model-net-mpi-replay.c 102 KB
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/*
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* Copyright (C) 2014 University of Chicago.
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 * See COPYRIGHT notice in top-level directory.
 *
 */
#include <ross.h>
#include <inttypes.h>
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#include <sys/stat.h>
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#include <sys/resource.h>
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#include "codes/codes-workload.h"
#include "codes/codes.h"
#include "codes/configuration.h"
#include "codes/codes_mapping.h"
#include "codes/model-net.h"
#include "codes/rc-stack.h"
#include "codes/quicklist.h"
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#include "codes/quickhash.h"
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#include "codes/codes-jobmap.h"
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/* turning on track lp will generate a lot of output messages */
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#define MN_LP_NM "modelnet_dragonfly_custom"
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#define CONTROL_MSG_SZ 64
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#define TRACE -1
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#define MAX_WAIT_REQS 1024
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#define CS_LP_DBG 1
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#define RANK_HASH_TABLE_SZ 2000
#define NW_LP_NM "nw-lp"
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#define lprintf(_fmt, ...) \
        do {if (CS_LP_DBG) printf(_fmt, __VA_ARGS__);} while (0)
#define MAX_STATS 65536
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#define COL_TAG 1235
#define BAR_TAG 1234
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static int msg_size_hash_compare(
            void *key, struct qhash_head *link);

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static unsigned long perm_switch_thresh = 8388608;
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/* NOTE: Message tracking works in sequential mode only! */
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static int debug_cols = 0;
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static int synthetic_pattern = 1;
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/* Turning on this option slows down optimistic mode substantially. Only turn
 * on if you get issues with wait-all completion with traces. */
static int preserve_wait_ordering = 0;
static int enable_msg_tracking = 0;
static int is_synthetic = 0;
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static unsigned long long max_gen_data = 1310720;
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static int num_qos_levels;
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tw_lpid TRACK_LP = -1;
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int nprocs = 0;
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static double total_syn_data = 0;
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static int unmatched = 0;
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char workload_type[128];
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char workload_name[128];
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char workload_file[8192];
char offset_file[8192];
static int wrkld_id;
static int num_net_traces = 0;
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static int priority_type = 0;
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static int num_dumpi_traces = 0;
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static int64_t EAGER_THRESHOLD = 8192;
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static long num_ops = 0;
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static int upper_threshold = 1048576;
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static int alloc_spec = 0;
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static tw_stime self_overhead = 10.0;
static tw_stime mean_interval = 100000;
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static int payload_sz = 1024;
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/* Doing LP IO*/
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static char * params = NULL;
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static char lp_io_dir[256] = {'\0'};
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static char sampling_dir[32] = {'\0'};
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static char mpi_msg_dir[32] = {'\0'};
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static lp_io_handle io_handle;
static unsigned int lp_io_use_suffix = 0;
static int do_lp_io = 0;

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/* variables for loading multiple applications */
char workloads_conf_file[8192];
char alloc_file[8192];
int num_traces_of_job[5];
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tw_stime soft_delay_mpi = 2500;
tw_stime nic_delay = 1000;
tw_stime copy_per_byte_eager = 0.55;
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char file_name_of_job[5][8192];

struct codes_jobmap_ctx *jobmap_ctx;
struct codes_jobmap_params_list jobmap_p;

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/* Variables for Cortex Support */
/* Matthieu's additions start */
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#ifdef ENABLE_CORTEX_PYTHON
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static char cortex_file[512] = "\0";
static char cortex_class[512] = "\0";
static char cortex_gen[512] = "\0";
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#endif
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/* Matthieu's additions end */

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typedef struct nw_state nw_state;
typedef struct nw_message nw_message;
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typedef unsigned int dumpi_req_id;
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static int net_id = 0;
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static float noise = 1.0;
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static int num_nw_lps = 0, num_mpi_lps = 0;

static int num_syn_clients;
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static int finished_syn_clients = 0;
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static int syn_type = 0;
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FILE * workload_log = NULL;
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FILE * msg_size_log = NULL;
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FILE * workload_agg_log = NULL;
FILE * workload_meta_log = NULL;

static uint64_t sample_bytes_written = 0;
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unsigned long long num_bytes_sent=0;
unsigned long long num_bytes_recvd=0;
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unsigned long long num_syn_bytes_sent = 0;
unsigned long long num_syn_bytes_recvd = 0;
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double max_time = 0,  max_comm_time = 0, max_wait_time = 0, max_send_time = 0, max_recv_time = 0;
double avg_time = 0, avg_comm_time = 0, avg_wait_time = 0, avg_send_time = 0, avg_recv_time = 0;


