#include <math.h>
static xbt_graph_t platform_graph = NULL;
+static xbt_dynar_t promoter_dynar = NULL;
+static xbt_dynar_t labeler_dynar = NULL;
static RngStream rng_stream = NULL;
for(i=0 ; i<node_count ; i++) {
context_node_t node_data = NULL;
- node_data = xbt_new(s_context_node_t, 1);
+ node_data = xbt_new0(s_context_node_t, 1);
node_data->id = i+1;
node_data->x = 0;
node_data->y = 0;
node1_data->degree++;
node2_data->degree++;
- unsigned long *link_id = xbt_new(unsigned long, 1);
- *link_id = ++last_link_id;
+ context_edge_t edge_data = NULL;
+ edge_data = xbt_new0(s_context_edge_t, 1);
+ edge_data->id = ++last_link_id;
+ edge_data->labeled = FALSE;
+ xbt_graph_new_edge(platform_graph, node1, node2, (void*)edge_data);
+}
- xbt_graph_new_edge(platform_graph, node1, node2, (void*)link_id);
+double platf_node_distance(xbt_node_t node1, xbt_node_t node2) {
+ context_node_t node1_data;
+ context_node_t node2_data;
+ double delta_x;
+ double delta_y;
+ double distance;
+ node1_data = (context_node_t) xbt_graph_node_get_data(node1);
+ node2_data = (context_node_t) xbt_graph_node_get_data(node2);
+ delta_x = node1_data->x - node2_data->x;
+ delta_y = node1_data->y - node2_data->y;
+ distance = sqrt(delta_x*delta_x + delta_y*delta_y);
+ return distance;
}
void platf_graph_uniform(unsigned long node_count) {
}
}
+void platf_graph_interconnect_ring(void) {
+ /* Create a simple topology where all nodes are connected along a ring */
+ xbt_dynar_t dynar_nodes = NULL;
+ xbt_node_t graph_node = NULL;
+ xbt_node_t old_node = NULL;
+ xbt_node_t first_node = NULL;
+ unsigned int i;
+ dynar_nodes = xbt_graph_get_nodes(platform_graph);
+ xbt_dynar_foreach(dynar_nodes, i, graph_node) {
+ if(i == 0) {
+ // this is the first node, let's keep it somewhere
+ first_node = graph_node;
+ } else {
+ //connect each node to the previous one
+ platf_node_connect(graph_node, old_node);
+ }
+ old_node = graph_node;
+ }
+ //we still have to connect the first and the last node together
+ platf_node_connect(first_node, graph_node);
+}
+
+void platf_graph_interconnect_clique(void) {
+ /* Create a simple topology where all nodes are connected to each other, in a clique manner */
+ xbt_dynar_t dynar_nodes = NULL;
+ xbt_node_t first_node = NULL;
+ xbt_node_t second_node = NULL;
+ unsigned int i,j;
+
+ dynar_nodes = xbt_graph_get_nodes(platform_graph);
+ xbt_dynar_foreach(dynar_nodes, i, first_node) {
+ xbt_dynar_foreach(dynar_nodes, j, second_node) {
+ platf_node_connect(first_node, second_node);
+ }
+ }
+}
+
+void platf_graph_interconnect_uniform(double alpha) {
+ /* Creates a topology where the probability to connect two nodes is uniform (unrealistic, but simple)
+ alpha : Probability for two nodes to get connected */
+ xbt_dynar_t dynar_nodes = NULL;
+ xbt_node_t first_node = NULL;
+ xbt_node_t second_node = NULL;
+ unsigned int i,j;
+
+ dynar_nodes = xbt_graph_get_nodes(platform_graph);
+ xbt_dynar_foreach(dynar_nodes, i, first_node) {
+ xbt_dynar_foreach(dynar_nodes, j, second_node) {
+ if(j>=i)
+ break;
+ if(RngStream_RandU01(rng_stream) < alpha) {
+ platf_node_connect(first_node, second_node);
+ }
+ }
+ }
+}
+
+void platf_graph_interconnect_exponential(double alpha) {
+ /* Create a topology where the probability follows an exponential law
+ Number of edges increases with alpha */
+ xbt_dynar_t dynar_nodes = NULL;
+ xbt_node_t first_node = NULL;
+ xbt_node_t second_node = NULL;
+ unsigned int i,j;
+ double L = sqrt(2.0); /* L = c*sqrt(2); c=side of placement square */
+ dynar_nodes = xbt_graph_get_nodes(platform_graph);
+ xbt_dynar_foreach(dynar_nodes, i, first_node) {
+ xbt_dynar_foreach(dynar_nodes, j, second_node) {
+ if(j>=i)
+ break;
+ double d = platf_node_distance(first_node, second_node);
+ if(RngStream_RandU01(rng_stream) < alpha*exp(-d/(L-d))) {
+ platf_node_connect(first_node, second_node);
+ }
+ }
+ }
+}
+
+void platf_graph_interconnect_zegura(double alpha, double beta, double r) {
+ /* Create a topology where the probability follows the model of Zegura
+ * (see Zegura, Calvert, Donahoo, A quantitative comparison of graph-based models
+ * for Internet topology, IEEE/ACM Transactions on Networking, 1997.)
