for (unsigned int i = 0 ; i < this->nodes.size() ; i++) {
delete this->nodes[i];
}
+ for (unsigned int i = 0 ; i < this->links.size() ; i++) {
+ delete this->links[i];
+ }
}
bool AsClusterFatTree::isInSubTree(FatTreeNode *root, FatTreeNode *node) {
+ XBT_DEBUG("Is %d(%u,%u) in the sub tree of %d(%u,%u) ?", node->id,
+ node->level, node->position, root->id, root->level, root->position);
+ if (root->level <= node->level) {
+ return false;
+ }
for (unsigned int i = 0 ; i < node->level ; i++) {
if(root->label[i] != node->label[i]) {
return false;
}
}
- for (unsigned int i = root->level + 1 ; i < this->levels ; i++) {
+ for (unsigned int i = root->level ; i < this->levels ; i++) {
if(root->label[i] != node->label[i]) {
return false;
}
sg_platf_route_cbarg_t into,
double *latency) {
FatTreeNode *source, *destination, *currentNode;
- std::vector<NetworkLink*> route;
- source = this->computeNodes.find(src->getId())->second;
- destination = this->computeNodes.find(dst->getId())->second;
- XBT_DEBUG("Get route and latency from '%s' [%d] to '%s' [%d] in a fat tree",
+ std::map<int, FatTreeNode*>::const_iterator tempIter;
+
+if (dst->getRcType() == SURF_NETWORK_ELEMENT_ROUTER || src->getRcType() == SURF_NETWORK_ELEMENT_ROUTER) return;
+
+ /* Let's find the source and the destination in our internal structure */
+ tempIter = this->computeNodes.find(src->getId());
+
+ // xbt_die -> assert
+ if (tempIter == this->computeNodes.end()) {
+ xbt_die("Could not find the source %s [%d] in the fat tree", src->getName(),
+ src->getId());
+ }
+ source = tempIter->second;
+ tempIter = this->computeNodes.find(dst->getId());
+ if (tempIter == this->computeNodes.end()) {
+ xbt_die("Could not find the destination %s [%d] in the fat tree",
+ dst->getName(), dst->getId());
+ }
+
+
+ destination = tempIter->second;
+
+ XBT_VERB("Get route and latency from '%s' [%d] to '%s' [%d] in a fat tree",
src->getName(), src->getId(), dst->getName(), dst->getId());
+ /* In case destination is the source, and there is a loopback, let's get
+ through it instead of going up to a switch*/
+ if(source->id == destination->id && this->p_has_loopback) {
+ xbt_dynar_push_as(into->link_list, void*, source->loopback);
+ if(latency) {
+ *latency += source->loopback->getLatency();
+ }
+ return;
+ }
+
currentNode = source;
// up part
for (unsigned int i = 0 ; i < currentNode->level ; i++) {
d /= this->upperLevelNodesNumber[i];
}
- k = this->upperLevelNodesNumber[currentNode->level] *
- this->lowerLevelNodesNumber[currentNode->level];
- d = d % k;
- route.push_back(currentNode->parents[d]->upLink);
- if(latency) {
- *latency += currentNode->parents[d]->upLink->getLatency();
- }
- currentNode = currentNode->parents[d]->upNode;
+ k = this->upperLevelNodesNumber[currentNode->level];
+ d = d % k;
+ xbt_dynar_push_as(into->link_list, void*,currentNode->parents[d]->upLink);
+
+ if(latency) {
+ *latency += currentNode->parents[d]->upLink->getLatency();
+ }
+
+ if (this->p_has_limiter) {
+ xbt_dynar_push_as(into->link_list, void*,currentNode->limiterLink);
+ }
+ currentNode = currentNode->parents[d]->upNode;
}
-
+
+ XBT_DEBUG("%d(%u,%u) is in the sub tree of %d(%u,%u).", destination->id,
+ destination->level, destination->position, currentNode->id,
+ currentNode->level, currentNode->position);
+
// Down part
while(currentNode != destination) {
for(unsigned int i = 0 ; i < currentNode->children.size() ; i++) {
- if(i % this->lowerLevelNodesNumber[currentNode->level] ==
- destination->label[currentNode->level]) {
- route.push_back(currentNode->children[i]->downLink);
