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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
* Definition of a bus object.
*/
#include <limits>
#include "base/misc.hh"
#include "base/trace.hh"
#include "mem/bus.hh"
#include "sim/builder.hh"
Port *
Bus::getPort(const std::string &if_name, int idx)
{
if (if_name == "default") {
if (defaultPort == NULL) {
defaultPort = new BusPort(csprintf("%s-default",name()), this,
defaultId);
cachedBlockSizeValid = false;
return defaultPort;
} else
fatal("Default port already set\n");
}
int id;
if (if_name == "functional") {
if (!funcPort) {
id = maxId++;
funcPort = new BusPort(csprintf("%s-p%d-func", name(), id), this, id);
funcPortId = id;
interfaces[id] = funcPort;
}
return funcPort;
}
// if_name ignored? forced to be empty?
id = maxId++;
assert(maxId < std::numeric_limits<typeof(maxId)>::max());
BusPort *bp = new BusPort(csprintf("%s-p%d", name(), id), this, id);
interfaces[id] = bp;
cachedBlockSizeValid = false;
return bp;
}
void
Bus::deletePortRefs(Port *p)
{
BusPort *bp = dynamic_cast<BusPort*>(p);
if (bp == NULL)
panic("Couldn't convert Port* to BusPort*\n");
// If this is our one functional port
if (funcPort == bp)
return;
interfaces.erase(bp->getId());
delete bp;
}
/** Get the ranges of anyone other buses that we are connected to. */
void
Bus::init()
{
m5::hash_map<short,BusPort*>::iterator intIter;
for (intIter = interfaces.begin(); intIter != interfaces.end(); intIter++)
intIter->second->sendStatusChange(Port::RangeChange);
}
Bus::BusFreeEvent::BusFreeEvent(Bus *_bus) : Event(&mainEventQueue), bus(_bus)
{}
void Bus::BusFreeEvent::process()
{
bus->recvRetry(-1);
}
const char * Bus::BusFreeEvent::description()
{
return "bus became available";
}
void Bus::occupyBus(PacketPtr pkt)
{
//Bring tickNextIdle up to the present tick
//There is some potential ambiguity where a cycle starts, which might make
//a difference when devices are acting right around a cycle boundary. Using
//a < allows things which happen exactly on a cycle boundary to take up only
//the following cycle. Anthing that happens later will have to "wait" for
//the end of that cycle, and then start using the bus after that.
while (tickNextIdle < curTick)
tickNextIdle += clock;
// The packet will be sent. Figure out how long it occupies the bus, and
// how much of that time is for the first "word", aka bus width.
int numCycles = 0;
// Requests need one cycle to send an address
if (pkt->isRequest())
numCycles++;
else if (pkt->isResponse() || pkt->hasData()) {
// If a packet has data, it needs ceil(size/width) cycles to send it
// We're using the "adding instead of dividing" trick again here
if (pkt->hasData()) {
int dataSize = pkt->getSize();
for (int transmitted = 0; transmitted < dataSize;
transmitted += width) {
numCycles++;
}
} else {
// If the packet didn't have data, it must have been a response.
// Those use the bus for one cycle to send their data.
numCycles++;
}
}
// The first word will be delivered after the current tick, the delivery
// of the address if any, and one bus cycle to deliver the data
pkt->firstWordTime =
tickNextIdle +
pkt->isRequest() ? clock : 0 +
clock;
//Advance it numCycles bus cycles.
//XXX Should this use the repeated addition trick as well?
tickNextIdle += (numCycles * clock);
if (!busIdle.scheduled()) {
busIdle.schedule(tickNextIdle);
} else {
busIdle.reschedule(tickNextIdle);
}
DPRINTF(Bus, "The bus is now occupied from tick %d to %d\n",
curTick, tickNextIdle);
// The bus will become idle once the current packet is delivered.
pkt->finishTime = tickNextIdle;
}
/** Function called by the port when the bus is receiving a Timing
* transaction.*/
bool
Bus::recvTiming(PacketPtr pkt)
{
Port *port;
DPRINTF(Bus, "recvTiming: packet src %d dest %d addr 0x%x cmd %s result %d\n",
pkt->getSrc(), pkt->getDest(), pkt->getAddr(), pkt->cmdString(),
pkt->result);
BusPort *pktPort;
if (pkt->getSrc() == defaultId)
pktPort = defaultPort;
else pktPort = interfaces[pkt->getSrc()];
// If the bus is busy, or other devices are in line ahead of the current
// one, put this device on the retry list.
