_spin_unlock(&sb->lock);
goto again;
}
pr_devel(" EOI on saved P...\n");
/* Clear old_p, that will cause unmask to perform an EOI */
state->old_p = false;
arch_spin_unlock(&sb->lock);
} else {
pr_devel(" EOI on source...\n");
/* Perform EOI on the source */
xive_vm_source_eoi(hw_num, xd);
/* If it's an emulated LSI, check level and resend */
if (state->lsi && state->asserted)
__raw_writeq(0, __x_trig_page(xd));
}
/*
* This barrier orders the above guest_priority check
* and spin_lock/unlock with clearing in_eoi below.
*
* It also has to be a full mb() as it must ensure
* the MMIOs done in source_eoi() are completed before
* state->in_eoi is visible.
*/
mb();
state->in_eoi = false;
bail:
/* Re-evaluate pending IRQs and update HW */
xive_vm_scan_interrupts(xc, xc->pending, scan_eoi);
xive_vm_push_pending_to_hw(xc);
pr_devel(" after scan pending=%02x\n", xc->pending);
/* Apply new CPPR */
xc->hw_cppr = xc->cppr;
__raw_writeb(xc->cppr, xive_tima + TM_QW1_OS + TM_CPPR);
return rc;
}
static int xive_vm_h_ipi(struct kvm_vcpu *vcpu, unsigned long server,
unsigned long mfrr)
{
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
pr_devel("H_IPI(server=%08lx,mfrr=%ld)\n", server, mfrr);
xc->stat_vm_h_ipi++;
/* Find target */
vcpu = kvmppc_xive_find_server(vcpu->kvm, server);
if (!vcpu)
return H_PARAMETER;
xc = vcpu->arch.xive_vcpu;
/* Locklessly write over MFRR */
xc->mfrr = mfrr;
/*
* The load of xc->cppr below and the subsequent MMIO store
* to the IPI must happen after the above mfrr update is
* globally visible so that:
*
* - Synchronize with another CPU doing an H_EOI or a H_CPPR
* updating xc->cppr then reading xc->mfrr.
*
* - The target of the IPI sees the xc->mfrr update
*/
mb();
/* Shoot the IPI if most favored than target cppr */
if (mfrr < xc->cppr)
__raw_writeq(0, __x_trig_page(&xc->vp_ipi_data));
return H_SUCCESS;
}
/*
* We leave a gap of a couple of interrupts in the queue to
* account for the IPI and additional safety guard.
*/
#define XIVE_Q_GAP 2
static bool kvmppc_xive_vcpu_has_save_restore(struct kvm_vcpu *vcpu)
{
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
/* Check enablement at VP level */
return xc->vp_cam & TM_QW1W2_HO;
}
bool kvmppc_xive_check_save_restore(struct kvm_vcpu *vcpu)
{
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
struct kvmppc_xive *xive = xc->xive;
if (xive->flags & KVMPPC_XIVE_FLAG_SAVE_RESTORE)
return kvmppc_xive_vcpu_has_save_restore(vcpu);
return true;
}
/*
* Push a vcpu's context to the XIVE on guest entry.
* This assumes we are in virtual mode (MMU on)
*/
void kvmppc_xive_push_vcpu(struct kvm_vcpu *vcpu)
{
void __iomem *tima = local_paca->kvm_hstate.xive_tima_virt;
u64 pq;
/*
* Nothing to do if the platform doesn't have a XIVE
* or this vCPU doesn't have its own XIVE context
* (e.g. because it's not using an in-kernel interrupt controller).
*/
if (!tima || !vcpu->arch.xive_cam_word)
return;
eieio();
if (!kvmppc_xive_vcpu_has_save_restore(vcpu))
__raw_writeq(vcpu->arch.xive_saved_state.w01, tima + TM_QW1_OS);
__raw_writel(vcpu->arch.xive_cam_word, tima + TM_QW1_OS + TM_WORD2);
vcpu->arch.xive_pushed = 1;
eieio();
/*
* We clear the irq_pending flag. There is a small chance of a
* race vs. the escalation interrupt happening on another
* processor setting it again, but the only consequence is to
* cause a spurious wakeup on the next H_CEDE, which is not an
* issue.
*/
vcpu->arch.irq_pending = 0;
/*
* In single escalation mode, if the escalation interrupt is
* on, we mask it.
*/
if (vcpu->arch.xive_esc_on) {
pq = __raw_readq((void __iomem *)(vcpu->arch.xive_esc_vaddr +
XIVE_ESB_SET_PQ_01));
mb();
/*
* We have a possible subtle race here: The escalation
* interrupt might have fired and be on its way to the
* host queue while we mask it, and if we unmask it
* early enough (re-cede right away), there is a
* theoretical possibility that it fires again, thus
* landing in the target queue more than once which is
* a big no-no.
*
* Fortunately, solving this is rather easy. If the
* above load setting PQ to 01 returns a previous
* value where P is set, then we know the escalation
* interrupt is somewhere on its way to the host. In
* that case we simply don't clear the xive_esc_on
* flag below. It will be eventually cleared by the
* handler for the escalation interrupt.
*
* Then, when doing a cede, we check that flag again
* before re-enabling the escalation interrupt, and if
* set, we abort the cede.
*/
if (!(pq & XIVE_ESB_VAL_P))
/* Now P is 0, we can clear the flag */
vcpu->arch.xive_esc_on = 0;
}
}
EXPORT_SYMBOL_GPL(kvmppc_xive_push_vcpu);
/*
* Pull a vcpu's context from the XIVE on guest exit.
* This assumes we are in virtual mode (MMU on)
*/
void kvmppc_xive_pull_vcpu(struct kvm_vcpu *vcpu)
{
void __iomem *tima = local_paca->kvm_hstate.xive_tima_virt;
if (!vcpu->arch.xive_pushed)
return;
/*
* Should not have been pushed if there is no tima
*/
if (WARN_ON(!tima))
return;
eieio();
/* First load to pull the context, we ignore the value */
__raw_readl(tima + TM_SPC_PULL_OS_CTX);
/* Second load to recover the context state (Words 0 and 1) */
if (!kvmppc_xive_vcpu_has_save_restore(vcpu))
vcpu->arch.xive_saved_state.w01 = __raw_readq(tima + TM_QW1_OS);
/* Fixup some of the state for the next load */
vcpu->arch.xive_saved_state.lsmfb = 0;
vcpu->arch.xive_saved_state.ack = 0xff;
vcpu->arch.xive_pushed = 0;
eieio();
}
EXPORT_SYMBOL_GPL(kvmppc_xive_pull_vcpu);
bool kvmppc_xive_rearm_escalation(struct kvm_vcpu *vcpu)
{
void __iomem *esc_vaddr = (void __iomem *)vcpu->arch.xive_esc_vaddr;
bool ret = true;
if (!esc_vaddr)
return ret;
/* we are using XIVE with single escalation */
if (vcpu->arch.xive_esc_on) {
/*
* If we still have a pending escalation, abort the cede,
* and we must set PQ to 10 rather than 00 so that we don't
* potentially end up with two entries for the escalation
* interrupt in the XIVE interrupt queue. In that case
* we also don't want to set xive_esc_on to 1 here in
* case we race with xive_esc_irq().
*/
ret = false;
/*
* The escalation interrupts are special as we don't EOI them.
* There is no need to use the load-after-store ordering offset
* to set PQ to 10 as we won't use StoreEOI.
*/
__raw_readq(esc_vaddr + XIVE_ESB_SET_PQ_10);
} else {
vcpu->arch.xive_esc_on = true;
mb();
__raw_readq(esc_vaddr + XIVE_ESB_SET_PQ_00);
}
mb();
return ret;
}
EXPORT_SYMBOL_GPL(kvmppc_xive_rearm_escalation);
/*
* This is a simple trigger for a generic XIVE IRQ. This must
* only be called for interrupts that support a trigger page
*/
static bool xive_irq_trigger(struct xive_irq_data *xd)
{
/* This should be only for MSIs */
if (WARN_ON(xd->flags & XIVE_IRQ_FLAG_LSI))
return false;
/* Those interrupts should always have a trigger page */
if (WARN_ON(!xd->trig_mmio))
return false;
out_be64(xd->trig_mmio, 0);
return true;
}
static irqreturn_t xive_esc_irq(int irq, void *data)
{
struct kvm_vcpu *vcpu = data;
vcpu->arch.irq_pending = 1;
smp_mb();
if (vcpu->arch.ceded || vcpu->arch.nested)
kvmppc_fast_vcpu_kick(vcpu);
/* Since we have the no-EOI flag, the interrupt is effectively
* disabled now. Clearing xive_esc_on means we won't bother
* doing so on the next entry.
