freebsd-skq/sys/amd64/vmm/vmm.c
Mark Johnston 54a3a11421 Provide separate accounting for user-wired pages.
Historically we have not distinguished between kernel wirings and user
wirings for accounting purposes.  User wirings (via mlock(2)) were
subject to a global limit on the number of wired pages, so if large
swaths of physical memory were wired by the kernel, as happens with
the ZFS ARC among other things, the limit could be exceeded, causing
user wirings to fail.

The change adds a new counter, v_user_wire_count, which counts the
number of virtual pages wired by user processes via mlock(2) and
mlockall(2).  Only user-wired pages are subject to the system-wide
limit which helps provide some safety against deadlocks.  In
particular, while sources of kernel wirings typically support some
backpressure mechanism, there is no way to reclaim user-wired pages
shorting of killing the wiring process.  The limit is exported as
vm.max_user_wired, renamed from vm.max_wired, and changed from u_int
to u_long.

The choice to count virtual user-wired pages rather than physical
pages was done for simplicity.  There are mechanisms that can cause
user-wired mappings to be destroyed while maintaining a wiring of
the backing physical page; these make it difficult to accurately
track user wirings at the physical page layer.

The change also closes some holes which allowed user wirings to succeed
even when they would cause the system limit to be exceeded.  For
instance, mmap() may now fail with ENOMEM in a process that has called
mlockall(MCL_FUTURE) if the new mapping would cause the user wiring
limit to be exceeded.

Note that bhyve -S is subject to the user wiring limit, which defaults
to 1/3 of physical RAM.  Users that wish to exceed the limit must tune
vm.max_user_wired.

Reviewed by:	kib, ngie (mlock() test changes)
Tested by:	pho (earlier version)
MFC after:	45 days
Sponsored by:	Netflix
Differential Revision:	https://reviews.freebsd.org/D19908
2019-05-13 16:38:48 +00:00

2720 lines
62 KiB
C

/*-
* SPDX-License-Identifier: BSD-2-Clause-FreeBSD
*
* Copyright (c) 2011 NetApp, Inc.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY NETAPP, INC ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL NETAPP, INC OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* $FreeBSD$
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/kernel.h>
#include <sys/module.h>
#include <sys/sysctl.h>
#include <sys/malloc.h>
#include <sys/pcpu.h>
#include <sys/lock.h>
#include <sys/mutex.h>
#include <sys/proc.h>
#include <sys/rwlock.h>
#include <sys/sched.h>
#include <sys/smp.h>
#include <sys/systm.h>
#include <vm/vm.h>
#include <vm/vm_object.h>
#include <vm/vm_page.h>
#include <vm/pmap.h>
#include <vm/vm_map.h>
#include <vm/vm_extern.h>
#include <vm/vm_param.h>
#include <machine/cpu.h>
#include <machine/pcb.h>
#include <machine/smp.h>
#include <machine/md_var.h>
#include <x86/psl.h>
#include <x86/apicreg.h>
#include <machine/vmm.h>
#include <machine/vmm_dev.h>
#include <machine/vmm_instruction_emul.h>
#include "vmm_ioport.h"
#include "vmm_ktr.h"
#include "vmm_host.h"
#include "vmm_mem.h"
#include "vmm_util.h"
#include "vatpic.h"
#include "vatpit.h"
#include "vhpet.h"
#include "vioapic.h"
#include "vlapic.h"
#include "vpmtmr.h"
#include "vrtc.h"
#include "vmm_stat.h"
#include "vmm_lapic.h"
#include "io/ppt.h"
#include "io/iommu.h"
struct vlapic;
/*
* Initialization:
* (a) allocated when vcpu is created
* (i) initialized when vcpu is created and when it is reinitialized
* (o) initialized the first time the vcpu is created
* (x) initialized before use
*/
struct vcpu {
struct mtx mtx; /* (o) protects 'state' and 'hostcpu' */
enum vcpu_state state; /* (o) vcpu state */
int hostcpu; /* (o) vcpu's host cpu */
int reqidle; /* (i) request vcpu to idle */
struct vlapic *vlapic; /* (i) APIC device model */
enum x2apic_state x2apic_state; /* (i) APIC mode */
uint64_t exitintinfo; /* (i) events pending at VM exit */
int nmi_pending; /* (i) NMI pending */
int extint_pending; /* (i) INTR pending */
int exception_pending; /* (i) exception pending */
int exc_vector; /* (x) exception collateral */
int exc_errcode_valid;
uint32_t exc_errcode;
struct savefpu *guestfpu; /* (a,i) guest fpu state */
uint64_t guest_xcr0; /* (i) guest %xcr0 register */
void *stats; /* (a,i) statistics */
struct vm_exit exitinfo; /* (x) exit reason and collateral */
uint64_t nextrip; /* (x) next instruction to execute */
};
#define vcpu_lock_initialized(v) mtx_initialized(&((v)->mtx))
#define vcpu_lock_init(v) mtx_init(&((v)->mtx), "vcpu lock", 0, MTX_SPIN)
#define vcpu_lock(v) mtx_lock_spin(&((v)->mtx))
#define vcpu_unlock(v) mtx_unlock_spin(&((v)->mtx))
#define vcpu_assert_locked(v) mtx_assert(&((v)->mtx), MA_OWNED)
struct mem_seg {
size_t len;
bool sysmem;
struct vm_object *object;
};
#define VM_MAX_MEMSEGS 3
struct mem_map {
vm_paddr_t gpa;
size_t len;
vm_ooffset_t segoff;
int segid;
int prot;
int flags;
};
#define VM_MAX_MEMMAPS 4
/*
* Initialization:
* (o) initialized the first time the VM is created
* (i) initialized when VM is created and when it is reinitialized
* (x) initialized before use
*/
struct vm {
void *cookie; /* (i) cpu-specific data */
void *iommu; /* (x) iommu-specific data */
struct vhpet *vhpet; /* (i) virtual HPET */
struct vioapic *vioapic; /* (i) virtual ioapic */
struct vatpic *vatpic; /* (i) virtual atpic */
struct vatpit *vatpit; /* (i) virtual atpit */
struct vpmtmr *vpmtmr; /* (i) virtual ACPI PM timer */
struct vrtc *vrtc; /* (o) virtual RTC */
volatile cpuset_t active_cpus; /* (i) active vcpus */
volatile cpuset_t debug_cpus; /* (i) vcpus stopped for debug */
int suspend; /* (i) stop VM execution */
volatile cpuset_t suspended_cpus; /* (i) suspended vcpus */
volatile cpuset_t halted_cpus; /* (x) cpus in a hard halt */
cpuset_t rendezvous_req_cpus; /* (x) rendezvous requested */
cpuset_t rendezvous_done_cpus; /* (x) rendezvous finished */
void *rendezvous_arg; /* (x) rendezvous func/arg */
vm_rendezvous_func_t rendezvous_func;
struct mtx rendezvous_mtx; /* (o) rendezvous lock */
struct mem_map mem_maps[VM_MAX_MEMMAPS]; /* (i) guest address space */
struct mem_seg mem_segs[VM_MAX_MEMSEGS]; /* (o) guest memory regions */
struct vmspace *vmspace; /* (o) guest's address space */
char name[VM_MAX_NAMELEN]; /* (o) virtual machine name */
struct vcpu vcpu[VM_MAXCPU]; /* (i) guest vcpus */
/* The following describe the vm cpu topology */
uint16_t sockets; /* (o) num of sockets */
uint16_t cores; /* (o) num of cores/socket */
uint16_t threads; /* (o) num of threads/core */
uint16_t maxcpus; /* (o) max pluggable cpus */
};
static int vmm_initialized;
static struct vmm_ops *ops;
#define VMM_INIT(num) (ops != NULL ? (*ops->init)(num) : 0)
#define VMM_CLEANUP() (ops != NULL ? (*ops->cleanup)() : 0)
#define VMM_RESUME() (ops != NULL ? (*ops->resume)() : 0)
#define VMINIT(vm, pmap) (ops != NULL ? (*ops->vminit)(vm, pmap): NULL)
#define VMRUN(vmi, vcpu, rip, pmap, evinfo) \
(ops != NULL ? (*ops->vmrun)(vmi, vcpu, rip, pmap, evinfo) : ENXIO)
#define VMCLEANUP(vmi) (ops != NULL ? (*ops->vmcleanup)(vmi) : NULL)
#define VMSPACE_ALLOC(min, max) \
(ops != NULL ? (*ops->vmspace_alloc)(min, max) : NULL)
#define VMSPACE_FREE(vmspace) \
(ops != NULL ? (*ops->vmspace_free)(vmspace) : ENXIO)
#define VMGETREG(vmi, vcpu, num, retval) \
(ops != NULL ? (*ops->vmgetreg)(vmi, vcpu, num, retval) : ENXIO)
#define VMSETREG(vmi, vcpu, num, val) \
(ops != NULL ? (*ops->vmsetreg)(vmi, vcpu, num, val) : ENXIO)
#define VMGETDESC(vmi, vcpu, num, desc) \
(ops != NULL ? (*ops->vmgetdesc)(vmi, vcpu, num, desc) : ENXIO)
#define VMSETDESC(vmi, vcpu, num, desc) \
(ops != NULL ? (*ops->vmsetdesc)(vmi, vcpu, num, desc) : ENXIO)
#define VMGETCAP(vmi, vcpu, num, retval) \
(ops != NULL ? (*ops->vmgetcap)(vmi, vcpu, num, retval) : ENXIO)
#define VMSETCAP(vmi, vcpu, num, val) \
(ops != NULL ? (*ops->vmsetcap)(vmi, vcpu, num, val) : ENXIO)
#define VLAPIC_INIT(vmi, vcpu) \
(ops != NULL ? (*ops->vlapic_init)(vmi, vcpu) : NULL)
#define VLAPIC_CLEANUP(vmi, vlapic) \
(ops != NULL ? (*ops->vlapic_cleanup)(vmi, vlapic) : NULL)
#define fpu_start_emulating() load_cr0(rcr0() | CR0_TS)
#define fpu_stop_emulating() clts()
SDT_PROVIDER_DEFINE(vmm);
static MALLOC_DEFINE(M_VM, "vm", "vm");
/* statistics */
static VMM_STAT(VCPU_TOTAL_RUNTIME, "vcpu total runtime");
SYSCTL_NODE(_hw, OID_AUTO, vmm, CTLFLAG_RW, NULL, NULL);
/*
* Halt the guest if all vcpus are executing a HLT instruction with
* interrupts disabled.
