/*
* Copyright (c) 2012 ARM Limited
* All rights reserved
*
* The license below extends only to copyright in the software and shall
* not be construed as granting a license to any other intellectual
* property including but not limited to intellectual property relating
* to a hardware implementation of the functionality of the software
* licensed hereunder. You may use the software subject to the license
* terms below provided that you ensure that this notice is replicated
* unmodified and in its entirety in all distributions of the software,
* modified or unmodified, in source code or in binary form.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met: redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer;
* 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;
* neither the name of the copyright holders nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "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 THE COPYRIGHT
* OWNER 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.
*
* Authors: Andreas Sandberg
*/
#include <linux/kvm.h>
#include <sys/ioctl.h>
#include <sys/mman.h>
#include <unistd.h>
#include <cerrno>
#include <csignal>
#include <ostream>
#include "arch/mmapped_ipr.hh"
#include "arch/utility.hh"
#include "cpu/kvm/base.hh"
#include "debug/Checkpoint.hh"
#include "debug/Drain.hh"
#include "debug/Kvm.hh"
#include "debug/KvmIO.hh"
#include "debug/KvmRun.hh"
#include "params/BaseKvmCPU.hh"
#include "sim/process.hh"
#include "sim/system.hh"
#include <signal.h>
/* Used by some KVM macros */
#define PAGE_SIZE pageSize
volatile bool timerOverflowed = false;
static void
onTimerOverflow(int signo, siginfo_t *si, void *data)
{
timerOverflowed = true;
}
BaseKvmCPU::BaseKvmCPU(BaseKvmCPUParams *params)
: BaseCPU(params),
vm(*params->kvmVM),
_status(Idle),
dataPort(name() + ".dcache_port", this),
instPort(name() + ".icache_port", this),
threadContextDirty(true),
kvmStateDirty(false),
vcpuID(vm.allocVCPUID()), vcpuFD(-1), vcpuMMapSize(0),
_kvmRun(NULL), mmioRing(NULL),
pageSize(sysconf(_SC_PAGE_SIZE)),
tickEvent(*this),
perfControlledByTimer(params->usePerfOverflow),
hostFreq(params->hostFreq),
hostFactor(params->hostFactor),
drainManager(NULL),
ctrInsts(0)
{
if (pageSize == -1)
panic("KVM: Failed to determine host page size (%i)\n",
errno);
thread = new SimpleThread(this, 0, params->system,
params->itb, params->dtb, params->isa[0]);
thread->setStatus(ThreadContext::Halted);
tc = thread->getTC();
threadContexts.push_back(tc);
setupCounters();
if (params->usePerfOverflow)
runTimer.reset(new PerfKvmTimer(hwCycles,
KVM_TIMER_SIGNAL,
params->hostFactor,
params->hostFreq));
else
runTimer.reset(new PosixKvmTimer(KVM_TIMER_SIGNAL, CLOCK_MONOTONIC,
params->hostFactor,
params->hostFreq));
}
BaseKvmCPU::~BaseKvmCPU()
{
if (_kvmRun)
munmap(_kvmRun, vcpuMMapSize);
close(vcpuFD);
}
void
BaseKvmCPU::init()
{
BaseCPU::init();
if (numThreads != 1)
fatal("KVM: Multithreading not supported");
tc->initMemProxies(tc);
// initialize CPU, including PC
if (FullSystem && !switchedOut())
TheISA::initCPU(tc, tc->contextId());
mmio_req.setThreadContext(tc->contextId(), 0);
}
void
BaseKvmCPU::startup()
{
const BaseKvmCPUParams * const p(
dynamic_cast<const BaseKvmCPUParams *>(params()));
Kvm &kvm(vm.kvm);
BaseCPU::startup();
assert(vcpuFD == -1);
// Tell the VM that a CPU is about to start.
vm.cpuStartup();
// We can't initialize KVM CPUs in BaseKvmCPU::init() since we are
// not guaranteed that the parent KVM VM has initialized at that
// point. Initialize virtual CPUs here instead.
vcpuFD = vm.createVCPU(vcpuID);
// Setup signal handlers. This has to be done after the vCPU is
// created since it manipulates the vCPU signal mask.
