dragonfly.c 61.4 KB
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/*
 * Copyright (C) 2013 University of Chicago.
 * See COPYRIGHT notice in top-level directory.
 *
 */

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// Local router ID: 0 --- total_router-1
// Router LP ID 
// Terminal LP ID

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#include <ross.h>

#include "codes/codes_mapping.h"
#include "codes/codes.h"
#include "codes/model-net.h"
#include "codes/model-net-method.h"
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#include "codes/model-net-lp.h"
#include "codes/net/dragonfly.h"
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#define CREDIT_SIZE 8
#define MEAN_PROCESS 1.0

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/* collective specific parameters */
#define TREE_DEGREE 4
#define LEVEL_DELAY 1000
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#define DRAGONFLY_COLLECTIVE_DEBUG 0
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#define NUM_COLLECTIVES  1
#define COLLECTIVE_COMPUTATION_DELAY 5700
#define DRAGONFLY_FAN_OUT_DELAY 20.0

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// debugging parameters
#define TRACK 235221
#define PRINT_ROUTER_TABLE 1
#define DEBUG 1

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#define LP_CONFIG_NM (model_net_lp_config_names[DRAGONFLY])
#define LP_METHOD_NM (model_net_method_names[DRAGONFLY])

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static double maxd(double a, double b) { return a < b ? b : a; }

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// arrival rate
static double MEAN_INTERVAL=200.0;
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// threshold for adaptive routing
static int adaptive_threshold = 10;
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/* minimal and non-minimal packet counts for adaptive routing*/
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int minimal_count=0, nonmin_count=0;
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typedef struct dragonfly_param dragonfly_param;
/* annotation-specific parameters (unannotated entry occurs at the 
 * last index) */
static uint64_t                  num_params = 0;
static dragonfly_param         * all_params = NULL;
static const config_anno_map_t * anno_map   = NULL;
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/* global variables for codes mapping */
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static char lp_group_name[MAX_NAME_LENGTH];
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static int mapping_grp_id, mapping_type_id, mapping_rep_id, mapping_offset;

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struct dragonfly_param
{
    // configuration parameters
    int num_routers; /*Number of routers in a group*/
    double local_bandwidth;/* bandwidth of the router-router channels within a group */
    double global_bandwidth;/* bandwidth of the inter-group router connections */
    double cn_bandwidth;/* bandwidth of the compute node channels connected to routers */
    int num_vcs; /* number of virtual channels */
    int local_vc_size; /* buffer size of the router-router channels */
    int global_vc_size; /* buffer size of the global channels */
    int cn_vc_size; /* buffer size of the compute node channels */
    int routing; /* minimal or non-minimal routing */
    int chunk_size; /* full-sized packets are broken into smaller chunks.*/

    // derived parameters
    int num_cn;
    int num_groups;
    int radix;
    int total_routers;
    int num_global_channels;
};

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/* handles terminal and router events like packet generate/send/receive/buffer */
typedef enum event_t event_t;

typedef struct terminal_state terminal_state;
typedef struct router_state router_state;

/* dragonfly compute node data structure */
struct terminal_state
{
   unsigned long long packet_counter;

   // Dragonfly specific parameters
   unsigned int router_id;
   unsigned int terminal_id;

   // Each terminal will have an input and output channel with the router
   int* vc_occupancy; // NUM_VC
   int* output_vc_state;
   tw_stime terminal_available_time;
   tw_stime next_credit_available_time;
// Terminal generate, sends and arrival T_SEND, T_ARRIVAL, T_GENERATE
// Router-Router Intra-group sends and receives RR_LSEND, RR_LARRIVE
// Router-Router Inter-group sends and receives RR_GSEND, RR_GARRIVE
   struct mn_stats dragonfly_stats_array[CATEGORY_MAX];
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  /* collective init time */
  tw_stime collective_init_time;

  /* node ID in the tree */ 
   tw_lpid node_id;

   /* messages sent & received in collectives may get interchanged several times so we have to save the 
     origin server information in the node's state */
   tw_lpid origin_svr; 
  
  /* parent node ID of the current node */
   tw_lpid parent_node_id;
   /* array of children to be allocated in terminal_init*/
   tw_lpid* children;

   /* children of a node can be less than or equal to the tree degree */
   int num_children;

   short is_root;
   short is_leaf;

   /* to maintain a count of child nodes that have fanned in at the parent during the collective
      fan-in phase*/
   int num_fan_nodes;
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   const char * anno;
   const dragonfly_param *params;
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};
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/* terminal event type (1-4) */
enum event_t
{
  T_GENERATE=1,
  T_ARRIVE,
  T_SEND,
  T_BUFFER,
  R_SEND,
  R_ARRIVE,
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  R_BUFFER,
  D_COLLECTIVE_INIT,
  D_COLLECTIVE_FAN_IN,
  D_COLLECTIVE_FAN_OUT
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};
/* status of a virtual channel can be idle, active, allocated or wait for credit */
enum vc_status
{
   VC_IDLE,
   VC_ACTIVE,
   VC_ALLOC,
   VC_CREDIT
};

/* whether the last hop of a packet was global, local or a terminal */
enum last_hop
{
   GLOBAL,
   LOCAL,
   TERMINAL
};

/* three forms of routing algorithms available, adaptive routing is not
 * accurate and fully functional in the current version as the formulas
 * for detecting load on global channels are not very accurate */
enum ROUTING_ALGO
{
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    MINIMAL = 0,
    NON_MINIMAL,
    ADAPTIVE
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};

struct router_state
{
   unsigned int router_id;
   unsigned int group_id;
  
   int* global_channel; 
   tw_stime* next_output_available_time;
   tw_stime* next_credit_available_time;
   int* vc_occupancy;
   int* output_vc_state;
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   const char * anno;
   const dragonfly_param *params;
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};

static short routing = MINIMAL;

static tw_stime         dragonfly_total_time = 0;
static tw_stime         dragonfly_max_latency = 0;
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static tw_stime         max_collective = 0;
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static long long       total_hops = 0;
static long long       N_finished_packets = 0;

/* returns the dragonfly router lp type for lp registration */
static const tw_lptype* dragonfly_get_router_lp_type(void);

/* returns the dragonfly message size */
static int dragonfly_get_msg_sz(void)
{
	   return sizeof(terminal_message);
}

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static void dragonfly_read_config(const char * anno, dragonfly_param *params){
    // shorthand
    dragonfly_param *p = params;
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    configuration_get_value_int(&config, "PARAMS", "num_routers", anno,
            &p->num_routers);
    if(p->num_routers <= 0) {
        p->num_routers = 4;
        fprintf(stderr, "Number of dimensions not specified, setting to %d\n",
                p->num_routers);
    }

    configuration_get_value_int(&config, "PARAMS", "num_vcs", anno,
            &p->num_vcs);
    if(p->num_vcs <= 0) {
        p->num_vcs = 1;
        fprintf(stderr, "Number of virtual channels not specified, setting to %d\n", p->num_vcs);
    }

    configuration_get_value_int(&config, "PARAMS", "local_vc_size", anno, &p->local_vc_size);
    if(!p->local_vc_size) {
        p->local_vc_size = 1024;
        fprintf(stderr, "Buffer size of local channels not specified, setting to %d\n", p->local_vc_size);
    }

    configuration_get_value_int(&config, "PARAMS", "global_vc_size", anno, &p->global_vc_size);
    if(!p->global_vc_size) {
        p->global_vc_size = 2048;
        fprintf(stderr, "Buffer size of global channels not specified, setting to %d\n", p->global_vc_size);
    }

