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/*
* Copyright (c) 2006 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 8254x line of gigabit ethernet controllers.
*/
#ifndef __DEV_I8254XGBE_HH__
#define __DEV_I8254XGBE_HH__
#include <deque>
#include <string>
#include "base/inet.hh"
#include "base/statistics.hh"
#include "dev/etherint.hh"
#include "dev/etherpkt.hh"
#include "dev/i8254xGBe_defs.hh"
#include "dev/pcidev.hh"
#include "dev/pktfifo.hh"
#include "sim/eventq.hh"
class IGbEInt;
class IGbE : public PciDev
{
private:
IGbEInt *etherInt;
// device registers
iGbReg::Regs regs;
// eeprom data, status and control bits
int eeOpBits, eeAddrBits, eeDataBits;
uint8_t eeOpcode, eeAddr;
uint16_t flash[iGbReg::EEPROM_SIZE];
// The drain event if we have one
Event *drainEvent;
// cached parameters from params struct
bool useFlowControl;
// packet fifos
PacketFifo rxFifo;
PacketFifo txFifo;
// Packet that we are currently putting into the txFifo
EthPacketPtr txPacket;
// Should to Rx/Tx State machine tick?
bool rxTick;
bool txTick;
bool txFifoTick;
bool rxDmaPacket;
// Event and function to deal with RDTR timer expiring
void rdtrProcess() {
rxDescCache.writeback(0);
DPRINTF(EthernetIntr, "Posting RXT interrupt because RDTR timer expired\n");
postInterrupt(iGbReg::IT_RXT, true);
}
//friend class EventWrapper<IGbE, &IGbE::rdtrProcess>;
EventWrapper<IGbE, &IGbE::rdtrProcess> rdtrEvent;
// Event and function to deal with RADV timer expiring
void radvProcess() {
rxDescCache.writeback(0);
DPRINTF(EthernetIntr, "Posting RXT interrupt because RADV timer expired\n");
postInterrupt(iGbReg::IT_RXT, true);
}
//friend class EventWrapper<IGbE, &IGbE::radvProcess>;
EventWrapper<IGbE, &IGbE::radvProcess> radvEvent;
// Event and function to deal with TADV timer expiring
void tadvProcess() {
txDescCache.writeback(0);
DPRINTF(EthernetIntr, "Posting TXDW interrupt because TADV timer expired\n");
postInterrupt(iGbReg::IT_TXDW, true);
}
//friend class EventWrapper<IGbE, &IGbE::tadvProcess>;
EventWrapper<IGbE, &IGbE::tadvProcess> tadvEvent;
// Event and function to deal with TIDV timer expiring
void tidvProcess() {
txDescCache.writeback(0);
DPRINTF(EthernetIntr, "Posting TXDW interrupt because TIDV timer expired\n");
postInterrupt(iGbReg::IT_TXDW, true);
}
//friend class EventWrapper<IGbE, &IGbE::tidvProcess>;
EventWrapper<IGbE, &IGbE::tidvProcess> tidvEvent;
// Main event to tick the device
void tick();
//friend class EventWrapper<IGbE, &IGbE::tick>;
EventWrapper<IGbE, &IGbE::tick> tickEvent;
void rxStateMachine();
void txStateMachine();
void txWire();
/** Write an interrupt into the interrupt pending register and check mask
* and interrupt limit timer before sending interrupt to CPU
* @param t the type of interrupt we are posting
* @param now should we ignore the interrupt limiting timer
*/
void postInterrupt(iGbReg::IntTypes t, bool now = false);
/** Check and see if changes to the mask register have caused an interrupt
* to need to be sent or perhaps removed an interrupt cause.
*/
void chkInterrupt();
/** Send an interrupt to the cpu
*/
void cpuPostInt();
// Event to moderate interrupts
EventWrapper<IGbE, &IGbE::cpuPostInt> interEvent;
/** Clear the interupt line to the cpu
*/
void cpuClearInt();
Tick intClock() { return Clock::Int::ns * 1024; }
/** This function is used to restart the clock so it can handle things like
* draining and resume in one place. */
void restartClock();
/** Check if all the draining things that need to occur have occured and
* handle the drain event if so.