setupSignalHandler();
// Map the KVM run structure */
vcpuMMapSize = kvm.getVCPUMMapSize();
_kvmRun = (struct kvm_run *)mmap(0, vcpuMMapSize,
PROT_READ | PROT_WRITE, MAP_SHARED,
vcpuFD, 0);
if (_kvmRun == MAP_FAILED)
panic("KVM: Failed to map run data structure\n");
// Setup a pointer to the MMIO ring buffer if coalesced MMIO is
// available. The offset into the KVM's communication page is
// provided by the coalesced MMIO capability.
int mmioOffset(kvm.capCoalescedMMIO());
if (!p->useCoalescedMMIO) {
inform("KVM: Coalesced MMIO disabled by config.\n");
} else if (mmioOffset) {
inform("KVM: Coalesced IO available\n");
mmioRing = (struct kvm_coalesced_mmio_ring *)(
(char *)_kvmRun + (mmioOffset * pageSize));
} else {
inform("KVM: Coalesced not supported by host OS\n");
}
thread->startup();
}
void
BaseKvmCPU::regStats()
{
using namespace Stats;
BaseCPU::regStats();
numInsts
.name(name() + ".committedInsts")
.desc("Number of instructions committed")
;
numVMExits
.name(name() + ".numVMExits")
.desc("total number of KVM exits")
;
numVMHalfEntries
.name(name() + ".numVMHalfEntries")
.desc("number of KVM entries to finalize pending operations")
;
numExitSignal
.name(name() + ".numExitSignal")
.desc("exits due to signal delivery")
;
numMMIO
.name(name() + ".numMMIO")
.desc("number of VM exits due to memory mapped IO")
;
numCoalescedMMIO
.name(name() + ".numCoalescedMMIO")
.desc("number of coalesced memory mapped IO requests")
;
numIO
.name(name() + ".numIO")
.desc("number of VM exits due to legacy IO")
;
numHalt
.name(name() + ".numHalt")
.desc("number of VM exits due to wait for interrupt instructions")
;
numInterrupts
.name(name() + ".numInterrupts")
.desc("number of interrupts delivered")
;
numHypercalls
.name(name() + ".numHypercalls")
.desc("number of hypercalls")
;
}
void
BaseKvmCPU::serializeThread(std::ostream &os, ThreadID tid)
{
if (DTRACE(Checkpoint)) {
DPRINTF(Checkpoint, "KVM: Serializing thread %i:\n", tid);
dump();
}
assert(tid == 0);
assert(_status == Idle);
thread->serialize(os);
}
void
BaseKvmCPU::unserializeThread(Checkpoint *cp, const std::string §ion,
ThreadID tid)
{
DPRINTF(Checkpoint, "KVM: Unserialize thread %i:\n", tid);
assert(tid == 0);
assert(_status == Idle);
thread->unserialize(cp, section);
threadContextDirty = true;
}
unsigned int
BaseKvmCPU::drain(DrainManager *dm)
{
if (switchedOut())
return 0;
DPRINTF(Drain, "BaseKvmCPU::drain\n");
switch (_status) {
case Running:
// The base KVM code is normally ready when it is in the
// Running state, but the architecture specific code might be
// of a different opinion. This may happen when the CPU been
// notified of an event that hasn't been accepted by the vCPU
// yet.
if (!archIsDrained()) {
drainManager = dm;
return 1;
}
// The state of the CPU is consistent, so we don't need to do
// anything special to drain it. We simply de-schedule the
// tick event and enter the Idle state to prevent nasty things
// like MMIOs from happening.
if (tickEvent.scheduled())
deschedule(tickEvent);
_status = Idle;
/** FALLTHROUGH */
case Idle:
// Idle, no need to drain
assert(!tickEvent.scheduled());
// Sync the thread context here since we'll need it when we
// switch CPUs or checkpoint the CPU.