+ if(i % this->lowerLevelNodesNumber[currentNode->level - 1] ==
+ destination->label[currentNode->level - 1]) {
+ xbt_dynar_push_as(into->link_list, void*,currentNode->children[i]->downLink);
if(latency) {
*latency += currentNode->children[i]->downLink->getLatency();
}
currentNode = currentNode->children[i]->downNode;
+ if (this->p_has_limiter) {
+ xbt_dynar_push_as(into->link_list, void*,currentNode->limiterLink);
+ }
+ XBT_DEBUG("%d(%u,%u) is accessible through %d(%u,%u)", destination->id,
+ destination->level, destination->position, currentNode->id,
+ currentNode->level, currentNode->position);
}
}
}
-
- for (unsigned int i = 0 ; i < route.size() ; i++) {
- xbt_dynar_push_as(into->link_list, void*, route[i]);
- }
-
}
/* This function makes the assumption that parse_specific_arguments() and
* addNodes() have already been called
*/
-void AsClusterFatTree::create_links(sg_platf_cluster_cbarg_t cluster){
+void AsClusterFatTree::create_links(){
if(this->levels == 0) {
return;
}
for (unsigned int i = 1 ; i <= this->levels ; i++) {
msgBuffer << ", " << this->nodesByLevel[i] << " switches at level " << i;
}
- XBT_DEBUG(msgBuffer.str().c_str());
+ XBT_DEBUG("%s", msgBuffer.str().c_str());
msgBuffer.str("");
msgBuffer << "Nodes are : ";
msgBuffer << this->nodes[i]->id << "(" << this->nodes[i]->level << ","
<< this->nodes[i]->position << ") ";
}
- XBT_DEBUG(msgBuffer.str().c_str());
+ XBT_DEBUG("%s", msgBuffer.str().c_str());
}
// Nodes are totally ordered, by level and then by position, in this->nodes
for (unsigned int i = 0 ; i < this->levels ; i++) {
for (unsigned int j = 0 ; j < this->nodesByLevel[i] ; j++) {
- this->connectNodeToParents(cluster, this->nodes[k]);
+ this->connectNodeToParents(this->nodes[k]);
k++;
}
}
msgBuffer << "(" << this->links[i]->upNode->id << ","
<< this->links[i]->downNode->id << ") ";
}
- XBT_DEBUG(msgBuffer.str().c_str());
+ XBT_DEBUG("%s", msgBuffer.str().c_str());
}
}
-int AsClusterFatTree::connectNodeToParents(sg_platf_cluster_cbarg_t cluster,
- FatTreeNode *node) {
+int AsClusterFatTree::connectNodeToParents(FatTreeNode *node) {
std::vector<FatTreeNode*>::iterator currentParentNode = this->nodes.begin();
int connectionsNumber = 0;
const int level = node->level;
node->level, node->position, (*currentParentNode)->id,
(*currentParentNode)->level, (*currentParentNode)->position, this->lowerLevelPortsNumber[level]);
for (unsigned int j = 0 ; j < this->lowerLevelPortsNumber[level] ; j++) {
- this->addLink(cluster, *currentParentNode, node->label[level + 1] +
+ this->addLink(*currentParentNode, node->label[level] +
j * this->lowerLevelNodesNumber[level], node,
- (*currentParentNode)->label[level + 1] +
+ (*currentParentNode)->label[level] +
j * this->upperLevelNodesNumber[level]);
}
connectionsNumber++;
}
msgBuffer << ">";
msgBuffer << " related ? ";
- XBT_DEBUG(msgBuffer.str().c_str());
+ XBT_DEBUG("%s", msgBuffer.str().c_str());
}
if (parent->level != child->level + 1) {
return false;
}
- for (unsigned int i = 1 ; i <= this->levels; i++) {
- if (parent->label[this->levels - i] != child->label[this->levels - i] && i != parent->level) {
+ for (unsigned int i = 0 ; i < this->levels; i++) {
+ if (parent->label[i] != child->label[i] && i + 1 != parent->level) {
return false;
}
}
}
- if(this->nodesByLevel[0] > this->nodes.size()) {
- surf_parse_error("There is not enough nodes to fit to the described topology."
- " Please check your platform description (We need %d nodes, we only got %zu)",
+ if(this->nodesByLevel[0] != this->nodes.size()) {
+ surf_parse_error("The number of provided nodes does not fit with the wanted topology."