*/
void checkDrain();
template<class T>
class DescCache
{
protected:
virtual Addr descBase() const = 0;
virtual long descHead() const = 0;
virtual long descTail() const = 0;
virtual long descLen() const = 0;
virtual void updateHead(long h) = 0;
virtual void enableSm() = 0;
virtual void intAfterWb() const {}
std::deque<T*> usedCache;
std::deque<T*> unusedCache;
T *fetchBuf;
T *wbBuf;
// Pointer to the device we cache for
IGbE *igbe;
// Name of this descriptor cache
std::string _name;
// How far we've cached
int cachePnt;
// The size of the descriptor cache
int size;
// How many descriptors we are currently fetching
int curFetching;
// How many descriptors we are currently writing back
int wbOut;
// if the we wrote back to the end of the descriptor ring and are going
// to have to wrap and write more
bool moreToWb;
// What the alignment is of the next descriptor writeback
Addr wbAlignment;
/** The packet that is currently being dmad to memory if any
*/
EthPacketPtr pktPtr;
public:
DescCache(IGbE *i, const std::string n, int s)
: igbe(i), _name(n), cachePnt(0), size(s), curFetching(0), wbOut(0),
pktPtr(NULL), fetchEvent(this), wbEvent(this)
{
fetchBuf = new T[size];
wbBuf = new T[size];
}
virtual ~DescCache()
{
reset();
}
std::string name() { return _name; }
/** If the address/len/head change when we've got descriptors that are
* dirty that is very bad. This function checks that we don't and if we
* do panics.
*/
void areaChanged()
{
if (usedCache.size() > 0 || curFetching || wbOut)
panic("Descriptor Address, Length or Head changed. Bad\n");
reset();
}
void writeback(Addr aMask)
{
int curHead = descHead();
int max_to_wb = usedCache.size();
DPRINTF(EthernetDesc, "Writing back descriptors head: %d tail: "
"%d len: %d cachePnt: %d max_to_wb: %d descleft: %d\n",
curHead, descTail(), descLen(), cachePnt, max_to_wb,
descLeft());
// Check if this writeback is less restrictive that the previous
// and if so setup another one immediately following it
if (wbOut && (aMask < wbAlignment)) {
moreToWb = true;
wbAlignment = aMask;
DPRINTF(EthernetDesc, "Writing back already in process, returning\n");
return;
}
moreToWb = false;
wbAlignment = aMask;
if (max_to_wb + curHead >= descLen()) {
max_to_wb = descLen() - curHead;
moreToWb = true;
// this is by definition aligned correctly
} else if (aMask != 0) {
// align the wb point to the mask
max_to_wb = max_to_wb & ~aMask;
}
DPRINTF(EthernetDesc, "Writing back %d descriptors\n", max_to_wb);
if (max_to_wb <= 0 || wbOut)
return;
wbOut = max_to_wb;
for (int x = 0; x < wbOut; x++)
memcpy(&wbBuf[x], usedCache[x], sizeof(T));
for (int x = 0; x < wbOut; x++) {
assert(usedCache.size());
delete usedCache[0];
usedCache.pop_front();
};
assert(wbOut);
igbe->dmaWrite(igbe->platform->pciToDma(descBase() + curHead * sizeof(T)),
wbOut * sizeof(T), &wbEvent, (uint8_t*)wbBuf);
}
/** Fetch a chunk of descriptors into the descriptor cache.