syncThreadContext();
return 0;
case RunningServiceCompletion:
// The CPU has just requested a service that was handled in
// the RunningService state, but the results have still not
// been reported to the CPU. Now, we /could/ probably just
// update the register state ourselves instead of letting KVM
// handle it, but that would be tricky. Instead, we enter KVM
// and let it do its stuff.
drainManager = dm;
DPRINTF(Drain, "KVM CPU is waiting for service completion, "
"requesting drain.\n");
return 1;
case RunningService:
// We need to drain since the CPU is waiting for service (e.g., MMIOs)
drainManager = dm;
DPRINTF(Drain, "KVM CPU is waiting for service, requesting drain.\n");
return 1;
default:
panic("KVM: Unhandled CPU state in drain()\n");
return 0;
}
}
void
BaseKvmCPU::drainResume()
{
assert(!tickEvent.scheduled());
// We might have been switched out. In that case, we don't need to
// do anything.
if (switchedOut())
return;
DPRINTF(Kvm, "drainResume\n");
verifyMemoryMode();
// The tick event is de-scheduled as a part of the draining
// process. Re-schedule it if the thread context is active.
if (tc->status() == ThreadContext::Active) {
schedule(tickEvent, nextCycle());
_status = Running;
} else {
_status = Idle;
}
}
void
BaseKvmCPU::switchOut()
{
DPRINTF(Kvm, "switchOut\n");
BaseCPU::switchOut();
// We should have drained prior to executing a switchOut, which
// means that the tick event shouldn't be scheduled and the CPU is
// idle.
assert(!tickEvent.scheduled());
assert(_status == Idle);
}
void
BaseKvmCPU::takeOverFrom(BaseCPU *cpu)
{
DPRINTF(Kvm, "takeOverFrom\n");
BaseCPU::takeOverFrom(cpu);
// We should have drained prior to executing a switchOut, which
// means that the tick event shouldn't be scheduled and the CPU is
// idle.
assert(!tickEvent.scheduled());
assert(_status == Idle);
assert(threadContexts.size() == 1);
// Force an update of the KVM state here instead of flagging the
// TC as dirty. This is not ideal from a performance point of
// view, but it makes debugging easier as it allows meaningful KVM
// state to be dumped before and after a takeover.
updateKvmState();
threadContextDirty = false;
}
void
BaseKvmCPU::verifyMemoryMode() const
{
if (!(system->isAtomicMode() && system->bypassCaches())) {
fatal("The KVM-based CPUs requires the memory system to be in the "
"'atomic_noncaching' mode.\n");
}
}
void
BaseKvmCPU::wakeup()
{
DPRINTF(Kvm, "wakeup()\n");
if (thread->status() != ThreadContext::Suspended)
return;
thread->activate();
}
void
BaseKvmCPU::activateContext(ThreadID thread_num, Cycles delay)
{
DPRINTF(Kvm, "ActivateContext %d (%d cycles)\n", thread_num, delay);
assert(thread_num == 0);
assert(thread);
assert(_status == Idle);
assert(!tickEvent.scheduled());
numCycles += ticksToCycles(thread->lastActivate - thread->lastSuspend);
schedule(tickEvent, clockEdge(delay));
_status = Running;
}
void
BaseKvmCPU::suspendContext(ThreadID thread_num)
{
DPRINTF(Kvm, "SuspendContext %d\n", thread_num);
assert(thread_num == 0);
assert(thread);
if (_status == Idle)
return;
assert(_status == Running);
// The tick event may no be scheduled if the quest has requested
// the monitor to wait for interrupts. The normal CPU models can
// get their tick events descheduled by quiesce instructions, but
// that can't happen here.