    configuration_get_value_int(&config, "PARAMS", "cn_vc_size", anno, &p->cn_vc_size);
    if(!p->cn_vc_size) {
        p->cn_vc_size = 1024;
        fprintf(stderr, "Buffer size of compute node channels not specified, setting to %d\n", p->cn_vc_size);
    }

    configuration_get_value_int(&config, "PARAMS", "chunk_size", anno, &p->chunk_size);
    if(!p->chunk_size) {
        p->chunk_size = 64;
        fprintf(stderr, "Chunk size for packets is specified, setting to %d\n", p->chunk_size);
    }

    configuration_get_value_double(&config, "PARAMS", "local_bandwidth", anno, &p->local_bandwidth);
    if(!p->local_bandwidth) {
        p->local_bandwidth = 5.25;
        fprintf(stderr, "Bandwidth of local channels not specified, setting to %lf\n", p->local_bandwidth);
    }

    configuration_get_value_double(&config, "PARAMS", "global_bandwidth", anno, &p->global_bandwidth);
    if(!p->global_bandwidth) {
        p->global_bandwidth = 4.7;
        fprintf(stderr, "Bandwidth of global channels not specified, setting to %lf\n", p->global_bandwidth);
    }

    configuration_get_value_double(&config, "PARAMS", "cn_bandwidth", anno, &p->cn_bandwidth);
    if(!p->cn_bandwidth) {
        p->cn_bandwidth = 5.25;
        fprintf(stderr, "Bandwidth of compute node channels not specified, setting to %lf\n", p->cn_bandwidth);
    }


    char routing[MAX_NAME_LENGTH];
    configuration_get_value(&config, "PARAMS", "routing", anno, routing,
            MAX_NAME_LENGTH);
    if(strcmp(routing, "minimal") == 0)
        p->routing = 0;
    else if(strcmp(routing, "nonminimal")==0 || strcmp(routing,"non-minimal")==0)
        p->routing = 1;
    else if (strcmp(routing, "adaptive") == 0)
        p->routing = 2;
    else
    {
        fprintf(stderr, 
                "No routing protocol specified, setting to minimal routing\n");
        p->routing = 0;
    }

    // set the derived parameters
    p->num_cn = p->num_routers/2;
    p->num_global_channels = p->num_routers/2;
    p->num_groups = p->num_routers * p->num_cn + 1;
    p->radix = p->num_vcs *
        (p->num_cn + p->num_global_channels + p->num_routers);
    p->total_routers = p->num_groups * p->num_routers;
}

static void dragonfly_configure(){
    anno_map = codes_mapping_get_lp_anno_map(LP_CONFIG_NM);
    assert(anno_map);
    num_params = anno_map->num_annos + (anno_map->has_unanno_lp > 0);
    all_params = malloc(num_params * sizeof(*all_params));

    for (uint64_t i = 0; i < anno_map->num_annos; i++){
        const char * anno = anno_map->annotations[i];
        dragonfly_read_config(anno, &all_params[i]);
    }
    if (anno_map->has_unanno_lp > 0){
        dragonfly_read_config(NULL, &all_params[anno_map->num_annos]);
    }
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}

/* report dragonfly statistics like average and maximum packet latency, average number of hops traversed */
static void dragonfly_report_stats()
{
/* TODO: Add dragonfly packet average, maximum latency and average number of hops traversed */
   long long avg_hops, total_finished_packets;
   tw_stime avg_time, max_time;
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   int total_minimal_packets, total_nonmin_packets;
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   MPI_Reduce( &total_hops, &avg_hops, 1, MPI_LONG_LONG, MPI_SUM, 0, MPI_COMM_WORLD);
   MPI_Reduce( &N_finished_packets, &total_finished_packets, 1, MPI_LONG_LONG, MPI_SUM, 0, MPI_COMM_WORLD);
   MPI_Reduce( &dragonfly_total_time, &avg_time, 1,MPI_DOUBLE, MPI_SUM, 0, MPI_COMM_WORLD);
   MPI_Reduce( &dragonfly_max_latency, &max_time, 1, MPI_DOUBLE, MPI_MAX, 0, MPI_COMM_WORLD);
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   if(routing == ADAPTIVE)
    {
	MPI_Reduce(&minimal_count, &total_minimal_packets, 1, MPI_INT, MPI_SUM, 0, MPI_COMM_WORLD);
 	MPI_Reduce(&nonmin_count, &total_nonmin_packets, 1, MPI_INT, MPI_SUM, 0, MPI_COMM_WORLD);
    }
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   /* print statistics */
   if(!g_tw_mynode)
   {
      printf(" Average number of hops traversed %f average message latency %lf us maximum message latency %lf us \n", (float)avg_hops/total_finished_packets, avg_time/(total_finished_packets*1000), max_time/1000);
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     if(routing == ADAPTIVE)
              printf("\n ADAPTIVE ROUTING STATS: %d packets routed minimally %d packets routed non-minimally ", total_minimal_packets, total_nonmin_packets);
 
  }
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   return;
}
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void dragonfly_collective_init(terminal_state * s,
           		   tw_lp * lp)
{
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    // TODO: be annotation-aware
    codes_mapping_get_lp_info(lp->gid, lp_group_name, &mapping_grp_id, NULL,
            &mapping_type_id, NULL, &mapping_rep_id, &mapping_offset);
    int num_lps = codes_mapping_get_lp_count(lp_group_name, 1, LP_CONFIG_NM,
            NULL, 1);
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    int num_reps = codes_mapping_get_group_reps(lp_group_name);
    s->node_id = (mapping_rep_id * num_lps) + mapping_offset;

    int i;
   /* handle collective operations by forming a tree of all the LPs */
   /* special condition for root of the tree */
   if( s->node_id == 0)
    {
        s->parent_node_id = -1;
        s->is_root = 1;
   }
   else
   {
       s->parent_node_id = (s->node_id - ((s->node_id - 1) % TREE_DEGREE)) / TREE_DEGREE;
       s->is_root = 0;
   }
   s->children = (tw_lpid*)malloc(TREE_DEGREE * sizeof(tw_lpid));

   /* set the isleaf to zero by default */
   s->is_leaf = 1;
   s->num_children = 0;

   /* calculate the children of the current node. If its a leaf, no need to set children,
      only set isleaf and break the loop*/

   for( i = 0; i < TREE_DEGREE; i++ )
    {
        tw_lpid next_child = (TREE_DEGREE * s->node_id) + i + 1;
        if(next_child < (num_lps * num_reps))
        {
            s->num_children++;
            s->is_leaf = 0;
            s->children[i] = next_child;
        }
        else
           s->children[i] = -1;
    }

#if DRAGONFLY_COLLECTIVE_DEBUG == 1
   printf("\n LP %ld parent node id ", s->node_id);

   for( i = 0; i < TREE_DEGREE; i++ )
        printf(" child node ID %ld ", s->children[i]);
   printf("\n");

   if(s->is_leaf)
        printf("\n LP %ld is leaf ", s->node_id);
#endif
}

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/* dragonfly packet event , generates a dragonfly packet on the compute node */
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static tw_stime dragonfly_packet_event(char* category, tw_lpid final_dest_lp, uint64_t packet_size, int is_pull, uint64_t pull_size, tw_stime offset, const mn_sched_params *sched_params, int remote_event_size, const void* remote_event, int self_event_size, const void* self_event, tw_lpid src_lp, tw_lp *sender, int is_last_pckt)
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{
    tw_event * e_new;
    tw_stime xfer_to_nic_time;
    terminal_message * msg;
    char* tmp_ptr;