/* runtime option for disabling computation time simulation */
static int disable_delay = 0;
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static int enable_sampling = 0;
static double sampling_interval = 5000000;
static double sampling_end_time = 3000000000;
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static int enable_debug = 0;
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/* set group context */
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struct codes_mctx mapping_context;
enum MAPPING_CONTEXTS
{
    GROUP_RATIO=1,
    GROUP_RATIO_REVERSE,
    GROUP_DIRECT,
    GROUP_MODULO,
    GROUP_MODULO_REVERSE,
    UNKNOWN
};
static int map_ctxt = GROUP_MODULO;
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/* MPI_OP_GET_NEXT is for getting next MPI operation when the previous operation completes.
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* MPI_SEND_ARRIVED is issued when a MPI message arrives at its destination (the message is transported by model-net and an event is invoked when it arrives.
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* MPI_SEND_POSTED is issued when a MPI message has left the source LP (message is transported via model-net). */
enum MPI_NW_EVENTS
{
	MPI_OP_GET_NEXT=1,
	MPI_SEND_ARRIVED,
    MPI_SEND_ARRIVED_CB, // for tracking message times on sender
	MPI_SEND_POSTED,
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    MPI_REND_ARRIVED,
    MPI_REND_ACK_ARRIVED,
    CLI_BCKGND_FIN,
    CLI_BCKGND_ARRIVE,
    CLI_BCKGND_GEN,
    CLI_NBR_FINISH,
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};

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/* type of synthetic traffic */
enum TRAFFIC
{
    UNIFORM = 1, /* sends message to a randomly selected node */
    NEAREST_NEIGHBOR = 2, /* sends message to the next node (potentially connected to the same router) */
    ALLTOALL = 3, /* sends message to all other nodes */
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    STENCIL = 4, /* sends message to 4 nearby neighbors */
    PERMUTATION = 5
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};
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struct mpi_workload_sample
{
    /* Sampling data */
    int nw_id;
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    int app_id;
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    unsigned long num_sends_sample;
    unsigned long num_bytes_sample;
    unsigned long num_waits_sample;
    double sample_end_time;
};
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/* stores pointers of pending MPI operations to be matched with their respective sends/receives. */
struct mpi_msgs_queue
{
    int op_type;
    int tag;
    int source_rank;
    int dest_rank;
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    int64_t num_bytes;
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    int64_t seq_id;
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    tw_stime req_init_time;
	dumpi_req_id req_id;
    struct qlist_head ql;
};

/* stores request IDs of completed MPI operations (Isends or Irecvs) */
struct completed_requests
{
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	unsigned int req_id;
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    struct qlist_head ql;
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    int index;
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};

/* for wait operations, store the pending operation and number of completed waits so far. */
struct pending_waits
{
    int op_type;
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    unsigned int req_ids[MAX_WAIT_REQS];
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	int num_completed;
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	int count;
    tw_stime start_time;
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    struct qlist_head ql;
};

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struct msg_size_info
{
    int64_t msg_size;
    int num_msgs;
    tw_stime agg_latency;
    tw_stime avg_latency;
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    struct qhash_head  hash_link;
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    struct qlist_head ql; 
};
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struct ross_model_sample
{
    tw_lpid nw_id;
    int app_id;
    int local_rank;
    unsigned long num_sends;
    unsigned long num_recvs;
    unsigned long long num_bytes_sent;
    unsigned long long num_bytes_recvd;
    double send_time;
    double recv_time;
    double wait_time;
    double compute_time;
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    double comm_time;
    double max_time;
    double avg_msg_time;
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};

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typedef struct mpi_msgs_queue mpi_msgs_queue;
typedef struct completed_requests completed_requests;
typedef struct pending_waits pending_waits;

/* state of the network LP. It contains the pointers to send/receive lists */
struct nw_state
{
	long num_events_per_lp;
	tw_lpid nw_id;
	short wrkld_end;
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    int app_id;
    int local_rank;
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    int synthetic_pattern;
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    int is_finished;
    int neighbor_completed;