if (tickEvent.scheduled())
deschedule(tickEvent);
_status = Idle;
}
void
BaseKvmCPU::deallocateContext(ThreadID thread_num)
{
// for now, these are equivalent
suspendContext(thread_num);
}
void
BaseKvmCPU::haltContext(ThreadID thread_num)
{
// for now, these are equivalent
suspendContext(thread_num);
}
ThreadContext *
BaseKvmCPU::getContext(int tn)
{
assert(tn == 0);
syncThreadContext();
return tc;
}
Counter
BaseKvmCPU::totalInsts() const
{
return ctrInsts;
}
Counter
BaseKvmCPU::totalOps() const
{
hack_once("Pretending totalOps is equivalent to totalInsts()\n");
return ctrInsts;
}
void
BaseKvmCPU::dump()
{
inform("State dumping not implemented.");
}
void
BaseKvmCPU::tick()
{
Tick delay(0);
assert(_status != Idle);
switch (_status) {
case RunningService:
// handleKvmExit() will determine the next state of the CPU
delay = handleKvmExit();
if (tryDrain())
_status = Idle;
break;
case RunningServiceCompletion:
case Running: {
Tick ticksToExecute(mainEventQueue.nextTick() - curTick());
// We might need to update the KVM state.
syncKvmState();
DPRINTF(KvmRun, "Entering KVM...\n");
if (drainManager) {
// Force an immediate exit from KVM after completing
// pending operations. The architecture-specific code
// takes care to run until it is in a state where it can
// safely be drained.
delay = kvmRunDrain();
} else {
delay = kvmRun(ticksToExecute);
}
// Entering into KVM implies that we'll have to reload the thread
// context from KVM if we want to access it. Flag the KVM state as
// dirty with respect to the cached thread context.
kvmStateDirty = true;
// Enter into the RunningService state unless the
// simulation was stopped by a timer.
if (_kvmRun->exit_reason != KVM_EXIT_INTR) {
_status = RunningService;
} else {
++numExitSignal;
_status = Running;
}
if (tryDrain())
_status = Idle;
} break;
default:
panic("BaseKvmCPU entered tick() in an illegal state (%i)\n",
_status);
}
// Schedule a new tick if we are still running
if (_status != Idle)
schedule(tickEvent, clockEdge(ticksToCycles(delay)));
}
Tick
BaseKvmCPU::kvmRunDrain()
{
// By default, the only thing we need to drain is a pending IO
// operation which assumes that we are in the
// RunningServiceCompletion state.
assert(_status == RunningServiceCompletion);
// Deliver the data from the pending IO operation and immediately
// exit.
return kvmRun(0);
}
uint64_t
BaseKvmCPU::getHostCycles() const
{
return hwCycles.read();
}
Tick
BaseKvmCPU::kvmRun(Tick ticks)
{
Tick ticksExecuted;
DPRINTF(KvmRun, "KVM: Executing for %i ticks\n", ticks);
timerOverflowed = false;
if (ticks == 0) {
// Settings ticks == 0 is a special case which causes an entry
// into KVM that finishes pending operations (e.g., IO) and
// then immediately exits.
DPRINTF(KvmRun, "KVM: Delivering IO without full guest entry\n");
++numVMHalfEntries;
// This signal is always masked while we are executing in gem5
// and gets unmasked temporarily as soon as we enter into
// KVM. See setSignalMask() and setupSignalHandler().
raise(KVM_TIMER_SIGNAL);
// Enter into KVM. KVM will check for signals after completing
// pending operations (IO). Since the KVM_TIMER_SIGNAL is
// pending, this forces an immediate exit into gem5 again. We
// don't bother to setup timers since this shouldn't actually
// execute any code in the guest.
ioctlRun();
// We always execute at least one cycle to prevent the
// BaseKvmCPU::tick() to be rescheduled on the same tick
// twice.
ticksExecuted = clockPeriod();
} else {
if (ticks < runTimer->resolution()) {
DPRINTF(KvmRun, "KVM: Adjusting tick count (%i -> %i)\n",
ticks, runTimer->resolution());
ticks = runTimer->resolution();
}
// Get hardware statistics after synchronizing contexts. The KVM
// state update might affect guest cycle counters.
uint64_t baseCycles(getHostCycles());
uint64_t baseInstrs(hwInstructions.read());
// Arm the run timer and start the cycle timer if it isn't
// controlled by the overflow timer. Starting/stopping the cycle
// timer automatically starts the other perf timers as they are in
// the same counter group.