*/
static int halt_detection_enabled = 1;
SYSCTL_INT(_hw_vmm, OID_AUTO, halt_detection, CTLFLAG_RDTUN,
&halt_detection_enabled, 0,
"Halt VM if all vcpus execute HLT with interrupts disabled");
static int vmm_ipinum;
SYSCTL_INT(_hw_vmm, OID_AUTO, ipinum, CTLFLAG_RD, &vmm_ipinum, 0,
"IPI vector used for vcpu notifications");
static int trace_guest_exceptions;
SYSCTL_INT(_hw_vmm, OID_AUTO, trace_guest_exceptions, CTLFLAG_RDTUN,
&trace_guest_exceptions, 0,
"Trap into hypervisor on all guest exceptions and reflect them back");
static void vm_free_memmap(struct vm *vm, int ident);
static bool sysmem_mapping(struct vm *vm, struct mem_map *mm);
static void vcpu_notify_event_locked(struct vcpu *vcpu, bool lapic_intr);
#ifdef KTR
static const char *
vcpu_state2str(enum vcpu_state state)
{
switch (state) {
case VCPU_IDLE:
return ("idle");
case VCPU_FROZEN:
return ("frozen");
case VCPU_RUNNING:
return ("running");
case VCPU_SLEEPING:
return ("sleeping");
default:
return ("unknown");
}
}
#endif
static void
vcpu_cleanup(struct vm *vm, int i, bool destroy)
{
struct vcpu *vcpu = &vm->vcpu[i];
VLAPIC_CLEANUP(vm->cookie, vcpu->vlapic);
if (destroy) {
vmm_stat_free(vcpu->stats);
fpu_save_area_free(vcpu->guestfpu);
}
}
static void
vcpu_init(struct vm *vm, int vcpu_id, bool create)
{
struct vcpu *vcpu;
KASSERT(vcpu_id >= 0 && vcpu_id < vm->maxcpus,
("vcpu_init: invalid vcpu %d", vcpu_id));
vcpu = &vm->vcpu[vcpu_id];
if (create) {
KASSERT(!vcpu_lock_initialized(vcpu), ("vcpu %d already "
"initialized", vcpu_id));
vcpu_lock_init(vcpu);
vcpu->state = VCPU_IDLE;
vcpu->hostcpu = NOCPU;
vcpu->guestfpu = fpu_save_area_alloc();
vcpu->stats = vmm_stat_alloc();
}
vcpu->vlapic = VLAPIC_INIT(vm->cookie, vcpu_id);
vm_set_x2apic_state(vm, vcpu_id, X2APIC_DISABLED);
vcpu->reqidle = 0;
vcpu->exitintinfo = 0;
vcpu->nmi_pending = 0;
vcpu->extint_pending = 0;
vcpu->exception_pending = 0;
vcpu->guest_xcr0 = XFEATURE_ENABLED_X87;
fpu_save_area_reset(vcpu->guestfpu);
vmm_stat_init(vcpu->stats);
}
int
vcpu_trace_exceptions(struct vm *vm, int vcpuid)
{
return (trace_guest_exceptions);
}
struct vm_exit *
vm_exitinfo(struct vm *vm, int cpuid)
{
struct vcpu *vcpu;
if (cpuid < 0 || cpuid >= vm->maxcpus)
panic("vm_exitinfo: invalid cpuid %d", cpuid);
vcpu = &vm->vcpu[cpuid];
return (&vcpu->exitinfo);
}
static void
vmm_resume(void)
{
VMM_RESUME();
}
static int
vmm_init(void)
{
int error;
vmm_host_state_init();
vmm_ipinum = lapic_ipi_alloc(pti ? &IDTVEC(justreturn1_pti) :
&IDTVEC(justreturn));
if (vmm_ipinum < 0)
vmm_ipinum = IPI_AST;
error = vmm_mem_init();
if (error)
return (error);
if (vmm_is_intel())
ops = &vmm_ops_intel;
else if (vmm_is_amd())
ops = &vmm_ops_amd;
else
return (ENXIO);
vmm_resume_p = vmm_resume;
return (VMM_INIT(vmm_ipinum));
}
static int
vmm_handler(module_t mod, int what, void *arg)
{
int error;
switch (what) {
case MOD_LOAD:
vmmdev_init();
error = vmm_init();
if (error == 0)
vmm_initialized = 1;
break;
case MOD_UNLOAD:
error = vmmdev_cleanup();
if (error == 0) {
vmm_resume_p = NULL;
iommu_cleanup();
if (vmm_ipinum != IPI_AST)
lapic_ipi_free(vmm_ipinum);
error = VMM_CLEANUP();
/*
* Something bad happened - prevent new
* VMs from being created
*/
if (error)
vmm_initialized = 0;
}
break;
default:
error = 0;
break;
}
return (error);
}
static moduledata_t vmm_kmod = {
"vmm",
vmm_handler,
NULL
};
/*
* vmm initialization has the following dependencies:
*
* - VT-x initialization requires smp_rendezvous() and therefore must happen
* after SMP is fully functional (after SI_SUB_SMP).
*/
DECLARE_MODULE(vmm, vmm_kmod, SI_SUB_SMP + 1, SI_ORDER_ANY);
MODULE_VERSION(vmm, 1);
static void
vm_init(struct vm *vm, bool create)
{
int i;
vm->cookie = VMINIT(vm, vmspace_pmap(vm->vmspace));
vm->iommu = NULL;
vm->vioapic = vioapic_init(vm);
vm->vhpet = vhpet_init(vm);
vm->vatpic = vatpic_init(vm);
vm->vatpit = vatpit_init(vm);
vm->vpmtmr = vpmtmr_init(vm);
if (create)
vm->vrtc = vrtc_init(vm);
CPU_ZERO(&vm->active_cpus);
CPU_ZERO(&vm->debug_cpus);
vm->suspend = 0;
CPU_ZERO(&vm->suspended_cpus);
for (i = 0; i < vm->maxcpus; i++)
vcpu_init(vm, i, create);
}
/*
* The default CPU topology is a single thread per package.
*/
u_int cores_per_package = 1;
u_int threads_per_core = 1;
int
vm_create(const char *name, struct vm **retvm)
{
struct vm *vm;
struct vmspace *vmspace;
/*
* If vmm.ko could not be successfully initialized then don't attempt
* to create the virtual machine.
*/
if (!vmm_initialized)
return (ENXIO);
if (name == NULL || strlen(name) >= VM_MAX_NAMELEN)
return (EINVAL);
vmspace = VMSPACE_ALLOC(0, VM_MAXUSER_ADDRESS);
if (vmspace == NULL)
return (ENOMEM);
vm = malloc(sizeof(struct vm), M_VM, M_WAITOK | M_ZERO);
strcpy(vm->name, name);
vm->vmspace = vmspace;
mtx_init(&vm->rendezvous_mtx, "vm rendezvous lock", 0, MTX_DEF);
vm->sockets = 1;
vm->cores = cores_per_package; /* XXX backwards compatibility */
vm->threads = threads_per_core; /* XXX backwards compatibility */
vm->maxcpus = VM_MAXCPU; /* XXX temp to keep code working */
vm_init(vm, true);
*retvm = vm;
return (0);
}
void
vm_get_topology(struct vm *vm, uint16_t *sockets, uint16_t *cores,
uint16_t *threads, uint16_t *maxcpus)
{
*sockets = vm->sockets;
*cores = vm->cores;
*threads = vm->threads;
*maxcpus = vm->maxcpus;
}
uint16_t
vm_get_maxcpus(struct vm *vm)
{
return (vm->maxcpus);
}
int
vm_set_topology(struct vm *vm, uint16_t sockets, uint16_t cores,
uint16_t threads, uint16_t maxcpus)
{
if (maxcpus != 0)
return (EINVAL); /* XXX remove when supported */
if ((sockets * cores * threads) > vm->maxcpus)
return (EINVAL);
/* XXX need to check sockets * cores * threads == vCPU, how? */
vm->sockets = sockets;
vm->cores = cores;
vm->threads = threads;
vm->maxcpus = VM_MAXCPU; /* XXX temp to keep code working */
return(0);
}
static void
vm_cleanup(struct vm *vm, bool destroy)
{
struct mem_map *mm;
int i;
ppt_unassign_all(vm);
if (vm->iommu != NULL)
iommu_destroy_domain(vm->iommu);
if (destroy)
vrtc_cleanup(vm->vrtc);
else
vrtc_reset(vm->vrtc);
vpmtmr_cleanup(vm->vpmtmr);
vatpit_cleanup(vm->vatpit);
vhpet_cleanup(vm->vhpet);
vatpic_cleanup(vm->vatpic);
vioapic_cleanup(vm->vioapic);
for (i = 0; i < vm->maxcpus; i++)
vcpu_cleanup(vm, i, destroy);
VMCLEANUP(vm->cookie);
/*
* System memory is removed from the guest address space only when
* the VM is destroyed. This is because the mapping remains the same
* across VM reset.
*
* Device memory can be relocated by the guest (e.g. using PCI BARs)
* so those mappings are removed on a VM reset.
*/
for (i = 0; i < VM_MAX_MEMMAPS; i++) {
mm = &vm->mem_maps[i];
if (destroy || !sysmem_mapping(vm, mm))
vm_free_memmap(vm, i);
}
if (destroy) {
for (i = 0; i < VM_MAX_MEMSEGS; i++)
vm_free_memseg(vm, i);
VMSPACE_FREE(vm->vmspace);
vm->vmspace = NULL;
}
}
void
vm_destroy(struct vm *vm)
{
vm_cleanup(vm, true);
free(vm, M_VM);
}
int
vm_reinit(struct vm *vm)
{
int error;
/*
* A virtual machine can be reset only if all vcpus are suspended.
*/
if (CPU_CMP(&vm->suspended_cpus, &vm->active_cpus) == 0) {
vm_cleanup(vm, false);
vm_init(vm, false);
error = 0;
} else {
error = EBUSY;
}
return (error);
}
const char *
vm_name(struct vm *vm)
{
return (vm->name);
}
int
vm_map_mmio(struct vm *vm, vm_paddr_t gpa, size_t len, vm_paddr_t hpa)
{
vm_object_t obj;
if ((obj = vmm_mmio_alloc(vm->vmspace, gpa, len, hpa)) == NULL)
return (ENOMEM);
else
return (0);
}
int
vm_unmap_mmio(struct vm *vm, vm_paddr_t gpa, size_t len)
{
vmm_mmio_free(vm->vmspace, gpa, len);
return (0);
}
/*
* Return 'true' if 'gpa' is allocated in the guest address space.