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    xfer_to_nic_time = codes_local_latency(sender); /* Throws an error of found last KP time > current event time otherwise when LPs of one type are placed together*/
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    //printf("\n transfer in time %f %f ", xfer_to_nic_time+offset, tw_now(sender));
    //e_new = tw_event_new(sender->gid, xfer_to_nic_time+offset, sender);
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    //msg = tw_event_data(e_new);
    e_new = model_net_method_event_new(sender->gid, xfer_to_nic_time+offset,
            sender, DRAGONFLY, (void**)&msg, (void**)&tmp_ptr);
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    strcpy(msg->category, category);
    msg->final_dest_gid = final_dest_lp;
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    msg->sender_lp=src_lp;
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    msg->packet_size = packet_size;
    msg->remote_event_size_bytes = 0;
    msg->local_event_size_bytes = 0;
    msg->type = T_GENERATE;
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    msg->is_pull = is_pull;
    msg->pull_size = pull_size;
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    if(is_last_pckt) /* Its the last packet so pass in remote and local event information*/
      {
	if(remote_event_size > 0)
	 {
		msg->remote_event_size_bytes = remote_event_size;
		memcpy(tmp_ptr, remote_event, remote_event_size);
		tmp_ptr += remote_event_size;
	}
	if(self_event_size > 0)
	{
		msg->local_event_size_bytes = self_event_size;
		memcpy(tmp_ptr, self_event, self_event_size);
		tmp_ptr += self_event_size;
	}
     }
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	   //printf("\n dragonfly remote event %d local event %d last packet %d %lf ", msg->remote_event_size_bytes, msg->local_event_size_bytes, is_last_pckt, xfer_to_nic_time);
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    tw_event_send(e_new);
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    return xfer_to_nic_time;
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}

/* dragonfly packet event reverse handler */
static void dragonfly_packet_event_rc(tw_lp *sender)
{
	  codes_local_latency_reverse(sender);
	    return;
}

/* given a group ID gid, find the router in the current group that is attached
 * to a router in the group gid */
tw_lpid getRouterFromGroupID(int gid, 
		    router_state * r)
{
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    const dragonfly_param *p = r->params;
  int group_begin = r->group_id * p->num_routers;
  int group_end = (r->group_id * p->num_routers) + p->num_routers-1;
  int offset = (gid * p->num_routers - group_begin) / p->num_routers;
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  if((gid * p->num_routers) < group_begin)
    offset = (group_begin - gid * p->num_routers) / p->num_routers; // take absolute value
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  int half_channel = p->num_global_channels / 2;
  int index = (offset - 1)/(half_channel * p->num_routers);
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  offset=(offset - 1) % (half_channel * p->num_routers);
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  // If the destination router is in the same group
  tw_lpid router_id;

  if(index % 2 != 0)
    router_id = group_end - (offset / half_channel); // start from the end
  else
    router_id = group_begin + (offset / half_channel);

  return router_id;
}	

/*When a packet is sent from the current router and a buffer slot becomes available, a credit is sent back to schedule another packet event*/
void router_credit_send(router_state * s, tw_bf * bf, terminal_message * msg, tw_lp * lp)
{
  tw_event * buf_e;
  tw_stime ts;
  terminal_message * buf_msg;

  int dest=0, credit_delay=0, type = R_BUFFER;
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  int is_terminal = 0;
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  const dragonfly_param *p = s->params;
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 // Notify sender terminal about available buffer space
  if(msg->last_hop == TERMINAL)
  {
   dest = msg->src_terminal_id;
   //determine the time in ns to transfer the credit
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   credit_delay = (1 / p->cn_bandwidth) * CREDIT_SIZE;
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   type = T_BUFFER;
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   is_terminal = 1;
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  }
   else if(msg->last_hop == GLOBAL)
   {
     dest = msg->intm_lp_id;
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     credit_delay = (1 / p->global_bandwidth) * CREDIT_SIZE;
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   }
    else if(msg->last_hop == LOCAL)
     {
        dest = msg->intm_lp_id;
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     	credit_delay = (1/p->local_bandwidth) * CREDIT_SIZE;
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     }
    else
      printf("\n Invalid message type");

   // Assume it takes 0.1 ns of serialization latency for processing the credits in the queue
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    int output_port = msg->saved_vc / p->num_vcs;
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    msg->saved_available_time = s->next_credit_available_time[output_port];
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    s->next_credit_available_time[output_port] = maxd(tw_now(lp), s->next_credit_available_time[output_port]);
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    ts = credit_delay + 0.1 + tw_rand_exponential(lp->rng, (double)credit_delay/1000);
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    s->next_credit_available_time[output_port]+=ts;
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    if (is_terminal){
        buf_e = model_net_method_event_new(dest, 
                s->next_credit_available_time[output_port] - tw_now(lp), lp,
                DRAGONFLY, (void**)&buf_msg, NULL);
    }
    else{
        buf_e = tw_event_new(dest, s->next_credit_available_time[output_port] - tw_now(lp) , lp);
        buf_msg = tw_event_data(buf_e);
    }
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    buf_msg->vc_index = msg->saved_vc;
    buf_msg->type=type;
    buf_msg->last_hop = msg->last_hop;
    buf_msg->packet_ID=msg->packet_ID;

    tw_event_send(buf_e);

    return;
}

/* generates packet at the current dragonfly compute node */
void packet_generate(terminal_state * s, tw_bf * bf, terminal_message * msg, tw_lp * lp)
{
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    tw_lpid dest_terminal_id;
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    dest_terminal_id = model_net_find_local_device(DRAGONFLY, s->anno, 0,
            msg->final_dest_gid);
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    msg->dest_terminal_id = dest_terminal_id;

    const dragonfly_param *p = s->params;

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  tw_stime ts;
  tw_event *e;
  terminal_message *m;
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  int i, total_event_size;
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  uint64_t num_chunks = msg->packet_size / p->chunk_size;
  if (msg->packet_size % s->params->chunk_size)
      num_chunks++;
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  msg->packet_ID = lp->gid + g_tw_nlp * s->packet_counter + tw_rand_integer(lp->rng, 0, lp->gid + g_tw_nlp * s->packet_counter);
  msg->travel_start_time = tw_now(lp);
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  msg->my_N_hop = 0;
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  for(i = 0; i < num_chunks; i++)
  {
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	  // Before
	  // msg->my_N_hop = 0; generating a packet, check if the input queue is available
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        ts = g_tw_lookahead + 0.1 + tw_rand_exponential(lp->rng, MEAN_INTERVAL/200);
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	int chan = -1, j;
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	for(j = 0; j < p->num_vcs; j++)
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	 {
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	     if(s->vc_occupancy[j] < p->cn_vc_size * num_chunks)
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	      {
	       chan=j;
	       break;
	      }
         }