runTimer->arm(ticks);
if (!perfControlledByTimer)
hwCycles.start();
ioctlRun();
runTimer->disarm();
if (!perfControlledByTimer)
hwCycles.stop();
// The timer signal may have been delivered after we exited
// from KVM. It will be pending in that case since it is
// masked when we aren't executing in KVM. Discard it to make
// sure we don't deliver it immediately next time we try to
// enter into KVM.
discardPendingSignal(KVM_TIMER_SIGNAL);
const uint64_t hostCyclesExecuted(getHostCycles() - baseCycles);
const uint64_t simCyclesExecuted(hostCyclesExecuted * hostFactor);
const uint64_t instsExecuted(hwInstructions.read() - baseInstrs);
ticksExecuted = runTimer->ticksFromHostCycles(hostCyclesExecuted);
if (ticksExecuted < ticks &&
timerOverflowed &&
_kvmRun->exit_reason == KVM_EXIT_INTR) {
// TODO: We should probably do something clever here...
warn("KVM: Early timer event, requested %i ticks but got %i ticks.\n",
ticks, ticksExecuted);
}
/* Update statistics */
numCycles += simCyclesExecuted;;
numInsts += instsExecuted;
ctrInsts += instsExecuted;
system->totalNumInsts += instsExecuted;
DPRINTF(KvmRun,
"KVM: Executed %i instructions in %i cycles "
"(%i ticks, sim cycles: %i).\n",
instsExecuted, hostCyclesExecuted, ticksExecuted, simCyclesExecuted);
}
++numVMExits;
return ticksExecuted + flushCoalescedMMIO();
}
void
BaseKvmCPU::kvmNonMaskableInterrupt()
{
++numInterrupts;
if (ioctl(KVM_NMI) == -1)
panic("KVM: Failed to deliver NMI to virtual CPU\n");
}
void
BaseKvmCPU::kvmInterrupt(const struct kvm_interrupt &interrupt)
{
++numInterrupts;
if (ioctl(KVM_INTERRUPT, (void *)&interrupt) == -1)
panic("KVM: Failed to deliver interrupt to virtual CPU\n");
}
void
BaseKvmCPU::getRegisters(struct kvm_regs ®s) const
{
if (ioctl(KVM_GET_REGS, ®s) == -1)
panic("KVM: Failed to get guest registers\n");
}
void
BaseKvmCPU::setRegisters(const struct kvm_regs ®s)
{
if (ioctl(KVM_SET_REGS, (void *)®s) == -1)
panic("KVM: Failed to set guest registers\n");
}
void
BaseKvmCPU::getSpecialRegisters(struct kvm_sregs ®s) const
{
if (ioctl(KVM_GET_SREGS, ®s) == -1)
panic("KVM: Failed to get guest special registers\n");
}
void
BaseKvmCPU::setSpecialRegisters(const struct kvm_sregs ®s)
{
if (ioctl(KVM_SET_SREGS, (void *)®s) == -1)
panic("KVM: Failed to set guest special registers\n");
}
void
BaseKvmCPU::getFPUState(struct kvm_fpu &state) const
{
if (ioctl(KVM_GET_FPU, &state) == -1)
panic("KVM: Failed to get guest FPU state\n");
}
void
BaseKvmCPU::setFPUState(const struct kvm_fpu &state)
{
if (ioctl(KVM_SET_FPU, (void *)&state) == -1)
panic("KVM: Failed to set guest FPU state\n");
}
void
BaseKvmCPU::setOneReg(uint64_t id, const void *addr)