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    struct rc_stack * processed_ops;
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    struct rc_stack * processed_wait_op;
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    struct rc_stack * matched_reqs;
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//    struct rc_stack * indices;
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    /* count of sends, receives, collectives and delays */
	unsigned long num_sends;
	unsigned long num_recvs;
	unsigned long num_cols;
	unsigned long num_delays;
	unsigned long num_wait;
	unsigned long num_waitall;
	unsigned long num_waitsome;

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	/* time spent by the LP in executing the app trace*/
	double start_time;
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    double col_time;

    double reduce_time;
    int num_reduce;

    double all_reduce_time;
    int num_all_reduce;

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	double elapsed_time;
	/* time spent in compute operations */
	double compute_time;
	/* time spent in message send/isend */
	double send_time;
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    /* max time for synthetic traffic message */
    double max_time;
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	/* time spent in message receive */
	double recv_time;
	/* time spent in wait operation */
	double wait_time;
	/* FIFO for isend messages arrived on destination */
	struct qlist_head arrival_queue;
	/* FIFO for irecv messages posted but not yet matched with send operations */
	struct qlist_head pending_recvs_queue;
	/* List of completed send/receive requests */
	struct qlist_head completed_reqs;
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    tw_stime cur_interval_end;
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    /* Pending wait operation */
    struct pending_waits * wait_op;
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    /* Message size latency information */
    struct qhash_table * msg_sz_table;
    struct qlist_head msg_sz_list;

    /* quick hash for maintaining message latencies */

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    unsigned long long num_bytes_sent;
    unsigned long long num_bytes_recvd;
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    unsigned long long syn_data;
    unsigned long long gen_data;
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    unsigned long prev_switch;
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    int saved_perm_dest;
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    unsigned long rc_perm;

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    /* For sampling data */
    int sampling_indx;
    int max_arr_size;
    struct mpi_workload_sample * mpi_wkld_samples;
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    char output_buf[512];
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    char col_stats[64];
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    struct ross_model_sample ross_sample;
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};

/* data for handling reverse computation.
* saved_matched_req holds the request ID of matched receives/sends for wait operations.
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* ptr_match_op holds the matched MPI operation which are removed from the queues when a send is matched with the receive in forward event handler.
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* network event being sent. op is the MPI operation issued by the network workloads API. rv_data holds the data for reverse computation (TODO: Fill this data structure only when the simulation runs in optimistic mode). */
struct nw_message
{
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   // forward message handler
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   int msg_type;
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   int op_type;
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   model_net_event_return event_rc;
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   struct codes_workload_op * mpi_op;
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   struct
   {
       tw_lpid src_rank;
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       int dest_rank;
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       int64_t num_bytes;
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       int num_matched;
       int data_type;
       double sim_start_time;
       // for callbacks - time message was received
       double msg_send_time;
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       unsigned int req_id;
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       int matched_req;
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       int tag;
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       int app_id;
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       int found_match;
       short wait_completed;
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       short rend_send;
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   } fwd;
   struct
   {
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       int saved_perm;
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       double saved_send_time;
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       double saved_send_time_sample;
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       double saved_recv_time;
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       double saved_recv_time_sample;
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       double saved_wait_time;
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       double saved_wait_time_sample;
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       double saved_delay;
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       double saved_delay_sample;
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       int64_t saved_num_bytes;
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       int saved_syn_length;
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       unsigned long saved_prev_switch;
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       double saved_prev_max_time;
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   } rc;
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};

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static void send_ack_back(nw_state* s, tw_bf * bf, nw_message * m, tw_lp * lp, mpi_msgs_queue * mpi_op, int matched_req);
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static void send_ack_back_rc(nw_state* s, tw_bf * bf, nw_message * m, tw_lp * lp);
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/* executes MPI isend and send operations */
static void codes_exec_mpi_send(
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        nw_state* s, tw_bf * bf, nw_message * m, tw_lp* lp, struct codes_workload_op * mpi_op, int is_rend);
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/* execute MPI irecv operation */
static void codes_exec_mpi_recv(
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        nw_state* s, tw_bf * bf, nw_message * m, tw_lp * lp, struct codes_workload_op * mpi_op);
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/* reverse of mpi recv function. */
static void codes_exec_mpi_recv_rc(
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        nw_state* s, tw_bf * bf, nw_message* m, tw_lp* lp);
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/* execute the computational delay */
static void codes_exec_comp_delay(
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        nw_state* s, tw_bf *bf, nw_message * m, tw_lp* lp, struct codes_workload_op * mpi_op);
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/* gets the next MPI operation from the network-workloads API. */
static void get_next_mpi_operation(
        nw_state* s, tw_bf * bf, nw_message * m, tw_lp * lp);
/* reverse handler of get next mpi operation. */
static void get_next_mpi_operation_rc(
        nw_state* s, tw_bf * bf, nw_message * m, tw_lp * lp);
/* Makes a call to get_next_mpi_operation. */
static void codes_issue_next_event(tw_lp* lp);
/* reverse handler of next operation */
static void codes_issue_next_event_rc(tw_lp* lp);