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        // this is a terminal event, so use the method-event version
       //e = tw_event_new(lp->gid, i + ts, lp);
       //m = tw_event_data(e);
       //memcpy(m, msg, sizeof(terminal_message) + msg->remote_event_size_bytes + msg->local_event_size_bytes);
       void * m_data;
       e = model_net_method_event_new(lp->gid, i+ts, lp, DRAGONFLY,
               (void**)&m, &m_data);
       memcpy(m, msg, sizeof(terminal_message));
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       m->dest_terminal_id = dest_terminal_id;
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       void * m_data_src = model_net_method_get_edata(DRAGONFLY, msg);
       if (msg->remote_event_size_bytes){
            memcpy(m_data, m_data_src, msg->remote_event_size_bytes);
       }
       if (msg->local_event_size_bytes){ 
            memcpy((char*)m_data + msg->remote_event_size_bytes,
                    (char*)m_data_src + msg->remote_event_size_bytes,
                    msg->local_event_size_bytes);
       }
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       m->intm_group_id = -1;
       m->saved_vc=0;
       m->chunk_id = i;
       
       if(msg->packet_ID == TRACK && msg->chunk_id == num_chunks-1)
         printf("\n packet generated %lld at terminal %d chunk id %d ", msg->packet_ID, (int)lp->gid, i);
       
       m->output_chan = -1;
       if(chan != -1) // If the input queue is available
   	{
	    // Send the packet out
	     m->type = T_SEND;
 	     tw_event_send(e);
        }
      else
         {
	  printf("\n Exceeded queue size, exitting %d", s->vc_occupancy[0]);
	  MPI_Finalize();
	  exit(-1);
        } //else
  } // for
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  total_event_size = model_net_get_msg_sz(DRAGONFLY) + 
      msg->remote_event_size_bytes + msg->local_event_size_bytes;
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  mn_stats* stat;
  stat = model_net_find_stats(msg->category, s->dragonfly_stats_array);
  stat->send_count++;
  stat->send_bytes += msg->packet_size;
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  stat->send_time += (1/p->cn_bandwidth) * msg->packet_size;
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  if(stat->max_event_size < total_event_size)
	  stat->max_event_size = total_event_size;
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  return;
}

/* sends the packet from the current dragonfly compute node to the attached router */
void packet_send(terminal_state * s, tw_bf * bf, terminal_message * msg, tw_lp * lp)
{
  tw_stime ts;
  tw_event *e;
  terminal_message *m;
  tw_lpid router_id;
  /* Route the packet to its source router */ 
   int vc=msg->saved_vc;

   //  Each packet is broken into chunks and then sent over the channel
   msg->saved_available_time = s->terminal_available_time;
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   double head_delay = (1/s->params->cn_bandwidth) * s->params->chunk_size;
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   ts = head_delay + tw_rand_exponential(lp->rng, (double)head_delay/200);
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   s->terminal_available_time = maxd(s->terminal_available_time, tw_now(lp));
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   s->terminal_available_time += ts;

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   //TODO: be annotation-aware
   codes_mapping_get_lp_info(lp->gid, lp_group_name, &mapping_grp_id, NULL,
           &mapping_type_id, NULL, &mapping_rep_id, &mapping_offset);
   codes_mapping_get_lp_id(lp_group_name, "dragonfly_router", NULL, 1,
           s->router_id, 0, &router_id);
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   // we are sending an event to the router, so no method_event here
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   e = tw_event_new(router_id, s->terminal_available_time - tw_now(lp), lp);

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   uint64_t num_chunks = msg->packet_size/s->params->chunk_size;
   if(msg->packet_size % s->params->chunk_size)
       num_chunks++;

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   if(msg->packet_ID == TRACK && msg->chunk_id == num_chunks-1)
     printf("\n terminal %d packet %lld chunk %d being sent to router %d router id %d ", (int)lp->gid, (long long)msg->packet_ID, msg->chunk_id, (int)router_id, s->router_id);
   m = tw_event_data(e);
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   memcpy(m, msg, sizeof(terminal_message));
   if (msg->remote_event_size_bytes){
        memcpy(m+1, model_net_method_get_edata(DRAGONFLY, msg),
                msg->remote_event_size_bytes);
   }
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   m->type = R_ARRIVE;
   m->src_terminal_id = lp->gid;
   m->saved_vc = vc;
   m->last_hop = TERMINAL;
   m->intm_group_id = -1;
   m->local_event_size_bytes = 0;
   tw_event_send(e);
//  Each chunk is 32B and the VC occupancy is in chunks to enable efficient flow control

   if(msg->chunk_id == num_chunks - 1) 
    {
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      // now that message is sent, issue an "idle" event to tell the scheduler
      // when I'm next available
      model_net_method_idle_event(codes_local_latency(lp) +
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              s->terminal_available_time - tw_now(lp), 0, lp);
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      /* local completion message */
      if(msg->local_event_size_bytes > 0)
	 {
           tw_event* e_new;
	   terminal_message* m_new;
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	   void* local_event = 
               (char*)model_net_method_get_edata(DRAGONFLY, msg) + 
               msg->remote_event_size_bytes;
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	   ts = g_tw_lookahead + (1/s->params->cn_bandwidth) * msg->local_event_size_bytes;
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	   e_new = tw_event_new(msg->sender_lp, ts, lp);
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	   m_new = tw_event_data(e_new);
	   memcpy(m_new, local_event, msg->local_event_size_bytes);
	   tw_event_send(e_new);
	}
    }
   
   s->packet_counter++;
   s->vc_occupancy[vc]++;

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   if(s->vc_occupancy[vc] >= (s->params->cn_vc_size * num_chunks))
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      s->output_vc_state[vc] = VC_CREDIT;
   return;
}

/* packet arrives at the destination terminal */
void packet_arrive(terminal_state * s, tw_bf * bf, terminal_message * msg, tw_lp * lp)
{
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    uint64_t num_chunks = msg->packet_size / s->params->chunk_size;
    if (msg->packet_size % s->params->chunk_size)
        num_chunks++;
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#if DEBUG
if( msg->packet_ID == TRACK && msg->chunk_id == num_chunks-1)
    {
	printf( "(%lf) [Terminal %d] packet %lld has arrived  \n",
              tw_now(lp), (int)lp->gid, msg->packet_ID);

	printf("travel start time is %f\n",
                msg->travel_start_time);

	printf("My hop now is %d\n",msg->my_N_hop);
    }
#endif

  // Packet arrives and accumulate # queued
  // Find a queue with an empty buffer slot
   tw_event * e, * buf_e;
   terminal_message * m, * buf_msg;
   tw_stime ts;
   bf->c3 = 0;
   bf->c2 = 0;

   msg->my_N_hop++;
  if(msg->chunk_id == num_chunks-1)
  {
	 bf->c2 = 1;
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	 mn_stats* stat = model_net_find_stats(msg->category, s->dragonfly_stats_array);
	 stat->recv_count++;
	 stat->recv_bytes += msg->packet_size;
	 stat->recv_time += tw_now(lp) - msg->travel_start_time;

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	 N_finished_packets++;
	 dragonfly_total_time += tw_now( lp ) - msg->travel_start_time;
	 total_hops += msg->my_N_hop;

	 if (dragonfly_max_latency < tw_now( lp ) - msg->travel_start_time) 
	 {
		bf->c3 = 1;
		msg->saved_available_time = dragonfly_max_latency;
		dragonfly_max_latency=tw_now( lp ) - msg->travel_start_time;
	 }
	// Trigger an event on receiving server
	if(msg->remote_event_size_bytes)
	{
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            void * tmp_ptr = model_net_method_get_edata(DRAGONFLY, msg);
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            ts = g_tw_lookahead + 0.1 + (1/s->params->cn_bandwidth) * msg->remote_event_size_bytes;
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            if (msg->is_pull){
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                int net_id = model_net_get_id(LP_METHOD_NM);
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                model_net_event(net_id, msg->category, msg->sender_lp,
                        msg->pull_size, ts, msg->remote_event_size_bytes,
                        tmp_ptr, 0, NULL, lp);
            }
            else{
                e = tw_event_new(msg->final_dest_gid, ts, lp);
                m = tw_event_data(e);
                memcpy(m, tmp_ptr, msg->remote_event_size_bytes);
                tw_event_send(e); 
            }
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	}
  }