+ *
+ * alpha : Probability of connexion for short edges
+ * beta : Probability of connexion for long edges
+ * r : Limit between long and short edges (between 0 and sqrt(2) since nodes are placed on the unit square)
+ */
+ xbt_dynar_t dynar_nodes = NULL;
+ xbt_node_t first_node = NULL;
+ xbt_node_t second_node = NULL;
+ unsigned int i,j;
+ dynar_nodes = xbt_graph_get_nodes(platform_graph);
+ xbt_dynar_foreach(dynar_nodes, i, first_node) {
+ xbt_dynar_foreach(dynar_nodes, j, second_node) {
+ if(j>=i)
+ break;
+ double d = platf_node_distance(first_node, second_node);
+ double proba = d < r ? alpha : beta;
+ if(RngStream_RandU01(rng_stream) < proba) {
+ platf_node_connect(first_node, second_node);
+ }
+ }
+ }
+}
+
+void platf_graph_interconnect_barabasi(void) {
+ /* Create a topology constructed according to the Barabasi-Albert algorithm (follows power laws)
+ (see Barabasi and Albert, Emergence of scaling in random networks, Science 1999, num 59, p509-512.) */
+ xbt_dynar_t dynar_nodes = NULL;
+ xbt_node_t first_node = NULL;
+ xbt_node_t second_node = NULL;
+ context_node_t node_data = NULL;
+ unsigned int i,j;
+ unsigned long sum = 0;
+ dynar_nodes = xbt_graph_get_nodes(platform_graph);
+ xbt_dynar_foreach(dynar_nodes, i, first_node) {
+ xbt_dynar_foreach(dynar_nodes, j, second_node) {
+ if(j>=i)
+ break;
+ node_data = xbt_graph_node_get_data(second_node);
+ if(sum==0 || RngStream_RandU01(rng_stream) < ((double)(node_data->degree)/ (double)sum)) {
+ platf_node_connect(first_node, second_node);
+ sum += 2;
+ }
+ }
+ }
+}
+
+void platf_graph_promote_to_host(context_node_t node, sg_platf_host_cbarg_t parameters) {
+ node->kind = HOST;
+ memcpy(&(node->host_parameters), parameters, sizeof(s_sg_platf_host_cbarg_t));
+}
+
+void platf_graph_promote_to_cluster(context_node_t node, sg_platf_cluster_cbarg_t parameters) {
+ node->kind = CLUSTER;
+ memcpy(&(node->cluster_parameters), parameters, sizeof(s_sg_platf_cluster_cbarg_t));
+}
+
+void platf_graph_link_label(context_edge_t edge, sg_platf_link_cbarg_t parameters) {
+ memcpy(&(edge->link_parameters), parameters, sizeof(s_sg_platf_link_cbarg_t));
+}
+
+void platf_graph_promoter(platf_promoter_cb_t promoter_callback) {
+ if(promoter_dynar == NULL) {
+ promoter_dynar = xbt_dynar_new(sizeof(platf_promoter_cb_t), NULL);
+ }
+ xbt_dynar_push(promoter_dynar, &promoter_callback);
+}
+
+void platf_graph_labeler(platf_labeler_cb_t labeler_callback) {
+ if(labeler_dynar == NULL) {
+ labeler_dynar = xbt_dynar_new(sizeof(void*), NULL);
+ }
+ xbt_dynar_push(labeler_dynar, &labeler_callback);
+}
+
+void platf_do_promote(void) {
+ platf_promoter_cb_t promoter_callback;
+ xbt_node_t graph_node = NULL;
+ xbt_dynar_t dynar_nodes = NULL;
+ context_node_t node = NULL;
+ unsigned int i, j;
+ dynar_nodes = xbt_graph_get_nodes(platform_graph);
+ xbt_dynar_foreach(dynar_nodes, i, graph_node) {
+ node = (context_node_t) xbt_graph_node_get_data(graph_node);
+ xbt_dynar_foreach(promoter_dynar, j, promoter_callback) {
+ if(node->kind != ROUTER)
+ break;
+ promoter_callback(node);
+ }
+ }
+}
+
+void platf_do_label(void) {
+ platf_labeler_cb_t labeler_callback;
+ xbt_edge_t graph_edge = NULL;
+ xbt_dynar_t dynar_edges = NULL;
+ context_edge_t edge = NULL;
+ unsigned int i, j;
+ dynar_edges = xbt_graph_get_edges(platform_graph);
+ xbt_dynar_foreach(dynar_edges, i, graph_edge) {
+ edge = (context_edge_t) xbt_graph_edge_get_data(graph_edge);
+ xbt_dynar_foreach(promoter_dynar, j, labeler_callback) {
+ if(edge->labeled == TRUE)
+ break;
+ labeler_callback(edge);
+ }
+ }
+}
/* Functions used to generate interesting random values */