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gem5 / public / gem5 / e71e2d6a35233250ad05b358c27cad5a05609d55 / . / src / dev / pci / copy_engine.cc
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/*
* 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.
*
* Copyright (c) 2008 The Regents of The University of Michigan
* All rights reserved.
*
* 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: Ali Saidi
*/
/* @file
* Device model for Intel's I/O AT DMA copy engine.
*/
#include "dev/pci/copy_engine.hh"
#include <algorithm>
#include "base/cp_annotate.hh"
#include "base/trace.hh"
#include "debug/DMACopyEngine.hh"
#include "debug/Drain.hh"
#include "mem/packet.hh"
#include "mem/packet_access.hh"
#include "params/CopyEngine.hh"
#include "sim/stats.hh"
#include "sim/system.hh"
using namespace CopyEngineReg;
CopyEngine::CopyEngine(const Params *p)
: PciDevice(p)
{
// All Reg regs are initialized to 0 by default
regs.chanCount = p->ChanCnt;
regs.xferCap = findMsbSet(p->XferCap);
regs.attnStatus = 0;
if (regs.chanCount > 64)
fatal("CopyEngine interface doesn't support more than 64 DMA engines\n");
for (int x = 0; x < regs.chanCount; x++) {
CopyEngineChannel *ch = new CopyEngineChannel(this, x);
chan.push_back(ch);
}
}
CopyEngine::CopyEngineChannel::CopyEngineChannel(CopyEngine *_ce, int cid)
: cePort(_ce, _ce->sys),
ce(_ce), channelId(cid), busy(false), underReset(false),
refreshNext(false), latBeforeBegin(ce->params()->latBeforeBegin),
latAfterCompletion(ce->params()->latAfterCompletion),
completionDataReg(0), nextState(Idle),
fetchCompleteEvent([this]{ fetchDescComplete(); }, name()),
addrCompleteEvent([this]{ fetchAddrComplete(); }, name()),
readCompleteEvent([this]{ readCopyBytesComplete(); }, name()),
writeCompleteEvent([this]{ writeCopyBytesComplete(); }, name()),
statusCompleteEvent([this]{ writeStatusComplete(); }, name())
{
cr.status.dma_transfer_status(3);
cr.descChainAddr = 0;
cr.completionAddr = 0;
curDmaDesc = new DmaDesc;
memset(curDmaDesc, 0, sizeof(DmaDesc));
copyBuffer = new uint8_t[ce->params()->XferCap];
}
CopyEngine::~CopyEngine()
{
for (int x = 0; x < chan.size(); x++) {
delete chan[x];
}
}
CopyEngine::CopyEngineChannel::~CopyEngineChannel()
{
delete curDmaDesc;
delete [] copyBuffer;
}
Port &
CopyEngine::getPort(const std::string &if_name, PortID idx)
{
if (if_name != "dma") {
// pass it along to our super class
return PciDevice::getPort(if_name, idx);
} else {
if (idx >= static_cast<int>(chan.size())) {
panic("CopyEngine::getPort: unknown index %d\n", idx);
}
return chan[idx]->getPort();
}
}
Port &
CopyEngine::CopyEngineChannel::getPort()
{
return cePort;
}
void
CopyEngine::CopyEngineChannel::recvCommand()
{
if (cr.command.start_dma()) {
assert(!busy);
cr.status.dma_transfer_status(0);
nextState = DescriptorFetch;
fetchAddress = cr.descChainAddr;
if (ce->drainState() == DrainState::Running)
fetchDescriptor(cr.descChainAddr);
} else if (cr.command.append_dma()) {
if (!busy) {
nextState = AddressFetch;
if (ce->drainState() == DrainState::Running)
fetchNextAddr(lastDescriptorAddr);
} else
refreshNext = true;
} else if (cr.command.reset_dma()) {
if (busy)
underReset = true;
else {
cr.status.dma_transfer_status(3);
nextState = Idle;
}
} else if (cr.command.resume_dma() || cr.command.abort_dma() ||
cr.command.suspend_dma())
panic("Resume, Abort, and Suspend are not supported\n");
cr.command(0);
}
Tick
CopyEngine::read(PacketPtr pkt)
{
int bar;
Addr daddr;
