#include "simgrid/kernel/routing/TorusZone.hpp"
#include "simgrid/kernel/routing/NetPoint.hpp"
+#include "simgrid/s4u/Host.hpp"
#include "src/surf/network_interface.hpp"
-#include "src/surf/xml/platf_private.hpp"
#include <boost/algorithm/string/classification.hpp>
#include <boost/algorithm/string/split.hpp>
+#include <numeric>
#include <string>
#include <vector>
namespace simgrid {
namespace kernel {
namespace routing {
-TorusZone::TorusZone(NetZoneImpl* father, const std::string& name, resource::NetworkModel* netmodel)
- : ClusterZone(father, name, netmodel)
-{
-}
-void TorusZone::create_links_for_node(ClusterCreationArgs* cluster, int id, int rank, unsigned int position)
+void TorusZone::create_torus_links(int id, int rank, unsigned int position)
{
/* Create all links that exist in the torus. Each rank creates @a dimensions-1 links */
int dim_product = 1; // Needed to calculate the next neighbor_id
for (unsigned int j = 0; j < dimensions_.size(); j++) {
- LinkCreationArgs link;
int current_dimension = dimensions_[j]; // which dimension are we currently in?
// we need to iterate over all dimensions and create all links there
// The other node the link connects
? rank - (current_dimension - 1) * dim_product
: rank + dim_product;
// name of neighbor is not right for non contiguous cluster radicals (as id != rank in this case)
- std::string link_id =
- std::string(cluster->id) + "_link_from_" + std::to_string(id) + "_to_" + std::to_string(neighbor_rank_id);
- link.id = link_id;
- link.bandwidths.push_back(cluster->bw);
- link.latency = cluster->lat;
- link.policy = cluster->sharing_policy;
- sg_platf_new_link(&link);
- resource::LinkImpl* linkUp;
- resource::LinkImpl* linkDown;
- if (link.policy == s4u::Link::SharingPolicy::SPLITDUPLEX) {
- linkUp = s4u::Link::by_name(link_id + "_UP")->get_impl();
- linkDown = s4u::Link::by_name(link_id + "_DOWN")->get_impl();
+ std::string link_id = get_name() + "_link_from_" + std::to_string(id) + "_to_" + std::to_string(neighbor_rank_id);
+ const s4u::Link* linkup;
+ const s4u::Link* linkdown;
+ if (get_link_sharing_policy() == s4u::Link::SharingPolicy::SPLITDUPLEX) {
+ linkup = create_link(link_id + "_UP", {get_link_bandwidth()})->set_latency(get_link_latency())->seal();
+ linkdown = create_link(link_id + "_DOWN", {get_link_bandwidth()})->set_latency(get_link_latency())->seal();
+
} else {
- linkUp = s4u::Link::by_name(link_id)->get_impl();
- linkDown = linkUp;
+ linkup = create_link(link_id, {get_link_bandwidth()})->set_latency(get_link_latency())->seal();
+ linkdown = linkup;
}
/*
* Add the link to its appropriate position.
* Note that position rankId*(xbt_dynar_length(dimensions)+has_loopback?+has_limiter?)
* holds the link "rankId->rankId"
*/
- private_links_.insert({position + j, {linkUp, linkDown}});
+ add_private_link_at(position + j, {linkup->get_impl(), linkdown->get_impl()});
dim_product *= current_dimension;
}
}
-void TorusZone::parse_specific_arguments(ClusterCreationArgs* cluster)
+std::vector<unsigned int> TorusZone::parse_topo_parameters(const std::string& topo_parameters)
{
- std::vector<std::string> dimensions;
- boost::split(dimensions, cluster->topo_parameters, boost::is_any_of(","));
+ std::vector<std::string> dimensions_str;
+ boost::split(dimensions_str, topo_parameters, boost::is_any_of(","));
+ std::vector<unsigned int> dimensions;
- if (not dimensions.empty()) {
- /* We are in a torus cluster
- * Parse attribute dimensions="dim1,dim2,dim3,...,dimN" and save them into a vector.