*
* This function is called in the context of a running vcpu which acts as
* an implicit lock on 'vm->mem_maps[]'.
*/
bool
vm_mem_allocated(struct vm *vm, int vcpuid, vm_paddr_t gpa)
{
struct mem_map *mm;
int i;
#ifdef INVARIANTS
int hostcpu, state;
state = vcpu_get_state(vm, vcpuid, &hostcpu);
KASSERT(state == VCPU_RUNNING && hostcpu == curcpu,
("%s: invalid vcpu state %d/%d", __func__, state, hostcpu));
#endif
for (i = 0; i < VM_MAX_MEMMAPS; i++) {
mm = &vm->mem_maps[i];
if (mm->len != 0 && gpa >= mm->gpa && gpa < mm->gpa + mm->len)
return (true); /* 'gpa' is sysmem or devmem */
}
if (ppt_is_mmio(vm, gpa))
return (true); /* 'gpa' is pci passthru mmio */
return (false);
}
int
vm_alloc_memseg(struct vm *vm, int ident, size_t len, bool sysmem)
{
struct mem_seg *seg;
vm_object_t obj;
if (ident < 0 || ident >= VM_MAX_MEMSEGS)
return (EINVAL);
if (len == 0 || (len & PAGE_MASK))
return (EINVAL);
seg = &vm->mem_segs[ident];
if (seg->object != NULL) {
if (seg->len == len && seg->sysmem == sysmem)
return (EEXIST);
else
return (EINVAL);
}
obj = vm_object_allocate(OBJT_DEFAULT, len >> PAGE_SHIFT);
if (obj == NULL)
return (ENOMEM);
seg->len = len;
seg->object = obj;
seg->sysmem = sysmem;
return (0);
}
int
vm_get_memseg(struct vm *vm, int ident, size_t *len, bool *sysmem,
vm_object_t *objptr)
{
struct mem_seg *seg;
if (ident < 0 || ident >= VM_MAX_MEMSEGS)
return (EINVAL);
seg = &vm->mem_segs[ident];
if (len)
*len = seg->len;
if (sysmem)
*sysmem = seg->sysmem;
if (objptr)
*objptr = seg->object;
return (0);
}
void
vm_free_memseg(struct vm *vm, int ident)
{
struct mem_seg *seg;
KASSERT(ident >= 0 && ident < VM_MAX_MEMSEGS,
("%s: invalid memseg ident %d", __func__, ident));
seg = &vm->mem_segs[ident];
if (seg->object != NULL) {
vm_object_deallocate(seg->object);
bzero(seg, sizeof(struct mem_seg));
}
}
int
vm_mmap_memseg(struct vm *vm, vm_paddr_t gpa, int segid, vm_ooffset_t first,
size_t len, int prot, int flags)
{
struct mem_seg *seg;
struct mem_map *m, *map;
vm_ooffset_t last;
int i, error;
if (prot == 0 || (prot & ~(VM_PROT_ALL)) != 0)
return (EINVAL);
if (flags & ~VM_MEMMAP_F_WIRED)
return (EINVAL);
if (segid < 0 || segid >= VM_MAX_MEMSEGS)
return (EINVAL);
seg = &vm->mem_segs[segid];
if (seg->object == NULL)
return (EINVAL);
last = first + len;
if (first < 0 || first >= last || last > seg->len)
return (EINVAL);
if ((gpa | first | last) & PAGE_MASK)
return (EINVAL);
map = NULL;
for (i = 0; i < VM_MAX_MEMMAPS; i++) {
m = &vm->mem_maps[i];
if (m->len == 0) {
map = m;
break;
}
}
if (map == NULL)
return (ENOSPC);
error = vm_map_find(&vm->vmspace->vm_map, seg->object, first, &gpa,
len, 0, VMFS_NO_SPACE, prot, prot, 0);
if (error != KERN_SUCCESS)
return (EFAULT);
vm_object_reference(seg->object);
if (flags & VM_MEMMAP_F_WIRED) {
error = vm_map_wire(&vm->vmspace->vm_map, gpa, gpa + len,
VM_MAP_WIRE_USER | VM_MAP_WIRE_NOHOLES);
if (error != KERN_SUCCESS) {
vm_map_remove(&vm->vmspace->vm_map, gpa, gpa + len);
return (error == KERN_RESOURCE_SHORTAGE ? ENOMEM :
EFAULT);
}
}
map->gpa = gpa;
map->len = len;
map->segoff = first;
map->segid = segid;
map->prot = prot;
map->flags = flags;
return (0);
}
int
vm_mmap_getnext(struct vm *vm, vm_paddr_t *gpa, int *segid,
vm_ooffset_t *segoff, size_t *len, int *prot, int *flags)
{
struct mem_map *mm, *mmnext;
int i;
mmnext = NULL;
for (i = 0; i < VM_MAX_MEMMAPS; i++) {
mm = &vm->mem_maps[i];
if (mm->len == 0 || mm->gpa < *gpa)
continue;
if (mmnext == NULL || mm->gpa < mmnext->gpa)
mmnext = mm;
}
if (mmnext != NULL) {
*gpa = mmnext->gpa;
if (segid)
*segid = mmnext->segid;
if (segoff)
*segoff = mmnext->segoff;
if (len)
*len = mmnext->len;
if (prot)
*prot = mmnext->prot;
if (flags)
*flags = mmnext->flags;
return (0);
} else {
return (ENOENT);
}
}
static void
vm_free_memmap(struct vm *vm, int ident)
{
struct mem_map *mm;
int error;
mm = &vm->mem_maps[ident];
if (mm->len) {
error = vm_map_remove(&vm->vmspace->vm_map, mm->gpa,
mm->gpa + mm->len);
KASSERT(error == KERN_SUCCESS, ("%s: vm_map_remove error %d",
__func__, error));
bzero(mm, sizeof(struct mem_map));
}
}
static __inline bool
sysmem_mapping(struct vm *vm, struct mem_map *mm)
{
if (mm->len != 0 && vm->mem_segs[mm->segid].sysmem)
return (true);
else
return (false);
}
vm_paddr_t
vmm_sysmem_maxaddr(struct vm *vm)
{
struct mem_map *mm;
vm_paddr_t maxaddr;
int i;
maxaddr = 0;
for (i = 0; i < VM_MAX_MEMMAPS; i++) {
mm = &vm->mem_maps[i];
if (sysmem_mapping(vm, mm)) {
if (maxaddr < mm->gpa + mm->len)
maxaddr = mm->gpa + mm->len;
}
}
return (maxaddr);
}
static void
vm_iommu_modify(struct vm *vm, boolean_t map)
{
int i, sz;
vm_paddr_t gpa, hpa;
struct mem_map *mm;
void *vp, *cookie, *host_domain;
sz = PAGE_SIZE;
host_domain = iommu_host_domain();
for (i = 0; i < VM_MAX_MEMMAPS; i++) {
mm = &vm->mem_maps[i];
if (!sysmem_mapping(vm, mm))
continue;
if (map) {
KASSERT((mm->flags & VM_MEMMAP_F_IOMMU) == 0,
("iommu map found invalid memmap %#lx/%#lx/%#x",
mm->gpa, mm->len, mm->flags));
if ((mm->flags & VM_MEMMAP_F_WIRED) == 0)
continue;
mm->flags |= VM_MEMMAP_F_IOMMU;
} else {
if ((mm->flags & VM_MEMMAP_F_IOMMU) == 0)
continue;
mm->flags &= ~VM_MEMMAP_F_IOMMU;
KASSERT((mm->flags & VM_MEMMAP_F_WIRED) != 0,
("iommu unmap found invalid memmap %#lx/%#lx/%#x",
mm->gpa, mm->len, mm->flags));
}
gpa = mm->gpa;
while (gpa < mm->gpa + mm->len) {
vp = vm_gpa_hold(vm, -1, gpa, PAGE_SIZE, VM_PROT_WRITE,
&cookie);
KASSERT(vp != NULL, ("vm(%s) could not map gpa %#lx",
vm_name(vm), gpa));
vm_gpa_release(cookie);
hpa = DMAP_TO_PHYS((uintptr_t)vp);
if (map) {
iommu_create_mapping(vm->iommu, gpa, hpa, sz);
iommu_remove_mapping(host_domain, hpa, sz);
} else {
iommu_remove_mapping(vm->iommu, gpa, sz);
iommu_create_mapping(host_domain, hpa, hpa, sz);
}
gpa += PAGE_SIZE;
}
}
/*
* Invalidate the cached translations associated with the domain
* from which pages were removed.
*/
if (map)
iommu_invalidate_tlb(host_domain);
else
iommu_invalidate_tlb(vm->iommu);
}
#define vm_iommu_unmap(vm) vm_iommu_modify((vm), FALSE)
#define vm_iommu_map(vm) vm_iommu_modify((vm), TRUE)
int
vm_unassign_pptdev(struct vm *vm, int bus, int slot, int func)
{
int error;
error = ppt_unassign_device(vm, bus, slot, func);
if (error)
return (error);
if (ppt_assigned_devices(vm) == 0)
vm_iommu_unmap(vm);
return (0);
}
int
vm_assign_pptdev(struct vm *vm, int bus, int slot, int func)
{
int error;
vm_paddr_t maxaddr;
/* Set up the IOMMU to do the 'gpa' to 'hpa' translation */
if (ppt_assigned_devices(vm) == 0) {
KASSERT(vm->iommu == NULL,
("vm_assign_pptdev: iommu must be NULL"));
maxaddr = vmm_sysmem_maxaddr(vm);
vm->iommu = iommu_create_domain(maxaddr);
if (vm->iommu == NULL)
return (ENXIO);
vm_iommu_map(vm);
}
error = ppt_assign_device(vm, bus, slot, func);
return (error);
}
void *
vm_gpa_hold(struct vm *vm, int vcpuid, vm_paddr_t gpa, size_t len, int reqprot,
void **cookie)
{
int i, count, pageoff;
struct mem_map *mm;
vm_page_t m;
#ifdef INVARIANTS
/*
* All vcpus are frozen by ioctls that modify the memory map
* (e.g. VM_MMAP_MEMSEG). Therefore 'vm->memmap[]' stability is
* guaranteed if at least one vcpu is in the VCPU_FROZEN state.