if (!getBAR(pkt->getAddr(), bar, daddr))
panic("Invalid PCI memory access to unmapped memory.\n");
// Only Memory register BAR is allowed
assert(bar == 0);
int size = pkt->getSize();
if (size != sizeof(uint64_t) && size != sizeof(uint32_t) &&
size != sizeof(uint16_t) && size != sizeof(uint8_t)) {
panic("Unknown size for MMIO access: %d\n", pkt->getSize());
}
DPRINTF(DMACopyEngine, "Read device register %#X size: %d\n", daddr, size);
///
/// Handle read of register here
///
if (daddr < 0x80) {
switch (daddr) {
case GEN_CHANCOUNT:
assert(size == sizeof(regs.chanCount));
pkt->setLE<uint8_t>(regs.chanCount);
break;
case GEN_XFERCAP:
assert(size == sizeof(regs.xferCap));
pkt->setLE<uint8_t>(regs.xferCap);
break;
case GEN_INTRCTRL:
assert(size == sizeof(uint8_t));
pkt->setLE<uint8_t>(regs.intrctrl());
regs.intrctrl.master_int_enable(0);
break;
case GEN_ATTNSTATUS:
assert(size == sizeof(regs.attnStatus));
pkt->setLE<uint32_t>(regs.attnStatus);
regs.attnStatus = 0;
break;
default:
panic("Read request to unknown register number: %#x\n", daddr);
}
pkt->makeAtomicResponse();
return pioDelay;
}
// Find which channel we're accessing
int chanid = 0;
daddr -= 0x80;
while (daddr >= 0x80) {
chanid++;
daddr -= 0x80;
}
if (chanid >= regs.chanCount)
panic("Access to channel %d (device only configured for %d channels)",
chanid, regs.chanCount);
///
/// Channel registers are handled here
///
chan[chanid]->channelRead(pkt, daddr, size);
pkt->makeAtomicResponse();
return pioDelay;
}
void
CopyEngine::CopyEngineChannel::channelRead(Packet *pkt, Addr daddr, int size)
{
switch (daddr) {
case CHAN_CONTROL:
assert(size == sizeof(uint16_t));
pkt->setLE<uint16_t>(cr.ctrl());
cr.ctrl.in_use(1);
break;
case CHAN_STATUS:
assert(size == sizeof(uint64_t));
pkt->setLE<uint64_t>(cr.status() | (busy ? 0 : 1));
break;
case CHAN_CHAINADDR:
assert(size == sizeof(uint64_t) || size == sizeof(uint32_t));
if (size == sizeof(uint64_t))
pkt->setLE<uint64_t>(cr.descChainAddr);
else
pkt->setLE<uint32_t>(bits(cr.descChainAddr,0,31));
break;
case CHAN_CHAINADDR_HIGH:
assert(size == sizeof(uint32_t));
pkt->setLE<uint32_t>(bits(cr.descChainAddr,32,63));
break;
case CHAN_COMMAND:
assert(size == sizeof(uint8_t));
pkt->setLE<uint32_t>(cr.command());
break;
case CHAN_CMPLNADDR:
assert(size == sizeof(uint64_t) || size == sizeof(uint32_t));
if (size == sizeof(uint64_t))
pkt->setLE<uint64_t>(cr.completionAddr);
else
pkt->setLE<uint32_t>(bits(cr.completionAddr,0,31));
break;
case CHAN_CMPLNADDR_HIGH:
assert(size == sizeof(uint32_t));
pkt->setLE<uint32_t>(bits(cr.completionAddr,32,63));
break;
case CHAN_ERROR:
assert(size == sizeof(uint32_t));
pkt->setLE<uint32_t>(cr.error());
break;
default:
panic("Read request to unknown channel register number: (%d)%#x\n",
channelId, daddr);
}
}
Tick
CopyEngine::write(PacketPtr pkt)
{
int bar;
Addr daddr;
if (!getBAR(pkt->getAddr(), bar, daddr))
panic("Invalid PCI memory access to unmapped memory.\n");
// Only Memory register BAR is allowed
assert(bar == 0);
int size = pkt->getSize();
///
/// Handle write of register here
///
if (size == sizeof(uint64_t)) {
uint64_t val M5_VAR_USED = pkt->getLE<uint64_t>();
DPRINTF(DMACopyEngine, "Wrote device register %#X value %#X\n",
daddr, val);
} else if (size == sizeof(uint32_t)) {
uint32_t val M5_VAR_USED = pkt->getLE<uint32_t>();
DPRINTF(DMACopyEngine, "Wrote device register %#X value %#X\n",
daddr, val);
} else if (size == sizeof(uint16_t)) {
uint16_t val M5_VAR_USED = pkt->getLE<uint16_t>();
