* should certainly be checked for)
*/
+/* TODO : limiter link ? Loopback?
+ *
+ */
+class FatTreeNode;
+class FatTreeLink;
+/* \class FatTreeNode
+ * \brief A node in a fat tree
+ */
class FatTreeNode {
public:
- int id; // ID as given by the user, should be unique
- int level; // The 0th level represents the leafs of the PGFT
- int position; // Position in the level
-
- /* We can see the sizes sum of the two following vectors as the device
- * ports number. If we use the notations used in Zahavi's paper,
- * children.size() = m_level and parents.size() = w_(level+1)
- *
+ /* \brief Unique ID which identifies every node
+ */
+ int id;
+ /* \brief Level into the tree, with 0 being the leafs
+ */
+ unsigned int level;
+ /* \brief Position into the level, starting from 0
+ */
+ unsigned int position;
+ /* In order to link nodes between them, each one must be assigned a label,
+ * consisting of l integers, l being the levels number of the tree. Each label
+ * is unique in the level, and the way it is generated allows the construction
+ * of a fat tree which fits the desired topology
*/
- std::vector<FatTreeNode*> children; // m, apply from lvl 0 to levels - 1
- std::vector<FatTreeNode*> parents; // w, apply from lvl 1 to levels
- FatTreeNode(int id, int level=-1, int position=-1);
+ std::vector<unsigned int> label;
+
+ /* Links to the lower level, where the position in the vector corresponds to
+ * a port number.
+ */
+ std::vector<FatTreeLink*> children;
+ /* Links to the upper level, where the position in the vector corresponds to
+ * a port number.
+ */
+ std::vector<FatTreeLink*> parents;
+
+ NetworkLink* limiterLink;
+ NetworkLink* loopback;
+ FatTreeNode(sg_platf_cluster_cbarg_t cluster, int id, int level,
+ int position);
};
class FatTreeLink {
public:
- unsigned int ports;
- std::vector<s_sg_platf_link_cbarg_t> linksUp; // From source to destination
- std::vector<s_sg_platf_link_cbarg_t> linksDown; // From destination to source
- /* As it is symetric, it might as well be first / second instead
- * of source / destination
+ FatTreeLink(sg_platf_cluster_cbarg_t cluster, FatTreeNode *source,
+ FatTreeNode *destination);
+ /* Links are dependant of the chosen network model, but must implement
+ * NetworkLink
*/
- FatTreeNode *source;
- FatTreeNode *destination;
- //FatTreeLink(FatTreeNode *source, FatTreeNode *destination, unsigned int ports = 0);
+ NetworkLink *upLink;
+ NetworkLink *downLink;
+ FatTreeNode *upNode;
+ FatTreeNode *downNode;
};
class AsClusterFatTree : public AsCluster {
~AsClusterFatTree();
virtual void getRouteAndLatency(RoutingEdgePtr src, RoutingEdgePtr dst,
sg_platf_route_cbarg_t into,
- double *latency) const;
+ double *latency);
// virtual void getRouteAndLatency(const int src, const int dst,
// std::vector<NetworkLink> *route,
// double *latency) const;
- virtual void create_links(sg_platf_cluster_cbarg_t cluster);
+ virtual void create_links();
void parse_specific_arguments(sg_platf_cluster_cbarg_t cluster);
- void addNodes(std::vector<int> const& id);
+ void addProcessingNode(int id);
void generateDotFile(const string& filename = "fatTree.dot") const;
-protected:
+private:
+
//description of a PGFT (TODO : better doc)
unsigned int levels;
- std::vector<int> lowerLevelNodesNumber;
- std::vector<int> upperLevelNodesNumber;
- std::vector<int> lowerLevelPortsNumber;
+ std::vector<unsigned int> lowerLevelNodesNumber; // number of children by node
+ std::vector<unsigned int> upperLevelNodesNumber; // number of parents by node
+ std::vector<unsigned int> lowerLevelPortsNumber; // ports between each level l and l-1
+ std::map<int, FatTreeNode*> computeNodes;
std::vector<FatTreeNode*> nodes;
- std::map<std::pair<int,int>, FatTreeLink*> links;
- std::vector<int> nodesByLevel;
+ std::vector<FatTreeLink*> links;
+ std::vector<unsigned int> nodesByLevel;
+
+ sg_platf_cluster_cbarg_t cluster;
- void addLink(FatTreeNode *parent, FatTreeNode *child);
- void getLevelPosition(const int level, int &position, int &size);
+ void addLink(FatTreeNode *parent, unsigned int parentPort,
+ FatTreeNode *child, unsigned int childPort);
+ int getLevelPosition(const unsigned int level);
+ void generateLabels();
+ void generateSwitches();
+ int connectNodeToParents(FatTreeNode *node);
+ bool areRelated(FatTreeNode *parent, FatTreeNode *child);
+ bool isInSubTree(FatTreeNode *root, FatTreeNode *node);
};
#endif