*
* This also allows the entry code to know that if a PQ combination
* of 10 is observed while xive_esc_on is true, it means the queue
* contains an unprocessed escalation interrupt. We don't make use of
* that knowledge today but might (see comment in book3s_hv_rmhandler.S)
*/
vcpu->arch.xive_esc_on = false;
/* This orders xive_esc_on = false vs. subsequent stale_p = true */
smp_wmb(); /* goes with smp_mb() in cleanup_single_escalation */
return IRQ_HANDLED;
}
int kvmppc_xive_attach_escalation(struct kvm_vcpu *vcpu, u8 prio,
bool single_escalation)
{
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
struct xive_q *q = &xc->queues[prio];
char *name = NULL;
int rc;
/* Already there ? */
if (xc->esc_virq[prio])
return 0;
/* Hook up the escalation interrupt */
xc->esc_virq[prio] = irq_create_mapping(NULL, q->esc_irq);
if (!xc->esc_virq[prio]) {
pr_err("Failed to map escalation interrupt for queue %d of VCPU %d\n",
prio, xc->server_num);
return -EIO;
}
if (single_escalation)
name = kasprintf(GFP_KERNEL, "kvm-%lld-%d",
vcpu->kvm->arch.lpid, xc->server_num);
else
name = kasprintf(GFP_KERNEL, "kvm-%lld-%d-%d",
vcpu->kvm->arch.lpid, xc->server_num, prio);
if (!name) {
pr_err("Failed to allocate escalation irq name for queue %d of VCPU %d\n",
prio, xc->server_num);
rc = -ENOMEM;
goto error;
}
pr_devel("Escalation %s irq %d (prio %d)\n", name, xc->esc_virq[prio], prio);
rc = request_irq(xc->esc_virq[prio], xive_esc_irq,
IRQF_NO_THREAD, name, vcpu);
if (rc) {
pr_err("Failed to request escalation interrupt for queue %d of VCPU %d\n",
prio, xc->server_num);
goto error;
}
xc->esc_virq_names[prio] = name;
/* In single escalation mode, we grab the ESB MMIO of the
* interrupt and mask it. Also populate the VCPU v/raddr
* of the ESB page for use by asm entry/exit code. Finally
* set the XIVE_IRQ_FLAG_NO_EOI flag which will prevent the
* core code from performing an EOI on the escalation
* interrupt, thus leaving it effectively masked after
* it fires once.
*/
if (single_escalation) {
struct irq_data *d = irq_get_irq_data(xc->esc_virq[prio]);
struct xive_irq_data *xd = irq_data_get_irq_handler_data(d);
xive_vm_esb_load(xd, XIVE_ESB_SET_PQ_01);
vcpu->arch.xive_esc_raddr = xd->eoi_page;
vcpu->arch.xive_esc_vaddr = (__force u64)xd->eoi_mmio;
xd->flags |= XIVE_IRQ_FLAG_NO_EOI;
}
return 0;
error:
irq_dispose_mapping(xc->esc_virq[prio]);
xc->esc_virq[prio] = 0;
kfree(name);
return rc;
}
static int xive_provision_queue(struct kvm_vcpu *vcpu, u8 prio)
{
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
struct kvmppc_xive *xive = xc->xive;
struct xive_q *q = &xc->queues[prio];
void *qpage;
int rc;
if (WARN_ON(q->qpage))
return 0;
/* Allocate the queue and retrieve infos on current node for now */
qpage = (__be32 *)__get_free_pages(GFP_KERNEL, xive->q_page_order);
if (!qpage) {
pr_err("Failed to allocate queue %d for VCPU %d\n",
prio, xc->server_num);
return -ENOMEM;
}
memset(qpage, 0, 1 << xive->q_order);
/*
* Reconfigure the queue. This will set q->qpage only once the
* queue is fully configured. This is a requirement for prio 0
* as we will stop doing EOIs for every IPI as soon as we observe
* qpage being non-NULL, and instead will only EOI when we receive
* corresponding queue 0 entries
*/
rc = xive_native_configure_queue(xc->vp_id, q, prio, qpage,
xive->q_order, true);
if (rc)
pr_err("Failed to configure queue %d for VCPU %d\n",
prio, xc->server_num);
return rc;
}
/* Called with xive->lock held */
static int xive_check_provisioning(struct kvm *kvm, u8 prio)
{
struct kvmppc_xive *xive = kvm->arch.xive;
struct kvm_vcpu *vcpu;
unsigned long i;
int rc;
lockdep_assert_held(&xive->lock);
/* Already provisioned ? */
if (xive->qmap & (1 << prio))
return 0;
pr_devel("Provisioning prio... %d\n", prio);
/* Provision each VCPU and enable escalations if needed */
kvm_for_each_vcpu(i, vcpu, kvm) {
if (!vcpu->arch.xive_vcpu)
continue;
rc = xive_provision_queue(vcpu, prio);
if (rc == 0 && !kvmppc_xive_has_single_escalation(xive))
kvmppc_xive_attach_escalation(vcpu, prio,
kvmppc_xive_has_single_escalation(xive));
if (rc)
return rc;
}
/* Order previous stores and mark it as provisioned */
mb();
xive->qmap |= (1 << prio);
return 0;
}
static void xive_inc_q_pending(struct kvm *kvm, u32 server, u8 prio)
{
struct kvm_vcpu *vcpu;
struct kvmppc_xive_vcpu *xc;
struct xive_q *q;
/* Locate target server */
vcpu = kvmppc_xive_find_server(kvm, server);
if (!vcpu) {
pr_warn("%s: Can't find server %d\n", __func__, server);
return;
}
xc = vcpu->arch.xive_vcpu;
if (WARN_ON(!xc))
return;
q = &xc->queues[prio];
atomic_inc(&q->pending_count);
}
static int xive_try_pick_queue(struct kvm_vcpu *vcpu, u8 prio)
{
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
struct xive_q *q;
u32 max;
if (WARN_ON(!xc))
return -ENXIO;
if (!xc->valid)
return -ENXIO;
q = &xc->queues[prio];
if (WARN_ON(!q->qpage))
return -ENXIO;
/* Calculate max number of interrupts in that queue. */
max = (q->msk + 1) - XIVE_Q_GAP;
return atomic_add_unless(&q->count, 1, max) ? 0 : -EBUSY;
}
int kvmppc_xive_select_target(struct kvm *kvm, u32 *server, u8 prio)
{
struct kvm_vcpu *vcpu;
unsigned long i;
int rc;
/* Locate target server */
vcpu = kvmppc_xive_find_server(kvm, *server);
if (!vcpu) {
pr_devel("Can't find server %d\n", *server);
return -EINVAL;
}
pr_devel("Finding irq target on 0x%x/%d...\n", *server, prio);
/* Try pick it */
rc = xive_try_pick_queue(vcpu, prio);
if (rc == 0)
return rc;
pr_devel(" .. failed, looking up candidate...\n");
/* Failed, pick another VCPU */
kvm_for_each_vcpu(i, vcpu, kvm) {
if (!vcpu->arch.xive_vcpu)
continue;
rc = xive_try_pick_queue(vcpu, prio);
if (rc == 0) {
*server = vcpu->arch.xive_vcpu->server_num;
pr_devel(" found on 0x%x/%d\n", *server, prio);
return rc;
}
}
pr_devel(" no available target !\n");
/* No available target ! */
return -EBUSY;
}
static u8 xive_lock_and_mask(struct kvmppc_xive *xive,
struct kvmppc_xive_src_block *sb,
struct kvmppc_xive_irq_state *state)
{
struct xive_irq_data *xd;
u32 hw_num;
u8 old_prio;
u64 val;
/*
* Take the lock, set masked, try again if racing
* with H_EOI
*/
for (;;) {
arch_spin_lock(&sb->lock);
old_prio = state->guest_priority;
state->guest_priority = MASKED;
mb();
if (!state->in_eoi)
break;
state->guest_priority = old_prio;
arch_spin_unlock(&sb->lock);
}
/* No change ? Bail */
if (old_prio == MASKED)
return old_prio;
/* Get the right irq */
kvmppc_xive_select_irq(state, &hw_num, &xd);
/* Set PQ to 10, return old P and old Q and remember them */
val = xive_vm_esb_load(xd, XIVE_ESB_SET_PQ_10);
state->old_p = !!(val & 2);
state->old_q = !!(val & 1);
/*
* Synchronize hardware to sensure the queues are updated when
* masking
*/
xive_native_sync_source(hw_num);
return old_prio;
}
static void xive_lock_for_unmask(struct kvmppc_xive_src_block *sb,
struct kvmppc_xive_irq_state *state)
{
/*
* Take the lock try again if racing with H_EOI
*/
for (;;) {
arch_spin_lock(&sb->lock);
if (!state->in_eoi)
break;
arch_spin_unlock(&sb->lock);
}
}
static void xive_finish_unmask(struct kvmppc_xive *xive,
struct kvmppc_xive_src_block *sb,
struct kvmppc_xive_irq_state *state,
u8 prio)
{
struct xive_irq_data *xd;
u32 hw_num;
/* If we aren't changing a thing, move on */
if (state->guest_priority != MASKED)
goto bail;
/* Get the right irq */
kvmppc_xive_select_irq(state, &hw_num, &xd);
/* Old Q set, set PQ to 11 */
if (state->old_q)
xive_vm_esb_load(xd, XIVE_ESB_SET_PQ_11);
/*
* If not old P, then perform an "effective" EOI,
* on the source. This will handle the cases where
* FW EOI is needed.
*/
if (!state->old_p)
xive_vm_source_eoi(hw_num, xd);
/* Synchronize ordering and mark unmasked */
mb();
bail:
state->guest_priority = prio;
}
/*
* Target an interrupt to a given server/prio, this will fallback
* to another server if necessary and perform the HW targetting
* updates as needed
*
* NOTE: Must be called with the state lock held
*/
static int xive_target_interrupt(struct kvm *kvm,
struct kvmppc_xive_irq_state *state,
u32 server, u8 prio)
{
struct kvmppc_xive *xive = kvm->arch.xive;
u32 hw_num;
int rc;
/*
* This will return a tentative server and actual
* priority. The count for that new target will have
* already been incremented.
*/
rc = kvmppc_xive_select_target(kvm, &server, prio);
/*
* We failed to find a target ? Not much we can do
* at least until we support the GIQ.
