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/* -*- Mode:C++; c-file-style:"gnu"; indent-tabs-mode:nil; -*- */
/**
* Copyright (c) 2014 University of Memphis,
* Regents of the University of California
*
* This file is part of NLSR (Named-data Link State Routing).
* See AUTHORS.md for complete list of NLSR authors and contributors.
*
* NLSR is free software: you can redistribute it and/or modify it under the terms
* of the GNU General Public License as published by the Free Software Foundation,
* either version 3 of the License, or (at your option) any later version.
*
* NLSR is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
* without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
* PURPOSE. See the GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License along with
* NLSR, e.g., in COPYING.md file. If not, see <http://www.gnu.org/licenses/>.
*
* \author A K M Mahmudul Hoque <ahoque1@memphis.edu>
*
**/
#include <iostream>
#include <cmath>
#include "lsdb.hpp"
#include "routing-table-calculator.hpp"
#include "map.hpp"
#include "lsa.hpp"
#include "nexthop.hpp"
#include "nlsr.hpp"
#include "logger.hpp"
#include <boost/math/constants/constants.hpp>
namespace nlsr {
INIT_LOGGER("RoutingTableCalculator");
using namespace std;
void
RoutingTableCalculator::allocateAdjMatrix()
{
adjMatrix = new double*[m_nRouters];
for (size_t i = 0; i < m_nRouters; ++i) {
adjMatrix[i] = new double[m_nRouters];
}
}
void
RoutingTableCalculator::initMatrix()
{
for (size_t i = 0; i < m_nRouters; i++) {
for (size_t j = 0; j < m_nRouters; j++) {
adjMatrix[i][j] = 0;
}
}
}
void
RoutingTableCalculator::makeAdjMatrix(Nlsr& pnlsr, Map pMap)
{
std::list<AdjLsa> adjLsdb = pnlsr.getLsdb().getAdjLsdb();
for (std::list<AdjLsa>::iterator it = adjLsdb.begin(); it != adjLsdb.end() ; it++) {
int32_t row = pMap.getMappingNoByRouterName((*it).getOrigRouter());
std::list<Adjacent> adl = (*it).getAdl().getAdjList();
for (std::list<Adjacent>::iterator itAdl = adl.begin(); itAdl != adl.end() ; itAdl++) {
int32_t col = pMap.getMappingNoByRouterName((*itAdl).getName());
double cost = (*itAdl).getLinkCost();
if ((row >= 0 && row < static_cast<int32_t>(m_nRouters)) &&
(col >= 0 && col < static_cast<int32_t>(m_nRouters)))
{
adjMatrix[row][col] = cost;
}
}
}
}
void
RoutingTableCalculator::writeAdjMatrixLog()
{
for (size_t i = 0; i < m_nRouters; i++) {
string line="";
for (size_t j = 0; j < m_nRouters; j++) {
line += boost::lexical_cast<std::string>(adjMatrix[i][j]);
line += " ";
}
_LOG_DEBUG(line);
}
}
void
RoutingTableCalculator::adjustAdMatrix(int source, int link, double linkCost)
{
for (int i = 0; i < static_cast<int>(m_nRouters); i++) {
if (i == link) {
adjMatrix[source][i] = linkCost;
}
else {
adjMatrix[source][i] = 0;
}
}
}
int
RoutingTableCalculator::getNumOfLinkfromAdjMatrix(int sRouter)
{
int noLink = 0;
for (size_t i = 0; i < m_nRouters; i++) {
if (adjMatrix[sRouter][i] > 0) {
noLink++;
}
}
return noLink;
}
void
RoutingTableCalculator::getLinksFromAdjMatrix(int* links,
double* linkCosts, int source)
{
int j = 0;
for (size_t i = 0; i < m_nRouters; i++) {
if (adjMatrix[source][i] > 0) {
links[j] = i;
linkCosts[j] = adjMatrix[source][i];
j++;
}
}
}
void
RoutingTableCalculator::freeAdjMatrix()
{
for (size_t i = 0; i < m_nRouters; ++i) {
delete [] adjMatrix[i];
}
delete [] adjMatrix;
}
void
RoutingTableCalculator::allocateLinks()
{
links = new int[vNoLink];
}
void
RoutingTableCalculator::allocateLinkCosts()
{
linkCosts = new double[vNoLink];
}
void
RoutingTableCalculator::freeLinks()
{
delete [] links;
}
void
RoutingTableCalculator::freeLinksCosts()
{
delete [] linkCosts;
}
void
LinkStateRoutingTableCalculator::calculatePath(Map& pMap,