if (tickNextIdle > curTick ||
(retryList.size() && (!inRetry || pktPort != retryList.front()))) {
addToRetryList(pktPort);
DPRINTF(Bus, "recvTiming: Bus is busy, returning false\n");
return false;
}
short dest = pkt->getDest();
// Make sure to clear the snoop commit flag so it doesn't think an
// access has been handled twice.
if (dest == Packet::Broadcast) {
port = findPort(pkt->getAddr(), pkt->getSrc());
pkt->flags &= ~SNOOP_COMMIT;
if (timingSnoop(pkt, port ? port : interfaces[pkt->getSrc()])) {
bool success;
pkt->flags |= SNOOP_COMMIT;
success = timingSnoop(pkt, port ? port : interfaces[pkt->getSrc()]);
assert(success);
if (pkt->flags & SATISFIED) {
//Cache-Cache transfer occuring
if (inRetry) {
retryList.front()->onRetryList(false);
retryList.pop_front();
inRetry = false;
}
occupyBus(pkt);
DPRINTF(Bus, "recvTiming: Packet sucessfully sent\n");
return true;
}
} else {
//Snoop didn't succeed
DPRINTF(Bus, "Adding1 a retry to RETRY list %d\n",
pktPort->getId());
addToRetryList(pktPort);
return false;
}
} else {
assert(dest >= 0 && dest < maxId);
assert(dest != pkt->getSrc()); // catch infinite loops
port = interfaces[dest];
}
occupyBus(pkt);
if (port) {
if (port->sendTiming(pkt)) {
// Packet was successfully sent. Return true.
// Also take care of retries
if (inRetry) {
DPRINTF(Bus, "Remove retry from list %d\n",
retryList.front()->getId());
retryList.front()->onRetryList(false);
retryList.pop_front();
inRetry = false;
}
return true;
}
// Packet not successfully sent. Leave or put it on the retry list.
DPRINTF(Bus, "Adding2 a retry to RETRY list %d\n",
pktPort->getId());
addToRetryList(pktPort);
return false;
}
else {
//Forwarding up from responder, just return true;
DPRINTF(Bus, "recvTiming: can we be here?\n");
return true;
}
}
void
Bus::recvRetry(int id)
{
DPRINTF(Bus, "Received a retry from %s\n", id == -1 ? "self" : interfaces[id]->getPeer()->name());
// If there's anything waiting, and the bus isn't busy...
if (retryList.size() && curTick >= tickNextIdle) {
//retryingPort = retryList.front();
inRetry = true;
DPRINTF(Bus, "Sending a retry to %s\n", retryList.front()->getPeer()->name());
retryList.front()->sendRetry();
// If inRetry is still true, sendTiming wasn't called
if (inRetry)
{
retryList.front()->onRetryList(false);
retryList.pop_front();
inRetry = false;
//Bring tickNextIdle up to the present
while (tickNextIdle < curTick)
tickNextIdle += clock;
//Burn a cycle for the missed grant.
tickNextIdle += clock;
busIdle.reschedule(tickNextIdle, true);
}
}
//If we weren't able to drain before, we might be able to now.
if (drainEvent && retryList.size() == 0 && curTick >= tickNextIdle) {
drainEvent->process();
// Clear the drain event once we're done with it.
drainEvent = NULL;
}
}
Port *
Bus::findPort(Addr addr, int id)
{
/* An interval tree would be a better way to do this. --ali. */
int dest_id = -1;
PortIter i = portMap.find(RangeSize(addr,1));
if (i != portMap.end())
dest_id = i->second;
// Check if this matches the default range
if (dest_id == -1) {
for (AddrRangeIter iter = defaultRange.begin();
iter != defaultRange.end(); iter++) {
if (*iter == addr) {
DPRINTF(Bus, " found addr %#llx on default\n", addr);
return defaultPort;
}
}
if (responderSet) {
panic("Unable to find destination for addr (user set default "
"responder): %#llx", addr);
} else {
DPRINTF(Bus, "Unable to find destination for addr: %#llx, will use "
"default port", addr);
return defaultPort;
}
}
// we shouldn't be sending this back to where it came from
// do the snoop access and then we should terminate
// the cyclical call.