*/
if (rc)
return rc;
/*
* Increment the old queue pending count if there
* was one so that the old queue count gets adjusted later
* when observed to be empty.
*/
if (state->act_priority != MASKED)
xive_inc_q_pending(kvm,
state->act_server,
state->act_priority);
/*
* Update state and HW
*/
state->act_priority = prio;
state->act_server = server;
/* Get the right irq */
kvmppc_xive_select_irq(state, &hw_num, NULL);
return xive_native_configure_irq(hw_num,
kvmppc_xive_vp(xive, server),
prio, state->number);
}
/*
* Targetting rules: In order to avoid losing track of
* pending interrupts across mask and unmask, which would
* allow queue overflows, we implement the following rules:
*
* - Unless it was never enabled (or we run out of capacity)
* an interrupt is always targetted at a valid server/queue
* pair even when "masked" by the guest. This pair tends to
* be the last one used but it can be changed under some
* circumstances. That allows us to separate targetting
* from masking, we only handle accounting during (re)targetting,
* this also allows us to let an interrupt drain into its target
* queue after masking, avoiding complex schemes to remove
* interrupts out of remote processor queues.
*
* - When masking, we set PQ to 10 and save the previous value
* of P and Q.
*
* - When unmasking, if saved Q was set, we set PQ to 11
* otherwise we leave PQ to the HW state which will be either
* 10 if nothing happened or 11 if the interrupt fired while
* masked. Effectively we are OR'ing the previous Q into the
* HW Q.
*
* Then if saved P is clear, we do an effective EOI (Q->P->Trigger)
* which will unmask the interrupt and shoot a new one if Q was
* set.
*
* Otherwise (saved P is set) we leave PQ unchanged (so 10 or 11,
* effectively meaning an H_EOI from the guest is still expected
* for that interrupt).
*
* - If H_EOI occurs while masked, we clear the saved P.
*
* - When changing target, we account on the new target and
* increment a separate "pending" counter on the old one.
* This pending counter will be used to decrement the old
* target's count when its queue has been observed empty.
*/
int kvmppc_xive_set_xive(struct kvm *kvm, u32 irq, u32 server,
u32 priority)
{
struct kvmppc_xive *xive = kvm->arch.xive;
struct kvmppc_xive_src_block *sb;
struct kvmppc_xive_irq_state *state;
u8 new_act_prio;
int rc = 0;
u16 idx;
if (!xive)
return -ENODEV;
pr_devel("set_xive ! irq 0x%x server 0x%x prio %d\n",
irq, server, priority);
/* First, check provisioning of queues */
if (priority != MASKED) {
mutex_lock(&xive->lock);
rc = xive_check_provisioning(xive->kvm,
xive_prio_from_guest(priority));
mutex_unlock(&xive->lock);
}
if (rc) {
pr_devel(" provisioning failure %d !\n", rc);
return rc;
}
sb = kvmppc_xive_find_source(xive, irq, &idx);
if (!sb)
return -EINVAL;
state = &sb->irq_state[idx];
/*
* We first handle masking/unmasking since the locking
* might need to be retried due to EOIs, we'll handle
* targetting changes later. These functions will return
* with the SB lock held.
*
* xive_lock_and_mask() will also set state->guest_priority
* but won't otherwise change other fields of the state.
*
* xive_lock_for_unmask will not actually unmask, this will
* be done later by xive_finish_unmask() once the targetting
* has been done, so we don't try to unmask an interrupt
* that hasn't yet been targetted.
*/
if (priority == MASKED)
xive_lock_and_mask(xive, sb, state);
else
xive_lock_for_unmask(sb, state);
/*
* Then we handle targetting.
*
* First calculate a new "actual priority"
*/
new_act_prio = state->act_priority;
if (priority != MASKED)
new_act_prio = xive_prio_from_guest(priority);
pr_devel(" new_act_prio=%x act_server=%x act_prio=%x\n",
new_act_prio, state->act_server, state->act_priority);
/*
* Then check if we actually need to change anything,
*
* The condition for re-targetting the interrupt is that
* we have a valid new priority (new_act_prio is not 0xff)
* and either the server or the priority changed.
*
* Note: If act_priority was ff and the new priority is
* also ff, we don't do anything and leave the interrupt
* untargetted. An attempt of doing an int_on on an
* untargetted interrupt will fail. If that is a problem
* we could initialize interrupts with valid default
*/
if (new_act_prio != MASKED &&
(state->act_server != server ||
state->act_priority != new_act_prio))
rc = xive_target_interrupt(kvm, state, server, new_act_prio);
/*
* Perform the final unmasking of the interrupt source
* if necessary
*/
if (priority != MASKED)
xive_finish_unmask(xive, sb, state, priority);
/*
* Finally Update saved_priority to match. Only int_on/off
* set this field to a different value.
*/
state->saved_priority = priority;
arch_spin_unlock(&sb->lock);
return rc;
}
int kvmppc_xive_get_xive(struct kvm *kvm, u32 irq, u32 *server,
u32 *priority)
{
struct kvmppc_xive *xive = kvm->arch.xive;
struct kvmppc_xive_src_block *sb;
struct kvmppc_xive_irq_state *state;
u16 idx;
if (!xive)
return -ENODEV;
sb = kvmppc_xive_find_source(xive, irq, &idx);
if (!sb)
return -EINVAL;
state = &sb->irq_state[idx];
arch_spin_lock(&sb->lock);
*server = state->act_server;
*priority = state->guest_priority;
arch_spin_unlock(&sb->lock);
return 0;
}
int kvmppc_xive_int_on(struct kvm *kvm, u32 irq)
{
struct kvmppc_xive *xive = kvm->arch.xive;
struct kvmppc_xive_src_block *sb;
struct kvmppc_xive_irq_state *state;
u16 idx;
if (!xive)
return -ENODEV;
sb = kvmppc_xive_find_source(xive, irq, &idx);
if (!sb)
return -EINVAL;
state = &sb->irq_state[idx];
pr_devel("int_on(irq=0x%x)\n", irq);
/*
* Check if interrupt was not targetted
*/
if (state->act_priority == MASKED) {
pr_devel("int_on on untargetted interrupt\n");
return -EINVAL;
}
/* If saved_priority is 0xff, do nothing */
if (state->saved_priority == MASKED)
return 0;
/*
* Lock and unmask it.
*/
xive_lock_for_unmask(sb, state);
xive_finish_unmask(xive, sb, state, state->saved_priority);
arch_spin_unlock(&sb->lock);
return 0;
}
int kvmppc_xive_int_off(struct kvm *kvm, u32 irq)
{
struct kvmppc_xive *xive = kvm->arch.xive;
struct kvmppc_xive_src_block *sb;
struct kvmppc_xive_irq_state *state;
u16 idx;
if (!xive)
return -ENODEV;
sb = kvmppc_xive_find_source(xive, irq, &idx);
if (!sb)
return -EINVAL;
state = &sb->irq_state[idx];
pr_devel("int_off(irq=0x%x)\n", irq);
/*
* Lock and mask
*/
state->saved_priority = xive_lock_and_mask(xive, sb, state);
arch_spin_unlock(&sb->lock);
return 0;
}
static bool xive_restore_pending_irq(struct kvmppc_xive *xive, u32 irq)
{
struct kvmppc_xive_src_block *sb;
struct kvmppc_xive_irq_state *state;
u16 idx;
sb = kvmppc_xive_find_source(xive, irq, &idx);
if (!sb)
return false;
state = &sb->irq_state[idx];
if (!state->valid)
return false;
/*
* Trigger the IPI. This assumes we never restore a pass-through
* interrupt which should be safe enough
*/
xive_irq_trigger(&state->ipi_data);
return true;
}
u64 kvmppc_xive_get_icp(struct kvm_vcpu *vcpu)
{
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
if (!xc)
return 0;
/* Return the per-cpu state for state saving/migration */
return (u64)xc->cppr << KVM_REG_PPC_ICP_CPPR_SHIFT |
(u64)xc->mfrr << KVM_REG_PPC_ICP_MFRR_SHIFT |
(u64)0xff << KVM_REG_PPC_ICP_PPRI_SHIFT;
}
int kvmppc_xive_set_icp(struct kvm_vcpu *vcpu, u64 icpval)
{
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
struct kvmppc_xive *xive = vcpu->kvm->arch.xive;
u8 cppr, mfrr;
u32 xisr;
if (!xc || !xive)
return -ENOENT;
/* Grab individual state fields. We don't use pending_pri */
cppr = icpval >> KVM_REG_PPC_ICP_CPPR_SHIFT;
xisr = (icpval >> KVM_REG_PPC_ICP_XISR_SHIFT) &
KVM_REG_PPC_ICP_XISR_MASK;
mfrr = icpval >> KVM_REG_PPC_ICP_MFRR_SHIFT;
pr_devel("set_icp vcpu %d cppr=0x%x mfrr=0x%x xisr=0x%x\n",
xc->server_num, cppr, mfrr, xisr);
/*
* We can't update the state of a "pushed" VCPU, but that
* shouldn't happen because the vcpu->mutex makes running a
* vcpu mutually exclusive with doing one_reg get/set on it.
*/
if (WARN_ON(vcpu->arch.xive_pushed))
return -EIO;
/* Update VCPU HW saved state */
vcpu->arch.xive_saved_state.cppr = cppr;
xc->hw_cppr = xc->cppr = cppr;
/*
* Update MFRR state. If it's not 0xff, we mark the VCPU as
* having a pending MFRR change, which will re-evaluate the
* target. The VCPU will thus potentially get a spurious
* interrupt but that's not a big deal.