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  int credit_delay = (1 / s->params->cn_bandwidth) * CREDIT_SIZE;
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  ts = credit_delay + 0.1 + tw_rand_exponential(lp->rng, credit_delay/1000);
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  msg->saved_credit_time = s->next_credit_available_time;
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  s->next_credit_available_time = maxd(s->next_credit_available_time, tw_now(lp));
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  s->next_credit_available_time += ts;

  tw_lpid router_dest_id;
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  //TODO: be annotation-aware
  codes_mapping_get_lp_info(lp->gid, lp_group_name, &mapping_grp_id, NULL,
          &mapping_type_id, NULL, &mapping_rep_id, &mapping_offset);
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  codes_mapping_get_lp_id(lp_group_name, "dragonfly_router", s->anno, 0,
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          s->router_id, 0, &router_dest_id);
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  // no method_event here - message going to router
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  buf_e = tw_event_new(router_dest_id, s->next_credit_available_time - tw_now(lp), lp);
  buf_msg = tw_event_data(buf_e);
  buf_msg->vc_index = msg->saved_vc;
  buf_msg->type=R_BUFFER;
  buf_msg->packet_ID=msg->packet_ID;
  buf_msg->last_hop = TERMINAL;
  tw_event_send(buf_e);

  return;
}

/* initialize a dragonfly compute node terminal */
void 
terminal_init( terminal_state * s, 
	       tw_lp * lp )
{
    int i;
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    char anno[MAX_NAME_LENGTH];

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    // Assign the global router ID
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    // TODO: be annotation-aware
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    codes_mapping_get_lp_info(lp->gid, lp_group_name, &mapping_grp_id, NULL,
            &mapping_type_id, anno, &mapping_rep_id, &mapping_offset);
    if (anno[0] == '\0'){
        s->anno = NULL;
        s->params = &all_params[num_params-1];
    }
    else{
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        s->anno = strdup(anno);
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        int id = configuration_get_annotation_index(anno, anno_map);
        s->params = &all_params[id];
    }

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   int num_lps = codes_mapping_get_lp_count(lp_group_name, 1, LP_CONFIG_NM,
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           s->anno, 0);
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   s->terminal_id = (mapping_rep_id * num_lps) + mapping_offset;  
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   s->router_id=(int)s->terminal_id / (s->params->num_routers/2);
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   s->terminal_available_time = 0.0;
   s->packet_counter = 0;

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   s->vc_occupancy = (int*)malloc(s->params->num_vcs * sizeof(int));
   s->output_vc_state = (int*)malloc(s->params->num_vcs * sizeof(int));
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   for( i = 0; i < s->params->num_vcs; i++ )
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    {
      s->vc_occupancy[i]=0;
      s->output_vc_state[i]=VC_IDLE;
    }
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   dragonfly_collective_init(s, lp);
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   return;
}

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/* collective operation for the torus network */
void dragonfly_collective(char* category, int message_size, int remote_event_size, const void* remote_event, tw_lp* sender)
{
    tw_event * e_new;
    tw_stime xfer_to_nic_time;
    terminal_message * msg;
    tw_lpid local_nic_id;
    char* tmp_ptr;

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    codes_mapping_get_lp_info(sender->gid, lp_group_name, &mapping_grp_id,
            NULL, &mapping_type_id, NULL, &mapping_rep_id, &mapping_offset);
    codes_mapping_get_lp_id(lp_group_name, LP_CONFIG_NM, NULL, 1,
            mapping_rep_id, mapping_offset, &local_nic_id);
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    xfer_to_nic_time = codes_local_latency(sender);
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    e_new = model_net_method_event_new(local_nic_id, xfer_to_nic_time,
            sender, DRAGONFLY, (void**)&msg, (void**)&tmp_ptr);

    msg->remote_event_size_bytes = message_size;
    strcpy(msg->category, category);
    msg->sender_svr=sender->gid;
    msg->type = D_COLLECTIVE_INIT;

    tmp_ptr = (char*)msg;
    tmp_ptr += dragonfly_get_msg_sz();
    if(remote_event_size > 0)
     {
            msg->remote_event_size_bytes = remote_event_size;
            memcpy(tmp_ptr, remote_event, remote_event_size);
            tmp_ptr += remote_event_size;
     }

    tw_event_send(e_new);
    return;
}

/* reverse for collective operation of the dragonfly network */
void dragonfly_collective_rc(int message_size, tw_lp* sender)
{
     codes_local_latency_reverse(sender);
     return;
}

static void send_remote_event(terminal_state * s,
                        tw_bf * bf,
                        terminal_message * msg,
                        tw_lp * lp)
{
    // Trigger an event on receiving server
    if(msg->remote_event_size_bytes)
     {
            tw_event* e;
            tw_stime ts;
            terminal_message * m;
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            ts = (1/s->params->cn_bandwidth) * msg->remote_event_size_bytes;
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            e = codes_event_new(s->origin_svr, ts, lp);
            m = tw_event_data(e);
            char* tmp_ptr = (char*)msg;
            tmp_ptr += dragonfly_get_msg_sz();
            memcpy(m, tmp_ptr, msg->remote_event_size_bytes);
            tw_event_send(e);
     }
}

static void node_collective_init(terminal_state * s,
                        tw_bf * bf,
                        terminal_message * msg,
                        tw_lp * lp)
{
        tw_event * e_new;
        tw_lpid parent_nic_id;
        tw_stime xfer_to_nic_time;
        terminal_message * msg_new;
        int num_lps;

        msg->saved_collective_init_time = s->collective_init_time;
        s->collective_init_time = tw_now(lp);
	s->origin_svr = msg->sender_svr;
	
        if(s->is_leaf)
        {
            //printf("\n LP %ld sending message to parent %ld ", s->node_id, s->parent_node_id);
            /* get the global LP ID of the parent node */
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            // TODO: be annotation-aware
            codes_mapping_get_lp_info(lp->gid, lp_group_name, &mapping_grp_id,
                    NULL, &mapping_type_id, NULL, &mapping_rep_id,
                    &mapping_offset);
            num_lps = codes_mapping_get_lp_count(lp_group_name, 1, LP_CONFIG_NM,
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                    s->anno, 0);
            codes_mapping_get_lp_id(lp_group_name, LP_CONFIG_NM, s->anno, 0,
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                    s->parent_node_id/num_lps, (s->parent_node_id % num_lps),
                    &parent_nic_id);
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           /* send a message to the parent that the LP has entered the collective operation */
            xfer_to_nic_time = g_tw_lookahead + LEVEL_DELAY;
            //e_new = codes_event_new(parent_nic_id, xfer_to_nic_time, lp);
	    void* m_data;
	    e_new = model_net_method_event_new(parent_nic_id, xfer_to_nic_time,
            	lp, DRAGONFLY, (void**)&msg_new, (void**)&m_data);
	    	
            memcpy(msg_new, msg, sizeof(terminal_message));
	    if (msg->remote_event_size_bytes){
        	memcpy(m_data, model_net_method_get_edata(DRAGONFLY, msg),
                	msg->remote_event_size_bytes);
      	    }
	    
            msg_new->type = D_COLLECTIVE_FAN_IN;
            msg_new->sender_node = s->node_id;

            tw_event_send(e_new);
        }
        return;
}

static void node_collective_fan_in(terminal_state * s,
                        tw_bf * bf,
                        terminal_message * msg,
                        tw_lp * lp)
{
        int i;
        s->num_fan_nodes++;

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        codes_mapping_get_lp_info(lp->gid, lp_group_name, &mapping_grp_id,
                NULL, &mapping_type_id, NULL, &mapping_rep_id, &mapping_offset);
        int num_lps = codes_mapping_get_lp_count(lp_group_name, 1, LP_CONFIG_NM,
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                s->anno, 0);
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        tw_event* e_new;
        terminal_message * msg_new;
        tw_stime xfer_to_nic_time;

        bf->c1 = 0;
        bf->c2 = 0;