- * Additionally, we need to know how many ranks we have in total
- */
- for (auto const& group : dimensions)
- dimensions_.push_back(surf_parse_get_int(group));
+ /* We are in a torus cluster
+ * Parse attribute dimensions="dim1,dim2,dim3,...,dimN" and save them into a vector.
+ * Additionally, we need to know how many ranks we have in total
+ */
+ std::transform(begin(dimensions_str), end(dimensions_str), std::back_inserter(dimensions),
+ [](const std::string& s) { return std::stoi(s); });
- num_links_per_node_ = dimensions_.size();
- }
+ return dimensions;
}
-void TorusZone::get_local_route(NetPoint* src, NetPoint* dst, RouteCreationArgs* route, double* lat)
+void TorusZone::set_topology(const std::vector<unsigned int>& dimensions)
+{
+ xbt_assert(not dimensions.empty(), "Torus dimensions cannot be empty");
+ dimensions_ = dimensions;
+ set_num_links_per_node(dimensions_.size());
+}
+
+void TorusZone::get_local_route(const NetPoint* src, const NetPoint* dst, Route* route, double* lat)
{
XBT_VERB("torus getLocalRoute from '%s'[%u] to '%s'[%u]", src->get_cname(), src->id(), dst->get_cname(), dst->id());
if (dst->is_router() || src->is_router())
return;
- if (src->id() == dst->id() && has_loopback_) {
- std::pair<resource::LinkImpl*, resource::LinkImpl*> info = private_links_.at(src->id() * num_links_per_node_);
+ if (src->id() == dst->id() && has_loopback()) {
+ resource::LinkImpl* uplink = get_uplink_from(node_pos(src->id()));
- route->link_list.push_back(info.first);
- if (lat)
- *lat += info.first->get_latency();
+ add_link_latency(route->link_list_, uplink, lat);
return;
}
* Arrays that hold the coordinates of the current node and the target; comparing the values at the i-th position of
* both arrays, we can easily assess whether we need to route into this dimension or not.
*/
- const unsigned int dsize = dimensions_.size();
+ const unsigned long dsize = dimensions_.size();
std::vector<unsigned int> myCoords(dsize);
std::vector<unsigned int> targetCoords(dsize);
unsigned int dim_size_product = 1;
- for (unsigned i = 0; i < dsize; i++) {
+ for (unsigned long i = 0; i < dsize; i++) {
unsigned cur_dim_size = dimensions_[i];
myCoords[i] = (src->id() / dim_size_product) % cur_dim_size;
targetCoords[i] = (dst->id() / dim_size_product) % cur_dim_size;
* linkOffset describes the offset where the link we want to use is stored(+1 is added because each node has a link
* from itself to itself, which can only be the case if src->m_id == dst->m_id -- see above for this special case)
*/
- int nodeOffset = (dsize + 1) * src->id();
+ unsigned int linkOffset = (dsize + 1) * src->id();
- int linkOffset = nodeOffset;
bool use_lnk_up = false; // Is this link of the form "cur -> next" or "next -> cur"? false means: next -> cur
unsigned int current_node = src->id();
while (current_node != dst->id()) {
if ((current_node / dim_product) % cur_dim != (dst->id() / dim_product) % cur_dim) {
if ((targetCoords[j] > myCoords[j] &&
targetCoords[j] <= myCoords[j] + cur_dim / 2) // Is the target node on the right, without the wrap-around?
- || (myCoords[j] > cur_dim / 2 &&
- (myCoords[j] + cur_dim / 2) % cur_dim >=
- targetCoords[j])) { // Or do we need to use the wrap around to reach it?
+ ||
+ (myCoords[j] > cur_dim / 2 && (myCoords[j] + cur_dim / 2) % cur_dim >=
+ targetCoords[j])) { // Or do we need to use the wrap around to reach it?
if ((current_node / dim_product) % cur_dim == cur_dim - 1)
next_node = (current_node + dim_product - dim_product * cur_dim);
else
next_node = (current_node + dim_product);
// HERE: We use *CURRENT* node for calculation (as opposed to next_node)
- nodeOffset = current_node * (num_links_per_node_);
- linkOffset = nodeOffset + (has_loopback_ ? 1 : 0) + (has_limiter_ ? 1 : 0) + j;
+ linkOffset = node_pos_with_loopback_limiter(current_node) + j;
use_lnk_up = true;
- assert(linkOffset >= 0);
} else { // Route to the left
if ((current_node / dim_product) % cur_dim == 0)
next_node = (current_node - dim_product + dim_product * cur_dim);
next_node = (current_node - dim_product);
// HERE: We use *next* node for calculation (as opposed to current_node!)