*/
xc->mfrr = mfrr;
if (mfrr < cppr)
xive_irq_trigger(&xc->vp_ipi_data);
/*
* Now saved XIRR is "interesting". It means there's something in
* the legacy "1 element" queue... for an IPI we simply ignore it,
* as the MFRR restore will handle that. For anything else we need
* to force a resend of the source.
* However the source may not have been setup yet. If that's the
* case, we keep that info and increment a counter in the xive to
* tell subsequent xive_set_source() to go look.
*/
if (xisr > XICS_IPI && !xive_restore_pending_irq(xive, xisr)) {
xc->delayed_irq = xisr;
xive->delayed_irqs++;
pr_devel(" xisr restore delayed\n");
}
return 0;
}
int kvmppc_xive_set_mapped(struct kvm *kvm, unsigned long guest_irq,
unsigned long host_irq)
{
struct kvmppc_xive *xive = kvm->arch.xive;
struct kvmppc_xive_src_block *sb;
struct kvmppc_xive_irq_state *state;
struct irq_data *host_data =
irq_domain_get_irq_data(irq_get_default_host(), host_irq);
unsigned int hw_irq = (unsigned int)irqd_to_hwirq(host_data);
u16 idx;
u8 prio;
int rc;
if (!xive)
return -ENODEV;
pr_debug("%s: GIRQ 0x%lx host IRQ %ld XIVE HW IRQ 0x%x\n",
__func__, guest_irq, host_irq, hw_irq);
sb = kvmppc_xive_find_source(xive, guest_irq, &idx);
if (!sb)
return -EINVAL;
state = &sb->irq_state[idx];
/*
* Mark the passed-through interrupt as going to a VCPU,
* this will prevent further EOIs and similar operations
* from the XIVE code. It will also mask the interrupt
* to either PQ=10 or 11 state, the latter if the interrupt
* is pending. This will allow us to unmask or retrigger it
* after routing it to the guest with a simple EOI.
*
* The "state" argument is a "token", all it needs is to be
* non-NULL to switch to passed-through or NULL for the
* other way around. We may not yet have an actual VCPU
* target here and we don't really care.
*/
rc = irq_set_vcpu_affinity(host_irq, state);
if (rc) {
pr_err("Failed to set VCPU affinity for host IRQ %ld\n", host_irq);
return rc;
}
/*
* Mask and read state of IPI. We need to know if its P bit
* is set as that means it's potentially already using a
* queue entry in the target
*/
prio = xive_lock_and_mask(xive, sb, state);
pr_devel(" old IPI prio %02x P:%d Q:%d\n", prio,
state->old_p, state->old_q);
/* Turn the IPI hard off */
xive_vm_esb_load(&state->ipi_data, XIVE_ESB_SET_PQ_01);
/*
* Reset ESB guest mapping. Needed when ESB pages are exposed
* to the guest in XIVE native mode
*/
if (xive->ops && xive->ops->reset_mapped)
xive->ops->reset_mapped(kvm, guest_irq);
/* Grab info about irq */
state->pt_number = hw_irq;
state->pt_data = irq_data_get_irq_handler_data(host_data);
/*
* Configure the IRQ to match the existing configuration of
* the IPI if it was already targetted. Otherwise this will
* mask the interrupt in a lossy way (act_priority is 0xff)
* which is fine for a never started interrupt.
*/
xive_native_configure_irq(hw_irq,
kvmppc_xive_vp(xive, state->act_server),
state->act_priority, state->number);
/*
* We do an EOI to enable the interrupt (and retrigger if needed)
* if the guest has the interrupt unmasked and the P bit was *not*
* set in the IPI. If it was set, we know a slot may still be in
* use in the target queue thus we have to wait for a guest
* originated EOI
*/
if (prio != MASKED && !state->old_p)
xive_vm_source_eoi(hw_irq, state->pt_data);
/* Clear old_p/old_q as they are no longer relevant */
state->old_p = state->old_q = false;
/* Restore guest prio (unlocks EOI) */
mb();
state->guest_priority = prio;
arch_spin_unlock(&sb->lock);
return 0;
}
EXPORT_SYMBOL_GPL(kvmppc_xive_set_mapped);
int kvmppc_xive_clr_mapped(struct kvm *kvm, unsigned long guest_irq,
unsigned long host_irq)
{
struct kvmppc_xive *xive = kvm->arch.xive;
struct kvmppc_xive_src_block *sb;
struct kvmppc_xive_irq_state *state;
u16 idx;
u8 prio;
int rc;
if (!xive)
return -ENODEV;
pr_debug("%s: GIRQ 0x%lx host IRQ %ld\n", __func__, guest_irq, host_irq);
sb = kvmppc_xive_find_source(xive, guest_irq, &idx);
if (!sb)
return -EINVAL;
state = &sb->irq_state[idx];
/*
* Mask and read state of IRQ. We need to know if its P bit
* is set as that means it's potentially already using a
* queue entry in the target
*/
prio = xive_lock_and_mask(xive, sb, state);
pr_devel(" old IRQ prio %02x P:%d Q:%d\n", prio,
state->old_p, state->old_q);
/*
* If old_p is set, the interrupt is pending, we switch it to
* PQ=11. This will force a resend in the host so the interrupt
* isn't lost to whatever host driver may pick it up
*/
if (state->old_p)
xive_vm_esb_load(state->pt_data, XIVE_ESB_SET_PQ_11);
/* Release the passed-through interrupt to the host */
rc = irq_set_vcpu_affinity(host_irq, NULL);
if (rc) {
pr_err("Failed to clr VCPU affinity for host IRQ %ld\n", host_irq);
return rc;
}
/* Forget about the IRQ */
state->pt_number = 0;
state->pt_data = NULL;
/*
* Reset ESB guest mapping. Needed when ESB pages are exposed
* to the guest in XIVE native mode
*/
if (xive->ops && xive->ops->reset_mapped) {
xive->ops->reset_mapped(kvm, guest_irq);
}
/* Reconfigure the IPI */
xive_native_configure_irq(state->ipi_number,
kvmppc_xive_vp(xive, state->act_server),
state->act_priority, state->number);
/*
* If old_p is set (we have a queue entry potentially
* occupied) or the interrupt is masked, we set the IPI
* to PQ=10 state. Otherwise we just re-enable it (PQ=00).
*/
if (prio == MASKED || state->old_p)
xive_vm_esb_load(&state->ipi_data, XIVE_ESB_SET_PQ_10);
else
xive_vm_esb_load(&state->ipi_data, XIVE_ESB_SET_PQ_00);
/* Restore guest prio (unlocks EOI) */
mb();
state->guest_priority = prio;
arch_spin_unlock(&sb->lock);
return 0;
}
EXPORT_SYMBOL_GPL(kvmppc_xive_clr_mapped);
void kvmppc_xive_disable_vcpu_interrupts(struct kvm_vcpu *vcpu)
{
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
struct kvm *kvm = vcpu->kvm;
struct kvmppc_xive *xive = kvm->arch.xive;
int i, j;
for (i = 0; i <= xive->max_sbid; i++) {
struct kvmppc_xive_src_block *sb = xive->src_blocks[i];
if (!sb)
continue;
for (j = 0; j < KVMPPC_XICS_IRQ_PER_ICS; j++) {
struct kvmppc_xive_irq_state *state = &sb->irq_state[j];
if (!state->valid)
continue;
if (state->act_priority == MASKED)
continue;
if (state->act_server != xc->server_num)
continue;
/* Clean it up */
arch_spin_lock(&sb->lock);
state->act_priority = MASKED;
xive_vm_esb_load(&state->ipi_data, XIVE_ESB_SET_PQ_01);
xive_native_configure_irq(state->ipi_number, 0, MASKED, 0);
if (state->pt_number) {
xive_vm_esb_load(state->pt_data, XIVE_ESB_SET_PQ_01);
xive_native_configure_irq(state->pt_number, 0, MASKED, 0);
}
arch_spin_unlock(&sb->lock);
}
}
/* Disable vcpu's escalation interrupt */
if (vcpu->arch.xive_esc_on) {
__raw_readq((void __iomem *)(vcpu->arch.xive_esc_vaddr +
XIVE_ESB_SET_PQ_01));
vcpu->arch.xive_esc_on = false;
}
/*
* Clear pointers to escalation interrupt ESB.
* This is safe because the vcpu->mutex is held, preventing
* any other CPU from concurrently executing a KVM_RUN ioctl.
*/
vcpu->arch.xive_esc_vaddr = 0;
vcpu->arch.xive_esc_raddr = 0;
}
/*
* In single escalation mode, the escalation interrupt is marked so
* that EOI doesn't re-enable it, but just sets the stale_p flag to
* indicate that the P bit has already been dealt with. However, the
* assembly code that enters the guest sets PQ to 00 without clearing
* stale_p (because it has no easy way to address it). Hence we have
* to adjust stale_p before shutting down the interrupt.
*/
void xive_cleanup_single_escalation(struct kvm_vcpu *vcpu, int irq)
{
struct irq_data *d = irq_get_irq_data(irq);
struct xive_irq_data *xd = irq_data_get_irq_handler_data(d);
/*
* This slightly odd sequence gives the right result
* (i.e. stale_p set if xive_esc_on is false) even if
* we race with xive_esc_irq() and xive_irq_eoi().