        /* if the number of fanned in nodes have completed at the current node then signal the parent */
        if((s->num_fan_nodes == s->num_children) && !s->is_root)
        {
            bf->c1 = 1;
            msg->saved_fan_nodes = s->num_fan_nodes-1;
            s->num_fan_nodes = 0;
            tw_lpid parent_nic_id;
            xfer_to_nic_time = g_tw_lookahead + LEVEL_DELAY;

            /* get the global LP ID of the parent node */
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            codes_mapping_get_lp_id(lp_group_name, LP_CONFIG_NM, s->anno, 0,
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                    s->parent_node_id/num_lps, (s->parent_node_id % num_lps),
                    &parent_nic_id);
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           /* send a message to the parent that the LP has entered the collective operation */
            //e_new = codes_event_new(parent_nic_id, xfer_to_nic_time, lp);
            //msg_new = tw_event_data(e_new);
	    void * m_data;
      	    e_new = model_net_method_event_new(parent_nic_id,
              xfer_to_nic_time,
              lp, DRAGONFLY, (void**)&msg_new, &m_data);
	    
            memcpy(msg_new, msg, sizeof(terminal_message));
            msg_new->type = D_COLLECTIVE_FAN_IN;
            msg_new->sender_node = s->node_id;

            if (msg->remote_event_size_bytes){
	        memcpy(m_data, model_net_method_get_edata(DRAGONFLY, msg),
        	        msg->remote_event_size_bytes);
      	   }
	    
            tw_event_send(e_new);
      }

      /* root node starts off with the fan-out phase */
      if(s->is_root && (s->num_fan_nodes == s->num_children))
      {
           bf->c2 = 1;
           msg->saved_fan_nodes = s->num_fan_nodes-1;
           s->num_fan_nodes = 0;
           send_remote_event(s, bf, msg, lp);

           for( i = 0; i < s->num_children; i++ )
           {
                tw_lpid child_nic_id;
                /* Do some computation and fan out immediate child nodes from the collective */
                xfer_to_nic_time = g_tw_lookahead + COLLECTIVE_COMPUTATION_DELAY + LEVEL_DELAY + tw_rand_exponential(lp->rng, (double)LEVEL_DELAY/50);

                /* get global LP ID of the child node */
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                codes_mapping_get_lp_id(lp_group_name, LP_CONFIG_NM, NULL, 1,
                        s->children[i]/num_lps, (s->children[i] % num_lps),
                        &child_nic_id);
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                //e_new = codes_event_new(child_nic_id, xfer_to_nic_time, lp);

                //msg_new = tw_event_data(e_new);
                void * m_data;
	        e_new = model_net_method_event_new(child_nic_id,
                xfer_to_nic_time,
		lp, DRAGONFLY, (void**)&msg_new, &m_data);

		memcpy(msg_new, msg, sizeof(terminal_message));
	        if (msg->remote_event_size_bytes){
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	                memcpy(m_data, model_net_method_get_edata(DRAGONFLY, msg),
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        	               msg->remote_event_size_bytes);
      		}
		
                msg_new->type = D_COLLECTIVE_FAN_OUT;
                msg_new->sender_node = s->node_id;

                tw_event_send(e_new);
           }
      }
}

static void node_collective_fan_out(terminal_state * s,
                        tw_bf * bf,
                        terminal_message * msg,
                        tw_lp * lp)
{
        int i;
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        int num_lps = codes_mapping_get_lp_count(lp_group_name, 1, LP_CONFIG_NM,
                NULL, 1);
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        bf->c1 = 0;
        bf->c2 = 0;

        send_remote_event(s, bf, msg, lp);

        if(!s->is_leaf)
        {
            bf->c1 = 1;
            tw_event* e_new;
            nodes_message * msg_new;
            tw_stime xfer_to_nic_time;

           for( i = 0; i < s->num_children; i++ )
           {
                xfer_to_nic_time = g_tw_lookahead + DRAGONFLY_FAN_OUT_DELAY + tw_rand_exponential(lp->rng, (double)DRAGONFLY_FAN_OUT_DELAY/10);

                if(s->children[i] > 0)
                {
                        tw_lpid child_nic_id;

                        /* get global LP ID of the child node */
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                        codes_mapping_get_lp_id(lp_group_name, LP_CONFIG_NM,
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                                s->anno, 0, s->children[i]/num_lps,
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                                (s->children[i] % num_lps), &child_nic_id);
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                        //e_new = codes_event_new(child_nic_id, xfer_to_nic_time, lp);
                        //msg_new = tw_event_data(e_new);
                        //memcpy(msg_new, msg, sizeof(nodes_message) + msg->remote_event_size_bytes);
			void* m_data;
			e_new = model_net_method_event_new(child_nic_id,
							xfer_to_nic_time,
					                lp, DRAGONFLY, (void**)&msg_new, &m_data);
		        memcpy(msg_new, msg, sizeof(nodes_message));
		        if (msg->remote_event_size_bytes){
			        memcpy(m_data, model_net_method_get_edata(DRAGONFLY, msg),
			                msg->remote_event_size_bytes);
      			}


                        msg_new->type = D_COLLECTIVE_FAN_OUT;
                        msg_new->sender_node = s->node_id;
                        tw_event_send(e_new);
                }
           }
         }
	//printf("\n Fan out phase completed %ld ", lp->gid);
        if(max_collective < tw_now(lp) - s->collective_init_time )
          {
              bf->c2 = 1;
              max_collective = tw_now(lp) - s->collective_init_time;
          }
}
1102 1103 1104 1105 1106 1107 1108 1109 1110 1111 1112 1113 1114 1115 1116 1117 1118 1119 1120 1121 1122 1123 1124 1125 1126 1127 1128 1129 1130 1131 1132 1133 1134 1135 1136 1137 1138 1139 1140 1141
/* update the compute node-router channel buffer */
void 
terminal_buf_update(terminal_state * s, 
		    tw_bf * bf, 
		    terminal_message * msg, 
		    tw_lp * lp)
{
  // Update the buffer space associated with this router LP 
    int msg_indx = msg->vc_index;
    
    s->vc_occupancy[msg_indx]--;
    s->output_vc_state[msg_indx] = VC_IDLE;

    return;
}

void 
terminal_event( terminal_state * s, 
		tw_bf * bf, 
		terminal_message * msg, 
		tw_lp * lp )
{
  *(int *)bf = (int)0;
  switch(msg->type)
    {
    case T_GENERATE:
       packet_generate(s,bf,msg,lp);
    break;
    
    case T_ARRIVE:
        packet_arrive(s,bf,msg,lp);
    break;
    
    case T_SEND:
      packet_send(s,bf,msg,lp);
    break;
    
    case T_BUFFER:
       terminal_buf_update(s, bf, msg, lp);
     break;
1142 1143 1144 1145
    
    case D_COLLECTIVE_INIT:
      node_collective_init(s, bf, msg, lp);
    break;
1146

1147 1148 1149 1150 1151 1152 1153 1154
    case D_COLLECTIVE_FAN_IN:
      node_collective_fan_in(s, bf, msg, lp);
    break;

    case D_COLLECTIVE_FAN_OUT:
      node_collective_fan_out(s, bf, msg, lp);
    break;
    
1155 1156 1157 1158 1159 1160
    default:
       printf("\n LP %d Terminal message type not supported %d ", (int)lp->gid, msg->type);
    }
}

void 
1161
dragonfly_terminal_final( terminal_state * s, 
1162 1163
      tw_lp * lp )
{
1164
	model_net_print_stats(lp->gid, s->dragonfly_stats_array);
1165 1166
}

