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-rw-r--r--src/cpu/kvm/base.cc129
-rw-r--r--src/cpu/kvm/base.hh56
-rw-r--r--src/cpu/kvm/x86_cpu.cc14
3 files changed, 159 insertions, 40 deletions
diff --git a/src/cpu/kvm/base.cc b/src/cpu/kvm/base.cc
index 0670f61c6..ddf80dbaa 100644
--- a/src/cpu/kvm/base.cc
+++ b/src/cpu/kvm/base.cc
@@ -170,6 +170,76 @@ BaseKvmCPU::startup()
schedule(startupEvent, curTick());
}
+BaseKvmCPU::Status
+BaseKvmCPU::KVMCpuPort::nextIOState() const
+{
+ return (activeMMIOReqs || pendingMMIOPkts.size())
+ ? RunningMMIOPending : RunningServiceCompletion;
+}
+
+Tick
+BaseKvmCPU::KVMCpuPort::submitIO(PacketPtr pkt)
+{
+ if (cpu->system->isAtomicMode()) {
+ Tick delay = sendAtomic(pkt);
+ delete pkt->req;
+ delete pkt;
+ return delay;
+ } else {
+ if (pendingMMIOPkts.empty() && sendTimingReq(pkt)) {
+ activeMMIOReqs++;
+ } else {
+ pendingMMIOPkts.push(pkt);
+ }
+ // Return value is irrelevant for timing-mode accesses.
+ return 0;
+ }
+}
+
+bool
+BaseKvmCPU::KVMCpuPort::recvTimingResp(PacketPtr pkt)
+{
+ DPRINTF(KvmIO, "KVM: Finished timing request\n");
+
+ delete pkt->req;
+ delete pkt;
+ activeMMIOReqs--;
+
+ // We can switch back into KVM when all pending and in-flight MMIO
+ // operations have completed.
+ if (!(activeMMIOReqs || pendingMMIOPkts.size())) {
+ DPRINTF(KvmIO, "KVM: Finished all outstanding timing requests\n");
+ cpu->finishMMIOPending();
+ }
+ return true;
+}
+
+void
+BaseKvmCPU::KVMCpuPort::recvReqRetry()
+{
+ DPRINTF(KvmIO, "KVM: Retry for timing request\n");
+
+ assert(pendingMMIOPkts.size());
+
+ // Assuming that we can issue infinite requests this cycle is a bit
+ // unrealistic, but it's not worth modeling something more complex in
+ // KVM.
+ while (pendingMMIOPkts.size() && sendTimingReq(pendingMMIOPkts.front())) {
+ pendingMMIOPkts.pop();
+ activeMMIOReqs++;
+ }
+}
+
+void
+BaseKvmCPU::finishMMIOPending()
+{
+ assert(_status = RunningMMIOPending);
+ assert(!tickEvent.scheduled());
+
+ _status = RunningServiceCompletion;
+ schedule(tickEvent, nextCycle());
+}
+
void
BaseKvmCPU::startupThread()
{
@@ -329,6 +399,12 @@ BaseKvmCPU::drain()
"requesting drain.\n");
return DrainState::Draining;
+ case RunningMMIOPending:
+ // We need to drain since there are in-flight timing accesses
+ DPRINTF(Drain, "KVM CPU is waiting for timing accesses to complete, "
+ "requesting drain.\n");
+ return DrainState::Draining;
+
case RunningService:
// We need to drain since the CPU is waiting for service (e.g., MMIOs)
DPRINTF(Drain, "KVM CPU is waiting for service, requesting drain.\n");
@@ -425,9 +501,9 @@ BaseKvmCPU::takeOverFrom(BaseCPU *cpu)
void
BaseKvmCPU::verifyMemoryMode() const
{
- if (!(system->isAtomicMode() && system->bypassCaches())) {
+ if (!(system->bypassCaches())) {
fatal("The KVM-based CPUs requires the memory system to be in the "
- "'atomic_noncaching' mode.\n");
+ "'noncaching' mode.\n");
}
}
@@ -536,7 +612,7 @@ void
BaseKvmCPU::tick()
{
Tick delay(0);
- assert(_status != Idle);
+ assert(_status != Idle && _status != RunningMMIOPending);
switch (_status) {
case RunningService:
@@ -620,7 +696,7 @@ BaseKvmCPU::tick()
}
// Schedule a new tick if we are still running
- if (_status != Idle)
+ if (_status != Idle && _status != RunningMMIOPending)
schedule(tickEvent, clockEdge(ticksToCycles(delay)));
}
@@ -629,8 +705,9 @@ 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);
+ // RunningServiceCompletion or RunningMMIOPending state.