///////////////////// HELPER FUNCTIONS FOR MPI MESSAGE QUEUE HANDLING ///////////////
/* upon arrival of local completion message, inserts operation in completed send queue */
/* upon arrival of an isend operation, updates the arrival queue of the network */
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static void update_completed_queue(
        nw_state * s, tw_bf * bf, nw_message * m, tw_lp * lp, dumpi_req_id req_id);
/* reverse of the above function */
static void update_completed_queue_rc(
        nw_state*s,
        tw_bf * bf,
        nw_message * m,
        tw_lp * lp);
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static void update_arrival_queue(
        nw_state*s, tw_bf* bf, nw_message* m, tw_lp * lp);
/* reverse of the above function */
static void update_arrival_queue_rc(
        nw_state*s, tw_bf* bf, nw_message* m, tw_lp * lp);
/* callback to a message sender for computing message time */
static void update_message_time(
        nw_state*s, tw_bf* bf, nw_message* m, tw_lp * lp);
/* reverse for computing message time */
static void update_message_time_rc(
        nw_state*s, tw_bf* bf, nw_message* m, tw_lp * lp);

/* conversion from seconds to eanaoseconds */
static tw_stime s_to_ns(tw_stime ns);

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/*static void update_message_size_rc(
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        struct nw_state * ns,
        tw_lp * lp,
        tw_bf * bf,
        struct nw_message * m)
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{*/
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/*TODO: Complete reverse handler */
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/*    (void)ns;
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    (void)lp;
    (void)bf;
    (void)m;
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}*/
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/* update the message size */
static void update_message_size(
        struct nw_state * ns,
        tw_lp * lp,
        tw_bf * bf,
        struct nw_message * m,
        mpi_msgs_queue * qitem,
        int is_eager,
        int is_send)
{
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            (void)bf;
            (void)is_eager;

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            struct qhash_head * hash_link = NULL;
            tw_stime msg_init_time = qitem->req_init_time;
        
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            if(ns->msg_sz_table == NULL)
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                ns->msg_sz_table = qhash_init(msg_size_hash_compare, quickhash_64bit_hash, RANK_HASH_TABLE_SZ); 
            
            hash_link = qhash_search(ns->msg_sz_table, &(qitem->num_bytes));

            if(is_send)
                msg_init_time = m->fwd.sim_start_time;
            
            /* update hash table */
            if(!hash_link)
            {
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                struct msg_size_info * msg_info = (struct msg_size_info*)malloc(sizeof(struct msg_size_info));
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                msg_info->msg_size = qitem->num_bytes;
                msg_info->num_msgs = 1;
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                msg_info->agg_latency = tw_now(lp) - msg_init_time;
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                msg_info->avg_latency = msg_info->agg_latency;
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                assert(ns->msg_sz_table);
                qhash_add(ns->msg_sz_table, &(msg_info->msg_size), &(msg_info->hash_link));
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                qlist_add(&msg_info->ql, &ns->msg_sz_list);
                //printf("\n Msg size %d aggregate latency %f num messages %d ", m->fwd.num_bytes, msg_info->agg_latency, msg_info->num_msgs);
            }
            else
            {
                struct msg_size_info * tmp = qhash_entry(hash_link, struct msg_size_info, hash_link);
                tmp->num_msgs++;
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                tmp->agg_latency += tw_now(lp) - msg_init_time;  
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                tmp->avg_latency = (tmp->agg_latency / tmp->num_msgs);
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//                printf("\n Msg size %lld aggregate latency %f num messages %d ", qitem->num_bytes, tmp->agg_latency, tmp->num_msgs);
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            }
}
static void notify_background_traffic_rc(
	    struct nw_state * ns,
        tw_lp * lp,
        tw_bf * bf,
        struct nw_message * m)
{
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    (void)ns;
    (void)bf;
    (void)m;
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    int num_jobs = codes_jobmap_get_num_jobs(jobmap_ctx); 
    