DPRINTF(DMACopyEngine, "Wrote device register %#X value %#X\n",
daddr, val);
} else if (size == sizeof(uint8_t)) {
uint8_t val M5_VAR_USED = pkt->getLE<uint8_t>();
DPRINTF(DMACopyEngine, "Wrote device register %#X value %#X\n",
daddr, val);
} else {
panic("Unknown size for MMIO access: %d\n", size);
}
if (daddr < 0x80) {
switch (daddr) {
case GEN_CHANCOUNT:
case GEN_XFERCAP:
case GEN_ATTNSTATUS:
DPRINTF(DMACopyEngine, "Warning, ignorning write to register %x\n",
daddr);
break;
case GEN_INTRCTRL:
regs.intrctrl.master_int_enable(bits(pkt->getLE<uint8_t>(), 0, 1));
break;
default:
panic("Read request to unknown register number: %#x\n", daddr);
}
pkt->makeAtomicResponse();
return pioDelay;
}
// Find which channel we're accessing
int chanid = 0;
daddr -= 0x80;
while (daddr >= 0x80) {
chanid++;
daddr -= 0x80;
}
if (chanid >= regs.chanCount)
panic("Access to channel %d (device only configured for %d channels)",
chanid, regs.chanCount);
///
/// Channel registers are handled here
///
chan[chanid]->channelWrite(pkt, daddr, size);
pkt->makeAtomicResponse();
return pioDelay;
}
void
CopyEngine::CopyEngineChannel::channelWrite(Packet *pkt, Addr daddr, int size)
{
switch (daddr) {
case CHAN_CONTROL:
assert(size == sizeof(uint16_t));
int old_int_disable;
old_int_disable = cr.ctrl.interrupt_disable();
cr.ctrl(pkt->getLE<uint16_t>());
if (cr.ctrl.interrupt_disable())
cr.ctrl.interrupt_disable(0);
else
cr.ctrl.interrupt_disable(old_int_disable);
break;
case CHAN_STATUS:
assert(size == sizeof(uint64_t));
DPRINTF(DMACopyEngine, "Warning, ignorning write to register %x\n",
daddr);
break;
case CHAN_CHAINADDR:
assert(size == sizeof(uint64_t) || size == sizeof(uint32_t));
if (size == sizeof(uint64_t))
cr.descChainAddr = pkt->getLE<uint64_t>();
else
cr.descChainAddr = (uint64_t)pkt->getLE<uint32_t>() |
(cr.descChainAddr & ~mask(32));
DPRINTF(DMACopyEngine, "Chain Address %x\n", cr.descChainAddr);
break;
case CHAN_CHAINADDR_HIGH:
assert(size == sizeof(uint32_t));
cr.descChainAddr = ((uint64_t)pkt->getLE<uint32_t>() << 32) |
(cr.descChainAddr & mask(32));
DPRINTF(DMACopyEngine, "Chain Address %x\n", cr.descChainAddr);
break;
case CHAN_COMMAND:
assert(size == sizeof(uint8_t));
cr.command(pkt->getLE<uint8_t>());
recvCommand();
break;
case CHAN_CMPLNADDR:
assert(size == sizeof(uint64_t) || size == sizeof(uint32_t));
if (size == sizeof(uint64_t))
cr.completionAddr = pkt->getLE<uint64_t>();
else
cr.completionAddr = pkt->getLE<uint32_t>() |
(cr.completionAddr & ~mask(32));
break;
case CHAN_CMPLNADDR_HIGH:
assert(size == sizeof(uint32_t));
cr.completionAddr = ((uint64_t)pkt->getLE<uint32_t>() <<32) |
(cr.completionAddr & mask(32));
break;
case CHAN_ERROR:
assert(size == sizeof(uint32_t));
cr.error(~pkt->getLE<uint32_t>() & cr.error());
break;
default:
panic("Read request to unknown channel register number: (%d)%#x\n",
channelId, daddr);
}
}
void
CopyEngine::regStats()
{
PciDevice::regStats();
using namespace Stats;
bytesCopied
.init(regs.chanCount)
.name(name() + ".bytes_copied")
.desc("Number of bytes copied by each engine")
.flags(total)
;
copiesProcessed
.init(regs.chanCount)
.name(name() + ".copies_processed")
.desc("Number of copies processed by each engine")
.flags(total)
;
}
void
CopyEngine::CopyEngineChannel::fetchDescriptor(Addr address)
{
anDq();
anBegin("FetchDescriptor");
DPRINTF(DMACopyEngine, "Reading descriptor from at memory location %#x(%#x)\n",
address, ce->pciToDma(address));