{
#ifdef KVM_SET_ONE_REG
struct kvm_one_reg reg;
reg.id = id;
reg.addr = (uint64_t)addr;
if (ioctl(KVM_SET_ONE_REG, ®) == -1) {
panic("KVM: Failed to set register (0x%x) value (errno: %i)\n",
id, errno);
}
#else
panic("KVM_SET_ONE_REG is unsupported on this platform.\n");
#endif
}
void
BaseKvmCPU::getOneReg(uint64_t id, void *addr) const
{
#ifdef KVM_GET_ONE_REG
struct kvm_one_reg reg;
reg.id = id;
reg.addr = (uint64_t)addr;
if (ioctl(KVM_GET_ONE_REG, ®) == -1) {
panic("KVM: Failed to get register (0x%x) value (errno: %i)\n",
id, errno);
}
#else
panic("KVM_GET_ONE_REG is unsupported on this platform.\n");
#endif
}
std::string
BaseKvmCPU::getAndFormatOneReg(uint64_t id) const
{
#ifdef KVM_GET_ONE_REG
std::ostringstream ss;
ss.setf(std::ios::hex, std::ios::basefield);
ss.setf(std::ios::showbase);
#define HANDLE_INTTYPE(len) \
case KVM_REG_SIZE_U ## len: { \
uint ## len ## _t value; \
getOneReg(id, &value); \
ss << value; \
} break
#define HANDLE_ARRAY(len) \
case KVM_REG_SIZE_U ## len: { \
uint8_t value[len / 8]; \
getOneReg(id, value); \
ss << "[" << value[0]; \
for (int i = 1; i < len / 8; ++i) \
ss << ", " << value[i]; \
ss << "]"; \
} break
switch (id & KVM_REG_SIZE_MASK) {
HANDLE_INTTYPE(8);
HANDLE_INTTYPE(16);
HANDLE_INTTYPE(32);
HANDLE_INTTYPE(64);
HANDLE_ARRAY(128);
HANDLE_ARRAY(256);
HANDLE_ARRAY(512);
HANDLE_ARRAY(1024);
default:
ss << "??";
}
#undef HANDLE_INTTYPE
#undef HANDLE_ARRAY
return ss.str();
#else
panic("KVM_GET_ONE_REG is unsupported on this platform.\n");
#endif
}
void
BaseKvmCPU::syncThreadContext()
{
if (!kvmStateDirty)
return;
assert(!threadContextDirty);
updateThreadContext();
kvmStateDirty = false;
}
void
BaseKvmCPU::syncKvmState()
{
if (!threadContextDirty)
return;
assert(!kvmStateDirty);
updateKvmState();
threadContextDirty = false;
}
Tick
BaseKvmCPU::handleKvmExit()
{
DPRINTF(KvmRun, "handleKvmExit (exit_reason: %i)\n", _kvmRun->exit_reason);
assert(_status == RunningService);
// Switch into the running state by default. Individual handlers
// can override this.
_status = Running;
switch (_kvmRun->exit_reason) {
case KVM_EXIT_UNKNOWN:
return handleKvmExitUnknown();
case KVM_EXIT_EXCEPTION:
return handleKvmExitException();
case KVM_EXIT_IO:
_status = RunningServiceCompletion;
++numIO;
return handleKvmExitIO();
case KVM_EXIT_HYPERCALL:
++numHypercalls;
return handleKvmExitHypercall();
case KVM_EXIT_HLT:
/* The guest has halted and is waiting for interrupts */
DPRINTF(Kvm, "handleKvmExitHalt\n");
++numHalt;
// Suspend the thread until the next interrupt arrives
thread->suspend();
// This is actually ignored since the thread is suspended.