    for(int i = 0; i < num_jobs - 1; i++)
        tw_rand_reverse_unif(lp->rng); 
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}

static void notify_background_traffic(
	    struct nw_state * ns,
        tw_lp * lp,
        tw_bf * bf,
        struct nw_message * m)
{
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        (void)bf;
        (void)m;

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        struct codes_jobmap_id jid; 
        jid = codes_jobmap_to_local_id(ns->nw_id, jobmap_ctx);
        
        int num_jobs = codes_jobmap_get_num_jobs(jobmap_ctx); 
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        //Assumption: synthetic job are at the bottom of workload configure file
        for(int other_id = num_jobs - 1; other_id >= 0; other_id--)
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        {
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            if(finished_syn_clients == num_syn_clients)
                break;
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            struct codes_jobmap_id other_jid;
            other_jid.job = other_id;

            int num_other_ranks = codes_jobmap_get_num_ranks(other_id, jobmap_ctx);

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            lprintf("\n Other ranks %d ", num_other_ranks);
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            tw_stime ts = (1.1 * g_tw_lookahead) + tw_rand_exponential(lp->rng, noise);
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            tw_lpid global_dest_id;
     
            for(int k = 0; k < num_other_ranks; k++)    
            {
                other_jid.rank = k;
                int intm_dest_id = codes_jobmap_to_global_id(other_jid, jobmap_ctx); 
                global_dest_id = codes_mapping_get_lpid_from_relative(intm_dest_id, NULL, NW_LP_NM, NULL, 0);

                tw_event * e;
                struct nw_message * m_new;  
                e = tw_event_new(global_dest_id, ts, lp);
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                m_new = (struct nw_message*)tw_event_data(e);
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                m_new->msg_type = CLI_BCKGND_FIN;
                tw_event_send(e);   
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                finished_syn_clients += 1;
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            }
        }
        return;
}
static void notify_neighbor_rc(
	    struct nw_state * ns,
        tw_lp * lp,
        tw_bf * bf,
        struct nw_message * m)
{
       if(bf->c0)
       {
            notify_background_traffic_rc(ns, lp, bf, m);
            return;
       }
   
       if(bf->c1)
       {
          tw_rand_reverse_unif(lp->rng); 
       }
} 
static void notify_neighbor(
	    struct nw_state * ns,
        tw_lp * lp,
        tw_bf * bf,
        struct nw_message * m)
{
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    int num_ranks = codes_jobmap_get_num_ranks(ns->app_id, jobmap_ctx);

    //if all application workloads finishes, notify background traffic to stop
    if(ns->local_rank == num_ranks - 1 
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            && ns->is_finished == 1
            && ns->neighbor_completed == 1)
    {
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        // printf("\n All ranks completed");
        num_dumpi_traces -= num_ranks;

        if(num_dumpi_traces == 0) {     
            // printf("All app traces finished, notify background traffic to stop\n");           
            bf->c0 = 1;
            notify_background_traffic(ns, lp, bf, m);
        }
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        return;
    }
    
    struct codes_jobmap_id nbr_jid;
    nbr_jid.job = ns->app_id;
    tw_lpid global_dest_id;

    if(ns->is_finished == 1 && (ns->neighbor_completed == 1 || ns->local_rank == 0))
    {
        bf->c1 = 1;

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//        printf("\n Local rank %d notifying neighbor %d ", ns->local_rank, ns->local_rank+1);
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        tw_stime ts = (1.1 * g_tw_lookahead) + tw_rand_exponential(lp->rng, noise);
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        nbr_jid.rank = ns->local_rank + 1;
        
