void unload_guest_pcore(struct proc *p, int guest_pcoreid)
{
struct guest_pcore *gpc;
struct per_cpu_info *pcpui = &per_cpu_info[core_id()];
gpc = lookup_guest_pcore(p, guest_pcoreid);
assert(gpc);
spin_lock(&p->vmm.lock);
assert(gpc->cpu != -1);
vmx_unload_guest_pcore(gpc);
gpc->cpu = -1;
/* Save guest's xcr0 and restore Akaros's default. */
gpc->xcr0 = rxcr0();
lxcr0(__proc_global_info.x86_default_xcr0);
/* We manage these MSRs manually. */
gpc->msr_kern_gs_base = read_kern_gsbase();
gpc->msr_star = read_msr(MSR_STAR);
gpc->msr_lstar = read_msr(MSR_LSTAR);
gpc->msr_sfmask = read_msr(MSR_SFMASK);
write_kern_gsbase((uint64_t)pcpui);
if (gpc->msr_star != AKAROS_MSR_STAR)
write_msr(MSR_STAR, AKAROS_MSR_STAR);
if (gpc->msr_lstar != AKAROS_MSR_LSTAR)
write_msr(MSR_LSTAR, AKAROS_MSR_LSTAR);
if (gpc->msr_sfmask, AKAROS_MSR_SFMASK)
write_msr(MSR_SFMASK, AKAROS_MSR_SFMASK);
/* As soon as we unlock, this gpc can be started on another core */
spin_unlock(&p->vmm.lock);
pcpui->guest_pcoreid = -1;
}
struct guest_pcore *load_guest_pcore(struct proc *p, int guest_pcoreid,
bool *should_vmresume)
{
struct guest_pcore *gpc;
struct per_cpu_info *pcpui = &per_cpu_info[core_id()];
gpc = lookup_guest_pcore(p, guest_pcoreid);
if (!gpc)
return 0;
assert(pcpui->guest_pcoreid == -1);
spin_lock(&p->vmm.lock);
if (gpc->cpu != -1) {
spin_unlock(&p->vmm.lock);
return 0;
}
gpc->cpu = core_id();
spin_unlock(&p->vmm.lock);
/* We've got dibs on the gpc; we don't need to hold the lock any longer. */
pcpui->guest_pcoreid = guest_pcoreid;
vmx_load_guest_pcore(gpc, should_vmresume);
/* Load guest's xcr0 */
lxcr0(gpc->xcr0);
/* Manual MSR save/restore */
write_kern_gsbase(gpc->msr_kern_gs_base);
if (gpc->msr_star != AKAROS_MSR_STAR)
write_msr(MSR_STAR, gpc->msr_star);
if (gpc->msr_lstar != AKAROS_MSR_LSTAR)
write_msr(MSR_LSTAR, gpc->msr_lstar);
if (gpc->msr_sfmask != AKAROS_MSR_SFMASK)
write_msr(MSR_SFMASK, gpc->msr_sfmask);
return gpc;
}
void unload_guest_pcore(struct proc *p, int guest_pcoreid)
{
struct guest_pcore *gpc;
struct per_cpu_info *pcpui = &per_cpu_info[core_id()];
gpc = lookup_guest_pcore(p, guest_pcoreid);
assert(gpc);
spin_lock(&p->vmm.lock);
assert(gpc->cpu != -1);
ept_sync_context(gpc_get_eptp(gpc));
vmx_unload_guest_pcore(gpc);
gpc->cpu = -1;
/* Save guest's xcr0 and restore Akaros's default. */
gpc->xcr0 = rxcr0();
lxcr0(x86_default_xcr0);
/* As soon as we unlock, this gpc can be started on another core */
spin_unlock(&p->vmm.lock);
pcpui->guest_pcoreid = -1;
}
int vmm_poke_guest(struct proc *p, int guest_pcoreid)
{
struct guest_pcore *gpc;
int pcoreid;
gpc = lookup_guest_pcore(p, guest_pcoreid);
if (!gpc) {
set_error(ENOENT, "Bad guest_pcoreid %d", guest_pcoreid);
return -1;
}
/* We're doing an unlocked peek; it could change immediately. This is a
* best effort service. */
pcoreid = ACCESS_ONCE(gpc->cpu);
if (pcoreid == -1) {
/* So we know that we'll miss the poke for the posted IRQ. We could
* return an error. However, error handling for this case isn't
* particularly helpful (yet). The absence of the error does not mean
* the IRQ was posted. We'll still return 0, meaning "the user didn't
* mess up; we tried." */
return 0;
}
send_ipi(pcoreid, I_POKE_CORE);
return 0;
}
struct guest_pcore *load_guest_pcore(struct proc *p, int guest_pcoreid)
{
struct guest_pcore *gpc;
struct per_cpu_info *pcpui = &per_cpu_info[core_id()];
gpc = lookup_guest_pcore(p, guest_pcoreid);
if (!gpc)
return 0;
assert(pcpui->guest_pcoreid == -1);
spin_lock(&p->vmm.lock);
if (gpc->cpu != -1) {
spin_unlock(&p->vmm.lock);
return 0;
}
gpc->cpu = core_id();
spin_unlock(&p->vmm.lock);
/* We've got dibs on the gpc; we don't need to hold the lock any longer. */
pcpui->guest_pcoreid = guest_pcoreid;
ept_sync_context(gpc_get_eptp(gpc));
vmx_load_guest_pcore(gpc);
/* Load guest's xcr0 */
lxcr0(gpc->xcr0);
return gpc;
}