assert(address);
busy = true;
DPRINTF(DMACopyEngine, "dmaAction: %#x, %d bytes, to addr %#x\n",
ce->pciToDma(address), sizeof(DmaDesc), curDmaDesc);
cePort.dmaAction(MemCmd::ReadReq, ce->pciToDma(address),
sizeof(DmaDesc), &fetchCompleteEvent,
(uint8_t*)curDmaDesc, latBeforeBegin);
lastDescriptorAddr = address;
}
void
CopyEngine::CopyEngineChannel::fetchDescComplete()
{
DPRINTF(DMACopyEngine, "Read of descriptor complete\n");
if ((curDmaDesc->command & DESC_CTRL_NULL)) {
DPRINTF(DMACopyEngine, "Got NULL descriptor, skipping\n");
assert(!(curDmaDesc->command & DESC_CTRL_CP_STS));
if (curDmaDesc->command & DESC_CTRL_CP_STS) {
panic("Shouldn't be able to get here\n");
nextState = CompletionWrite;
if (inDrain()) return;
writeCompletionStatus();
} else {
anBegin("Idle");
anWait();
busy = false;
nextState = Idle;
inDrain();
}
return;
}
if (curDmaDesc->command & ~DESC_CTRL_CP_STS)
panic("Descriptor has flag other that completion status set\n");
nextState = DMARead;
if (inDrain()) return;
readCopyBytes();
}
void
CopyEngine::CopyEngineChannel::readCopyBytes()
{
anBegin("ReadCopyBytes");
DPRINTF(DMACopyEngine, "Reading %d bytes from buffer to memory location %#x(%#x)\n",
curDmaDesc->len, curDmaDesc->dest,
ce->pciToDma(curDmaDesc->src));
cePort.dmaAction(MemCmd::ReadReq, ce->pciToDma(curDmaDesc->src),
curDmaDesc->len, &readCompleteEvent, copyBuffer, 0);
}
void
CopyEngine::CopyEngineChannel::readCopyBytesComplete()
{
DPRINTF(DMACopyEngine, "Read of bytes to copy complete\n");
nextState = DMAWrite;
if (inDrain()) return;
writeCopyBytes();
}
void
CopyEngine::CopyEngineChannel::writeCopyBytes()
{
anBegin("WriteCopyBytes");
DPRINTF(DMACopyEngine, "Writing %d bytes from buffer to memory location %#x(%#x)\n",
curDmaDesc->len, curDmaDesc->dest,
ce->pciToDma(curDmaDesc->dest));
cePort.dmaAction(MemCmd::WriteReq, ce->pciToDma(curDmaDesc->dest),
curDmaDesc->len, &writeCompleteEvent, copyBuffer, 0);
ce->bytesCopied[channelId] += curDmaDesc->len;
ce->copiesProcessed[channelId]++;
}
void
CopyEngine::CopyEngineChannel::writeCopyBytesComplete()
{
DPRINTF(DMACopyEngine, "Write of bytes to copy complete user1: %#x\n",
curDmaDesc->user1);
cr.status.compl_desc_addr(lastDescriptorAddr >> 6);
completionDataReg = cr.status() | 1;
anQ("DMAUsedDescQ", channelId, 1);
anQ("AppRecvQ", curDmaDesc->user1, curDmaDesc->len);
if (curDmaDesc->command & DESC_CTRL_CP_STS) {
nextState = CompletionWrite;
if (inDrain()) return;
writeCompletionStatus();
return;
}
continueProcessing();
}
void
CopyEngine::CopyEngineChannel::continueProcessing()
{
busy = false;
if (underReset) {
anBegin("Reset");
anWait();
underReset = false;
refreshNext = false;
busy = false;
nextState = Idle;
return;
}
if (curDmaDesc->next) {
nextState = DescriptorFetch;
fetchAddress = curDmaDesc->next;
if (inDrain()) return;
fetchDescriptor(curDmaDesc->next);
} else if (refreshNext) {
nextState = AddressFetch;
refreshNext = false;
if (inDrain()) return;
fetchNextAddr(lastDescriptorAddr);
} else {
inDrain();
nextState = Idle;
anWait();
anBegin("Idle");
}
}
void
CopyEngine::CopyEngineChannel::writeCompletionStatus()
{
anBegin("WriteCompletionStatus");
DPRINTF(DMACopyEngine, "Writing completion status %#x to address %#x(%#x)\n",
completionDataReg, cr.completionAddr,
ce->pciToDma(cr.completionAddr));
cePort.dmaAction(MemCmd::WriteReq,
ce->pciToDma(cr.completionAddr),
sizeof(completionDataReg), &statusCompleteEvent,
(uint8_t*)&completionDataReg, latAfterCompletion);
}
void