if (dest_id == id)
return 0;
return interfaces[dest_id];
}
Tick
Bus::atomicSnoop(PacketPtr pkt, Port *responder)
{
Tick response_time = 0;
for (SnoopIter s_iter = snoopPorts.begin();
s_iter != snoopPorts.end();
s_iter++) {
BusPort *p = *s_iter;
if (p != responder && p->getId() != pkt->getSrc()) {
Tick response = p->sendAtomic(pkt);
if (response) {
assert(!response_time); //Multiple responders
response_time = response;
}
}
}
return response_time;
}
void
Bus::functionalSnoop(PacketPtr pkt, Port *responder)
{
// The packet may be changed by another bus on snoops, restore the
// id after each
int src_id = pkt->getSrc();
for (SnoopIter s_iter = snoopPorts.begin();
s_iter != snoopPorts.end();
s_iter++) {
BusPort *p = *s_iter;
if (p != responder && p->getId() != src_id) {
p->sendFunctional(pkt);
}
if (pkt->result == Packet::Success) {
break;
}
pkt->setSrc(src_id);
}
}
bool
Bus::timingSnoop(PacketPtr pkt, Port* responder)
{
for (SnoopIter s_iter = snoopPorts.begin();
s_iter != snoopPorts.end();
s_iter++) {
BusPort *p = *s_iter;
if (p != responder && p->getId() != pkt->getSrc()) {
bool success = p->sendTiming(pkt);
if (!success)
return false;
}
}
return true;
}
/** Function called by the port when the bus is receiving a Atomic
* transaction.*/
Tick
Bus::recvAtomic(PacketPtr pkt)
{
DPRINTF(Bus, "recvAtomic: packet src %d dest %d addr 0x%x cmd %s\n",
pkt->getSrc(), pkt->getDest(), pkt->getAddr(), pkt->cmdString());
assert(pkt->getDest() == Packet::Broadcast);
pkt->flags |= SNOOP_COMMIT;
// Assume one bus cycle in order to get through. This may have
// some clock skew issues yet again...
pkt->finishTime = curTick + clock;
Port *port = findPort(pkt->getAddr(), pkt->getSrc());
Tick snoopTime = atomicSnoop(pkt, port ? port : interfaces[pkt->getSrc()]);
if (snoopTime)
return snoopTime; //Snoop satisfies it
else if (port)
return port->sendAtomic(pkt);
else
return 0;
}
/** Function called by the port when the bus is receiving a Functional
* transaction.*/
void
Bus::recvFunctional(PacketPtr pkt)
{
DPRINTF(Bus, "recvFunctional: packet src %d dest %d addr 0x%x cmd %s\n",
pkt->getSrc(), pkt->getDest(), pkt->getAddr(), pkt->cmdString());
assert(pkt->getDest() == Packet::Broadcast);
pkt->flags |= SNOOP_COMMIT;
Port* port = findPort(pkt->getAddr(), pkt->getSrc());
functionalSnoop(pkt, port ? port : interfaces[pkt->getSrc()]);
// If the snooping found what we were looking for, we're done.
if (pkt->result != Packet::Success && port) {
port->sendFunctional(pkt);
}
}
/** Function called by the port when the bus is receiving a status change.*/
void
Bus::recvStatusChange(Port::Status status, int id)
{
AddrRangeList ranges;
bool snoops;
AddrRangeIter iter;
assert(status == Port::RangeChange &&
"The other statuses need to be implemented.");
DPRINTF(BusAddrRanges, "received RangeChange from device id %d\n", id);
if (id == defaultId) {
defaultRange.clear();
// Only try to update these ranges if the user set a default responder.
if (responderSet) {
defaultPort->getPeerAddressRanges(ranges, snoops);
assert(snoops == false);
for(iter = ranges.begin(); iter != ranges.end(); iter++) {
defaultRange.push_back(*iter);
DPRINTF(BusAddrRanges, "Adding range %#llx - %#llx for default range\n",
iter->start, iter->end);
}
}
} else {
assert((id < maxId && id >= 0) || id == defaultId);
BusPort *port = interfaces[id];
// Clean out any previously existent ids
for (PortIter portIter = portMap.begin();
portIter != portMap.end(); ) {
if (portIter->second == id)
portMap.erase(portIter++);
else
portIter++;
}
for (SnoopIter s_iter = snoopPorts.begin();
s_iter != snoopPorts.end(); ) {
if ((*s_iter)->getId() == id)
s_iter = snoopPorts.erase(s_iter);
else
s_iter++;
}
port->getPeerAddressRanges(ranges, snoops);
if (snoops) {
DPRINTF(BusAddrRanges, "Adding id %d to snoop list\n", id);
snoopPorts.push_back(port);
}
for (iter = ranges.begin(); iter != ranges.end(); iter++) {
DPRINTF(BusAddrRanges, "Adding range %#llx - %#llx for id %d\n",
iter->start, iter->end, id);
if (portMap.insert(*iter, id) == portMap.end())
panic("Two devices with same range\n");
}
}
DPRINTF(MMU, "port list has %d entries\n", portMap.size());
// tell all our peers that our address range has changed.