+ assert(_status == RunningServiceCompletion ||
+ _status == RunningMMIOPending);
// Deliver the data from the pending IO operation and immediately
// exit.
@@ -922,9 +999,12 @@ BaseKvmCPU::handleKvmExit()
return handleKvmExitException();
case KVM_EXIT_IO:
- _status = RunningServiceCompletion;
+ {
++numIO;
- return handleKvmExitIO();
+ Tick ticks = handleKvmExitIO();
+ _status = dataPort.nextIOState();
+ return ticks;
+ }
case KVM_EXIT_HYPERCALL:
++numHypercalls;
@@ -942,15 +1022,21 @@ BaseKvmCPU::handleKvmExit()
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);
+ Tick ticks = doMMIOAccess(_kvmRun->mmio.phys_addr, _kvmRun->mmio.data,
+ _kvmRun->mmio.len, _kvmRun->mmio.is_write);
+ // doMMIOAccess could have triggered a suspend, in which case we don't
+ // want to overwrite the _status.
+ if (_status != Idle)
+ _status = dataPort.nextIOState();
+ return ticks;
+ }
case KVM_EXIT_IRQ_WINDOW_OPEN:
return handleKvmExitIRQWindowOpen();
@@ -1026,30 +1112,33 @@ BaseKvmCPU::doMMIOAccess(Addr paddr, void *data, int size, bool write)
ThreadContext *tc(thread->getTC());
syncThreadContext();
- Request mmio_req(paddr, size, Request::UNCACHEABLE, dataMasterId());
- mmio_req.setContext(tc->contextId());
+ RequestPtr mmio_req = new Request(paddr, size, Request::UNCACHEABLE,
+ dataMasterId());
+ mmio_req->setContext(tc->contextId());
// 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));
+ 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);
+ PacketPtr pkt = new Packet(mmio_req, cmd);
+ pkt->dataStatic(data);
- if (mmio_req.isMmappedIpr()) {
+ if (mmio_req->isMmappedIpr()) {
// We currently assume that there is no need to migrate to a
// different event queue when doing IPRs. Currently, IPRs are
// only used for m5ops, so it should be a valid assumption.
const Cycles ipr_delay(write ?
- TheISA::handleIprWrite(tc, &pkt) :
- TheISA::handleIprRead(tc, &pkt));
+ TheISA::handleIprWrite(tc, pkt) :
+ TheISA::handleIprRead(tc, pkt));
threadContextDirty = true;
+ delete pkt->req;
+ delete pkt;
return clockPeriod() * ipr_delay;
} else {
// Temporarily lock and migrate to the event queue of the
@@ -1057,7 +1146,7 @@ BaseKvmCPU::doMMIOAccess(Addr paddr, void *data, int size, bool write)
// access if running in multi-core mode.
EventQueue::ScopedMigration migrate(vm.eventQueue());
- return dataPort.sendAtomic(&pkt);
+ return dataPort.submitIO(pkt);
}
}
diff --git a/src/cpu/kvm/base.hh b/src/cpu/kvm/base.hh
index 7ff0cab5c..ef500974f 100644
--- a/src/cpu/kvm/base.hh
+++ b/src/cpu/kvm/base.hh
@@ -44,6 +44,7 @@
#include <csignal>
#include <memory>
+#include <queue>
#include "base/statistics.hh"
#include "cpu/kvm/perfevent.hh"
@@ -110,6 +111,12 @@ class BaseKvmCPU : public BaseCPU
Counter totalInsts() const override;
Counter totalOps() const override;
+ /**
+ * Callback from KvmCPUPort to transition the CPU out of RunningMMIOPending
+ * when all timing requests have completed.
