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/*
* Copyright (c) 2008 Princeton University
* 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: Niket Agarwal
*/
#include "base/cast.hh"
#include "base/stl_helpers.hh"
#include "debug/RubyNetwork.hh"
#include "mem/ruby/network/garnet/flexible-pipeline/InVcState.hh"
#include "mem/ruby/network/garnet/flexible-pipeline/OutVcState.hh"
#include "mem/ruby/network/garnet/flexible-pipeline/Router.hh"
#include "mem/ruby/network/garnet/flexible-pipeline/VCarbiter.hh"
#include "mem/ruby/slicc_interface/Message.hh"
using namespace std;
using m5::stl_helpers::deletePointers;
Router::Router(const Params *p)
: BasicRouter(p), FlexibleConsumer(this)
{
m_virtual_networks = p->virt_nets;
m_vc_per_vnet = p->vcs_per_vnet;
m_round_robin_inport = 0;
m_round_robin_start = 0;
m_num_vcs = m_vc_per_vnet * m_virtual_networks;
m_vc_arbiter = new VCarbiter(this);
}
Router::~Router()
{
for (int i = 0; i < m_in_link.size(); i++) {
deletePointers(m_in_vc_state[i]);
}
for (int i = 0; i < m_out_link.size(); i++) {
deletePointers(m_out_vc_state[i]);
deletePointers(m_router_buffers[i]);
}
deletePointers(m_out_src_queue);
delete m_vc_arbiter;
}
void
Router::addInPort(NetworkLink *in_link)
{
int port = m_in_link.size();
vector<InVcState *> in_vc_vector;
for (int i = 0; i < m_num_vcs; i++) {
in_vc_vector.push_back(new InVcState(i));
in_vc_vector[i]->setState(IDLE_, curCycle());
}
m_in_vc_state.push_back(in_vc_vector);
m_in_link.push_back(in_link);
in_link->setLinkConsumer(this);
in_link->setInPort(port);
int start = 0;
m_round_robin_invc.push_back(start);
}
void
Router::addOutPort(NetworkLink *out_link, const NetDest& routing_table_entry,
int link_weight)
{
int port = m_out_link.size();
out_link->setOutPort(port);
int start = 0;
m_vc_round_robin.push_back(start);
m_out_src_queue.push_back(new flitBuffer());
m_out_link.push_back(out_link);
m_routing_table.push_back(routing_table_entry);
out_link->setSourceQueue(m_out_src_queue[port]);
out_link->setSource(this);
vector<flitBuffer *> intermediateQueues;
for (int i = 0; i < m_num_vcs; i++) {
int buffer_size = m_net_ptr->getBufferSize();
if (buffer_size > 0) // finite size
intermediateQueues.push_back(new flitBuffer(buffer_size));
else // infinite size
intermediateQueues.push_back(new flitBuffer());
}
m_router_buffers.push_back(intermediateQueues);
vector<OutVcState *> out_vc_vector;
for (int i = 0; i < m_num_vcs; i++) {
out_vc_vector.push_back(new OutVcState(i));
out_vc_vector[i]->setState(IDLE_, curCycle());
}
m_out_vc_state.push_back(out_vc_vector);
m_link_weights.push_back(link_weight);
}
bool
Router::isBufferNotFull(int vc, int inport)
{
int outport = m_in_vc_state[inport][vc]->get_outport();
int outvc = m_in_vc_state[inport][vc]->get_outvc();
return (!m_router_buffers[outport][outvc]->isFull());
}
// A request for an output vc has been placed by an upstream Router/NI.