*/
int state;
KASSERT(vcpuid >= -1 && vcpuid < vm->maxcpus, ("%s: invalid vcpuid %d",
__func__, vcpuid));
for (i = 0; i < vm->maxcpus; i++) {
if (vcpuid != -1 && vcpuid != i)
continue;
state = vcpu_get_state(vm, i, NULL);
KASSERT(state == VCPU_FROZEN, ("%s: invalid vcpu state %d",
__func__, state));
}
#endif
pageoff = gpa & PAGE_MASK;
if (len > PAGE_SIZE - pageoff)
panic("vm_gpa_hold: invalid gpa/len: 0x%016lx/%lu", gpa, len);
count = 0;
for (i = 0; i < VM_MAX_MEMMAPS; i++) {
mm = &vm->mem_maps[i];
if (sysmem_mapping(vm, mm) && gpa >= mm->gpa &&
gpa < mm->gpa + mm->len) {
count = vm_fault_quick_hold_pages(&vm->vmspace->vm_map,
trunc_page(gpa), PAGE_SIZE, reqprot, &m, 1);
break;
}
}
if (count == 1) {
*cookie = m;
return ((void *)(PHYS_TO_DMAP(VM_PAGE_TO_PHYS(m)) + pageoff));
} else {
*cookie = NULL;
return (NULL);
}
}
void
vm_gpa_release(void *cookie)
{
vm_page_t m = cookie;
vm_page_lock(m);
vm_page_unhold(m);
vm_page_unlock(m);
}
int
vm_get_register(struct vm *vm, int vcpu, int reg, uint64_t *retval)
{
if (vcpu < 0 || vcpu >= vm->maxcpus)
return (EINVAL);
if (reg >= VM_REG_LAST)
return (EINVAL);
return (VMGETREG(vm->cookie, vcpu, reg, retval));
}
int
vm_set_register(struct vm *vm, int vcpuid, int reg, uint64_t val)
{
struct vcpu *vcpu;
int error;
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
return (EINVAL);
if (reg >= VM_REG_LAST)
return (EINVAL);
error = VMSETREG(vm->cookie, vcpuid, reg, val);
if (error || reg != VM_REG_GUEST_RIP)
return (error);
/* Set 'nextrip' to match the value of %rip */
VCPU_CTR1(vm, vcpuid, "Setting nextrip to %#lx", val);
vcpu = &vm->vcpu[vcpuid];
vcpu->nextrip = val;
return (0);
}
static boolean_t
is_descriptor_table(int reg)
{
switch (reg) {
case VM_REG_GUEST_IDTR:
case VM_REG_GUEST_GDTR:
return (TRUE);
default:
return (FALSE);
}
}
static boolean_t
is_segment_register(int reg)
{
switch (reg) {
case VM_REG_GUEST_ES:
case VM_REG_GUEST_CS:
case VM_REG_GUEST_SS:
case VM_REG_GUEST_DS:
case VM_REG_GUEST_FS:
case VM_REG_GUEST_GS:
case VM_REG_GUEST_TR:
case VM_REG_GUEST_LDTR:
return (TRUE);
default:
return (FALSE);
}
}
int
vm_get_seg_desc(struct vm *vm, int vcpu, int reg,
struct seg_desc *desc)
{
if (vcpu < 0 || vcpu >= vm->maxcpus)
return (EINVAL);
if (!is_segment_register(reg) && !is_descriptor_table(reg))
return (EINVAL);
return (VMGETDESC(vm->cookie, vcpu, reg, desc));
}
int
vm_set_seg_desc(struct vm *vm, int vcpu, int reg,
struct seg_desc *desc)
{
if (vcpu < 0 || vcpu >= vm->maxcpus)
return (EINVAL);
if (!is_segment_register(reg) && !is_descriptor_table(reg))
return (EINVAL);
return (VMSETDESC(vm->cookie, vcpu, reg, desc));
}
static void
restore_guest_fpustate(struct vcpu *vcpu)
{
/* flush host state to the pcb */
fpuexit(curthread);
/* restore guest FPU state */
fpu_stop_emulating();
fpurestore(vcpu->guestfpu);
/* restore guest XCR0 if XSAVE is enabled in the host */
if (rcr4() & CR4_XSAVE)
load_xcr(0, vcpu->guest_xcr0);
/*
* The FPU is now "dirty" with the guest's state so turn on emulation
* to trap any access to the FPU by the host.
*/
fpu_start_emulating();
}
static void
save_guest_fpustate(struct vcpu *vcpu)
{
if ((rcr0() & CR0_TS) == 0)
panic("fpu emulation not enabled in host!");
/* save guest XCR0 and restore host XCR0 */
if (rcr4() & CR4_XSAVE) {
vcpu->guest_xcr0 = rxcr(0);
load_xcr(0, vmm_get_host_xcr0());
}
/* save guest FPU state */
fpu_stop_emulating();
fpusave(vcpu->guestfpu);
fpu_start_emulating();
}
static VMM_STAT(VCPU_IDLE_TICKS, "number of ticks vcpu was idle");
static int
vcpu_set_state_locked(struct vm *vm, int vcpuid, enum vcpu_state newstate,
bool from_idle)
{
struct vcpu *vcpu;
int error;
vcpu = &vm->vcpu[vcpuid];
vcpu_assert_locked(vcpu);
/*
* State transitions from the vmmdev_ioctl() must always begin from
* the VCPU_IDLE state. This guarantees that there is only a single
* ioctl() operating on a vcpu at any point.
*/
if (from_idle) {
while (vcpu->state != VCPU_IDLE) {
vcpu->reqidle = 1;
vcpu_notify_event_locked(vcpu, false);
VCPU_CTR1(vm, vcpuid, "vcpu state change from %s to "
"idle requested", vcpu_state2str(vcpu->state));
msleep_spin(&vcpu->state, &vcpu->mtx, "vmstat", hz);
}
} else {
KASSERT(vcpu->state != VCPU_IDLE, ("invalid transition from "
"vcpu idle state"));
}
if (vcpu->state == VCPU_RUNNING) {
KASSERT(vcpu->hostcpu == curcpu, ("curcpu %d and hostcpu %d "
"mismatch for running vcpu", curcpu, vcpu->hostcpu));
} else {
KASSERT(vcpu->hostcpu == NOCPU, ("Invalid hostcpu %d for a "
"vcpu that is not running", vcpu->hostcpu));
}
/*
* The following state transitions are allowed:
* IDLE -> FROZEN -> IDLE
* FROZEN -> RUNNING -> FROZEN
* FROZEN -> SLEEPING -> FROZEN
*/
switch (vcpu->state) {
case VCPU_IDLE:
case VCPU_RUNNING:
case VCPU_SLEEPING:
error = (newstate != VCPU_FROZEN);
break;
case VCPU_FROZEN:
error = (newstate == VCPU_FROZEN);
break;
default:
error = 1;
break;
}
if (error)
return (EBUSY);
VCPU_CTR2(vm, vcpuid, "vcpu state changed from %s to %s",
vcpu_state2str(vcpu->state), vcpu_state2str(newstate));
vcpu->state = newstate;
if (newstate == VCPU_RUNNING)
vcpu->hostcpu = curcpu;
else
vcpu->hostcpu = NOCPU;
if (newstate == VCPU_IDLE)
wakeup(&vcpu->state);
return (0);
}
static void
vcpu_require_state(struct vm *vm, int vcpuid, enum vcpu_state newstate)
{
int error;
if ((error = vcpu_set_state(vm, vcpuid, newstate, false)) != 0)
panic("Error %d setting state to %d\n", error, newstate);
}
static void
vcpu_require_state_locked(struct vm *vm, int vcpuid, enum vcpu_state newstate)
{
int error;
if ((error = vcpu_set_state_locked(vm, vcpuid, newstate, false)) != 0)
panic("Error %d setting state to %d", error, newstate);
}
static void
vm_set_rendezvous_func(struct vm *vm, vm_rendezvous_func_t func)
{
KASSERT(mtx_owned(&vm->rendezvous_mtx), ("rendezvous_mtx not locked"));
/*
* Update 'rendezvous_func' and execute a write memory barrier to
* ensure that it is visible across all host cpus. This is not needed
* for correctness but it does ensure that all the vcpus will notice
* that the rendezvous is requested immediately.
*/
vm->rendezvous_func = func;
wmb();
}
#define RENDEZVOUS_CTR0(vm, vcpuid, fmt) \
do { \
if (vcpuid >= 0) \
VCPU_CTR0(vm, vcpuid, fmt); \
else \
VM_CTR0(vm, fmt); \
} while (0)
static void
vm_handle_rendezvous(struct vm *vm, int vcpuid)
{
KASSERT(vcpuid == -1 || (vcpuid >= 0 && vcpuid < vm->maxcpus),
("vm_handle_rendezvous: invalid vcpuid %d", vcpuid));
mtx_lock(&vm->rendezvous_mtx);
while (vm->rendezvous_func != NULL) {
/* 'rendezvous_req_cpus' must be a subset of 'active_cpus' */
CPU_AND(&vm->rendezvous_req_cpus, &vm->active_cpus);
if (vcpuid != -1 &&
CPU_ISSET(vcpuid, &vm->rendezvous_req_cpus) &&
!CPU_ISSET(vcpuid, &vm->rendezvous_done_cpus)) {
VCPU_CTR0(vm, vcpuid, "Calling rendezvous func");
(*vm->rendezvous_func)(vm, vcpuid, vm->rendezvous_arg);
CPU_SET(vcpuid, &vm->rendezvous_done_cpus);
}
if (CPU_CMP(&vm->rendezvous_req_cpus,
&vm->rendezvous_done_cpus) == 0) {
VCPU_CTR0(vm, vcpuid, "Rendezvous completed");
vm_set_rendezvous_func(vm, NULL);
wakeup(&vm->rendezvous_func);
break;
}
RENDEZVOUS_CTR0(vm, vcpuid, "Wait for rendezvous completion");
mtx_sleep(&vm->rendezvous_func, &vm->rendezvous_mtx, 0,
"vmrndv", 0);
}
mtx_unlock(&vm->rendezvous_mtx);
}
/*
* Emulate a guest 'hlt' by sleeping until the vcpu is ready to run.
*/
static int
vm_handle_hlt(struct vm *vm, int vcpuid, bool intr_disabled, bool *retu)
{
struct vcpu *vcpu;
const char *wmesg;
int t, vcpu_halted, vm_halted;
KASSERT(!CPU_ISSET(vcpuid, &vm->halted_cpus), ("vcpu already halted"));
vcpu = &vm->vcpu[vcpuid];
vcpu_halted = 0;
vm_halted = 0;
vcpu_lock(vcpu);
while (1) {
/*
* Do a final check for pending NMI or interrupts before
* really putting this thread to sleep. Also check for
* software events that would cause this vcpu to wakeup.