* Calls fetchComplete when the memory system returns the data
*/
void fetchDescriptors()
{
size_t max_to_fetch;
if (descTail() >= cachePnt)
max_to_fetch = descTail() - cachePnt;
else
max_to_fetch = descLen() - cachePnt;
max_to_fetch = std::min(max_to_fetch, (size - usedCache.size() -
unusedCache.size()));
DPRINTF(EthernetDesc, "Fetching descriptors head: %d tail: "
"%d len: %d cachePnt: %d max_to_fetch: %d descleft: %d\n",
descHead(), descTail(), descLen(), cachePnt,
max_to_fetch, descLeft());
// Nothing to do
if (max_to_fetch == 0 || curFetching)
return;
// So we don't have two descriptor fetches going on at once
curFetching = max_to_fetch;
DPRINTF(EthernetDesc, "Fetching descriptors at %#x (%#x), size: %#x\n",
descBase() + cachePnt * sizeof(T),
igbe->platform->pciToDma(descBase() + cachePnt * sizeof(T)),
curFetching * sizeof(T));
assert(curFetching);
igbe->dmaRead(igbe->platform->pciToDma(descBase() + cachePnt * sizeof(T)),
curFetching * sizeof(T), &fetchEvent, (uint8_t*)fetchBuf);
}
/** Called by event when dma to read descriptors is completed
*/
void fetchComplete()
{
T *newDesc;
for (int x = 0; x < curFetching; x++) {
newDesc = new T;
memcpy(newDesc, &fetchBuf[x], sizeof(T));
unusedCache.push_back(newDesc);
}
#ifndef NDEBUG
int oldCp = cachePnt;
#endif
cachePnt += curFetching;
assert(cachePnt <= descLen());
if (cachePnt == descLen())
cachePnt = 0;
curFetching = 0;
DPRINTF(EthernetDesc, "Fetching complete cachePnt %d -> %d\n",
oldCp, cachePnt);
enableSm();
igbe->checkDrain();
}
EventWrapper<DescCache, &DescCache::fetchComplete> fetchEvent;
/** Called by event when dma to writeback descriptors is completed
*/
void wbComplete()
{
long curHead = descHead();
#ifndef NDEBUG
long oldHead = curHead;
#endif
curHead += wbOut;
wbOut = 0;
if (curHead >= descLen())
curHead -= descLen();
// Update the head
updateHead(curHead);
DPRINTF(EthernetDesc, "Writeback complete curHead %d -> %d\n",
oldHead, curHead);
// If we still have more to wb, call wb now
if (moreToWb) {
DPRINTF(EthernetDesc, "Writeback has more todo\n");
writeback(wbAlignment);
}
intAfterWb();
igbe->checkDrain();
}
EventWrapper<DescCache, &DescCache::wbComplete> wbEvent;
/* Return the number of descriptors left in the ring, so the device has
* a way to figure out if it needs to interrupt.
*/
int descLeft() const
{
int left = unusedCache.size();
if (cachePnt - descTail() >= 0)
left += (cachePnt - descTail());
else
left += (descTail() - cachePnt);
return left;
}
/* Return the number of descriptors used and not written back.
*/
int descUsed() const { return usedCache.size(); }
/* Return the number of cache unused descriptors we have. */
int descUnused() const {return unusedCache.size(); }
/* Get into a state where the descriptor address/head/etc colud be
* changed */
void reset()
{
DPRINTF(EthernetDesc, "Reseting descriptor cache\n");
for (int x = 0; x < usedCache.size(); x++)
delete usedCache[x];
for (int x = 0; x < unusedCache.size(); x++)
delete unusedCache[x];
usedCache.clear();
unusedCache.clear();
cachePnt = 0;
}
virtual void serialize(std::ostream &os)
{
SERIALIZE_SCALAR(cachePnt);
SERIALIZE_SCALAR(curFetching);
SERIALIZE_SCALAR(wbOut);
SERIALIZE_SCALAR(moreToWb);
SERIALIZE_SCALAR(wbAlignment);
int usedCacheSize = usedCache.size();
SERIALIZE_SCALAR(usedCacheSize);
for(int x = 0; x < usedCacheSize; x++) {
arrayParamOut(os, csprintf("usedCache_%d", x),
(uint8_t*)usedCache[x],sizeof(T));
}
int unusedCacheSize = unusedCache.size();
SERIALIZE_SCALAR(unusedCacheSize);
for(int x = 0; x < unusedCacheSize; x++) {
arrayParamOut(os, csprintf("unusedCache_%d", x),
(uint8_t*)unusedCache[x],sizeof(T));
}
}
virtual void unserialize(Checkpoint *cp, const std::string §ion)
{
UNSERIALIZE_SCALAR(cachePnt);
UNSERIALIZE_SCALAR(curFetching);
UNSERIALIZE_SCALAR(wbOut);
UNSERIALIZE_SCALAR(moreToWb);
UNSERIALIZE_SCALAR(wbAlignment);
int usedCacheSize;
UNSERIALIZE_SCALAR(usedCacheSize);
T *temp;
for(int x = 0; x < usedCacheSize; x++) {
temp = new T;
arrayParamIn(cp, section, csprintf("usedCache_%d", x),
(uint8_t*)temp,sizeof(T));
usedCache.push_back(temp);
}
int unusedCacheSize;
UNSERIALIZE_SCALAR(unusedCacheSize);
for(int x = 0; x < unusedCacheSize; x++) {
temp = new T;
arrayParamIn(cp, section, csprintf("unusedCache_%d", x),
(uint8_t*)temp,sizeof(T));
unusedCache.push_back(temp);
}
}
virtual bool hasOutstandingEvents() {
return wbEvent.scheduled() || fetchEvent.scheduled();
}
};
class RxDescCache : public DescCache<iGbReg::RxDesc>
{
protected:
virtual Addr descBase() const { return igbe->regs.rdba(); }
virtual long descHead() const { return igbe->regs.rdh(); }
virtual long descLen() const { return igbe->regs.rdlen() >> 4; }
virtual long descTail() const { return igbe->regs.rdt(); }
virtual void updateHead(long h) { igbe->regs.rdh(h); }
virtual void enableSm();
bool pktDone;
public:
RxDescCache(IGbE *i, std::string n, int s);
/** Write the given packet into the buffer(s) pointed to by the
* descriptor and update the book keeping. Should only be called when
* there are no dma's pending.