return 0;
case KVM_EXIT_MMIO:
_status = RunningServiceCompletion;
/* Service memory mapped IO requests */
DPRINTF(KvmIO, "KVM: Handling MMIO (w: %u, addr: 0x%x, len: %u)\n",
_kvmRun->mmio.is_write,
_kvmRun->mmio.phys_addr, _kvmRun->mmio.len);
++numMMIO;
return doMMIOAccess(_kvmRun->mmio.phys_addr, _kvmRun->mmio.data,
_kvmRun->mmio.len, _kvmRun->mmio.is_write);
case KVM_EXIT_IRQ_WINDOW_OPEN:
return handleKvmExitIRQWindowOpen();
case KVM_EXIT_FAIL_ENTRY:
return handleKvmExitFailEntry();
case KVM_EXIT_INTR:
/* KVM was interrupted by a signal, restart it in the next
* tick. */
return 0;
case KVM_EXIT_INTERNAL_ERROR:
panic("KVM: Internal error (suberror: %u)\n",
_kvmRun->internal.suberror);
default:
dump();
panic("KVM: Unexpected exit (exit_reason: %u)\n", _kvmRun->exit_reason);
}
}
Tick
BaseKvmCPU::handleKvmExitIO()
{
panic("KVM: Unhandled guest IO (dir: %i, size: %i, port: 0x%x, count: %i)\n",
_kvmRun->io.direction, _kvmRun->io.size,
_kvmRun->io.port, _kvmRun->io.count);
}
Tick
BaseKvmCPU::handleKvmExitHypercall()
{
panic("KVM: Unhandled hypercall\n");
}
Tick
BaseKvmCPU::handleKvmExitIRQWindowOpen()
{
warn("KVM: Unhandled IRQ window.\n");
return 0;
}
Tick
BaseKvmCPU::handleKvmExitUnknown()
{
dump();
panic("KVM: Unknown error when starting vCPU (hw reason: 0x%llx)\n",
_kvmRun->hw.hardware_exit_reason);
}
Tick
BaseKvmCPU::handleKvmExitException()
{
dump();
panic("KVM: Got exception when starting vCPU "
"(exception: %u, error_code: %u)\n",
_kvmRun->ex.exception, _kvmRun->ex.error_code);
}
Tick
BaseKvmCPU::handleKvmExitFailEntry()
{
dump();
panic("KVM: Failed to enter virtualized mode (hw reason: 0x%llx)\n",
_kvmRun->fail_entry.hardware_entry_failure_reason);
}
Tick
BaseKvmCPU::doMMIOAccess(Addr paddr, void *data, int size, bool write)
{
ThreadContext *tc(thread->getTC());
syncThreadContext();
mmio_req.setPhys(paddr, size, Request::UNCACHEABLE, dataMasterId());
// Some architectures do need to massage physical addresses a bit
// before they are inserted into the memory system. This enables
// APIC accesses on x86 and m5ops where supported through a MMIO
// interface.
BaseTLB::Mode tlb_mode(write ? BaseTLB::Write : BaseTLB::Read);
Fault fault(tc->getDTBPtr()->finalizePhysical(&mmio_req, tc, tlb_mode));
if (fault != NoFault)
warn("Finalization of MMIO address failed: %s\n", fault->name());
const MemCmd cmd(write ? MemCmd::WriteReq : MemCmd::ReadReq);
Packet pkt(&mmio_req, cmd);
pkt.dataStatic(data);
if (mmio_req.isMmappedIpr()) {
const Cycles ipr_delay(write ?
TheISA::handleIprWrite(tc, &pkt) :
TheISA::handleIprRead(tc, &pkt));
return clockEdge(ipr_delay);
} else {
return dataPort.sendAtomic(&pkt);
}
}
void
BaseKvmCPU::setSignalMask(const sigset_t *mask)
{
std::unique_ptr<struct kvm_signal_mask> kvm_mask;
if (mask) {
kvm_mask.reset((struct kvm_signal_mask *)operator new(
sizeof(struct kvm_signal_mask) + sizeof(*mask)));
// The kernel and the user-space headers have different ideas
// about the size of sigset_t. This seems like a massive hack,
// but is actually what qemu does.