CopyEngine::CopyEngineChannel::writeStatusComplete()
{
DPRINTF(DMACopyEngine, "Writing completion status complete\n");
continueProcessing();
}
void
CopyEngine::CopyEngineChannel::fetchNextAddr(Addr address)
{
anBegin("FetchNextAddr");
DPRINTF(DMACopyEngine, "Fetching next address...\n");
busy = true;
cePort.dmaAction(MemCmd::ReadReq,
ce->pciToDma(address + offsetof(DmaDesc, next)),
sizeof(Addr), &addrCompleteEvent,
(uint8_t*)curDmaDesc + offsetof(DmaDesc, next), 0);
}
void
CopyEngine::CopyEngineChannel::fetchAddrComplete()
{
DPRINTF(DMACopyEngine, "Fetching next address complete: %#x\n",
curDmaDesc->next);
if (!curDmaDesc->next) {
DPRINTF(DMACopyEngine, "Got NULL descriptor, nothing more to do\n");
busy = false;
nextState = Idle;
anWait();
anBegin("Idle");
inDrain();
return;
}
nextState = DescriptorFetch;
fetchAddress = curDmaDesc->next;
if (inDrain()) return;
fetchDescriptor(curDmaDesc->next);
}
bool
CopyEngine::CopyEngineChannel::inDrain()
{
if (drainState() == DrainState::Draining) {
DPRINTF(Drain, "CopyEngine done draining, processing drain event\n");
signalDrainDone();
}
return ce->drainState() != DrainState::Running;
}
DrainState
CopyEngine::CopyEngineChannel::drain()
{
if (nextState == Idle || ce->drainState() != DrainState::Running) {
return DrainState::Drained;
} else {
DPRINTF(Drain, "CopyEngineChannel not drained\n");
return DrainState::Draining;
}
}
void
CopyEngine::serialize(CheckpointOut &cp) const
{
PciDevice::serialize(cp);
regs.serialize(cp);
for (int x =0; x < chan.size(); x++)
chan[x]->serializeSection(cp, csprintf("channel%d", x));
}
void
CopyEngine::unserialize(CheckpointIn &cp)
{
PciDevice::unserialize(cp);
regs.unserialize(cp);
for (int x = 0; x < chan.size(); x++)
chan[x]->unserializeSection(cp, csprintf("channel%d", x));
}
void
CopyEngine::CopyEngineChannel::serialize(CheckpointOut &cp) const
{
SERIALIZE_SCALAR(channelId);
SERIALIZE_SCALAR(busy);
SERIALIZE_SCALAR(underReset);
SERIALIZE_SCALAR(refreshNext);
SERIALIZE_SCALAR(lastDescriptorAddr);
SERIALIZE_SCALAR(completionDataReg);
SERIALIZE_SCALAR(fetchAddress);
int nextState = this->nextState;
SERIALIZE_SCALAR(nextState);
arrayParamOut(cp, "curDmaDesc", (uint8_t*)curDmaDesc, sizeof(DmaDesc));
SERIALIZE_ARRAY(copyBuffer, ce->params()->XferCap);
cr.serialize(cp);
}
void
CopyEngine::CopyEngineChannel::unserialize(CheckpointIn &cp)
{
UNSERIALIZE_SCALAR(channelId);
UNSERIALIZE_SCALAR(busy);
UNSERIALIZE_SCALAR(underReset);
UNSERIALIZE_SCALAR(refreshNext);
UNSERIALIZE_SCALAR(lastDescriptorAddr);
UNSERIALIZE_SCALAR(completionDataReg);
UNSERIALIZE_SCALAR(fetchAddress);
int nextState;
UNSERIALIZE_SCALAR(nextState);
this->nextState = (ChannelState)nextState;
arrayParamIn(cp, "curDmaDesc", (uint8_t*)curDmaDesc, sizeof(DmaDesc));
UNSERIALIZE_ARRAY(copyBuffer, ce->params()->XferCap);
cr.unserialize(cp);
}
void
CopyEngine::CopyEngineChannel::restartStateMachine()
{
switch(nextState) {
case AddressFetch:
fetchNextAddr(lastDescriptorAddr);
break;
case DescriptorFetch:
fetchDescriptor(fetchAddress);
break;
case DMARead:
readCopyBytes();
break;
case DMAWrite:
writeCopyBytes();
break;
case CompletionWrite:
writeCompletionStatus();
break;
case Idle:
break;
default:
panic("Unknown state for CopyEngineChannel\n");
}
}
void
CopyEngine::CopyEngineChannel::drainResume()
{
DPRINTF(DMACopyEngine, "Restarting state machine at state %d\n", nextState);
restartStateMachine();
}
CopyEngine *
CopyEngineParams::create()
{
return new CopyEngine(this);
}