        /* Send a notification to the neighbor about completion */
        int intm_dest_id = codes_jobmap_to_global_id(nbr_jid, jobmap_ctx); 
        global_dest_id = codes_mapping_get_lpid_from_relative(intm_dest_id, NULL, NW_LP_NM, NULL, 0);
       
        tw_event * e;
        struct nw_message * m_new;  
        e = tw_event_new(global_dest_id, ts, lp);
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        m_new = (struct nw_message*)tw_event_data(e); 
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        m_new->msg_type = CLI_NBR_FINISH;
        tw_event_send(e);   
    }
}
void finish_bckgnd_traffic_rc(
    struct nw_state * ns,
    tw_bf * b,
    struct nw_message * msg,
    tw_lp * lp)
{
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        (void)b;
        (void)msg;
        (void)lp;

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        ns->is_finished = 0;
        return;
}
void finish_bckgnd_traffic(
    struct nw_state * ns,
    tw_bf * b,
    struct nw_message * msg,
    tw_lp * lp)
{
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        (void)b;
        (void)msg;
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        ns->is_finished = 1;
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        lprintf("\n LP %llu completed sending data %lu completed at time %lf ", LLU(lp->gid), ns->gen_data, tw_now(lp));
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        return;
}

void finish_nbr_wkld_rc(
    struct nw_state * ns,
    tw_bf * b,
    struct nw_message * msg,
    tw_lp * lp)
{
    ns->neighbor_completed = 0;
    notify_neighbor_rc(ns, lp, b, msg);
}

void finish_nbr_wkld(
    struct nw_state * ns,
    tw_bf * b,
    struct nw_message * msg,
    tw_lp * lp)
{
    ns->neighbor_completed = 1;
    notify_neighbor(ns, lp, b, msg);
}
static void gen_synthetic_tr_rc(nw_state * s, tw_bf * bf, nw_message * m, tw_lp * lp)
{
    if(bf->c0)
        return;

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    if(bf->c1)
    {
        tw_rand_reverse_unif(lp->rng);
    }
    if(bf->c2)
    {
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        s->prev_switch = m->rc.saved_prev_switch;
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        s->saved_perm_dest = m->rc.saved_perm;
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        tw_rand_reverse_unif(lp->rng);
    }
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    int i;
    for (i=0; i < m->rc.saved_syn_length; i++){
        model_net_event_rc2(lp, &m->event_rc);
        s->gen_data -= payload_sz;
        num_syn_bytes_sent -= payload_sz;
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        s->num_bytes_sent -= payload_sz;
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        s->ross_sample.num_bytes_sent -= payload_sz;
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    }
        tw_rand_reverse_unif(lp->rng);
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        s->num_sends--;
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        s->ross_sample.num_sends--;
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     if(bf->c5)
         s->is_finished = 0;
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}

/* generate synthetic traffic */
static void gen_synthetic_tr(nw_state * s, tw_bf * bf, nw_message * m, tw_lp * lp)
{
    if(s->is_finished == 1)
    {
        bf->c0 = 1;
        return;
    }

    /* Get job information */
    tw_lpid global_dest_id;
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    int intm_dest_id;
    nw_message remote_m;
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    struct codes_jobmap_id jid;
    jid = codes_jobmap_to_local_id(s->nw_id, jobmap_ctx); 

    int num_clients = codes_jobmap_get_num_ranks(jid.job, jobmap_ctx);

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    /* Find destination */
    int* dest_svr = NULL; 
    int i, length=0;
    switch(s->synthetic_pattern)
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    {
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        case UNIFORM:
        {
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            bf->c1 = 1;
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            length = 1;
            dest_svr = (int*) calloc(1, sizeof(int));
            dest_svr[0] = tw_rand_integer(lp->rng, 0, num_clients - 1);
            if(dest_svr[0] == s->local_rank)
                dest_svr[0] = (s->local_rank + 1) % num_clients;
        }
        break;
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        case PERMUTATION:
        {
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            m->rc.saved_prev_switch = s->prev_switch; //for reverse computation