*
* These interrupts/events could have happened after the
* vcpu returned from VMRUN() and before it acquired the
* vcpu lock above.
*/
if (vm->rendezvous_func != NULL || vm->suspend || vcpu->reqidle)
break;
if (vm_nmi_pending(vm, vcpuid))
break;
if (!intr_disabled) {
if (vm_extint_pending(vm, vcpuid) ||
vlapic_pending_intr(vcpu->vlapic, NULL)) {
break;
}
}
/* Don't go to sleep if the vcpu thread needs to yield */
if (vcpu_should_yield(vm, vcpuid))
break;
if (vcpu_debugged(vm, vcpuid))
break;
/*
* Some Linux guests implement "halt" by having all vcpus
* execute HLT with interrupts disabled. 'halted_cpus' keeps
* track of the vcpus that have entered this state. When all
* vcpus enter the halted state the virtual machine is halted.
*/
if (intr_disabled) {
wmesg = "vmhalt";
VCPU_CTR0(vm, vcpuid, "Halted");
if (!vcpu_halted && halt_detection_enabled) {
vcpu_halted = 1;
CPU_SET_ATOMIC(vcpuid, &vm->halted_cpus);
}
if (CPU_CMP(&vm->halted_cpus, &vm->active_cpus) == 0) {
vm_halted = 1;
break;
}
} else {
wmesg = "vmidle";
}
t = ticks;
vcpu_require_state_locked(vm, vcpuid, VCPU_SLEEPING);
/*
* XXX msleep_spin() cannot be interrupted by signals so
* wake up periodically to check pending signals.
*/
msleep_spin(vcpu, &vcpu->mtx, wmesg, hz);
vcpu_require_state_locked(vm, vcpuid, VCPU_FROZEN);
vmm_stat_incr(vm, vcpuid, VCPU_IDLE_TICKS, ticks - t);
}
if (vcpu_halted)
CPU_CLR_ATOMIC(vcpuid, &vm->halted_cpus);
vcpu_unlock(vcpu);
if (vm_halted)
vm_suspend(vm, VM_SUSPEND_HALT);
return (0);
}
static int
vm_handle_paging(struct vm *vm, int vcpuid, bool *retu)
{
int rv, ftype;
struct vm_map *map;
struct vcpu *vcpu;
struct vm_exit *vme;
vcpu = &vm->vcpu[vcpuid];
vme = &vcpu->exitinfo;
KASSERT(vme->inst_length == 0, ("%s: invalid inst_length %d",
__func__, vme->inst_length));
ftype = vme->u.paging.fault_type;
KASSERT(ftype == VM_PROT_READ ||
ftype == VM_PROT_WRITE || ftype == VM_PROT_EXECUTE,
("vm_handle_paging: invalid fault_type %d", ftype));
if (ftype == VM_PROT_READ || ftype == VM_PROT_WRITE) {
rv = pmap_emulate_accessed_dirty(vmspace_pmap(vm->vmspace),
vme->u.paging.gpa, ftype);
if (rv == 0) {
VCPU_CTR2(vm, vcpuid, "%s bit emulation for gpa %#lx",
ftype == VM_PROT_READ ? "accessed" : "dirty",
vme->u.paging.gpa);
goto done;
}
}
map = &vm->vmspace->vm_map;
rv = vm_fault(map, vme->u.paging.gpa, ftype, VM_FAULT_NORMAL);
VCPU_CTR3(vm, vcpuid, "vm_handle_paging rv = %d, gpa = %#lx, "
"ftype = %d", rv, vme->u.paging.gpa, ftype);
if (rv != KERN_SUCCESS)
return (EFAULT);
done:
return (0);
}
static int
vm_handle_inst_emul(struct vm *vm, int vcpuid, bool *retu)
{
struct vie *vie;
struct vcpu *vcpu;
struct vm_exit *vme;
uint64_t gla, gpa, cs_base;
struct vm_guest_paging *paging;
mem_region_read_t mread;
mem_region_write_t mwrite;
enum vm_cpu_mode cpu_mode;
int cs_d, error, fault;
vcpu = &vm->vcpu[vcpuid];
vme = &vcpu->exitinfo;
KASSERT(vme->inst_length == 0, ("%s: invalid inst_length %d",
__func__, vme->inst_length));
gla = vme->u.inst_emul.gla;
gpa = vme->u.inst_emul.gpa;
cs_base = vme->u.inst_emul.cs_base;
cs_d = vme->u.inst_emul.cs_d;
vie = &vme->u.inst_emul.vie;
paging = &vme->u.inst_emul.paging;
cpu_mode = paging->cpu_mode;
VCPU_CTR1(vm, vcpuid, "inst_emul fault accessing gpa %#lx", gpa);
/* Fetch, decode and emulate the faulting instruction */
if (vie->num_valid == 0) {
error = vmm_fetch_instruction(vm, vcpuid, paging, vme->rip +
cs_base, VIE_INST_SIZE, vie, &fault);
} else {
/*
* The instruction bytes have already been copied into 'vie'
*/
error = fault = 0;
}
if (error || fault)
return (error);
if (vmm_decode_instruction(vm, vcpuid, gla, cpu_mode, cs_d, vie) != 0) {
VCPU_CTR1(vm, vcpuid, "Error decoding instruction at %#lx",
vme->rip + cs_base);
*retu = true; /* dump instruction bytes in userspace */
return (0);
}
/*
* Update 'nextrip' based on the length of the emulated instruction.
*/
vme->inst_length = vie->num_processed;
vcpu->nextrip += vie->num_processed;
VCPU_CTR1(vm, vcpuid, "nextrip updated to %#lx after instruction "
"decoding", vcpu->nextrip);
/* return to userland unless this is an in-kernel emulated device */
if (gpa >= DEFAULT_APIC_BASE && gpa < DEFAULT_APIC_BASE + PAGE_SIZE) {
mread = lapic_mmio_read;
mwrite = lapic_mmio_write;
} else if (gpa >= VIOAPIC_BASE && gpa < VIOAPIC_BASE + VIOAPIC_SIZE) {
mread = vioapic_mmio_read;
mwrite = vioapic_mmio_write;
} else if (gpa >= VHPET_BASE && gpa < VHPET_BASE + VHPET_SIZE) {
mread = vhpet_mmio_read;
mwrite = vhpet_mmio_write;
} else {
*retu = true;
return (0);
}
error = vmm_emulate_instruction(vm, vcpuid, gpa, vie, paging,
mread, mwrite, retu);
return (error);
}
static int
vm_handle_suspend(struct vm *vm, int vcpuid, bool *retu)
{
int i, done;
struct vcpu *vcpu;
done = 0;
vcpu = &vm->vcpu[vcpuid];
CPU_SET_ATOMIC(vcpuid, &vm->suspended_cpus);
/*
* Wait until all 'active_cpus' have suspended themselves.
*
* Since a VM may be suspended at any time including when one or
* more vcpus are doing a rendezvous we need to call the rendezvous
* handler while we are waiting to prevent a deadlock.
*/
vcpu_lock(vcpu);
while (1) {
if (CPU_CMP(&vm->suspended_cpus, &vm->active_cpus) == 0) {
VCPU_CTR0(vm, vcpuid, "All vcpus suspended");
break;
}
if (vm->rendezvous_func == NULL) {
VCPU_CTR0(vm, vcpuid, "Sleeping during suspend");
vcpu_require_state_locked(vm, vcpuid, VCPU_SLEEPING);
msleep_spin(vcpu, &vcpu->mtx, "vmsusp", hz);
vcpu_require_state_locked(vm, vcpuid, VCPU_FROZEN);
} else {
VCPU_CTR0(vm, vcpuid, "Rendezvous during suspend");
vcpu_unlock(vcpu);
vm_handle_rendezvous(vm, vcpuid);
vcpu_lock(vcpu);
}
}
vcpu_unlock(vcpu);
/*
* Wakeup the other sleeping vcpus and return to userspace.
*/
for (i = 0; i < vm->maxcpus; i++) {
if (CPU_ISSET(i, &vm->suspended_cpus)) {
vcpu_notify_event(vm, i, false);
}
}
*retu = true;
return (0);
}
static int
vm_handle_reqidle(struct vm *vm, int vcpuid, bool *retu)
{
struct vcpu *vcpu = &vm->vcpu[vcpuid];
vcpu_lock(vcpu);
KASSERT(vcpu->reqidle, ("invalid vcpu reqidle %d", vcpu->reqidle));
vcpu->reqidle = 0;
vcpu_unlock(vcpu);
*retu = true;
return (0);
}
int
vm_suspend(struct vm *vm, enum vm_suspend_how how)
{
int i;
if (how <= VM_SUSPEND_NONE || how >= VM_SUSPEND_LAST)
return (EINVAL);
if (atomic_cmpset_int(&vm->suspend, 0, how) == 0) {
VM_CTR2(vm, "virtual machine already suspended %d/%d",
vm->suspend, how);
return (EALREADY);
}
VM_CTR1(vm, "virtual machine successfully suspended %d", how);
/*
* Notify all active vcpus that they are now suspended.