*/
xd->stale_p = false;
smp_mb(); /* paired with smb_wmb in xive_esc_irq */
if (!vcpu->arch.xive_esc_on)
xd->stale_p = true;
}
void kvmppc_xive_cleanup_vcpu(struct kvm_vcpu *vcpu)
{
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
struct kvmppc_xive *xive = vcpu->kvm->arch.xive;
int i;
if (!kvmppc_xics_enabled(vcpu))
return;
if (!xc)
return;
pr_devel("cleanup_vcpu(cpu=%d)\n", xc->server_num);
/* Ensure no interrupt is still routed to that VP */
xc->valid = false;
kvmppc_xive_disable_vcpu_interrupts(vcpu);
/* Mask the VP IPI */
xive_vm_esb_load(&xc->vp_ipi_data, XIVE_ESB_SET_PQ_01);
/* Free escalations */
for (i = 0; i < KVMPPC_XIVE_Q_COUNT; i++) {
if (xc->esc_virq[i]) {
if (kvmppc_xive_has_single_escalation(xc->xive))
xive_cleanup_single_escalation(vcpu, xc->esc_virq[i]);
free_irq(xc->esc_virq[i], vcpu);
irq_dispose_mapping(xc->esc_virq[i]);
kfree(xc->esc_virq_names[i]);
}
}
/* Disable the VP */
xive_native_disable_vp(xc->vp_id);
/* Clear the cam word so guest entry won't try to push context */
vcpu->arch.xive_cam_word = 0;
/* Free the queues */
for (i = 0; i < KVMPPC_XIVE_Q_COUNT; i++) {
struct xive_q *q = &xc->queues[i];
xive_native_disable_queue(xc->vp_id, q, i);
if (q->qpage) {
free_pages((unsigned long)q->qpage,
xive->q_page_order);
q->qpage = NULL;
}
}
/* Free the IPI */
if (xc->vp_ipi) {
xive_cleanup_irq_data(&xc->vp_ipi_data);
xive_native_free_irq(xc->vp_ipi);
}
/* Free the VP */
kfree(xc);
/* Cleanup the vcpu */
vcpu->arch.irq_type = KVMPPC_IRQ_DEFAULT;
vcpu->arch.xive_vcpu = NULL;
}
static bool kvmppc_xive_vcpu_id_valid(struct kvmppc_xive *xive, u32 cpu)
{
/* We have a block of xive->nr_servers VPs. We just need to check
* packed vCPU ids are below that.
*/
return kvmppc_pack_vcpu_id(xive->kvm, cpu) < xive->nr_servers;
}
int kvmppc_xive_compute_vp_id(struct kvmppc_xive *xive, u32 cpu, u32 *vp)
{
u32 vp_id;
if (!kvmppc_xive_vcpu_id_valid(xive, cpu)) {
pr_devel("Out of bounds !\n");
return -EINVAL;
}
if (xive->vp_base == XIVE_INVALID_VP) {
xive->vp_base = xive_native_alloc_vp_block(xive->nr_servers);
pr_devel("VP_Base=%x nr_servers=%d\n", xive->vp_base, xive->nr_servers);
if (xive->vp_base == XIVE_INVALID_VP)
return -ENOSPC;
}
vp_id = kvmppc_xive_vp(xive, cpu);
if (kvmppc_xive_vp_in_use(xive->kvm, vp_id)) {
pr_devel("Duplicate !\n");
return -EEXIST;
}
*vp = vp_id;
return 0;
}
int kvmppc_xive_connect_vcpu(struct kvm_device *dev,
struct kvm_vcpu *vcpu, u32 cpu)
{
struct kvmppc_xive *xive = dev->private;
struct kvmppc_xive_vcpu *xc;
int i, r = -EBUSY;
u32 vp_id;
pr_devel("connect_vcpu(cpu=%d)\n", cpu);
if (dev->ops != &kvm_xive_ops) {
pr_devel("Wrong ops !\n");
return -EPERM;
}
if (xive->kvm != vcpu->kvm)
return -EPERM;
if (vcpu->arch.irq_type != KVMPPC_IRQ_DEFAULT)
return -EBUSY;
/* We need to synchronize with queue provisioning */
mutex_lock(&xive->lock);
r = kvmppc_xive_compute_vp_id(xive, cpu, &vp_id);
if (r)
goto bail;
xc = kzalloc(sizeof(*xc), GFP_KERNEL);
if (!xc) {
r = -ENOMEM;
goto bail;
}
vcpu->arch.xive_vcpu = xc;
xc->xive = xive;
xc->vcpu = vcpu;
xc->server_num = cpu;
xc->vp_id = vp_id;
xc->mfrr = 0xff;
xc->valid = true;
r = xive_native_get_vp_info(xc->vp_id, &xc->vp_cam, &xc->vp_chip_id);
if (r)
goto bail;
if (!kvmppc_xive_check_save_restore(vcpu)) {
pr_err("inconsistent save-restore setup for VCPU %d\n", cpu);
r = -EIO;
goto bail;
}
/* Configure VCPU fields for use by assembly push/pull */
vcpu->arch.xive_saved_state.w01 = cpu_to_be64(0xff000000);
vcpu->arch.xive_cam_word = cpu_to_be32(xc->vp_cam | TM_QW1W2_VO);
/* Allocate IPI */
xc->vp_ipi = xive_native_alloc_irq();
if (!xc->vp_ipi) {
pr_err("Failed to allocate xive irq for VCPU IPI\n");
r = -EIO;
goto bail;
}
pr_devel(" IPI=0x%x\n", xc->vp_ipi);
r = xive_native_populate_irq_data(xc->vp_ipi, &xc->vp_ipi_data);
if (r)
goto bail;
/*
* Enable the VP first as the single escalation mode will
* affect escalation interrupts numbering
*/
r = xive_native_enable_vp(xc->vp_id, kvmppc_xive_has_single_escalation(xive));
if (r) {
pr_err("Failed to enable VP in OPAL, err %d\n", r);
goto bail;
}
/*
* Initialize queues. Initially we set them all for no queueing
* and we enable escalation for queue 0 only which we'll use for
* our mfrr change notifications. If the VCPU is hot-plugged, we
* do handle provisioning however based on the existing "map"
* of enabled queues.
*/
for (i = 0; i < KVMPPC_XIVE_Q_COUNT; i++) {
struct xive_q *q = &xc->queues[i];
/* Single escalation, no queue 7 */
if (i == 7 && kvmppc_xive_has_single_escalation(xive))
break;
/* Is queue already enabled ? Provision it */
if (xive->qmap & (1 << i)) {
r = xive_provision_queue(vcpu, i);
if (r == 0 && !kvmppc_xive_has_single_escalation(xive))
kvmppc_xive_attach_escalation(
vcpu, i, kvmppc_xive_has_single_escalation(xive));
if (r)
goto bail;
} else {
r = xive_native_configure_queue(xc->vp_id,
q, i, NULL, 0, true);
if (r) {
pr_err("Failed to configure queue %d for VCPU %d\n",
i, cpu);
goto bail;
}
}
}
/* If not done above, attach priority 0 escalation */
r = kvmppc_xive_attach_escalation(vcpu, 0, kvmppc_xive_has_single_escalation(xive));
if (r)
goto bail;
/* Route the IPI */
r = xive_native_configure_irq(xc->vp_ipi, xc->vp_id, 0, XICS_IPI);
if (!r)
xive_vm_esb_load(&xc->vp_ipi_data, XIVE_ESB_SET_PQ_00);
bail:
mutex_unlock(&xive->lock);
if (r) {
kvmppc_xive_cleanup_vcpu(vcpu);
return r;
}
vcpu->arch.irq_type = KVMPPC_IRQ_XICS;
return 0;
}
/*
* Scanning of queues before/after migration save
*/
static void xive_pre_save_set_queued(struct kvmppc_xive *xive, u32 irq)
{
struct kvmppc_xive_src_block *sb;
struct kvmppc_xive_irq_state *state;
u16 idx;
sb = kvmppc_xive_find_source(xive, irq, &idx);
if (!sb)
return;
state = &sb->irq_state[idx];
/* Some sanity checking */
if (!state->valid) {
pr_err("invalid irq 0x%x in cpu queue!\n", irq);
return;
}
/*
* If the interrupt is in a queue it should have P set.
* We warn so that gets reported. A backtrace isn't useful
* so no need to use a WARN_ON.
*/
if (!state->saved_p)
pr_err("Interrupt 0x%x is marked in a queue but P not set !\n", irq);
/* Set flag */
state->in_queue = true;
}
static void xive_pre_save_mask_irq(struct kvmppc_xive *xive,
struct kvmppc_xive_src_block *sb,
u32 irq)
{
struct kvmppc_xive_irq_state *state = &sb->irq_state[irq];
if (!state->valid)
return;
/* Mask and save state, this will also sync HW queues */
state->saved_scan_prio = xive_lock_and_mask(xive, sb, state);
/* Transfer P and Q */
state->saved_p = state->old_p;
state->saved_q = state->old_q;
/* Unlock */
arch_spin_unlock(&sb->lock);
}
static void xive_pre_save_unmask_irq(struct kvmppc_xive *xive,
struct kvmppc_xive_src_block *sb,
u32 irq)
{
struct kvmppc_xive_irq_state *state = &sb->irq_state[irq];
if (!state->valid)
return;
/*
* Lock / exclude EOI (not technically necessary if the
* guest isn't running concurrently. If this becomes a
* performance issue we can probably remove the lock.