- nodeOffset = next_node * (num_links_per_node_);
- linkOffset = nodeOffset + j + (has_loopback_ ? 1 : 0) + (has_limiter_ ? 1 : 0);
+ linkOffset = node_pos_with_loopback_limiter(next_node) + j;
use_lnk_up = false;
-
- assert(linkOffset >= 0);
}
- XBT_DEBUG("torus_get_route_and_latency - current_node: %u, next_node: %u, linkOffset is %i", current_node,
+ XBT_DEBUG("torus_get_route_and_latency - current_node: %u, next_node: %u, linkOffset is %u", current_node,
next_node, linkOffset);
break;
}
dim_product *= cur_dim;
}
- std::pair<resource::LinkImpl*, resource::LinkImpl*> info;
-
- if (has_limiter_) { // limiter for sender
- info = private_links_.at(nodeOffset + (has_loopback_ ? 1 : 0));
- route->link_list.push_back(info.first);
+ if (has_limiter()) { // limiter for sender
+ route->link_list_.push_back(get_uplink_from(node_pos_with_loopback(current_node)));
}
- info = private_links_.at(linkOffset);
- resource::LinkImpl* lnk = use_lnk_up ? info.first : info.second;
+ resource::LinkImpl* lnk;
+ if (use_lnk_up)
+ lnk = get_uplink_from(linkOffset);
+ else
+ lnk = get_downlink_to(linkOffset);
- route->link_list.push_back(lnk);
- if (lat)
- *lat += lnk->get_latency();
+ add_link_latency(route->link_list_, lnk, lat);
current_node = next_node;
}
+ if (has_limiter()) { // limiter for receiver/destination
+ route->link_list_.push_back(get_downlink_to(node_pos_with_loopback(dst->id())));
+ }
+ // set gateways (if any)
+ route->gw_src_ = get_gateway(src->id());
+ route->gw_dst_ = get_gateway(dst->id());
}
+
} // namespace routing
} // namespace kernel
+
+namespace s4u {
+
+NetZone* create_torus_zone(const std::string& name, const NetZone* parent, const std::vector<unsigned int>& dimensions,
+ const ClusterCallbacks& set_callbacks, double bandwidth, double latency,
+ Link::SharingPolicy sharing_policy)
+{
+ int tot_elements = std::accumulate(dimensions.begin(), dimensions.end(), 1, std::multiplies<>());
+ if (dimensions.empty() || tot_elements <= 0)
+ throw std::invalid_argument("TorusZone: incorrect dimensions parameter, each value must be > 0");
+ if (bandwidth <= 0)
+ throw std::invalid_argument("TorusZone: incorrect bandwidth for internode communication, bw=" +
+ std::to_string(bandwidth));
+ if (latency < 0)
+ throw std::invalid_argument("TorusZone: incorrect latency for internode communication, lat=" +
+ std::to_string(latency));
+
+ auto* zone = new kernel::routing::TorusZone(name);
+ zone->set_topology(dimensions);
+ if (parent)
+ zone->set_parent(parent->get_impl());
+
+ zone->set_link_characteristics(bandwidth, latency, sharing_policy);
+
+ for (int i = 0; i < tot_elements; i++) {
+ kernel::routing::NetPoint* netpoint;
+ Link* limiter;
+ Link* loopback;
+ zone->fill_leaf_from_cb(i, dimensions, set_callbacks, &netpoint, &loopback, &limiter);
+
+ zone->create_torus_links(netpoint->id(), i, zone->node_pos_with_loopback_limiter(netpoint->id()));
+ }
+
+ return zone->get_iface();
+}
+} // namespace s4u
+
} // namespace simgrid