// This has to be updated and arbitration performed
void
Router::request_vc(int in_vc, int in_port, NetDest destination,
Cycles request_time)
{
assert(m_in_vc_state[in_port][in_vc]->isInState(IDLE_, request_time));
int outport = getRoute(destination);
m_in_vc_state[in_port][in_vc]->setRoute(outport);
m_in_vc_state[in_port][in_vc]->setState(VC_AB_, request_time);
assert(request_time >= curCycle());
if (request_time > curCycle())
m_vc_arbiter->scheduleEventAbsolute(clockPeriod() * request_time);
else
vc_arbitrate();
}
void
Router::vc_arbitrate()
{
int inport = m_round_robin_inport;
m_round_robin_inport++;
if (m_round_robin_inport == m_in_link.size())
m_round_robin_inport = 0;
for (int port_iter = 0; port_iter < m_in_link.size(); port_iter++) {
inport++;
if (inport >= m_in_link.size())
inport = 0;
int invc = m_round_robin_invc[inport];
int next_round_robin_invc = invc;
do {
next_round_robin_invc++;
if (next_round_robin_invc >= m_num_vcs)
next_round_robin_invc = 0;
} while (!(m_net_ptr->validVirtualNetwork(
get_vnet(next_round_robin_invc))));
m_round_robin_invc[inport] = next_round_robin_invc;
for (int vc_iter = 0; vc_iter < m_num_vcs; vc_iter++) {
invc++;
if (invc >= m_num_vcs)
invc = 0;
if (!(m_net_ptr->validVirtualNetwork(get_vnet(invc))))
continue;
InVcState *in_vc_state = m_in_vc_state[inport][invc];
if (in_vc_state->isInState(VC_AB_, curCycle())) {
int outport = in_vc_state->get_outport();
vector<int> valid_vcs = get_valid_vcs(invc);
for (int valid_vc_iter = 0; valid_vc_iter < valid_vcs.size();
valid_vc_iter++) {
if (m_out_vc_state[outport][valid_vcs[valid_vc_iter]]
->isInState(IDLE_, curCycle())) {
in_vc_state->grant_vc(valid_vcs[valid_vc_iter],
curCycle());
m_in_link[inport]->grant_vc_link(invc, curCycle());
m_out_vc_state[outport][valid_vcs[valid_vc_iter]]
->setState(VC_AB_, curCycle());
break;
}
}
}
}
}
}
vector<int>
Router::get_valid_vcs(int invc)
{
vector<int> vc_list;
for (int vnet = 0; vnet < m_virtual_networks; vnet++) {
if (invc >= (vnet*m_vc_per_vnet) && invc < ((vnet+1)*m_vc_per_vnet)) {
int base = vnet*m_vc_per_vnet;
int vc_per_vnet;
if (m_net_ptr->isVNetOrdered(vnet))
vc_per_vnet = 1;
else
vc_per_vnet = m_vc_per_vnet;
for (int offset = 0; offset < vc_per_vnet; offset++) {
vc_list.push_back(base+offset);
}
break;
}
}
return vc_list;
}
void
Router::grant_vc(int out_port, int vc, Cycles grant_time)
{
assert(m_out_vc_state[out_port][vc]->isInState(VC_AB_, grant_time));
m_out_vc_state[out_port][vc]->grant_vc(grant_time);
scheduleEvent(Cycles(1));
}
void
Router::release_vc(int out_port, int vc, Cycles release_time)
{
assert(m_out_vc_state[out_port][vc]->isInState(ACTIVE_, release_time));
m_out_vc_state[out_port][vc]->setState(IDLE_, release_time);
scheduleEvent(Cycles(1));
}
// This function calculated the output port for a particular destination.
int
Router::getRoute(NetDest destination)
{
int output_link = -1;
int min_weight = INFINITE_;
for (int link = 0; link < m_routing_table.size(); link++) {
if (destination.intersectionIsNotEmpty(m_routing_table[link])) {
if ((m_link_weights[link] >= min_weight))
continue;
output_link = link;
min_weight = m_link_weights[link];
}
}
return output_link;
}
void
Router::routeCompute(flit *m_flit, int inport)
{
int invc = m_flit->get_vc();
int outport = m_in_vc_state[inport][invc]->get_outport();
int outvc = m_in_vc_state[inport][invc]->get_outvc();
assert(m_net_ptr->getNumPipeStages() >= 1);
// Subtract 1 as 1 cycle will be consumed in scheduling the output link
m_flit->set_time(curCycle() + Cycles((m_net_ptr->getNumPipeStages() - 1)));
m_flit->set_vc(outvc);
m_router_buffers[outport][outvc]->insert(m_flit);
if (m_net_ptr->getNumPipeStages() > 1)
scheduleEvent(Cycles(m_net_ptr->getNumPipeStages() - 1));
if ((m_flit->get_type() == HEAD_) || (m_flit->get_type() == HEAD_TAIL_)) {
Message *nm = m_flit->get_msg_ptr().get();
NetDest destination = nm->getDestination();
if (m_net_ptr->getNumPipeStages() > 1) {
m_out_vc_state[outport][outvc]->setState(VC_AB_, curCycle() +
Cycles(1));
m_out_link[outport]->request_vc_link(outvc, destination,
curCycle() + Cycles(1));