*/
xive_lock_for_unmask(sb, state);
/* Restore mask/prio if it wasn't masked */
if (state->saved_scan_prio != MASKED)
xive_finish_unmask(xive, sb, state, state->saved_scan_prio);
/* Unlock */
arch_spin_unlock(&sb->lock);
}
static void xive_pre_save_queue(struct kvmppc_xive *xive, struct xive_q *q)
{
u32 idx = q->idx;
u32 toggle = q->toggle;
u32 irq;
do {
irq = __xive_read_eq(q->qpage, q->msk, &idx, &toggle);
if (irq > XICS_IPI)
xive_pre_save_set_queued(xive, irq);
} while(irq);
}
static void xive_pre_save_scan(struct kvmppc_xive *xive)
{
struct kvm_vcpu *vcpu = NULL;
unsigned long i;
int j;
/*
* See comment in xive_get_source() about how this
* work. Collect a stable state for all interrupts
*/
for (i = 0; i <= xive->max_sbid; i++) {
struct kvmppc_xive_src_block *sb = xive->src_blocks[i];
if (!sb)
continue;
for (j = 0; j < KVMPPC_XICS_IRQ_PER_ICS; j++)
xive_pre_save_mask_irq(xive, sb, j);
}
/* Then scan the queues and update the "in_queue" flag */
kvm_for_each_vcpu(i, vcpu, xive->kvm) {
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
if (!xc)
continue;
for (j = 0; j < KVMPPC_XIVE_Q_COUNT; j++) {
if (xc->queues[j].qpage)
xive_pre_save_queue(xive, &xc->queues[j]);
}
}
/* Finally restore interrupt states */
for (i = 0; i <= xive->max_sbid; i++) {
struct kvmppc_xive_src_block *sb = xive->src_blocks[i];
if (!sb)
continue;
for (j = 0; j < KVMPPC_XICS_IRQ_PER_ICS; j++)
xive_pre_save_unmask_irq(xive, sb, j);
}
}
static void xive_post_save_scan(struct kvmppc_xive *xive)
{
u32 i, j;
/* Clear all the in_queue flags */
for (i = 0; i <= xive->max_sbid; i++) {
struct kvmppc_xive_src_block *sb = xive->src_blocks[i];
if (!sb)
continue;
for (j = 0; j < KVMPPC_XICS_IRQ_PER_ICS; j++)
sb->irq_state[j].in_queue = false;
}
/* Next get_source() will do a new scan */
xive->saved_src_count = 0;
}
/*
* This returns the source configuration and state to user space.
*/
static int xive_get_source(struct kvmppc_xive *xive, long irq, u64 addr)
{
struct kvmppc_xive_src_block *sb;
struct kvmppc_xive_irq_state *state;
u64 __user *ubufp = (u64 __user *) addr;
u64 val, prio;
u16 idx;
sb = kvmppc_xive_find_source(xive, irq, &idx);
if (!sb)
return -ENOENT;
state = &sb->irq_state[idx];
if (!state->valid)
return -ENOENT;
pr_devel("get_source(%ld)...\n", irq);
/*
* So to properly save the state into something that looks like a
* XICS migration stream we cannot treat interrupts individually.
*
* We need, instead, mask them all (& save their previous PQ state)
* to get a stable state in the HW, then sync them to ensure that
* any interrupt that had already fired hits its queue, and finally
* scan all the queues to collect which interrupts are still present
* in the queues, so we can set the "pending" flag on them and
* they can be resent on restore.
*
* So we do it all when the "first" interrupt gets saved, all the
* state is collected at that point, the rest of xive_get_source()
* will merely collect and convert that state to the expected
* userspace bit mask.
*/
if (xive->saved_src_count == 0)
xive_pre_save_scan(xive);
xive->saved_src_count++;
/* Convert saved state into something compatible with xics */
val = state->act_server;
prio = state->saved_scan_prio;
if (prio == MASKED) {
val |= KVM_XICS_MASKED;
prio = state->saved_priority;
}
val |= prio << KVM_XICS_PRIORITY_SHIFT;
if (state->lsi) {
val |= KVM_XICS_LEVEL_SENSITIVE;
if (state->saved_p)
val |= KVM_XICS_PENDING;
} else {
if (state->saved_p)
val |= KVM_XICS_PRESENTED;
if (state->saved_q)
val |= KVM_XICS_QUEUED;
/*
* We mark it pending (which will attempt a re-delivery)
* if we are in a queue *or* we were masked and had
* Q set which is equivalent to the XICS "masked pending"
* state
*/
if (state->in_queue || (prio == MASKED && state->saved_q))
val |= KVM_XICS_PENDING;
}
/*
* If that was the last interrupt saved, reset the
* in_queue flags
*/
if (xive->saved_src_count == xive->src_count)
xive_post_save_scan(xive);
/* Copy the result to userspace */
if (put_user(val, ubufp))
return -EFAULT;
return 0;
}
struct kvmppc_xive_src_block *kvmppc_xive_create_src_block(
struct kvmppc_xive *xive, int irq)
{
struct kvmppc_xive_src_block *sb;
int i, bid;
bid = irq >> KVMPPC_XICS_ICS_SHIFT;
mutex_lock(&xive->lock);
/* block already exists - somebody else got here first */
if (xive->src_blocks[bid])
goto out;
/* Create the ICS */
sb = kzalloc(sizeof(*sb), GFP_KERNEL);
if (!sb)
goto out;
sb->id = bid;
for (i = 0; i < KVMPPC_XICS_IRQ_PER_ICS; i++) {
sb->irq_state[i].number = (bid << KVMPPC_XICS_ICS_SHIFT) | i;
sb->irq_state[i].eisn = 0;
sb->irq_state[i].guest_priority = MASKED;
sb->irq_state[i].saved_priority = MASKED;
sb->irq_state[i].act_priority = MASKED;
}
smp_wmb();
xive->src_blocks[bid] = sb;
if (bid > xive->max_sbid)
xive->max_sbid = bid;
out:
mutex_unlock(&xive->lock);
return xive->src_blocks[bid];
}
static bool xive_check_delayed_irq(struct kvmppc_xive *xive, u32 irq)
{
struct kvm *kvm = xive->kvm;
struct kvm_vcpu *vcpu = NULL;
unsigned long i;
kvm_for_each_vcpu(i, vcpu, kvm) {
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
if (!xc)
continue;
if (xc->delayed_irq == irq) {
xc->delayed_irq = 0;
xive->delayed_irqs--;
return true;
}
}
return false;
}
static int xive_set_source(struct kvmppc_xive *xive, long irq, u64 addr)
{
struct kvmppc_xive_src_block *sb;
struct kvmppc_xive_irq_state *state;
u64 __user *ubufp = (u64 __user *) addr;
u16 idx;
u64 val;
u8 act_prio, guest_prio;
u32 server;
int rc = 0;
if (irq < KVMPPC_XICS_FIRST_IRQ || irq >= KVMPPC_XICS_NR_IRQS)
return -ENOENT;
pr_devel("set_source(irq=0x%lx)\n", irq);
/* Find the source */
sb = kvmppc_xive_find_source(xive, irq, &idx);
if (!sb) {
pr_devel("No source, creating source block...\n");
sb = kvmppc_xive_create_src_block(xive, irq);
if (!sb) {
pr_devel("Failed to create block...\n");
return -ENOMEM;
}
}
state = &sb->irq_state[idx];
/* Read user passed data */
if (get_user(val, ubufp)) {
pr_devel("fault getting user info !\n");
return -EFAULT;
}
server = val & KVM_XICS_DESTINATION_MASK;
guest_prio = val >> KVM_XICS_PRIORITY_SHIFT;
pr_devel(" val=0x016%llx (server=0x%x, guest_prio=%d)\n",
val, server, guest_prio);
/*
* If the source doesn't already have an IPI, allocate
* one and get the corresponding data
*/
if (!state->ipi_number) {
state->ipi_number = xive_native_alloc_irq();
if (state->ipi_number == 0) {
pr_devel("Failed to allocate IPI !\n");
return -ENOMEM;
}
xive_native_populate_irq_data(state->ipi_number, &state->ipi_data);
pr_devel(" src_ipi=0x%x\n", state->ipi_number);
}
/*
* We use lock_and_mask() to set us in the right masked
* state. We will override that state from the saved state
* further down, but this will handle the cases of interrupts
* that need FW masking. We set the initial guest_priority to
* 0 before calling it to ensure it actually performs the masking.
*/
state->guest_priority = 0;
xive_lock_and_mask(xive, sb, state);
/*
* Now, we select a target if we have one. If we don't we
* leave the interrupt untargetted. It means that an interrupt
* can become "untargetted" across migration if it was masked
* by set_xive() but there is little we can do about it.
*/
/* First convert prio and mark interrupt as untargetted */
act_prio = xive_prio_from_guest(guest_prio);
state->act_priority = MASKED;
/*
* We need to drop the lock due to the mutex below. Hopefully
* nothing is touching that interrupt yet since it hasn't been
* advertized to a running guest yet
*/
arch_spin_unlock(&sb->lock);
/* If we have a priority target the interrupt */
if (act_prio != MASKED) {
/* First, check provisioning of queues */
mutex_lock(&xive->lock);
rc = xive_check_provisioning(xive->kvm, act_prio);
mutex_unlock(&xive->lock);
/* Target interrupt */
if (rc == 0)
rc = xive_target_interrupt(xive->kvm, state,
server, act_prio);
/*
* If provisioning or targetting failed, leave it
* alone and masked. It will remain disabled until
* the guest re-targets it.