*/
for (i = 0; i < vm->maxcpus; i++) {
if (CPU_ISSET(i, &vm->active_cpus))
vcpu_notify_event(vm, i, false);
}
return (0);
}
void
vm_exit_suspended(struct vm *vm, int vcpuid, uint64_t rip)
{
struct vm_exit *vmexit;
KASSERT(vm->suspend > VM_SUSPEND_NONE && vm->suspend < VM_SUSPEND_LAST,
("vm_exit_suspended: invalid suspend type %d", vm->suspend));
vmexit = vm_exitinfo(vm, vcpuid);
vmexit->rip = rip;
vmexit->inst_length = 0;
vmexit->exitcode = VM_EXITCODE_SUSPENDED;
vmexit->u.suspended.how = vm->suspend;
}
void
vm_exit_debug(struct vm *vm, int vcpuid, uint64_t rip)
{
struct vm_exit *vmexit;
vmexit = vm_exitinfo(vm, vcpuid);
vmexit->rip = rip;
vmexit->inst_length = 0;
vmexit->exitcode = VM_EXITCODE_DEBUG;
}
void
vm_exit_rendezvous(struct vm *vm, int vcpuid, uint64_t rip)
{
struct vm_exit *vmexit;
KASSERT(vm->rendezvous_func != NULL, ("rendezvous not in progress"));
vmexit = vm_exitinfo(vm, vcpuid);
vmexit->rip = rip;
vmexit->inst_length = 0;
vmexit->exitcode = VM_EXITCODE_RENDEZVOUS;
vmm_stat_incr(vm, vcpuid, VMEXIT_RENDEZVOUS, 1);
}
void
vm_exit_reqidle(struct vm *vm, int vcpuid, uint64_t rip)
{
struct vm_exit *vmexit;
vmexit = vm_exitinfo(vm, vcpuid);
vmexit->rip = rip;
vmexit->inst_length = 0;
vmexit->exitcode = VM_EXITCODE_REQIDLE;
vmm_stat_incr(vm, vcpuid, VMEXIT_REQIDLE, 1);
}
void
vm_exit_astpending(struct vm *vm, int vcpuid, uint64_t rip)
{
struct vm_exit *vmexit;
vmexit = vm_exitinfo(vm, vcpuid);
vmexit->rip = rip;
vmexit->inst_length = 0;
vmexit->exitcode = VM_EXITCODE_BOGUS;
vmm_stat_incr(vm, vcpuid, VMEXIT_ASTPENDING, 1);
}
int
vm_run(struct vm *vm, struct vm_run *vmrun)
{
struct vm_eventinfo evinfo;
int error, vcpuid;
struct vcpu *vcpu;
struct pcb *pcb;
uint64_t tscval;
struct vm_exit *vme;
bool retu, intr_disabled;
pmap_t pmap;
vcpuid = vmrun->cpuid;
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
return (EINVAL);
if (!CPU_ISSET(vcpuid, &vm->active_cpus))
return (EINVAL);
if (CPU_ISSET(vcpuid, &vm->suspended_cpus))
return (EINVAL);
pmap = vmspace_pmap(vm->vmspace);
vcpu = &vm->vcpu[vcpuid];
vme = &vcpu->exitinfo;
evinfo.rptr = &vm->rendezvous_func;
evinfo.sptr = &vm->suspend;
evinfo.iptr = &vcpu->reqidle;
restart:
critical_enter();
KASSERT(!CPU_ISSET(curcpu, &pmap->pm_active),
("vm_run: absurd pm_active"));
tscval = rdtsc();
pcb = PCPU_GET(curpcb);
set_pcb_flags(pcb, PCB_FULL_IRET);
restore_guest_fpustate(vcpu);
vcpu_require_state(vm, vcpuid, VCPU_RUNNING);
error = VMRUN(vm->cookie, vcpuid, vcpu->nextrip, pmap, &evinfo);
vcpu_require_state(vm, vcpuid, VCPU_FROZEN);
save_guest_fpustate(vcpu);
vmm_stat_incr(vm, vcpuid, VCPU_TOTAL_RUNTIME, rdtsc() - tscval);
critical_exit();
if (error == 0) {
retu = false;
vcpu->nextrip = vme->rip + vme->inst_length;
switch (vme->exitcode) {
case VM_EXITCODE_REQIDLE:
error = vm_handle_reqidle(vm, vcpuid, &retu);
break;
case VM_EXITCODE_SUSPENDED:
error = vm_handle_suspend(vm, vcpuid, &retu);
break;
case VM_EXITCODE_IOAPIC_EOI:
vioapic_process_eoi(vm, vcpuid,
vme->u.ioapic_eoi.vector);
break;
case VM_EXITCODE_RENDEZVOUS:
vm_handle_rendezvous(vm, vcpuid);
error = 0;
break;
case VM_EXITCODE_HLT:
intr_disabled = ((vme->u.hlt.rflags & PSL_I) == 0);
error = vm_handle_hlt(vm, vcpuid, intr_disabled, &retu);
break;
case VM_EXITCODE_PAGING:
error = vm_handle_paging(vm, vcpuid, &retu);
break;
case VM_EXITCODE_INST_EMUL:
error = vm_handle_inst_emul(vm, vcpuid, &retu);
break;
case VM_EXITCODE_INOUT:
case VM_EXITCODE_INOUT_STR:
error = vm_handle_inout(vm, vcpuid, vme, &retu);
break;
case VM_EXITCODE_MONITOR:
case VM_EXITCODE_MWAIT:
case VM_EXITCODE_VMINSN:
vm_inject_ud(vm, vcpuid);
break;
default:
retu = true; /* handled in userland */
break;
}
}
if (error == 0 && retu == false)
goto restart;
VCPU_CTR2(vm, vcpuid, "retu %d/%d", error, vme->exitcode);
/* copy the exit information */
bcopy(vme, &vmrun->vm_exit, sizeof(struct vm_exit));
return (error);
}
int
vm_restart_instruction(void *arg, int vcpuid)
{
struct vm *vm;
struct vcpu *vcpu;
enum vcpu_state state;
uint64_t rip;
int error;
vm = arg;
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
return (EINVAL);
vcpu = &vm->vcpu[vcpuid];
state = vcpu_get_state(vm, vcpuid, NULL);
if (state == VCPU_RUNNING) {
/*
* When a vcpu is "running" the next instruction is determined
* by adding 'rip' and 'inst_length' in the vcpu's 'exitinfo'.
* Thus setting 'inst_length' to zero will cause the current
* instruction to be restarted.
*/
vcpu->exitinfo.inst_length = 0;
VCPU_CTR1(vm, vcpuid, "restarting instruction at %#lx by "
"setting inst_length to zero", vcpu->exitinfo.rip);
} else if (state == VCPU_FROZEN) {
/*
* When a vcpu is "frozen" it is outside the critical section
* around VMRUN() and 'nextrip' points to the next instruction.
* Thus instruction restart is achieved by setting 'nextrip'
* to the vcpu's %rip.
*/
error = vm_get_register(vm, vcpuid, VM_REG_GUEST_RIP, &rip);
KASSERT(!error, ("%s: error %d getting rip", __func__, error));
VCPU_CTR2(vm, vcpuid, "restarting instruction by updating "
"nextrip from %#lx to %#lx", vcpu->nextrip, rip);
vcpu->nextrip = rip;
} else {
panic("%s: invalid state %d", __func__, state);
}
return (0);
}
int
vm_exit_intinfo(struct vm *vm, int vcpuid, uint64_t info)
{
struct vcpu *vcpu;
int type, vector;
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
return (EINVAL);
vcpu = &vm->vcpu[vcpuid];
if (info & VM_INTINFO_VALID) {
type = info & VM_INTINFO_TYPE;
vector = info & 0xff;
if (type == VM_INTINFO_NMI && vector != IDT_NMI)
return (EINVAL);
if (type == VM_INTINFO_HWEXCEPTION && vector >= 32)
return (EINVAL);
if (info & VM_INTINFO_RSVD)
return (EINVAL);
} else {
info = 0;
}
VCPU_CTR2(vm, vcpuid, "%s: info1(%#lx)", __func__, info);
vcpu->exitintinfo = info;
return (0);
}
enum exc_class {
EXC_BENIGN,
EXC_CONTRIBUTORY,
EXC_PAGEFAULT
};
#define IDT_VE 20 /* Virtualization Exception (Intel specific) */
static enum exc_class
exception_class(uint64_t info)
{
int type, vector;
KASSERT(info & VM_INTINFO_VALID, ("intinfo must be valid: %#lx", info));
type = info & VM_INTINFO_TYPE;
vector = info & 0xff;
/* Table 6-4, "Interrupt and Exception Classes", Intel SDM, Vol 3 */
switch (type) {
case VM_INTINFO_HWINTR:
case VM_INTINFO_SWINTR:
case VM_INTINFO_NMI:
return (EXC_BENIGN);
default:
/*
* Hardware exception.
*
* SVM and VT-x use identical type values to represent NMI,
* hardware interrupt and software interrupt.
*
* SVM uses type '3' for all exceptions. VT-x uses type '3'
* for exceptions except #BP and #OF. #BP and #OF use a type
* value of '5' or '6'. Therefore we don't check for explicit
* values of 'type' to classify 'intinfo' into a hardware
* exception.
*/
break;
}
switch (vector) {
case IDT_PF:
case IDT_VE:
return (EXC_PAGEFAULT);
case IDT_DE:
case IDT_TS:
case IDT_NP:
case IDT_SS:
case IDT_GP:
return (EXC_CONTRIBUTORY);
default:
return (EXC_BENIGN);
}
}
static int
nested_fault(struct vm *vm, int vcpuid, uint64_t info1, uint64_t info2,
uint64_t *retinfo)
{
enum exc_class exc1, exc2;
int type1, vector1;
KASSERT(info1 & VM_INTINFO_VALID, ("info1 %#lx is not valid", info1));
KASSERT(info2 & VM_INTINFO_VALID, ("info2 %#lx is not valid", info2));
/*
* If an exception occurs while attempting to call the double-fault
* handler the processor enters shutdown mode (aka triple fault).