} else {
m_out_vc_state[outport][outvc]->setState(VC_AB_, curCycle());
m_out_link[outport]->request_vc_link(outvc, destination,
curCycle());
}
}
if ((m_flit->get_type() == TAIL_) || (m_flit->get_type() == HEAD_TAIL_)) {
m_in_vc_state[inport][invc]->setState(IDLE_, curCycle() + Cycles(1));
m_in_link[inport]->release_vc_link(invc, curCycle() + Cycles(1));
}
}
void
Router::wakeup()
{
flit *t_flit;
// This is for round-robin scheduling of incoming ports
int incoming_port = m_round_robin_start;
m_round_robin_start++;
if (m_round_robin_start >= m_in_link.size()) {
m_round_robin_start = 0;
}
for (int port = 0; port < m_in_link.size(); port++) {
// Round robin scheduling
incoming_port++;
if (incoming_port >= m_in_link.size())
incoming_port = 0;
// checking the incoming link
if (m_in_link[incoming_port]->isReady()) {
DPRINTF(RubyNetwork, "m_id: %d, Time: %lld\n", m_id, curCycle());
t_flit = m_in_link[incoming_port]->peekLink();
routeCompute(t_flit, incoming_port);
m_in_link[incoming_port]->consumeLink();
}
}
scheduleOutputLinks();
checkReschedule(); // This is for flits lying in the router buffers
vc_arbitrate();
check_arbiter_reschedule();
}
void
Router::scheduleOutputLinks()
{
for (int port = 0; port < m_out_link.size(); port++) {
int vc_tolookat = m_vc_round_robin[port];
int next_round_robin_vc_tolookat = vc_tolookat;
do {
next_round_robin_vc_tolookat++;
if (next_round_robin_vc_tolookat == m_num_vcs)
next_round_robin_vc_tolookat = 0;
} while (!(m_net_ptr->validVirtualNetwork(
get_vnet(next_round_robin_vc_tolookat))));
m_vc_round_robin[port] = next_round_robin_vc_tolookat;
for (int i = 0; i < m_num_vcs; i++) {
vc_tolookat++;
if (vc_tolookat == m_num_vcs)
vc_tolookat = 0;
if (m_router_buffers[port][vc_tolookat]->isReady(curCycle())) {
// models buffer backpressure
if (m_out_vc_state[port][vc_tolookat]->isInState(ACTIVE_,
curCycle()) &&
m_out_link[port]->isBufferNotFull_link(vc_tolookat)) {
flit *t_flit =
m_router_buffers[port][vc_tolookat]->getTopFlit();
t_flit->set_time(curCycle() + Cycles(1));
m_out_src_queue[port]->insert(t_flit);
m_out_link[port]->
scheduleEventAbsolute(clockEdge(Cycles(1)));
break; // done for this port
}
}
}
}
}
int
Router::get_vnet(int vc)
{
int vnet = vc/m_vc_per_vnet;
assert(vnet < m_virtual_networks);
return vnet;
}
void
Router::checkReschedule()
{
for (int port = 0; port < m_out_link.size(); port++) {
for (int vc = 0; vc < m_num_vcs; vc++) {
if (m_router_buffers[port][vc]->isReady(curCycle() + Cycles(1))) {
scheduleEvent(Cycles(1));
return;
}
}
}
}
void
Router::check_arbiter_reschedule()
{
for (int port = 0; port < m_in_link.size(); port++) {
for (int vc = 0; vc < m_num_vcs; vc++) {
if (m_in_vc_state[port][vc]->isInState(VC_AB_, curCycle() +
Cycles(1))) {
m_vc_arbiter->scheduleEventAbsolute(clockEdge(Cycles(1)));
return;
}
}
}
}
bool
Router::functionalRead(Packet *pkt)
{
// Access the buffers in the router for performing a functional read
for (unsigned int i = 0; i < m_router_buffers.size(); i++) {
for (unsigned int j = 0; j < m_router_buffers[i].size(); ++j) {
if (m_router_buffers[i][j]->functionalRead(pkt)) {
return true;
}
}
}
// Access the link queues for performing a functional read
for (unsigned int i = 0; i < m_out_src_queue.size(); i++) {
if (m_out_src_queue[i]->functionalRead(pkt)) {
return true;
}
}
return false;
}
uint32_t
Router::functionalWrite(Packet *pkt)
{
uint32_t num_functional_writes = 0;
// Access the buffers in the router for performing a functional write
for (unsigned int i = 0; i < m_router_buffers.size(); i++) {
for (unsigned int j = 0; j < m_router_buffers[i].size(); ++j) {
num_functional_writes +=
m_router_buffers[i][j]->functionalWrite(pkt);
}
}
// Access the link queues for performing a functional write
for (unsigned int i = 0; i < m_out_src_queue.size(); i++) {
num_functional_writes += m_out_src_queue[i]->functionalWrite(pkt);
}
return num_functional_writes;
}
void
Router::print(ostream& out) const
{
out << "[Router]";
}
Router *
GarnetRouterParams::create()
{
return new Router(this);
}
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