1167 1168 1169 1170 1171
void dragonfly_router_final(router_state * s,
		tw_lp * lp)
{
   free(s->global_channel);
}
1172 1173 1174 1175 1176 1177 1178 1179 1180 1181 1182
/* get the next stop for the current packet
 * determines if it is a router within a group, a router in another group
 * or the destination terminal */
tw_lpid 
get_next_stop(router_state * s, 
		      tw_bf * bf, 
		      terminal_message * msg, 
		      tw_lp * lp, 
		      int path)
{
   int dest_lp;
1183
   tw_lpid router_dest_id = -1;
1184 1185 1186
   int i;
   int dest_group_id;

1187 1188 1189 1190 1191
   //TODO: be annotation-aware
   codes_mapping_get_lp_info(msg->dest_terminal_id, lp_group_name,
           &mapping_grp_id, NULL, &mapping_type_id, NULL, &mapping_rep_id,
           &mapping_offset); 
   int num_lps = codes_mapping_get_lp_count(lp_group_name, 1, LP_CONFIG_NM,
1192 1193
           s->anno, 0);
   int dest_router_id = (mapping_offset + (mapping_rep_id * num_lps)) / s->params->num_routers;
1194
   
1195 1196
   codes_mapping_get_lp_info(lp->gid, lp_group_name, &mapping_grp_id, NULL,
           &mapping_type_id, NULL, &mapping_rep_id, &mapping_offset);
1197 1198 1199 1200
   int local_router_id = (mapping_offset + mapping_rep_id);

   bf->c2 = 0;

1201
  /* If the packet has arrived at the destination router */
1202 1203 1204 1205 1206 1207
   if(dest_router_id == local_router_id)
    {
        dest_lp = msg->dest_terminal_id;

        return dest_lp;
    }
1208
   /* Generate inter-mediate destination for non-minimal routing (selecting a random group) */
1209
   if(msg->last_hop == TERMINAL && msg->path_type == NON_MINIMAL)
1210
    {
1211
      if(dest_router_id / s->params->num_routers != s->group_id)
1212 1213
         {
            bf->c2 = 1;
1214
            int intm_grp_id = tw_rand_integer(lp->rng, 0, s->params->num_groups-1);
1215 1216
            //int intm_grp_id = (s->group_id + s->group_id/2) % num_groups;
	    msg->intm_group_id = intm_grp_id;
1217 1218
          }    
    }
1219
  /* It means that the packet has arrived at the inter-mediate group for non-minimal routing. Reset the group now. */
1220 1221 1222 1223
   if(msg->intm_group_id == s->group_id)
   {  
           msg->intm_group_id = -1;//no inter-mediate group
   } 
1224
  /* Intermediate group ID is set. Divert the packet to an intermediate group. */
1225 1226 1227 1228
  if(msg->intm_group_id >= 0)
   {
      dest_group_id = msg->intm_group_id;
   }
1229
  else /* direct the packet to the destination group */
1230
   {
1231
     dest_group_id = dest_router_id / s->params->num_routers;
1232 1233
   }
  
1234
  /* It means the packet has arrived at the destination group. Now divert it to the destination router. */
1235 1236 1237 1238 1239 1240
  if(s->group_id == dest_group_id)
   {
     dest_lp = dest_router_id;
   }
   else
   {
1241
      /* Packet is at the source or intermediate group. Find a router that has a path to the destination group. */
1242 1243 1244 1245
      dest_lp=getRouterFromGroupID(dest_group_id,s);
  
      if(dest_lp == local_router_id)
      {
1246
        for(i=0; i < s->params->num_global_channels; i++)
1247
           {
1248
            if(s->global_channel[i] / s->params->num_routers == dest_group_id)
1249 1250 1251 1252
                dest_lp=s->global_channel[i];
          }
      }
   }
1253
  codes_mapping_get_lp_id(lp_group_name, "dragonfly_router", s->anno, 0, dest_lp,
1254
          0, &router_dest_id);
1255 1256 1257 1258 1259 1260 1261 1262 1263 1264 1265 1266
  return router_dest_id;
}

/* gets the output port corresponding to the next stop of the message */
int 
get_output_port( router_state * s, 
		tw_bf * bf, 
		terminal_message * msg, 
		tw_lp * lp, 
		int next_stop )
{
  int output_port = -1, i, terminal_id;
1267 1268 1269
  codes_mapping_get_lp_info(msg->dest_terminal_id, lp_group_name,
          &mapping_grp_id, NULL, &mapping_type_id, NULL, &mapping_rep_id,
          &mapping_offset);
1270
  int num_lps = codes_mapping_get_lp_count(lp_group_name,1,LP_CONFIG_NM,s->anno,0);
1271
  terminal_id = (mapping_rep_id * num_lps) + mapping_offset;
1272 1273 1274

  if(next_stop == msg->dest_terminal_id)
   {
1275 1276
      output_port = s->params->num_routers + s->params->num_global_channels +
          ( terminal_id % s->params->num_cn);
1277 1278
      //if(output_port > 6)
	//      printf("\n incorrect output port %d terminal id %d ", output_port, terminal_id);
1279 1280 1281
    }
    else
    {
1282 1283
     codes_mapping_get_lp_info(next_stop, lp_group_name, &mapping_grp_id,
             NULL, &mapping_type_id, NULL, &mapping_rep_id, &mapping_offset);
1284
     int local_router_id = mapping_rep_id + mapping_offset;
1285
     int intm_grp_id = local_router_id / s->params->num_routers;
1286 1287 1288

     if(intm_grp_id != s->group_id)
      {
1289
        for(i=0; i < s->params->num_global_channels; i++)
1290
         {
1291
           if(s->global_channel[i] == local_router_id)
1292
             output_port = s->params->num_routers + i;
1293 1294 1295 1296
          }
      }
      else
       {
1297
        output_port = local_router_id % s->params->num_routers;
1298
       }
1299
//	      printf("\n output port not found %d next stop %d local router id %d group id %d intm grp id %d %d", output_port, next_stop, local_router_id, s->group_id, intm_grp_id, local_router_id%num_routers);
1300 1301 1302 1303 1304 1305 1306 1307 1308 1309
    }
    return output_port;
}

/* routes the current packet to the next stop */
void 
router_packet_send( router_state * s, 
		    tw_bf * bf, 
		     terminal_message * msg, tw_lp * lp)
{
1310
//   *(int *)bf = (int)0;
1311 1312 1313 1314 1315
   tw_stime ts;
   tw_event *e;
   terminal_message *m;

   int next_stop = -1, output_port = -1, output_chan = -1;
1316 1317
   float bandwidth = s->params->local_bandwidth;
   int path = s->params->routing;
1318
   int minimal_out_port = -1, nonmin_out_port = -1;
1319 1320
   bf->c3 = 0;

1321 1322 1323 1324 1325 1326
   uint64_t num_chunks = msg->packet_size/s->params->chunk_size;
   if(msg->packet_size % s->params->chunk_size)
       num_chunks++;
    

   if(msg->last_hop == TERMINAL && s->params->routing == ADAPTIVE)
1327
   {
1328 1329 1330 1331 1332 1333 1334
  // decide which routing to take
    int minimal_next_stop=get_next_stop(s, bf, msg, lp, MINIMAL);
    minimal_out_port = get_output_port(s, bf, msg, lp, minimal_next_stop);
    int nonmin_next_stop = get_next_stop(s, bf, msg, lp, NON_MINIMAL);
    nonmin_out_port = get_output_port(s, bf, msg, lp, nonmin_next_stop);
    int nonmin_port_count = s->vc_occupancy[nonmin_out_port];
    int min_port_count = s->vc_occupancy[minimal_out_port];
1335 1336
    int nonmin_vc = s->vc_occupancy[nonmin_out_port * s->params->num_vcs + 2];
    int min_vc = s->vc_occupancy[minimal_out_port * s->params->num_vcs + 1];
1337 1338