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            length = 1;
            dest_svr = (int*) calloc(1, sizeof(int));
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            if(s->gen_data - s->prev_switch >= perm_switch_thresh)
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            {
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                // printf("%d - %d >= %d\n",s->gen_data,s->prev_switch,perm_switch_thresh);
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                bf->c2 = 1;
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                m->rc.saved_prev_switch = s->prev_switch;
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                s->prev_switch = s->gen_data; //Amount of data pushed at time when switch initiated
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                dest_svr[0] = tw_rand_integer(lp->rng, 0, num_clients - 1);
                if(dest_svr[0] == s->local_rank)
                    dest_svr[0] = (s->local_rank + num_clients/2) % num_clients;
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                /* TODO: Fix random number generation code */
                m->rc.saved_perm = s->saved_perm_dest;
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                s->saved_perm_dest = dest_svr[0];
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                assert(s->saved_perm_dest != s->local_rank);
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            }
            else
                dest_svr[0] = s->saved_perm_dest;
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            assert(dest_svr[0] != s->local_rank);
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        }
        break;
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        case NEAREST_NEIGHBOR:
        {
            length = 1;
            dest_svr = (int*) calloc(1, sizeof(int));
            dest_svr[0] = (s->local_rank + 1) % num_clients;
        }
        break;
        case ALLTOALL:
        {
            dest_svr = (int*) calloc(num_clients-1, sizeof(int));
            int index = 0;
            for (i=0;i<num_clients;i++)
            {
                if(i!=s->local_rank) 
                {
                    dest_svr[index] = i;
                    index++;
                    length++;
                }
            }
        }
        break;
        case STENCIL:  //2D 4-point stencil
        {
            /* I think this code snippet is coming from the LLNL stencil patterns. */
            int digits, x=1, y=1, row, col, temp=num_clients;
            length = 4;
            dest_svr = (int*) calloc(4, sizeof(int));
            for (digits = 0; temp > 0; temp >>= 1)
                digits++;
            digits = digits/2;
            for (i = 0; i < digits; i++)
                x = x * 2;
            y = num_clients / x;
            //printf("\nStencil Syn: x=%d, y=%d", x, y);
            row = s->local_rank / y;
            col = s->local_rank % y;

            dest_svr[0] = row * y + ((col-1+y)%y);   /* left neighbor */
            dest_svr[1] = row * y + ((col+1+y)%y);   /* right neighbor */
            dest_svr[2] = ((row-1+x)%x) * y + col;   /* bottom neighbor */
            dest_svr[3] = ((row+1+x)%x) * y + col;   /* up neighbor */
        }
        break;
        default:
            tw_error(TW_LOC, "Undefined traffic pattern");
    }   
    /* Record length for reverse handler*/
    m->rc.saved_syn_length = length;
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    if(length > 0)
    {
        // m->event_array_rc = (model_net_event_return) malloc(length * sizeof(model_net_event_return));
        //printf("\nRANK %d Dests %d", s->local_rank, length);
        for (i = 0; i < length; i++)
        {
            /* Generate synthetic traffic */
            jid.rank = dest_svr[i];
            intm_dest_id = codes_jobmap_to_global_id(jid, jobmap_ctx); 
            global_dest_id = codes_mapping_get_lpid_from_relative(intm_dest_id, NULL, NW_LP_NM, NULL, 0);

            remote_m.fwd.sim_start_time = tw_now(lp);
            remote_m.fwd.dest_rank = dest_svr[i];
            remote_m.msg_type = CLI_BCKGND_ARRIVE;
            remote_m.fwd.num_bytes = payload_sz;
            remote_m.fwd.app_id = s->app_id;
            remote_m.fwd.src_rank = s->local_rank;

            // printf("\nAPP %d SRC %d Dest %d (twid %llu)", jid.job, s->local_rank, dest_svr[i], global_dest_id);
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            m->event_rc = model_net_event(net_id, "medium", global_dest_id, payload_sz, 0.0, 
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                    sizeof(nw_message), (const void*)&remote_m, 
                    0, NULL, lp);
            
            s->gen_data += payload_sz;
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            s->num_bytes_sent += payload_sz;
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            s->ross_sample.num_bytes_sent += payload_sz;
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            num_syn_bytes_sent += payload_sz; 
        }
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    }
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    s->num_sends++;
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    s->ross_sample.num_sends++;
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    /* New event after MEAN_INTERVAL */  
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    tw_stime ts = mean_interval + tw_rand_exponential(lp->rng, noise); 
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    tw_event * e;
    nw_message * m_new;
    e = tw_event_new(lp->gid, ts, lp);
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    m_new = (struct nw_message*)tw_event_data(e);
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    m_new->msg_type = CLI_BCKGND_GEN;
    tw_event_send(e);
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    if(num_qos_levels > 1) { //instead of using notify neighbor with QoS, ranks constantly check to see if they have exceeded the hard limit on data - if they have, then they're finished.
        if(s->gen_data >= max_gen_data) {
            bf->c5 = 1;
            s->is_finished = 1;
        }
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    }
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    free(dest_svr);
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}