RoutingTable& rt, Nlsr& pnlsr)
{
_LOG_DEBUG("LinkStateRoutingTableCalculator::calculatePath Called");
allocateAdjMatrix();
initMatrix();
makeAdjMatrix(pnlsr, pMap);
writeAdjMatrixLog();
int sourceRouter = pMap.getMappingNoByRouterName(pnlsr.getConfParameter().getRouterPrefix());
allocateParent();
allocateDistance();
if (pnlsr.getConfParameter().getMaxFacesPerPrefix() == 1) {
// Single Path
doDijkstraPathCalculation(sourceRouter);
// update routing table
addAllLsNextHopsToRoutingTable(pnlsr, rt, pMap, sourceRouter);
}
else {
// Multi Path
setNoLink(getNumOfLinkfromAdjMatrix(sourceRouter));
allocateLinks();
allocateLinkCosts();
getLinksFromAdjMatrix(links, linkCosts, sourceRouter);
for (int i = 0 ; i < vNoLink; i++) {
adjustAdMatrix(sourceRouter, links[i], linkCosts[i]);
writeAdjMatrixLog();
doDijkstraPathCalculation(sourceRouter);
//update routing table
addAllLsNextHopsToRoutingTable(pnlsr, rt, pMap, sourceRouter);
}
freeLinks();
freeLinksCosts();
}
freeParent();
freeDistance();
freeAdjMatrix();
}
void
LinkStateRoutingTableCalculator::doDijkstraPathCalculation(int sourceRouter)
{
int i;
int v, u;
int* Q = new int[m_nRouters];
int head = 0;
/* Initiate the Parent */
for (i = 0 ; i < static_cast<int>(m_nRouters); i++) {
m_parent[i] = EMPTY_PARENT;
m_distance[i] = INF_DISTANCE;
Q[i] = i;
}
if (sourceRouter != NO_MAPPING_NUM) {
m_distance[sourceRouter] = 0;
sortQueueByDistance(Q, m_distance, head, m_nRouters);
while (head < static_cast<int>(m_nRouters)) {
u = Q[head];
if (m_distance[u] == INF_DISTANCE) {
break;
}
for (v = 0 ; v < static_cast<int>(m_nRouters); v++) {
if (adjMatrix[u][v] > 0) {
if (isNotExplored(Q, v, head + 1, m_nRouters)) {
if (m_distance[u] + adjMatrix[u][v] < m_distance[v]) {
m_distance[v] = m_distance[u] + adjMatrix[u][v] ;
m_parent[v] = u;
}
}
}
}
head++;
sortQueueByDistance(Q, m_distance, head, m_nRouters);
}
}
delete [] Q;
}
void
LinkStateRoutingTableCalculator::addAllLsNextHopsToRoutingTable(Nlsr& pnlsr, RoutingTable& rt,
Map& pMap, uint32_t sourceRouter)
{
_LOG_DEBUG("LinkStateRoutingTableCalculator::addAllNextHopsToRoutingTable Called");
int nextHopRouter = 0;
for (size_t i = 0; i < m_nRouters ; i++) {
if (i != sourceRouter) {
nextHopRouter = getLsNextHop(i, sourceRouter);
if (nextHopRouter != NO_NEXT_HOP) {
double routeCost = m_distance[i];
ndn::Name nextHopRouterName = pMap.getRouterNameByMappingNo(nextHopRouter);
std::string nextHopFace =
pnlsr.getAdjacencyList().getAdjacent(nextHopRouterName).getConnectingFaceUri();
// Add next hop to routing table
NextHop nh(nextHopFace, routeCost);
rt.addNextHop(pMap.getRouterNameByMappingNo(i), nh);
}
}
}
}
int
LinkStateRoutingTableCalculator::getLsNextHop(int dest, int source)
{
int nextHop = NO_NEXT_HOP;
while (m_parent[dest] != EMPTY_PARENT) {
nextHop = dest;
dest = m_parent[dest];
}
if (dest != source) {
nextHop = NO_NEXT_HOP;
}
return nextHop;
}
void
LinkStateRoutingTableCalculator::sortQueueByDistance(int* Q,
double* dist,
int start, int element)
{
for (int i = start ; i < element ; i++) {
for (int j = i + 1; j < element; j++) {
if (dist[Q[j]] < dist[Q[i]]) {
int tempU = Q[j];
Q[j] = Q[i];
Q[i] = tempU;
}
}
}
}
int
LinkStateRoutingTableCalculator::isNotExplored(int* Q,
int u, int start, int element)
{
int ret = 0;
for (int i = start; i < element; i++) {
if (Q[i] == u) {
ret = 1;
break;
}
}
return ret;
}
void
LinkStateRoutingTableCalculator::allocateParent()
{
m_parent = new int[m_nRouters];
}
void
LinkStateRoutingTableCalculator::allocateDistance()
{
m_distance = new double[m_nRouters];
}
void
LinkStateRoutingTableCalculator::freeParent()
{
delete [] m_parent;
}
void LinkStateRoutingTableCalculator::freeDistance()