*/
}
/*
* Find out if this was a delayed irq stashed in an ICP,
* in which case, treat it as pending
*/
if (xive->delayed_irqs && xive_check_delayed_irq(xive, irq)) {
val |= KVM_XICS_PENDING;
pr_devel(" Found delayed ! forcing PENDING !\n");
}
/* Cleanup the SW state */
state->old_p = false;
state->old_q = false;
state->lsi = false;
state->asserted = false;
/* Restore LSI state */
if (val & KVM_XICS_LEVEL_SENSITIVE) {
state->lsi = true;
if (val & KVM_XICS_PENDING)
state->asserted = true;
pr_devel(" LSI ! Asserted=%d\n", state->asserted);
}
/*
* Restore P and Q. If the interrupt was pending, we
* force Q and !P, which will trigger a resend.
*
* That means that a guest that had both an interrupt
* pending (queued) and Q set will restore with only
* one instance of that interrupt instead of 2, but that
* is perfectly fine as coalescing interrupts that haven't
* been presented yet is always allowed.
*/
if (val & KVM_XICS_PRESENTED && !(val & KVM_XICS_PENDING))
state->old_p = true;
if (val & KVM_XICS_QUEUED || val & KVM_XICS_PENDING)
state->old_q = true;
pr_devel(" P=%d, Q=%d\n", state->old_p, state->old_q);
/*
* If the interrupt was unmasked, update guest priority and
* perform the appropriate state transition and do a
* re-trigger if necessary.
*/
if (val & KVM_XICS_MASKED) {
pr_devel(" masked, saving prio\n");
state->guest_priority = MASKED;
state->saved_priority = guest_prio;
} else {
pr_devel(" unmasked, restoring to prio %d\n", guest_prio);
xive_finish_unmask(xive, sb, state, guest_prio);
state->saved_priority = guest_prio;
}
/* Increment the number of valid sources and mark this one valid */
if (!state->valid)
xive->src_count++;
state->valid = true;
return 0;
}
int kvmppc_xive_set_irq(struct kvm *kvm, int irq_source_id, u32 irq, int level,
bool line_status)
{
struct kvmppc_xive *xive = kvm->arch.xive;
struct kvmppc_xive_src_block *sb;
struct kvmppc_xive_irq_state *state;
u16 idx;
if (!xive)
return -ENODEV;
sb = kvmppc_xive_find_source(xive, irq, &idx);
if (!sb)
return -EINVAL;
/* Perform locklessly .... (we need to do some RCUisms here...) */
state = &sb->irq_state[idx];
if (!state->valid)
return -EINVAL;
/* We don't allow a trigger on a passed-through interrupt */
if (state->pt_number)
return -EINVAL;
if ((level == 1 && state->lsi) || level == KVM_INTERRUPT_SET_LEVEL)
state->asserted = true;
else if (level == 0 || level == KVM_INTERRUPT_UNSET) {
state->asserted = false;
return 0;
}
/* Trigger the IPI */
xive_irq_trigger(&state->ipi_data);
return 0;
}
int kvmppc_xive_set_nr_servers(struct kvmppc_xive *xive, u64 addr)
{
u32 __user *ubufp = (u32 __user *) addr;
u32 nr_servers;
int rc = 0;
if (get_user(nr_servers, ubufp))
return -EFAULT;
pr_devel("%s nr_servers=%u\n", __func__, nr_servers);
if (!nr_servers || nr_servers > KVM_MAX_VCPU_IDS)
return -EINVAL;
mutex_lock(&xive->lock);
if (xive->vp_base != XIVE_INVALID_VP)
/* The VP block is allocated once and freed when the device
* is released. Better not allow to change its size since its
* used by connect_vcpu to validate vCPU ids are valid (eg,
* setting it back to a higher value could allow connect_vcpu
* to come up with a VP id that goes beyond the VP block, which
* is likely to cause a crash in OPAL).
*/
rc = -EBUSY;
else if (nr_servers > KVM_MAX_VCPUS)
/* We don't need more servers. Higher vCPU ids get packed
* down below KVM_MAX_VCPUS by kvmppc_pack_vcpu_id().
*/
xive->nr_servers = KVM_MAX_VCPUS;
else
xive->nr_servers = nr_servers;
mutex_unlock(&xive->lock);
return rc;
}
static int xive_set_attr(struct kvm_device *dev, struct kvm_device_attr *attr)
{
struct kvmppc_xive *xive = dev->private;
/* We honor the existing XICS ioctl */
switch (attr->group) {
case KVM_DEV_XICS_GRP_SOURCES:
return xive_set_source(xive, attr->attr, attr->addr);
case KVM_DEV_XICS_GRP_CTRL:
switch (attr->attr) {
case KVM_DEV_XICS_NR_SERVERS:
return kvmppc_xive_set_nr_servers(xive, attr->addr);
}
}
return -ENXIO;
}
static int xive_get_attr(struct kvm_device *dev, struct kvm_device_attr *attr)
{
struct kvmppc_xive *xive = dev->private;
/* We honor the existing XICS ioctl */
switch (attr->group) {
case KVM_DEV_XICS_GRP_SOURCES:
return xive_get_source(xive, attr->attr, attr->addr);
}
return -ENXIO;
}
static int xive_has_attr(struct kvm_device *dev, struct kvm_device_attr *attr)
{
/* We honor the same limits as XICS, at least for now */
switch (attr->group) {
case KVM_DEV_XICS_GRP_SOURCES:
if (attr->attr >= KVMPPC_XICS_FIRST_IRQ &&
attr->attr < KVMPPC_XICS_NR_IRQS)
return 0;
break;
case KVM_DEV_XICS_GRP_CTRL:
switch (attr->attr) {
case KVM_DEV_XICS_NR_SERVERS:
return 0;
}
}
return -ENXIO;
}
static void kvmppc_xive_cleanup_irq(u32 hw_num, struct xive_irq_data *xd)
{
xive_vm_esb_load(xd, XIVE_ESB_SET_PQ_01);
xive_native_configure_irq(hw_num, 0, MASKED, 0);
}
void kvmppc_xive_free_sources(struct kvmppc_xive_src_block *sb)
{
int i;
for (i = 0; i < KVMPPC_XICS_IRQ_PER_ICS; i++) {
struct kvmppc_xive_irq_state *state = &sb->irq_state[i];
if (!state->valid)
continue;
kvmppc_xive_cleanup_irq(state->ipi_number, &state->ipi_data);
xive_cleanup_irq_data(&state->ipi_data);
xive_native_free_irq(state->ipi_number);
/* Pass-through, cleanup too but keep IRQ hw data */
if (state->pt_number)
kvmppc_xive_cleanup_irq(state->pt_number, state->pt_data);
state->valid = false;
}
}
/*
* Called when device fd is closed. kvm->lock is held.
*/
static void kvmppc_xive_release(struct kvm_device *dev)
{
struct kvmppc_xive *xive = dev->private;
struct kvm *kvm = xive->kvm;
struct kvm_vcpu *vcpu;
unsigned long i;
pr_devel("Releasing xive device\n");
/*
* Since this is the device release function, we know that
* userspace does not have any open fd referring to the
* device. Therefore there can not be any of the device
* attribute set/get functions being executed concurrently,
* and similarly, the connect_vcpu and set/clr_mapped
* functions also cannot be being executed.
*/
debugfs_remove(xive->dentry);
/*
* We should clean up the vCPU interrupt presenters first.
*/
kvm_for_each_vcpu(i, vcpu, kvm) {
/*
* Take vcpu->mutex to ensure that no one_reg get/set ioctl
* (i.e. kvmppc_xive_[gs]et_icp) can be done concurrently.
* Holding the vcpu->mutex also means that the vcpu cannot
* be executing the KVM_RUN ioctl, and therefore it cannot
* be executing the XIVE push or pull code or accessing
* the XIVE MMIO regions.
*/
mutex_lock(&vcpu->mutex);
kvmppc_xive_cleanup_vcpu(vcpu);
mutex_unlock(&vcpu->mutex);
}
/*
* Now that we have cleared vcpu->arch.xive_vcpu, vcpu->arch.irq_type
* and vcpu->arch.xive_esc_[vr]addr on each vcpu, we are safe
* against xive code getting called during vcpu execution or
* set/get one_reg operations.
*/
kvm->arch.xive = NULL;
/* Mask and free interrupts */
for (i = 0; i <= xive->max_sbid; i++) {
if (xive->src_blocks[i])
kvmppc_xive_free_sources(xive->src_blocks[i]);
kfree(xive->src_blocks[i]);
xive->src_blocks[i] = NULL;
}
if (xive->vp_base != XIVE_INVALID_VP)
xive_native_free_vp_block(xive->vp_base);
/*
* A reference of the kvmppc_xive pointer is now kept under
* the xive_devices struct of the machine for reuse. It is
* freed when the VM is destroyed for now until we fix all the
* execution paths.
*/
kfree(dev);
}
/*
* When the guest chooses the interrupt mode (XICS legacy or XIVE
* native), the VM will switch of KVM device. The previous device will
* be "released" before the new one is created.
*
* Until we are sure all execution paths are well protected, provide a
* fail safe (transitional) method for device destruction, in which
* the XIVE device pointer is recycled and not directly freed.
*/
struct kvmppc_xive *kvmppc_xive_get_device(struct kvm *kvm, u32 type)
{
struct kvmppc_xive **kvm_xive_device = type == KVM_DEV_TYPE_XIVE ?