* @param packet ethernet packet to write
* @return if the packet could be written (there was a free descriptor)
*/
bool writePacket(EthPacketPtr packet);
/** Called by event when dma to write packet is completed
*/
void pktComplete();
/** Check if the dma on the packet has completed.
*/
bool packetDone();
EventWrapper<RxDescCache, &RxDescCache::pktComplete> pktEvent;
virtual bool hasOutstandingEvents();
virtual void serialize(std::ostream &os);
virtual void unserialize(Checkpoint *cp, const std::string §ion);
};
friend class RxDescCache;
RxDescCache rxDescCache;
class TxDescCache : public DescCache<iGbReg::TxDesc>
{
protected:
virtual Addr descBase() const { return igbe->regs.tdba(); }
virtual long descHead() const { return igbe->regs.tdh(); }
virtual long descTail() const { return igbe->regs.tdt(); }
virtual long descLen() const { return igbe->regs.tdlen() >> 4; }
virtual void updateHead(long h) { igbe->regs.tdh(h); }
virtual void enableSm();
virtual void intAfterWb() const { igbe->postInterrupt(iGbReg::IT_TXDW);}
bool pktDone;
bool isTcp;
bool pktWaiting;
public:
TxDescCache(IGbE *i, std::string n, int s);
/** Tell the cache to DMA a packet from main memory into its buffer and
* return the size the of the packet to reserve space in tx fifo.
* @return size of the packet
*/
int getPacketSize();
void getPacketData(EthPacketPtr p);
/** Ask if the packet has been transfered so the state machine can give
* it to the fifo.
* @return packet available in descriptor cache
*/
bool packetAvailable();
/** Ask if we are still waiting for the packet to be transfered.
* @return packet still in transit.
*/
bool packetWaiting() { return pktWaiting; }
/** Called by event when dma to write packet is completed
*/
void pktComplete();
EventWrapper<TxDescCache, &TxDescCache::pktComplete> pktEvent;
virtual bool hasOutstandingEvents();
virtual void serialize(std::ostream &os);
virtual void unserialize(Checkpoint *cp, const std::string §ion);
};
friend class TxDescCache;
TxDescCache txDescCache;
public:
struct Params : public PciDev::Params
{
Net::EthAddr hardware_address;
bool use_flow_control;
int rx_fifo_size;
int tx_fifo_size;
int rx_desc_cache_size;
int tx_desc_cache_size;
Tick clock;
};
IGbE(Params *params);
~IGbE() {;}
Tick clock;
inline Tick cycles(int numCycles) const { return numCycles * clock; }
virtual Tick read(PacketPtr pkt);
virtual Tick write(PacketPtr pkt);
virtual Tick writeConfig(PacketPtr pkt);
bool ethRxPkt(EthPacketPtr packet);
void ethTxDone();
void setEthInt(IGbEInt *i) { assert(!etherInt); etherInt = i; }
const Params *params() const {return (const Params *)_params; }
virtual void serialize(std::ostream &os);
virtual void unserialize(Checkpoint *cp, const std::string §ion);
virtual unsigned int drain(Event *de);
virtual void resume();
};
class IGbEInt : public EtherInt
{
private:
IGbE *dev;
public:
IGbEInt(const std::string &name, IGbE *d)
: EtherInt(name), dev(d)
{ dev->setEthInt(this); }
virtual bool recvPacket(EthPacketPtr pkt) { return dev->ethRxPkt(pkt); }
virtual void sendDone() { dev->ethTxDone(); }
};
#endif //__DEV_I8254XGBE_HH__
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