    // Adaptive routing condition from the dragonfly paper Page 83
1339
   // modified according to booksim adaptive routing condition
1340 1341 1342
   if((min_vc <= (nonmin_vc * 2 + adaptive_threshold) && minimal_out_port == nonmin_out_port)
               || (min_port_count <= (nonmin_port_count * 2 + adaptive_threshold) && minimal_out_port != nonmin_out_port))
        {
1343
	   msg->path_type = MINIMAL;
1344 1345 1346 1347
           next_stop = minimal_next_stop;
           output_port = minimal_out_port;
           minimal_count++;
           msg->intm_group_id = -1;
1348

1349 1350 1351 1352 1353
           if(msg->packet_ID == TRACK)
              printf("\n (%lf) [Router %d] Packet %d routing minimally ", tw_now(lp), (int)lp->gid, (int)msg->packet_ID);
        }
       else
         {
1354
	   msg->path_type = NON_MINIMAL;
1355 1356 1357 1358 1359 1360 1361 1362 1363 1364
           next_stop = nonmin_next_stop;
           output_port = nonmin_out_port;
           nonmin_count++;
           if(msg->packet_ID == TRACK)
                printf("\n (%lf) [Router %d] Packet %d routing non-minimally ", tw_now(lp), (int)lp->gid, (int)msg->packet_ID);

         }
  }
  else
   {
1365
	msg->path_type = routing; /*defaults to the routing algorithm if we don't have adaptive routing here*/
1366 1367 1368
   	next_stop = get_next_stop(s, bf, msg, lp, path);
   	output_port = get_output_port(s, bf, msg, lp, next_stop); 
   }
1369
   output_chan = output_port * s->params->num_vcs;
1370

1371
    // Even numbered channels for minimal routing
1372
   // Odd numbered channels for nonminimal routing
1373 1374 1375 1376 1377 1378 1379 1380 1381 1382 1383
   // Separate the queue occupancy into minimal and non minimal virtual channels if the min & non min
   // paths start at the same output port
   /*if((routing == ADAPTIVE) && (minimal_out_port == nonmin_out_port))
   {
        if(path == MINIMAL)
          output_chan = output_chan + 1;
        else
          if(path == NON_MINIMAL)
            output_chan = output_chan + 2;
   }*/

1384
   int global=0;
1385
   int buf_size = s->params->local_vc_size;
1386

1387 1388
   assert(output_port != -1);
   assert(output_chan != -1);
1389
   // Allocate output Virtual Channel
1390 1391
  if(output_port >= s->params->num_routers && 
          output_port < s->params->num_routers + s->params->num_global_channels)
1392
  {
1393
	 bandwidth = s->params->global_bandwidth;
1394
	 global = 1;
1395
	 buf_size = s->params->global_vc_size;
1396 1397
  }

1398 1399
  if(output_port >= s->params->num_routers + s->params->num_global_channels)
	buf_size = s->params->cn_vc_size;
1400 1401 1402

   if(s->vc_occupancy[output_chan] >= buf_size)
    {
1403
	    printf("\n %lf Router %ld buffers overflowed from incoming terminals channel %d occupancy %d radix %d next_stop %d ", tw_now(lp),(long int) lp->gid, output_chan, s->vc_occupancy[output_chan], s->params->radix, next_stop);
1404
	    bf->c3 = 1;
1405 1406 1407
	    return;
	    //MPI_Finalize();
	    //exit(-1);
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    }

#if DEBUG
if( msg->packet_ID == TRACK && next_stop != msg->dest_terminal_id && msg->chunk_id == num_chunks-1)
  {
   printf("\n (%lf) [Router %d] Packet %lld being sent to intermediate group router %d Final destination terminal %d Output Channel Index %d Saved vc %d msg_intm_id %d \n", 
              tw_now(lp), (int)lp->gid, msg->packet_ID, next_stop, 
	      msg->dest_terminal_id, output_chan, msg->saved_vc, msg->intm_group_id);
  }
#endif
 // If source router doesn't have global channel and buffer space is available, then assign to appropriate intra-group virtual channel 
  msg->saved_available_time = s->next_output_available_time[output_port];
1420
  ts = g_tw_lookahead + 0.1 + ((1/bandwidth) * s->params->chunk_size) + tw_rand_exponential(lp->rng, (double)s->params->chunk_size/200);
1421

1422
  s->next_output_available_time[output_port] = maxd(s->next_output_available_time[output_port], tw_now(lp));
1423
  s->next_output_available_time[output_port] += ts;
1424 1425 1426 1427 1428 1429 1430 1431 1432 1433 1434 1435 1436 1437 1438 1439
  // dest can be a router or a terminal, so we must check
  void * m_data;
  if (next_stop == msg->dest_terminal_id){
      e = model_net_method_event_new(next_stop, 
              s->next_output_available_time[output_port] - tw_now(lp), lp,
              DRAGONFLY, (void**)&m, &m_data);
  }
  else{
      e = tw_event_new(next_stop, s->next_output_available_time[output_port] - tw_now(lp), lp);
      m = tw_event_data(e);
      m_data = m+1;
  }
  memcpy(m, msg, sizeof(terminal_message));
  if (msg->remote_event_size_bytes){
      memcpy(m_data, msg+1, msg->remote_event_size_bytes);
  }
1440 1441 1442 1443 1444 1445 1446 1447 1448 1449 1450

  if(global)
    m->last_hop=GLOBAL;
  else
    m->last_hop = LOCAL;

  m->saved_vc = output_chan;
  msg->old_vc = output_chan;
  m->intm_lp_id = lp->gid;
  s->vc_occupancy[output_chan]++;

1451 1452
  /* Determine the event type. If the packet has arrived at the final destination
     router then it should arrive at the destination terminal next. */
1453 1454 1455 1456
  if(next_stop == msg->dest_terminal_id)
  {
    m->type = T_ARRIVE;

1457
    if(s->vc_occupancy[output_chan] >= s->params->cn_vc_size * num_chunks)
1458 1459 1460 1461
      s->output_vc_state[output_chan] = VC_CREDIT;
  }
  else
  {
1462
    /* The packet has to be sent to another router */
1463 1464
    m->type = R_ARRIVE;

1465
   /* If this is a global channel then the buffer space is different */
1466 1467
   if( global )
   {
1468
     if(s->vc_occupancy[output_chan] >= s->params->global_vc_size * num_chunks )
1469 1470 1471 1472
       s->output_vc_state[output_chan] = VC_CREDIT;
   }
  else
    {
1473
     /* buffer space is less for local channels */
1474
     if( s->vc_occupancy[output_chan] >= s->params->local_vc_size * num_chunks )
1475 1476 1477 1478 1479 1480 1481 1482 1483 1484 1485 1486 1487 1488 1489 1490 1491 1492 1493
	s->output_vc_state[output_chan] = VC_CREDIT;
    }
  }
  tw_event_send(e);
  return;
}

/* Packet arrives at the router and a credit is sent back to the sending terminal/router */
void 
router_packet_receive( router_state * s, 
			tw_bf * bf, 
			terminal_message * msg, 
			tw_lp * lp )
{
    tw_event *e;
    terminal_message *m;
    tw_stime ts;

    msg->my_N_hop++;
1494
    ts = g_tw_lookahead + 0.1 + tw_rand_exponential(lp->rng, (double)MEAN_INTERVAL/200);
1495 1496 1497
    uint64_t num_chunks = msg->packet_size/s->params->chunk_size;
    if(msg->packet_size % s->params->chunk_size)
        num_chunks++;
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