{
delete [] m_distance;
}
const double HyperbolicRoutingCalculator::MATH_PI = boost::math::constants::pi<double>();
const double HyperbolicRoutingCalculator::UNKNOWN_DISTANCE = -1.0;
const double HyperbolicRoutingCalculator::UNKNOWN_RADIUS = -1.0;
const int32_t HyperbolicRoutingCalculator::ROUTER_NOT_FOUND = -1.0;
void
HyperbolicRoutingCalculator::calculatePaths(Map& map, RoutingTable& rt,
Lsdb& lsdb, AdjacencyList& adjacencies)
{
_LOG_TRACE("Calculating hyperbolic paths");
int thisRouter = map.getMappingNoByRouterName(m_thisRouterName);
// Iterate over directly connected neighbors
std::list<Adjacent> neighbors = adjacencies.getAdjList();
for (std::list<Adjacent>::iterator adj = neighbors.begin(); adj != neighbors.end(); ++adj) {
// Don't calculate nexthops using an inactive router
if (adj->getStatus() == Adjacent::STATUS_INACTIVE) {
_LOG_TRACE(adj->getName() << " is inactive; not using it as a nexthop");
continue;
}
ndn::Name srcRouterName = adj->getName();
// Don't calculate nexthops for this router to other routers
if (srcRouterName == m_thisRouterName) {
continue;
}
std::string srcFaceUri = adj->getConnectingFaceUri();
// Install nexthops for this router to the neighbor; direct neighbors have a 0 cost link
addNextHop(srcRouterName, srcFaceUri, 0, rt);
int src = map.getMappingNoByRouterName(srcRouterName);
if (src == ROUTER_NOT_FOUND) {
_LOG_WARN(adj->getName() << " does not exist in the router map!");
continue;
}
// Get hyperbolic distance from direct neighbor to every other router
for (int dest = 0; dest < static_cast<int>(m_nRouters); ++dest) {
// Don't calculate nexthops to this router or from a router to itself
if (dest != thisRouter && dest != src) {
ndn::Name destRouterName = map.getRouterNameByMappingNo(dest);
double distance = getHyperbolicDistance(map, lsdb, srcRouterName, destRouterName);
// Could not compute distance
if (distance == UNKNOWN_DISTANCE) {
_LOG_WARN("Could not calculate hyperbolic distance from " << srcRouterName << " to " <<
destRouterName);
continue;
}
addNextHop(destRouterName, srcFaceUri, distance, rt);
}
}
}
}
double
HyperbolicRoutingCalculator::getHyperbolicDistance(Map& map, Lsdb& lsdb,
ndn::Name src, ndn::Name dest)
{
_LOG_TRACE("Calculating hyperbolic distance from " << src << " to " << dest);
double distance = UNKNOWN_DISTANCE;
ndn::Name srcLsaKey = src;
srcLsaKey.append("coordinate");
CoordinateLsa* srcLsa = lsdb.findCoordinateLsa(srcLsaKey);
ndn::Name destLsaKey = dest;
destLsaKey.append("coordinate");
CoordinateLsa* destLsa = lsdb.findCoordinateLsa(destLsaKey);
// Coordinate LSAs do not exist for these routers
if (srcLsa == NULL || destLsa == NULL) {
return UNKNOWN_DISTANCE;
}
double srcTheta = srcLsa->getCorTheta();
double destTheta = destLsa->getCorTheta();
double diffTheta = fabs(srcTheta - destTheta);
if (diffTheta > MATH_PI) {
diffTheta = 2 * MATH_PI - diffTheta;
}
double srcRadius = srcLsa->getCorRadius();
double destRadius = destLsa->getCorRadius();
if (srcRadius == UNKNOWN_RADIUS && destRadius == UNKNOWN_RADIUS) {
return UNKNOWN_DISTANCE;
}
if (diffTheta == 0) {
distance = fabs(srcRadius - destRadius);
}
else {
distance = acosh((cosh(srcRadius) * cosh(destRadius)) -
(sinh(srcRadius) * sinh(destRadius) * cos(diffTheta)));
}
_LOG_TRACE("Distance from " << src << " to " << dest << " is " << distance);
return distance;
}
void HyperbolicRoutingCalculator::addNextHop(ndn::Name dest, std::string faceUri,
double cost, RoutingTable& rt)
{
NextHop hop(faceUri, cost);
_LOG_TRACE("Calculated " << hop << " for destination: " << dest);
if (m_isDryRun) {
rt.addNextHopToDryTable(dest, hop);
}
else {
rt.addNextHop(dest, hop);
}
}
}//namespace nlsr