+ " Please check your platform description (We need %d nodes, we got %zu)",
this->nodesByLevel[0], this->nodes.size());
return;
}
+
for (unsigned int i = 0 ; i < this->levels ; i++) {
int nodesInThisLevel = 1;
}
- // If we have to many compute nodes, we ditch them
- if (this->nodesByLevel[0] < this->nodes.size()) {
- for (unsigned int i = this->nodesByLevel[0] ; i < this->nodes.size() ; i++) {
- this->computeNodes.erase(this->nodes[i]->id);
- delete this->nodes[i];
- }
- this->nodes.resize(this->nodesByLevel[0]);
- }
-
// We create the switches
int k = 0;
for (unsigned int i = 0 ; i < this->levels ; i++) {
for (unsigned int j = 0 ; j < this->nodesByLevel[i + 1] ; j++) {
FatTreeNode* newNode;
- newNode = new FatTreeNode(--k, i + 1, j);
- XBT_DEBUG("We create the switch %d(%d,%d)", newNode->id, newNode->level, newNode->position);
+ newNode = new FatTreeNode(this->cluster, --k, i + 1, j);
+ XBT_DEBUG("We create the switch %d(%d,%d)", newNode->id, newNode->level,
+ newNode->position);
newNode->children.resize(this->lowerLevelNodesNumber[i] *
this->lowerLevelPortsNumber[i]);
if (i != this->levels - 1) {
- newNode->parents.resize(this->upperLevelNodesNumber[i + 1]);
+ newNode->parents.resize(this->upperLevelNodesNumber[i + 1] *
+ this->lowerLevelPortsNumber[i + 1]);
}
newNode->label.resize(this->levels);
this->nodes.push_back(newNode);
unsigned int k = 0;
for (unsigned int i = 0 ; i <= this->levels ; i++) {
currentLabel.assign(this->levels, 0);
- for (unsigned int j = 1 ; j <= this->levels ; j++) {
- maxLabel[maxLabel.size() - j] = j > i ?
- this->lowerLevelNodesNumber[j - 1] : this->upperLevelNodesNumber[j - 1];
+ for (unsigned int j = 0 ; j < this->levels ; j++) {
+ maxLabel[j] = j + 1 > i ?
+ this->lowerLevelNodesNumber[j] : this->upperLevelNodesNumber[j];
}
for (unsigned int j = 0 ; j < this->nodesByLevel[i] ; j++) {
}
msgBuffer << "> to " << k << " (" << i << "," << j <<")";
- XBT_DEBUG(bprintf(msgBuffer.str().c_str()));
+ XBT_DEBUG("%s", msgBuffer.str().c_str());
}
this->nodes[k]->label.assign(currentLabel.begin(), currentLabel.end());
bool remainder = true;
- int pos = currentLabel.size() - 1;
+ unsigned int pos = 0;
do {
std::stringstream msgBuffer;
++currentLabel[pos];
- if (currentLabel[pos] >= maxLabel[pos] && pos > 0) {
+ if (currentLabel[pos] >= maxLabel[pos]) {
currentLabel[pos] = 0;
remainder = true;
}
remainder = false;
}
if (!remainder) {
- pos = currentLabel.size() - 1;
+ pos = 0;
}
else {
- --pos;
+ ++pos;
}
}
- while(remainder);
+ while(remainder && pos < this->levels);
k++;
}
}
using std::make_pair;
static int position = 0;
FatTreeNode* newNode;
- newNode = new FatTreeNode(id, 0, position++);
- newNode->parents.resize(this->upperLevelNodesNumber[0] * this->lowerLevelPortsNumber[0]);
+ newNode = new FatTreeNode(this->cluster, id, 0, position++);
+ newNode->parents.resize(this->upperLevelNodesNumber[0] *
+ this->lowerLevelPortsNumber[0]);
newNode->label.resize(this->levels);
this->computeNodes.insert(make_pair(id,newNode));
this->nodes.push_back(newNode);
}
-void AsClusterFatTree::addLink(sg_platf_cluster_cbarg_t cluster,
- FatTreeNode *parent, unsigned int parentPort,
+void AsClusterFatTree::addLink(FatTreeNode *parent, unsigned int parentPort,
FatTreeNode *child, unsigned int childPort) {
FatTreeLink *newLink;
- newLink = new FatTreeLink(cluster, parent, child);
+ newLink = new FatTreeLink(this->cluster, child, parent);
XBT_DEBUG("Creating a link between the parent (%d,%d,%u)"
" and the child (%d,%d,%u)", parent->level, parent->position,