assert(sizeof(*mask) >= 8);
kvm_mask->len = 8;
memcpy(kvm_mask->sigset, mask, kvm_mask->len);
}
if (ioctl(KVM_SET_SIGNAL_MASK, (void *)kvm_mask.get()) == -1)
panic("KVM: Failed to set vCPU signal mask (errno: %i)\n",
errno);
}
int
BaseKvmCPU::ioctl(int request, long p1) const
{
if (vcpuFD == -1)
panic("KVM: CPU ioctl called before initialization\n");
return ::ioctl(vcpuFD, request, p1);
}
Tick
BaseKvmCPU::flushCoalescedMMIO()
{
if (!mmioRing)
return 0;
DPRINTF(KvmIO, "KVM: Flushing the coalesced MMIO ring buffer\n");
// TODO: We might need to do synchronization when we start to
// support multiple CPUs
Tick ticks(0);
while (mmioRing->first != mmioRing->last) {
struct kvm_coalesced_mmio &ent(
mmioRing->coalesced_mmio[mmioRing->first]);
DPRINTF(KvmIO, "KVM: Handling coalesced MMIO (addr: 0x%x, len: %u)\n",
ent.phys_addr, ent.len);
++numCoalescedMMIO;
ticks += doMMIOAccess(ent.phys_addr, ent.data, ent.len, true);
mmioRing->first = (mmioRing->first + 1) % KVM_COALESCED_MMIO_MAX;
}
return ticks;
}
void
BaseKvmCPU::setupSignalHandler()
{
struct sigaction sa;
memset(&sa, 0, sizeof(sa));
sa.sa_sigaction = onTimerOverflow;
sa.sa_flags = SA_SIGINFO | SA_RESTART;
if (sigaction(KVM_TIMER_SIGNAL, &sa, NULL) == -1)
panic("KVM: Failed to setup vCPU signal handler\n");
sigset_t sigset;
if (sigprocmask(SIG_BLOCK, NULL, &sigset) == -1)
panic("KVM: Failed get signal mask\n");
// Request KVM to setup the same signal mask as we're currently
// running with. We'll sometimes need to mask the KVM_TIMER_SIGNAL
// to cause immediate exits from KVM after servicing IO
// requests. See kvmRun().
setSignalMask(&sigset);
// Mask the KVM_TIMER_SIGNAL so it isn't delivered unless we're
// actually executing inside KVM.
sigaddset(&sigset, KVM_TIMER_SIGNAL);
if (sigprocmask(SIG_SETMASK, &sigset, NULL) == -1)
panic("KVM: Failed mask the KVM timer signal\n");
}
bool
BaseKvmCPU::discardPendingSignal(int signum) const
{
int discardedSignal;
// Setting the timeout to zero causes sigtimedwait to return
// immediately.
struct timespec timeout;
timeout.tv_sec = 0;
timeout.tv_nsec = 0;
sigset_t sigset;
sigemptyset(&sigset);
sigaddset(&sigset, signum);
do {
discardedSignal = sigtimedwait(&sigset, NULL, &timeout);
} while (discardedSignal == -1 && errno == EINTR);
if (discardedSignal == signum)
return true;
else if (discardedSignal == -1 && errno == EAGAIN)
return false;
else
panic("Unexpected return value from sigtimedwait: %i (errno: %i)\n",
discardedSignal, errno);
}
void
BaseKvmCPU::setupCounters()
{
DPRINTF(Kvm, "Attaching cycle counter...\n");
PerfKvmCounterConfig cfgCycles(PERF_TYPE_HARDWARE,
PERF_COUNT_HW_CPU_CYCLES);
cfgCycles.disabled(true)
.pinned(true);
if (perfControlledByTimer) {
// We need to configure the cycles counter to send overflows
// since we are going to use it to trigger timer signals that
// trap back into m5 from KVM. In practice, this means that we
// need to set some non-zero sample period that gets
// overridden when the timer is armed.
cfgCycles.wakeupEvents(1)
.samplePeriod(42);
}
hwCycles.attach(cfgCycles,
0); // TID (0 => currentThread)
DPRINTF(Kvm, "Attaching instruction counter...\n");
PerfKvmCounterConfig cfgInstructions(PERF_TYPE_HARDWARE,
PERF_COUNT_HW_INSTRUCTIONS);
hwInstructions.attach(cfgInstructions,
0, // TID (0 => currentThread)
hwCycles);
}
bool
BaseKvmCPU::tryDrain()
{
if (!drainManager)
return false;
if (!archIsDrained()) {
DPRINTF(Drain, "tryDrain: Architecture code is not ready.\n");
return false;
}
if (_status == Idle || _status == Running) {
DPRINTF(Drain,
"tryDrain: CPU transitioned into the Idle state, drain done\n");
drainManager->signalDrainDone();
drainManager = NULL;
return true;
} else {
DPRINTF(Drain, "tryDrain: CPU not ready.\n");
return false;
}
}
void
BaseKvmCPU::ioctlRun()
{
if (ioctl(KVM_RUN) == -1) {
if (errno != EINTR)
panic("KVM: Failed to start virtual CPU (errno: %i)\n",
errno);
}
}