&kvm->arch.xive_devices.native :
&kvm->arch.xive_devices.xics_on_xive;
struct kvmppc_xive *xive = *kvm_xive_device;
if (!xive) {
xive = kzalloc(sizeof(*xive), GFP_KERNEL);
*kvm_xive_device = xive;
} else {
memset(xive, 0, sizeof(*xive));
}
return xive;
}
/*
* Create a XICS device with XIVE backend. kvm->lock is held.
*/
static int kvmppc_xive_create(struct kvm_device *dev, u32 type)
{
struct kvmppc_xive *xive;
struct kvm *kvm = dev->kvm;
pr_devel("Creating xive for partition\n");
/* Already there ? */
if (kvm->arch.xive)
return -EEXIST;
xive = kvmppc_xive_get_device(kvm, type);
if (!xive)
return -ENOMEM;
dev->private = xive;
xive->dev = dev;
xive->kvm = kvm;
mutex_init(&xive->lock);
/* We use the default queue size set by the host */
xive->q_order = xive_native_default_eq_shift();
if (xive->q_order < PAGE_SHIFT)
xive->q_page_order = 0;
else
xive->q_page_order = xive->q_order - PAGE_SHIFT;
/* VP allocation is delayed to the first call to connect_vcpu */
xive->vp_base = XIVE_INVALID_VP;
/* KVM_MAX_VCPUS limits the number of VMs to roughly 64 per sockets
* on a POWER9 system.
*/
xive->nr_servers = KVM_MAX_VCPUS;
if (xive_native_has_single_escalation())
xive->flags |= KVMPPC_XIVE_FLAG_SINGLE_ESCALATION;
if (xive_native_has_save_restore())
xive->flags |= KVMPPC_XIVE_FLAG_SAVE_RESTORE;
kvm->arch.xive = xive;
return 0;
}
int kvmppc_xive_xics_hcall(struct kvm_vcpu *vcpu, u32 req)
{
/* The VM should have configured XICS mode before doing XICS hcalls. */
if (!kvmppc_xics_enabled(vcpu))
return H_TOO_HARD;
switch (req) {
case H_XIRR:
return xive_vm_h_xirr(vcpu);
case H_CPPR:
return xive_vm_h_cppr(vcpu, kvmppc_get_gpr(vcpu, 4));
case H_EOI:
return xive_vm_h_eoi(vcpu, kvmppc_get_gpr(vcpu, 4));
case H_IPI:
return xive_vm_h_ipi(vcpu, kvmppc_get_gpr(vcpu, 4),
kvmppc_get_gpr(vcpu, 5));
case H_IPOLL:
return xive_vm_h_ipoll(vcpu, kvmppc_get_gpr(vcpu, 4));
case H_XIRR_X:
xive_vm_h_xirr(vcpu);
kvmppc_set_gpr(vcpu, 5, get_tb() + kvmppc_get_tb_offset(vcpu));
return H_SUCCESS;
}
return H_UNSUPPORTED;
}
EXPORT_SYMBOL_GPL(kvmppc_xive_xics_hcall);
int kvmppc_xive_debug_show_queues(struct seq_file *m, struct kvm_vcpu *vcpu)
{
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
unsigned int i;
for (i = 0; i < KVMPPC_XIVE_Q_COUNT; i++) {
struct xive_q *q = &xc->queues[i];
u32 i0, i1, idx;
if (!q->qpage && !xc->esc_virq[i])
continue;
if (q->qpage) {
seq_printf(m, " q[%d]: ", i);
idx = q->idx;
i0 = be32_to_cpup(q->qpage + idx);
idx = (idx + 1) & q->msk;
i1 = be32_to_cpup(q->qpage + idx);
seq_printf(m, "T=%d %08x %08x...\n", q->toggle,
i0, i1);
}
if (xc->esc_virq[i]) {
struct irq_data *d = irq_get_irq_data(xc->esc_virq[i]);
struct xive_irq_data *xd =
irq_data_get_irq_handler_data(d);
u64 pq = xive_vm_esb_load(xd, XIVE_ESB_GET);
seq_printf(m, " ESC %d %c%c EOI @%llx",
xc->esc_virq[i],
(pq & XIVE_ESB_VAL_P) ? 'P' : '-',
(pq & XIVE_ESB_VAL_Q) ? 'Q' : '-',
xd->eoi_page);
seq_puts(m, "\n");
}
}
return 0;
}
void kvmppc_xive_debug_show_sources(struct seq_file *m,
struct kvmppc_xive_src_block *sb)
{
int i;
seq_puts(m, " LISN HW/CHIP TYPE PQ EISN CPU/PRIO\n");
for (i = 0; i < KVMPPC_XICS_IRQ_PER_ICS; i++) {
struct kvmppc_xive_irq_state *state = &sb->irq_state[i];
struct xive_irq_data *xd;
u64 pq;
u32 hw_num;
if (!state->valid)
continue;
kvmppc_xive_select_irq(state, &hw_num, &xd);
pq = xive_vm_esb_load(xd, XIVE_ESB_GET);
seq_printf(m, "%08x %08x/%02x", state->number, hw_num,
xd->src_chip);
if (state->lsi)
seq_printf(m, " %cLSI", state->asserted ? '^' : ' ');
else
seq_puts(m, " MSI");
seq_printf(m, " %s %c%c %08x % 4d/%d",
state->ipi_number == hw_num ? "IPI" : " PT",
pq & XIVE_ESB_VAL_P ? 'P' : '-',
pq & XIVE_ESB_VAL_Q ? 'Q' : '-',
state->eisn, state->act_server,
state->act_priority);
seq_puts(m, "\n");
}
}
static int xive_debug_show(struct seq_file *m, void *private)
{
struct kvmppc_xive *xive = m->private;
struct kvm *kvm = xive->kvm;
struct kvm_vcpu *vcpu;
u64 t_rm_h_xirr = 0;
u64 t_rm_h_ipoll = 0;
u64 t_rm_h_cppr = 0;
u64 t_rm_h_eoi = 0;
u64 t_rm_h_ipi = 0;
u64 t_vm_h_xirr = 0;
u64 t_vm_h_ipoll = 0;
u64 t_vm_h_cppr = 0;
u64 t_vm_h_eoi = 0;
u64 t_vm_h_ipi = 0;
unsigned long i;
if (!kvm)
return 0;
seq_puts(m, "=========\nVCPU state\n=========\n");
kvm_for_each_vcpu(i, vcpu, kvm) {
struct kvmppc_xive_vcpu *xc = vcpu->arch.xive_vcpu;
if (!xc)
continue;
seq_printf(m, "VCPU %d: VP:%#x/%02x\n"
" CPPR:%#x HWCPPR:%#x MFRR:%#x PEND:%#x h_xirr: R=%lld V=%lld\n",
xc->server_num, xc->vp_id, xc->vp_chip_id,
xc->cppr, xc->hw_cppr,
xc->mfrr, xc->pending,
xc->stat_rm_h_xirr, xc->stat_vm_h_xirr);
kvmppc_xive_debug_show_queues(m, vcpu);
t_rm_h_xirr += xc->stat_rm_h_xirr;
t_rm_h_ipoll += xc->stat_rm_h_ipoll;
t_rm_h_cppr += xc->stat_rm_h_cppr;
t_rm_h_eoi += xc->stat_rm_h_eoi;
t_rm_h_ipi += xc->stat_rm_h_ipi;
t_vm_h_xirr += xc->stat_vm_h_xirr;
t_vm_h_ipoll += xc->stat_vm_h_ipoll;
t_vm_h_cppr += xc->stat_vm_h_cppr;
t_vm_h_eoi += xc->stat_vm_h_eoi;
t_vm_h_ipi += xc->stat_vm_h_ipi;
}
seq_puts(m, "Hcalls totals\n");
seq_printf(m, " H_XIRR R=%10lld V=%10lld\n", t_rm_h_xirr, t_vm_h_xirr);
seq_printf(m, " H_IPOLL R=%10lld V=%10lld\n", t_rm_h_ipoll, t_vm_h_ipoll);
seq_printf(m, " H_CPPR R=%10lld V=%10lld\n", t_rm_h_cppr, t_vm_h_cppr);
seq_printf(m, " H_EOI R=%10lld V=%10lld\n", t_rm_h_eoi, t_vm_h_eoi);
seq_printf(m, " H_IPI R=%10lld V=%10lld\n", t_rm_h_ipi, t_vm_h_ipi);
seq_puts(m, "=========\nSources\n=========\n");
for (i = 0; i <= xive->max_sbid; i++) {
struct kvmppc_xive_src_block *sb = xive->src_blocks[i];
if (sb) {
arch_spin_lock(&sb->lock);
kvmppc_xive_debug_show_sources(m, sb);
arch_spin_unlock(&sb->lock);
}
}
return 0;
}
DEFINE_SHOW_ATTRIBUTE(xive_debug);
static void xive_debugfs_init(struct kvmppc_xive *xive)
{
xive->dentry = debugfs_create_file("xive", S_IRUGO, xive->kvm->debugfs_dentry,
xive, &xive_debug_fops);
pr_debug("%s: created\n", __func__);
}
static void kvmppc_xive_init(struct kvm_device *dev)
{
struct kvmppc_xive *xive = dev->private;
/* Register some debug interfaces */
xive_debugfs_init(xive);
}
struct kvm_device_ops kvm_xive_ops = {
.name = "kvm-xive",
.create = kvmppc_xive_create,
.init = kvmppc_xive_init,
.release = kvmppc_xive_release,
.set_attr = xive_set_attr,
.get_attr = xive_get_attr,
.has_attr = xive_has_attr,
};
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