parentPort, child->level, child->position, childPort);
if (parameters.size() != 4){
surf_parse_error("Fat trees are defined by the levels number and 3 vectors"
", see the documentation for more informations");
- // Well, there's no doc, yet
}
// The first parts of topo_parameters should be the levels number
for(size_t i = 0 ; i < tmp.size() ; i++){
this->lowerLevelPortsNumber.push_back(std::atoi(tmp[i].c_str()));
}
+ this->cluster = cluster;
}
file.close();
}
else {
- std::cerr << "Unable to open file " << filename << std::endl;
+ XBT_DEBUG("Unable to open file %s", filename.c_str());
return;
}
}
-FatTreeNode::FatTreeNode(int id, int level, int position) : id(id),
- level(level),
- position(position){}
+FatTreeNode::FatTreeNode(sg_platf_cluster_cbarg_t cluster, int id, int level,
+ int position) : id(id), level(level),
+ position(position) {
+ s_sg_platf_link_cbarg_t linkTemplate;
+ if(cluster->limiter_link) {
+ memset(&linkTemplate, 0, sizeof(linkTemplate));
+ linkTemplate.bandwidth = cluster->limiter_link;
+ linkTemplate.latency = 0;
+ linkTemplate.state = SURF_RESOURCE_ON;
+ linkTemplate.policy = SURF_LINK_SHARED;
+ linkTemplate.id = bprintf("limiter_%d", id);
+ sg_platf_new_link(&linkTemplate);
+ this->limiterLink = (NetworkLink*) xbt_lib_get_or_null(link_lib,
+ linkTemplate.id,
+ SURF_LINK_LEVEL);
+ free((void*)linkTemplate.id);
+ }
+ if(cluster->loopback_bw || cluster->loopback_lat) {
+ memset(&linkTemplate, 0, sizeof(linkTemplate));
+ linkTemplate.bandwidth = cluster->loopback_bw;
+ linkTemplate.latency = cluster->loopback_lat;
+ linkTemplate.state = SURF_RESOURCE_ON;
+ linkTemplate.policy = SURF_LINK_FATPIPE;
+ linkTemplate.id = bprintf("loopback_%d", id);
+ sg_platf_new_link(&linkTemplate);
+ this->loopback = (NetworkLink*) xbt_lib_get_or_null(link_lib,
+ linkTemplate.id,
+ SURF_LINK_LEVEL);
+ free((void*)linkTemplate.id);
+ }
+}
-FatTreeLink::FatTreeLink(sg_platf_cluster_cbarg_t cluster, FatTreeNode *downNode,
+FatTreeLink::FatTreeLink(sg_platf_cluster_cbarg_t cluster,
+ FatTreeNode *downNode,
FatTreeNode *upNode) : upNode(upNode),
downNode(downNode) {
static int uniqueId = 0;
linkTemplate.bandwidth = cluster->bw;
linkTemplate.latency = cluster->lat;
linkTemplate.state = SURF_RESOURCE_ON;
- linkTemplate.policy = cluster->sharing_policy; // Maybe should we do sthg with that ?
- linkTemplate.id = bprintf("link_from_%d_to_%d_%d", downNode->id, upNode->id, uniqueId);
+ linkTemplate.policy = cluster->sharing_policy; // sthg to do with that ?
+ linkTemplate.id = bprintf("link_from_%d_to_%d_%d", downNode->id, upNode->id,
+ uniqueId);
sg_platf_new_link(&linkTemplate);
NetworkLink* link;
+ std::string tmpID;
if (cluster->sharing_policy == SURF_LINK_FULLDUPLEX) {
- std::string tmpID;
tmpID = std::string(linkTemplate.id) + "_UP";
- link = (NetworkLink*) xbt_lib_get_or_null(link_lib, tmpID.c_str(), SURF_LINK_LEVEL);
+ link = (NetworkLink*) xbt_lib_get_or_null(link_lib, tmpID.c_str(),
+ SURF_LINK_LEVEL);
this->upLink = link; // check link?
tmpID = std::string(linkTemplate.id) + "_DOWN";
- link = (NetworkLink*) xbt_lib_get_or_null(link_lib, tmpID.c_str(), SURF_LINK_LEVEL);
+ link = (NetworkLink*) xbt_lib_get_or_null(link_lib, tmpID.c_str(),
+ SURF_LINK_LEVEL);
this->downLink = link; // check link ?
}
else {
- link = (NetworkLink*) xbt_lib_get_or_null(link_lib, linkTemplate.id, SURF_LINK_LEVEL);
+ link = (NetworkLink*) xbt_lib_get_or_null(link_lib, linkTemplate.id,
+ SURF_LINK_LEVEL);
this->upLink = link;
this->downLink = link;
}
uniqueId++;
-
+ free((void*)linkTemplate.id);
}