+ */
+ void finishMMIOPending();
+
/** Dump the internal state to the terminal. */
virtual void dump() const;
@@ -152,6 +159,7 @@ class BaseKvmCPU : public BaseCPU
* Running;
* RunningService;
* RunningServiceCompletion;
+ * RunningMMIOPending;
*
* Idle -> Idle;
* Idle -> Running [label="activateContext()", URL="\ref activateContext"];
@@ -161,6 +169,8 @@ class BaseKvmCPU : public BaseCPU
* Running -> Idle [label="drain()", URL="\ref drain"];
* Idle -> Running [label="drainResume()", URL="\ref drainResume"];
* RunningService -> RunningServiceCompletion [label="handleKvmExit()", URL="\ref handleKvmExit"];
+ * RunningService -> RunningMMIOPending [label="handleKvmExit()", URL="\ref handleKvmExit"];
+ * RunningMMIOPending -> RunningServiceCompletion [label="finishMMIOPending()", URL="\ref finishMMIOPending"];
* RunningServiceCompletion -> Running [label="tick()", URL="\ref tick"];
* RunningServiceCompletion -> RunningService [label="tick()", URL="\ref tick"];
* }
@@ -190,12 +200,21 @@ class BaseKvmCPU : public BaseCPU
* after running service is determined in handleKvmExit() and
* depends on what kind of service the guest requested:
* <ul>
- * <li>IO/MMIO: RunningServiceCompletion
+ * <li>IO/MMIO (Atomic): RunningServiceCompletion
+ * <li>IO/MMIO (Timing): RunningMMIOPending
* <li>Halt: Idle
* <li>Others: Running
* </ul>
*/
RunningService,
+ /** Timing MMIO request in flight or stalled.
+ *
+ * The VM has requested IO/MMIO and we are in timing mode. A timing
+ * request is either stalled (and will be retried with recvReqRetry())
+ * or it is in flight. After the timing request is complete, the CPU
+ * will transition to the RunningServiceCompletion state.
+ */
+ RunningMMIOPending,
/** Service completion in progress.
*
* The VM has requested service that requires KVM to be
@@ -543,28 +562,39 @@ class BaseKvmCPU : public BaseCPU
/**
- * KVM memory port. Uses the default MasterPort behavior, but
- * panics on timing accesses.
+ * KVM memory port. Uses default MasterPort behavior and provides an
+ * interface for KVM to transparently submit atomic or timing requests.
*/
class KVMCpuPort : public MasterPort
{
public:
KVMCpuPort(const std::string &_name, BaseKvmCPU *_cpu)
- : MasterPort(_name, _cpu)
+ : MasterPort(_name, _cpu), cpu(_cpu), activeMMIOReqs(0)
{ }
+ /**
+ * Interface to send Atomic or Timing IO request. Assumes that the pkt
+ * and corresponding req have been dynamically allocated and deletes
+ * them both if the system is in atomic mode.
+ */
+ Tick submitIO(PacketPtr pkt);
+
+ /** Returns next valid state after one or more IO accesses */
+ Status nextIOState() const;
protected:
- bool recvTimingResp(PacketPtr pkt)
- {
- panic("The KVM CPU doesn't expect recvTimingResp!\n");
- return true;
- }
+ /** KVM cpu pointer for finishMMIOPending() callback */
+ BaseKvmCPU *cpu;
- void recvReqRetry()
- {
- panic("The KVM CPU doesn't expect recvReqRetry!\n");
- }
+ /** Pending MMIO packets */
+ std::queue<PacketPtr> pendingMMIOPkts;
+
+ /** Number of MMIO requests in flight */
+ unsigned int activeMMIOReqs;
+
+ bool recvTimingResp(PacketPtr pkt) override;
+
+ void recvReqRetry() override;
};
diff --git a/src/cpu/kvm/x86_cpu.cc b/src/cpu/kvm/x86_cpu.cc
index 9e9115ef5..f8f66af2f 100644
--- a/src/cpu/kvm/x86_cpu.cc
+++ b/src/cpu/kvm/x86_cpu.cc
@@ -1344,20 +1344,20 @@ X86KvmCPU::handleKvmExitIO()
pAddr = X86ISA::x86IOAddress(port);
}
- Request io_req(pAddr, kvm_run.io.size, Request::UNCACHEABLE,
- dataMasterId());
- io_req.setContext(tc->contextId());
-
const MemCmd cmd(isWrite ? MemCmd::WriteReq : MemCmd::ReadReq);
// Temporarily lock and migrate to the event queue of the
// VM. This queue is assumed to "own" all devices we need to
// access if running in multi-core mode.
EventQueue::ScopedMigration migrate(vm.eventQueue());
for (int i = 0; i < count; ++i) {
- Packet pkt(&io_req, cmd);
+ RequestPtr io_req = new Request(pAddr, kvm_run.io.size,
+ Request::UNCACHEABLE, dataMasterId());
+ io_req->setContext(tc->contextId());
+
+ PacketPtr pkt = new Packet(io_req, cmd);
- pkt.dataStatic(guestData);
- delay += dataPort.sendAtomic(&pkt);
+ pkt->dataStatic(guestData);
+ delay += dataPort.submitIO(pkt);
guestData += kvm_run.io.size;
}