*/
type1 = info1 & VM_INTINFO_TYPE;
vector1 = info1 & 0xff;
if (type1 == VM_INTINFO_HWEXCEPTION && vector1 == IDT_DF) {
VCPU_CTR2(vm, vcpuid, "triple fault: info1(%#lx), info2(%#lx)",
info1, info2);
vm_suspend(vm, VM_SUSPEND_TRIPLEFAULT);
*retinfo = 0;
return (0);
}
/*
* Table 6-5 "Conditions for Generating a Double Fault", Intel SDM, Vol3
*/
exc1 = exception_class(info1);
exc2 = exception_class(info2);
if ((exc1 == EXC_CONTRIBUTORY && exc2 == EXC_CONTRIBUTORY) ||
(exc1 == EXC_PAGEFAULT && exc2 != EXC_BENIGN)) {
/* Convert nested fault into a double fault. */
*retinfo = IDT_DF;
*retinfo |= VM_INTINFO_VALID | VM_INTINFO_HWEXCEPTION;
*retinfo |= VM_INTINFO_DEL_ERRCODE;
} else {
/* Handle exceptions serially */
*retinfo = info2;
}
return (1);
}
static uint64_t
vcpu_exception_intinfo(struct vcpu *vcpu)
{
uint64_t info = 0;
if (vcpu->exception_pending) {
info = vcpu->exc_vector & 0xff;
info |= VM_INTINFO_VALID | VM_INTINFO_HWEXCEPTION;
if (vcpu->exc_errcode_valid) {
info |= VM_INTINFO_DEL_ERRCODE;
info |= (uint64_t)vcpu->exc_errcode << 32;
}
}
return (info);
}
int
vm_entry_intinfo(struct vm *vm, int vcpuid, uint64_t *retinfo)
{
struct vcpu *vcpu;
uint64_t info1, info2;
int valid;
KASSERT(vcpuid >= 0 &&
vcpuid < vm->maxcpus, ("invalid vcpu %d", vcpuid));
vcpu = &vm->vcpu[vcpuid];
info1 = vcpu->exitintinfo;
vcpu->exitintinfo = 0;
info2 = 0;
if (vcpu->exception_pending) {
info2 = vcpu_exception_intinfo(vcpu);
vcpu->exception_pending = 0;
VCPU_CTR2(vm, vcpuid, "Exception %d delivered: %#lx",
vcpu->exc_vector, info2);
}
if ((info1 & VM_INTINFO_VALID) && (info2 & VM_INTINFO_VALID)) {
valid = nested_fault(vm, vcpuid, info1, info2, retinfo);
} else if (info1 & VM_INTINFO_VALID) {
*retinfo = info1;
valid = 1;
} else if (info2 & VM_INTINFO_VALID) {
*retinfo = info2;
valid = 1;
} else {
valid = 0;
}
if (valid) {
VCPU_CTR4(vm, vcpuid, "%s: info1(%#lx), info2(%#lx), "
"retinfo(%#lx)", __func__, info1, info2, *retinfo);
}
return (valid);
}
int
vm_get_intinfo(struct vm *vm, int vcpuid, uint64_t *info1, uint64_t *info2)
{
struct vcpu *vcpu;
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
return (EINVAL);
vcpu = &vm->vcpu[vcpuid];
*info1 = vcpu->exitintinfo;
*info2 = vcpu_exception_intinfo(vcpu);
return (0);
}
int
vm_inject_exception(struct vm *vm, int vcpuid, int vector, int errcode_valid,
uint32_t errcode, int restart_instruction)
{
struct vcpu *vcpu;
uint64_t regval;
int error;
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
return (EINVAL);
if (vector < 0 || vector >= 32)
return (EINVAL);
/*
* A double fault exception should never be injected directly into
* the guest. It is a derived exception that results from specific
* combinations of nested faults.
*/
if (vector == IDT_DF)
return (EINVAL);
vcpu = &vm->vcpu[vcpuid];
if (vcpu->exception_pending) {
VCPU_CTR2(vm, vcpuid, "Unable to inject exception %d due to "
"pending exception %d", vector, vcpu->exc_vector);
return (EBUSY);
}
if (errcode_valid) {
/*
* Exceptions don't deliver an error code in real mode.
*/
error = vm_get_register(vm, vcpuid, VM_REG_GUEST_CR0, &regval);
KASSERT(!error, ("%s: error %d getting CR0", __func__, error));
if (!(regval & CR0_PE))
errcode_valid = 0;
}
/*
* From section 26.6.1 "Interruptibility State" in Intel SDM:
*
* Event blocking by "STI" or "MOV SS" is cleared after guest executes
* one instruction or incurs an exception.
*/
error = vm_set_register(vm, vcpuid, VM_REG_GUEST_INTR_SHADOW, 0);
KASSERT(error == 0, ("%s: error %d clearing interrupt shadow",
__func__, error));
if (restart_instruction)
vm_restart_instruction(vm, vcpuid);
vcpu->exception_pending = 1;
vcpu->exc_vector = vector;
vcpu->exc_errcode = errcode;
vcpu->exc_errcode_valid = errcode_valid;
VCPU_CTR1(vm, vcpuid, "Exception %d pending", vector);
return (0);
}
void
vm_inject_fault(void *vmarg, int vcpuid, int vector, int errcode_valid,
int errcode)
{
struct vm *vm;
int error, restart_instruction;
vm = vmarg;
restart_instruction = 1;
error = vm_inject_exception(vm, vcpuid, vector, errcode_valid,
errcode, restart_instruction);
KASSERT(error == 0, ("vm_inject_exception error %d", error));
}
void
vm_inject_pf(void *vmarg, int vcpuid, int error_code, uint64_t cr2)
{
struct vm *vm;
int error;
vm = vmarg;
VCPU_CTR2(vm, vcpuid, "Injecting page fault: error_code %#x, cr2 %#lx",
error_code, cr2);
error = vm_set_register(vm, vcpuid, VM_REG_GUEST_CR2, cr2);
KASSERT(error == 0, ("vm_set_register(cr2) error %d", error));
vm_inject_fault(vm, vcpuid, IDT_PF, 1, error_code);
}
static VMM_STAT(VCPU_NMI_COUNT, "number of NMIs delivered to vcpu");
int
vm_inject_nmi(struct vm *vm, int vcpuid)
{
struct vcpu *vcpu;
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
return (EINVAL);
vcpu = &vm->vcpu[vcpuid];
vcpu->nmi_pending = 1;
vcpu_notify_event(vm, vcpuid, false);
return (0);
}
int
vm_nmi_pending(struct vm *vm, int vcpuid)
{
struct vcpu *vcpu;
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
panic("vm_nmi_pending: invalid vcpuid %d", vcpuid);
vcpu = &vm->vcpu[vcpuid];
return (vcpu->nmi_pending);
}
void
vm_nmi_clear(struct vm *vm, int vcpuid)
{
struct vcpu *vcpu;
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
panic("vm_nmi_pending: invalid vcpuid %d", vcpuid);
vcpu = &vm->vcpu[vcpuid];
if (vcpu->nmi_pending == 0)
panic("vm_nmi_clear: inconsistent nmi_pending state");
vcpu->nmi_pending = 0;
vmm_stat_incr(vm, vcpuid, VCPU_NMI_COUNT, 1);
}
static VMM_STAT(VCPU_EXTINT_COUNT, "number of ExtINTs delivered to vcpu");
int
vm_inject_extint(struct vm *vm, int vcpuid)
{
struct vcpu *vcpu;
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
return (EINVAL);
vcpu = &vm->vcpu[vcpuid];
vcpu->extint_pending = 1;
vcpu_notify_event(vm, vcpuid, false);
return (0);
}
int
vm_extint_pending(struct vm *vm, int vcpuid)
{
struct vcpu *vcpu;
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
panic("vm_extint_pending: invalid vcpuid %d", vcpuid);
vcpu = &vm->vcpu[vcpuid];
return (vcpu->extint_pending);
}
void
vm_extint_clear(struct vm *vm, int vcpuid)
{
struct vcpu *vcpu;
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
panic("vm_extint_pending: invalid vcpuid %d", vcpuid);
vcpu = &vm->vcpu[vcpuid];
if (vcpu->extint_pending == 0)
panic("vm_extint_clear: inconsistent extint_pending state");
vcpu->extint_pending = 0;
vmm_stat_incr(vm, vcpuid, VCPU_EXTINT_COUNT, 1);
}
int
vm_get_capability(struct vm *vm, int vcpu, int type, int *retval)
{
if (vcpu < 0 || vcpu >= vm->maxcpus)
return (EINVAL);
if (type < 0 || type >= VM_CAP_MAX)
return (EINVAL);
return (VMGETCAP(vm->cookie, vcpu, type, retval));
}
int
vm_set_capability(struct vm *vm, int vcpu, int type, int val)
{
if (vcpu < 0 || vcpu >= vm->maxcpus)
return (EINVAL);
if (type < 0 || type >= VM_CAP_MAX)
return (EINVAL);
return (VMSETCAP(vm->cookie, vcpu, type, val));
}
struct vlapic *
vm_lapic(struct vm *vm, int cpu)
{
return (vm->vcpu[cpu].vlapic);
}
struct vioapic *
vm_ioapic(struct vm *vm)
{
return (vm->vioapic);
}
struct vhpet *
vm_hpet(struct vm *vm)
{
return (vm->vhpet);
}
boolean_t
vmm_is_pptdev(int bus, int slot, int func)
{
int found, i, n;
int b, s, f;
char *val, *cp, *cp2;
/*
* XXX
* The length of an environment variable is limited to 128 bytes which
* puts an upper limit on the number of passthru devices that may be
* specified using a single environment variable.
*
* Work around this by scanning multiple environment variable
* names instead of a single one - yuck!
*/
const char *names[] = { "pptdevs", "pptdevs2", "pptdevs3", NULL };
/* set pptdevs="1/2/3 4/5/6 7/8/9 10/11/12" */
found = 0;
for (i = 0; names[i] != NULL && !found; i++) {
cp = val = kern_getenv(names[i]);
while (cp != NULL && *cp != '\0') {
if ((cp2 = strchr(cp, ' ')) != NULL)
*cp2 = '\0';
n = sscanf(cp, "%d/%d/%d", &b, &s, &f);
if (n == 3 && bus == b && slot == s && func == f) {
found = 1;
break;
}
if (cp2 != NULL)
*cp2++ = ' ';
cp = cp2;
}
freeenv(val);
}
return (found);
}
void *
vm_iommu_domain(struct vm *vm)
{
return (vm->iommu);
}
int
vcpu_set_state(struct vm *vm, int vcpuid, enum vcpu_state newstate,
bool from_idle)
{
int error;
struct vcpu *vcpu;
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
panic("vm_set_run_state: invalid vcpuid %d", vcpuid);
vcpu = &vm->vcpu[vcpuid];
vcpu_lock(vcpu);
error = vcpu_set_state_locked(vm, vcpuid, newstate, from_idle);
vcpu_unlock(vcpu);
return (error);
}
enum vcpu_state
vcpu_get_state(struct vm *vm, int vcpuid, int *hostcpu)
{
struct vcpu *vcpu;
enum vcpu_state state;
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
panic("vm_get_run_state: invalid vcpuid %d", vcpuid);
vcpu = &vm->vcpu[vcpuid];
vcpu_lock(vcpu);
state = vcpu->state;
if (hostcpu != NULL)
*hostcpu = vcpu->hostcpu;
vcpu_unlock(vcpu);
return (state);
}
int
vm_activate_cpu(struct vm *vm, int vcpuid)
{
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
return (EINVAL);
if (CPU_ISSET(vcpuid, &vm->active_cpus))
return (EBUSY);
VCPU_CTR0(vm, vcpuid, "activated");
CPU_SET_ATOMIC(vcpuid, &vm->active_cpus);
return (0);
}
int
vm_suspend_cpu(struct vm *vm, int vcpuid)
{
int i;
if (vcpuid < -1 || vcpuid >= vm->maxcpus)
return (EINVAL);
if (vcpuid == -1) {
vm->debug_cpus = vm->active_cpus;
for (i = 0; i < vm->maxcpus; i++) {
if (CPU_ISSET(i, &vm->active_cpus))
vcpu_notify_event(vm, i, false);
}
} else {
if (!CPU_ISSET(vcpuid, &vm->active_cpus))
return (EINVAL);
CPU_SET_ATOMIC(vcpuid, &vm->debug_cpus);
vcpu_notify_event(vm, vcpuid, false);
}
return (0);
}
int
vm_resume_cpu(struct vm *vm, int vcpuid)
{
if (vcpuid < -1 || vcpuid >= vm->maxcpus)
return (EINVAL);
if (vcpuid == -1) {
CPU_ZERO(&vm->debug_cpus);
} else {
if (!CPU_ISSET(vcpuid, &vm->debug_cpus))
return (EINVAL);
CPU_CLR_ATOMIC(vcpuid, &vm->debug_cpus);
}
return (0);
}
int
vcpu_debugged(struct vm *vm, int vcpuid)
{
return (CPU_ISSET(vcpuid, &vm->debug_cpus));
}
cpuset_t
vm_active_cpus(struct vm *vm)
{
return (vm->active_cpus);
}
cpuset_t
vm_debug_cpus(struct vm *vm)
{
return (vm->debug_cpus);
}
cpuset_t
vm_suspended_cpus(struct vm *vm)
{
return (vm->suspended_cpus);
}
void *
vcpu_stats(struct vm *vm, int vcpuid)
{
return (vm->vcpu[vcpuid].stats);
}
int
vm_get_x2apic_state(struct vm *vm, int vcpuid, enum x2apic_state *state)
{
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
return (EINVAL);
*state = vm->vcpu[vcpuid].x2apic_state;
return (0);
}
int
vm_set_x2apic_state(struct vm *vm, int vcpuid, enum x2apic_state state)
{
if (vcpuid < 0 || vcpuid >= vm->maxcpus)
return (EINVAL);
if (state >= X2APIC_STATE_LAST)
return (EINVAL);
vm->vcpu[vcpuid].x2apic_state = state;
vlapic_set_x2apic_state(vm, vcpuid, state);
return (0);
}
/*
* This function is called to ensure that a vcpu "sees" a pending event
* as soon as possible:
* - If the vcpu thread is sleeping then it is woken up.