// Don't tell the device that caused this change, it already knows
m5::hash_map<short,BusPort*>::iterator intIter;
for (intIter = interfaces.begin(); intIter != interfaces.end(); intIter++)
if (intIter->first != id && intIter->first != funcPortId)
intIter->second->sendStatusChange(Port::RangeChange);
if (id != defaultId && defaultPort)
defaultPort->sendStatusChange(Port::RangeChange);
}
void
Bus::addressRanges(AddrRangeList &resp, bool &snoop, int id)
{
resp.clear();
snoop = false;
DPRINTF(BusAddrRanges, "received address range request, returning:\n");
for (AddrRangeIter dflt_iter = defaultRange.begin();
dflt_iter != defaultRange.end(); dflt_iter++) {
resp.push_back(*dflt_iter);
DPRINTF(BusAddrRanges, " -- Dflt: %#llx : %#llx\n",dflt_iter->start,
dflt_iter->end);
}
for (PortIter portIter = portMap.begin();
portIter != portMap.end(); portIter++) {
bool subset = false;
for (AddrRangeIter dflt_iter = defaultRange.begin();
dflt_iter != defaultRange.end(); dflt_iter++) {
if ((portIter->first.start < dflt_iter->start &&
portIter->first.end >= dflt_iter->start) ||
(portIter->first.start < dflt_iter->end &&
portIter->first.end >= dflt_iter->end))
fatal("Devices can not set ranges that itersect the default set\
but are not a subset of the default set.\n");
if (portIter->first.start >= dflt_iter->start &&
portIter->first.end <= dflt_iter->end) {
subset = true;
DPRINTF(BusAddrRanges, " -- %#llx : %#llx is a SUBSET\n",
portIter->first.start, portIter->first.end);
}
}
if (portIter->second != id && !subset) {
resp.push_back(portIter->first);
DPRINTF(BusAddrRanges, " -- %#llx : %#llx\n",
portIter->first.start, portIter->first.end);
}
}
for (SnoopIter s_iter = snoopPorts.begin(); s_iter != snoopPorts.end();
s_iter++) {
if ((*s_iter)->getId() != id) {
snoop = true;
break;
}
}
}
int
Bus::findBlockSize(int id)
{
if (cachedBlockSizeValid)
return cachedBlockSize;
int max_bs = -1;
for (PortIter portIter = portMap.begin();
portIter != portMap.end(); portIter++) {
int tmp_bs = interfaces[portIter->second]->peerBlockSize();
if (tmp_bs > max_bs)
max_bs = tmp_bs;
}
for (SnoopIter s_iter = snoopPorts.begin();
s_iter != snoopPorts.end(); s_iter++) {
int tmp_bs = (*s_iter)->peerBlockSize();
if (tmp_bs > max_bs)
max_bs = tmp_bs;
}
if (max_bs <= 0)
max_bs = defaultBlockSize;
if (max_bs != 64)
warn_once("Blocksize found to not be 64... hmm... probably not.\n");
cachedBlockSize = max_bs;
cachedBlockSizeValid = true;
return max_bs;
}
unsigned int
Bus::drain(Event * de)
{
//We should check that we're not "doing" anything, and that noone is
//waiting. We might be idle but have someone waiting if the device we
//contacted for a retry didn't actually retry.
if (curTick >= tickNextIdle && retryList.size() == 0) {
return 0;
} else {
drainEvent = de;
return 1;
}
}
void
Bus::startup()
{
if (tickNextIdle < curTick)
tickNextIdle = (curTick / clock) * clock + clock;
}
BEGIN_DECLARE_SIM_OBJECT_PARAMS(Bus)
Param<int> bus_id;
Param<int> clock;
Param<int> width;
Param<bool> responder_set;
Param<int> block_size;
END_DECLARE_SIM_OBJECT_PARAMS(Bus)
BEGIN_INIT_SIM_OBJECT_PARAMS(Bus)
INIT_PARAM(bus_id, "a globally unique bus id"),
INIT_PARAM(clock, "bus clock speed"),
INIT_PARAM(width, "width of the bus (bits)"),
INIT_PARAM(responder_set, "Is a default responder set by the user"),
INIT_PARAM(block_size, "Default blocksize if no device has one")
END_INIT_SIM_OBJECT_PARAMS(Bus)
CREATE_SIM_OBJECT(Bus)
{
return new Bus(getInstanceName(), bus_id, clock, width, responder_set,
block_size);
}
REGISTER_SIM_OBJECT("Bus", Bus)
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