void arrive_syn_tr_rc(nw_state * s, tw_bf * bf, nw_message * m, tw_lp * lp)
{
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    (void)bf;
    (void)m;
    (void)lp;
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//    printf("\n Data arrived %d total data %ld ", m->fwd.num_bytes, s->syn_data);
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    s->num_recvs--;
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    s->ross_sample.num_recvs--;
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    int data = m->fwd.num_bytes;
    s->syn_data -= data;
    num_syn_bytes_recvd -= data;
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    s->num_bytes_recvd -= data;
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    s->ross_sample.num_bytes_recvd -= data;
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    s->send_time = m->rc.saved_send_time;
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    s->ross_sample.send_time = m->rc.saved_send_time_sample;
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    if((tw_now(lp) - m->fwd.sim_start_time) > s->max_time)
    {
        s->max_time = m->rc.saved_prev_max_time;
        s->ross_sample.max_time = m->rc.saved_prev_max_time;
    }
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}
void arrive_syn_tr(nw_state * s, tw_bf * bf, nw_message * m, tw_lp * lp)
{
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    (void)bf;
    (void)lp;

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//    printf("\n Data arrived %d total data %ld ", m->fwd.num_bytes, s->syn_data);
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    if(s->local_rank == 0)
     {
    	printf("\n Data arrived %lld rank %llu total data %ld ", m->fwd.num_bytes, s->nw_id, s->syn_data);
/*	if(s->syn_data > upper_threshold)
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    if(s->local_rank == 0)
     {
    	printf("\n Data arrived %lld rank %llu total data %ld ", m->fwd.num_bytes, s->nw_id, s->syn_data);
	if(s->syn_data > upper_threshold)
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	{ 
        	struct rusage mem_usage;
		int who = RUSAGE_SELF;
		int err = getrusage(who, &mem_usage);
		printf("\n Memory usage %lf gigabytes", ((double)mem_usage.ru_maxrss / (1024.0 * 1024.0)));
		upper_threshold += 1048576;
	}*/
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	}
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    m->rc.saved_send_time = s->send_time;
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    m->rc.saved_send_time_sample = s->ross_sample.send_time;
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    if((tw_now(lp) - m->fwd.sim_start_time) > s->max_time)
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    {
        m->rc.saved_prev_max_time = s->max_time;
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        s->max_time = tw_now(lp) - m->fwd.sim_start_time;
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        s->ross_sample.max_time = tw_now(lp) - m->fwd.sim_start_time;
    }
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    s->send_time += (tw_now(lp) - m->fwd.sim_start_time);
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    s->ross_sample.send_time += (tw_now(lp) - m->fwd.sim_start_time);
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    s->num_recvs++;
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    s->ross_sample.num_recvs++;
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    int data = m->fwd.num_bytes;
    s->syn_data += data;
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    s->num_bytes_recvd += data;
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    s->ross_sample.num_bytes_recvd += data;
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    num_syn_bytes_recvd += data;
}
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/* Debugging functions, may generate unused function warning */
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/*static void print_waiting_reqs(uint32_t * reqs, int count)
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{
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    lprintf("\n Waiting reqs: %d count", count);
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    int i;
    for(i = 0; i < count; i++ )
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        lprintf(" %d ", reqs[i]);
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}*/
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static void print_msgs_queue(struct qlist_head * head, int is_send)
{
    if(is_send)
        printf("\n Send msgs queue: ");
    else
        printf("\n Recv msgs queue: ");

    struct qlist_head * ent = NULL;
    mpi_msgs_queue * current = NULL;
    qlist_for_each(ent, head)
       {
            current = qlist_entry(ent, mpi_msgs_queue, ql);
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            //printf(" \n Source %d Dest %d bytes %"PRId64" tag %d ", current->source_rank, current->dest_rank, current->num_bytes, current->tag);
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       }
}
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static void print_completed_queue(tw_lp * lp, struct qlist_head * head)
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{
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//    printf("\n Completed queue: ");
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      struct qlist_head * ent = NULL;
      struct completed_requests* current = NULL;
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      tw_output(lp, "\n");
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      qlist_for_each(ent, head)
       {
            current = qlist_entry(ent, completed_requests, ql);
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            tw_output(lp, " %llu ", current->req_id);
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       }
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}