* - If the vcpu is running on a different host_cpu then an IPI will be directed
* to the host_cpu to cause the vcpu to trap into the hypervisor.
*/
static void
vcpu_notify_event_locked(struct vcpu *vcpu, bool lapic_intr)
{
int hostcpu;
hostcpu = vcpu->hostcpu;
if (vcpu->state == VCPU_RUNNING) {
KASSERT(hostcpu != NOCPU, ("vcpu running on invalid hostcpu"));
if (hostcpu != curcpu) {
if (lapic_intr) {
vlapic_post_intr(vcpu->vlapic, hostcpu,
vmm_ipinum);
} else {
ipi_cpu(hostcpu, vmm_ipinum);
}
} else {
/*
* If the 'vcpu' is running on 'curcpu' then it must
* be sending a notification to itself (e.g. SELF_IPI).
* The pending event will be picked up when the vcpu
* transitions back to guest context.
*/
}
} else {
KASSERT(hostcpu == NOCPU, ("vcpu state %d not consistent "
"with hostcpu %d", vcpu->state, hostcpu));
if (vcpu->state == VCPU_SLEEPING)
wakeup_one(vcpu);
}
}
void
vcpu_notify_event(struct vm *vm, int vcpuid, bool lapic_intr)
{
struct vcpu *vcpu = &vm->vcpu[vcpuid];
vcpu_lock(vcpu);
vcpu_notify_event_locked(vcpu, lapic_intr);
vcpu_unlock(vcpu);
}
struct vmspace *
vm_get_vmspace(struct vm *vm)
{
return (vm->vmspace);
}
int
vm_apicid2vcpuid(struct vm *vm, int apicid)
{
/*
* XXX apic id is assumed to be numerically identical to vcpu id
*/
return (apicid);
}
void
vm_smp_rendezvous(struct vm *vm, int vcpuid, cpuset_t dest,
vm_rendezvous_func_t func, void *arg)
{
int i;
/*
* Enforce that this function is called without any locks
*/
WITNESS_WARN(WARN_PANIC, NULL, "vm_smp_rendezvous");
KASSERT(vcpuid == -1 || (vcpuid >= 0 && vcpuid < vm->maxcpus),
("vm_smp_rendezvous: invalid vcpuid %d", vcpuid));
restart:
mtx_lock(&vm->rendezvous_mtx);
if (vm->rendezvous_func != NULL) {
/*
* If a rendezvous is already in progress then we need to
* call the rendezvous handler in case this 'vcpuid' is one
* of the targets of the rendezvous.
*/
RENDEZVOUS_CTR0(vm, vcpuid, "Rendezvous already in progress");
mtx_unlock(&vm->rendezvous_mtx);
vm_handle_rendezvous(vm, vcpuid);
goto restart;
}
KASSERT(vm->rendezvous_func == NULL, ("vm_smp_rendezvous: previous "
"rendezvous is still in progress"));
RENDEZVOUS_CTR0(vm, vcpuid, "Initiating rendezvous");
vm->rendezvous_req_cpus = dest;
CPU_ZERO(&vm->rendezvous_done_cpus);
vm->rendezvous_arg = arg;
vm_set_rendezvous_func(vm, func);
mtx_unlock(&vm->rendezvous_mtx);
/*
* Wake up any sleeping vcpus and trigger a VM-exit in any running
* vcpus so they handle the rendezvous as soon as possible.
*/
for (i = 0; i < vm->maxcpus; i++) {
if (CPU_ISSET(i, &dest))
vcpu_notify_event(vm, i, false);
}
vm_handle_rendezvous(vm, vcpuid);
}
struct vatpic *
vm_atpic(struct vm *vm)
{
return (vm->vatpic);
}
struct vatpit *
vm_atpit(struct vm *vm)
{
return (vm->vatpit);
}
struct vpmtmr *
vm_pmtmr(struct vm *vm)
{
return (vm->vpmtmr);
}
struct vrtc *
vm_rtc(struct vm *vm)
{
return (vm->vrtc);
}
enum vm_reg_name
vm_segment_name(int seg)
{
static enum vm_reg_name seg_names[] = {
VM_REG_GUEST_ES,
VM_REG_GUEST_CS,
VM_REG_GUEST_SS,
VM_REG_GUEST_DS,
VM_REG_GUEST_FS,
VM_REG_GUEST_GS
};
KASSERT(seg >= 0 && seg < nitems(seg_names),
("%s: invalid segment encoding %d", __func__, seg));
return (seg_names[seg]);
}
void
vm_copy_teardown(struct vm *vm, int vcpuid, struct vm_copyinfo *copyinfo,
int num_copyinfo)
{
int idx;
for (idx = 0; idx < num_copyinfo; idx++) {
if (copyinfo[idx].cookie != NULL)
vm_gpa_release(copyinfo[idx].cookie);
}
bzero(copyinfo, num_copyinfo * sizeof(struct vm_copyinfo));
}
int
vm_copy_setup(struct vm *vm, int vcpuid, struct vm_guest_paging *paging,
uint64_t gla, size_t len, int prot, struct vm_copyinfo *copyinfo,
int num_copyinfo, int *fault)
{
int error, idx, nused;
size_t n, off, remaining;
void *hva, *cookie;
uint64_t gpa;
bzero(copyinfo, sizeof(struct vm_copyinfo) * num_copyinfo);
nused = 0;
remaining = len;
while (remaining > 0) {
KASSERT(nused < num_copyinfo, ("insufficient vm_copyinfo"));
error = vm_gla2gpa(vm, vcpuid, paging, gla, prot, &gpa, fault);
if (error || *fault)
return (error);
off = gpa & PAGE_MASK;
n = min(remaining, PAGE_SIZE - off);
copyinfo[nused].gpa = gpa;
copyinfo[nused].len = n;
remaining -= n;
gla += n;
nused++;
}
for (idx = 0; idx < nused; idx++) {
hva = vm_gpa_hold(vm, vcpuid, copyinfo[idx].gpa,
copyinfo[idx].len, prot, &cookie);
if (hva == NULL)
break;
copyinfo[idx].hva = hva;
copyinfo[idx].cookie = cookie;
}
if (idx != nused) {
vm_copy_teardown(vm, vcpuid, copyinfo, num_copyinfo);
return (EFAULT);
} else {
*fault = 0;
return (0);
}
}
void
vm_copyin(struct vm *vm, int vcpuid, struct vm_copyinfo *copyinfo, void *kaddr,
size_t len)
{
char *dst;
int idx;
dst = kaddr;
idx = 0;
while (len > 0) {
bcopy(copyinfo[idx].hva, dst, copyinfo[idx].len);
len -= copyinfo[idx].len;
dst += copyinfo[idx].len;
idx++;
}
}
void
vm_copyout(struct vm *vm, int vcpuid, const void *kaddr,
struct vm_copyinfo *copyinfo, size_t len)
{
const char *src;
int idx;
src = kaddr;
idx = 0;
while (len > 0) {
bcopy(src, copyinfo[idx].hva, copyinfo[idx].len);
len -= copyinfo[idx].len;
src += copyinfo[idx].len;
idx++;
}
}
/*
* Return the amount of in-use and wired memory for the VM. Since
* these are global stats, only return the values with for vCPU 0
*/
VMM_STAT_DECLARE(VMM_MEM_RESIDENT);
VMM_STAT_DECLARE(VMM_MEM_WIRED);
static void
vm_get_rescnt(struct vm *vm, int vcpu, struct vmm_stat_type *stat)
{
if (vcpu == 0) {
vmm_stat_set(vm, vcpu, VMM_MEM_RESIDENT,
PAGE_SIZE * vmspace_resident_count(vm->vmspace));
}
}
static void
vm_get_wiredcnt(struct vm *vm, int vcpu, struct vmm_stat_type *stat)
{
if (vcpu == 0) {
vmm_stat_set(vm, vcpu, VMM_MEM_WIRED,
PAGE_SIZE * pmap_wired_count(vmspace_pmap(vm->vmspace)));
}
}
VMM_STAT_FUNC(VMM_MEM_RESIDENT, "Resident memory", vm_get_rescnt);
VMM_STAT_FUNC(VMM_MEM_WIRED, "Wired memory", vm_get_wiredcnt);