/*************************************************************************
 * Copyright (c) 2016-2020, NVIDIA CORPORATION. All rights reserved.
 * Modifications Copyright (c) 2019-2020 Advanced Micro Devices, Inc. All rights reserved.
 *
 * See LICENSE.txt for license information
 ************************************************************************/

#include <sched.h>
#include <fcntl.h>
#include <unistd.h>
#include <hip/hip_runtime.h>
#include <string.h>
#include <errno.h>
#include <assert.h>
#include <dlfcn.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <unistd.h>
#include <cstdio>
#include <iostream>
#include <cstring>
#include "comm.h"
#include "net.h"
#include "graph.h"
#include <sys/time.h>
#include <numaif.h>
#include <sys/socket.h>
#include <netinet/in.h>
#include <arpa/inet.h>
#include <numa.h>
#include <list>
#include <iterator>

struct ibtestProxyArgs {
  proxyProgressFunc_t progress;
  struct ncclChannel* channel;
  struct ncclConnector* connector;
  int sliceSteps;
  int chunkSteps;
  int nsteps;
  uint64_t opCount;
  int protocol;
  ncclDataType_t dtype;
  ncclRedOp_t redOp;
  int state;   // add component before this line -- it is left out during initialization

  // Internal state
  uint64_t head;
  uint64_t tail;
  uint64_t end;
  void* requests[NCCL_STEPS];
  int idle;

  // Element linking
  pthread_mutex_t mutex;
  struct ibtestProxyArgs* next;
  struct ibtestProxyArgs* nextPeer;
};

ncclResult_t initNet();

char* getCmdOption(char ** begin, char ** end, const std::string & option) {
    char ** itr = std::find(begin, end, option);
    if (itr != end && ++itr != end)
    {
        return *itr;
    }
    return 0;
}

bool cmdOptionExists(char** begin, char** end, const std::string& option) {
    return std::find(begin, end, option) != end;
}

#define DEFAULT_BUFFSIZE (1LL << 22) /* 4MiB */
#define SLICE_STEPS 4
#define DEFAULT_CYCLES 4000
#define VEGA_GPU_RTC_FREQUENCY 2.5E7
#define ENABLE_VALIDATION
#define USE_UNROLL 8

typedef ulong2 Pack128;

__device__
inline  __attribute((always_inline))
long long int __rtc64() {
#if __HIP__
  return (long long int) __builtin_amdgcn_s_memrealtime();
#else
  return (long long int) __clock_u64();
#endif
}

inline __device__ void Fetch128(Pack128& v, const Pack128* p) {
  v.x = p->x;
  v.y = p->y;
}
inline __device__ void Store128(Pack128* p, Pack128& v) {
  p->x = v.x;
  p->y = v.y;
}

template<int UNROLL, bool SINK>
inline __device__ void DataSourceOrSink(const int w, const int nw, const int t,
    Pack128* buff, const int Npack, uint64_t seq, uint64_t *error) {
  const int inc = nw * UNROLL * WARP_SIZE;
  int offset = w * UNROLL * WARP_SIZE + t;

  Pack128* src = buff + offset;

  uint64_t x = (uint64_t)(offset) + (seq<<32);
  uint64_t y = seq + (((uint64_t)(offset))<<32);
  while (offset < Npack) {
    Pack128 vals[UNROLL];
    if (SINK) {
      for (int u = 0; u < UNROLL; ++u) Fetch128(vals[u], src + u*WARP_SIZE);
      for (int u = 0; u < UNROLL; ++u) {
          if (vals[u].x != x++ || vals[u].y != y++ ) {
          __atomic_fetch_add(error, 1, __ATOMIC_SEQ_CST);
        }
      }
    } else {
      for (int u = 0; u < UNROLL; ++u) {
        vals[u].x = x++;
        vals[u].y = y++;
      }
      for (int u = 0; u < UNROLL; ++u) Store128(src + u*WARP_SIZE, vals[u]);
    }
    src += inc;
    offset += inc;
  }
}

__global__ void DataSinkKernel(const uint64_t end, Pack128* data, uint64_t* recv_head, uint64_t* recv_tail, uint64_t* mismatch, uint64_t *sink_cycle, uint64_t *sink_bytes) {
  const int N = DEFAULT_BUFFSIZE*SLICE_STEPS/NCCL_STEPS/sizeof(Pack128);
  Pack128* recvBuff[NCCL_STEPS];
  const int tid = threadIdx.x;
  uint64_t tail = LOAD(recv_tail);
  __shared__ uint64_t error;
  const int w = tid / WARP_SIZE;
  const int nw = blockDim.x / WARP_SIZE;
  const int t = tid % WARP_SIZE;
  uint64_t t0;
  if (tid == 0) error = 0;
  __syncthreads();
  for (int i = 0; i < NCCL_STEPS; i++)
    recvBuff[i] = data + (i/SLICE_STEPS)*N;
  do {
    if (tid == 0) while (LOAD(recv_head) < tail + SLICE_STEPS);
    __syncthreads();
    if (tid == 0) t0 = __rtc64();
#ifdef ENABLE_VALIDATION
    Pack128* d = recvBuff[tail%NCCL_STEPS];
    DataSourceOrSink<USE_UNROLL, 1>(w, nw, t, recvBuff[tail%NCCL_STEPS], N, tail, &error);
    __syncthreads();
#endif
    tail += SLICE_STEPS;
    if (tid == 0) {
      STORE(recv_tail, tail);
      *sink_cycle += (__rtc64() - t0);
      *sink_bytes += N;
    }
  } while (tail < end);
  if (tid == 0) STORE(mismatch, error);
}


__global__ void DataSourceKernel(const uint64_t end, Pack128* data, uint64_t* send_head, uint64_t* send_tail, uint64_t *source_cycle, uint64_t *source_bytes) {
  const int N = DEFAULT_BUFFSIZE*SLICE_STEPS/NCCL_STEPS/sizeof(Pack128);
  Pack128* sendBuff[NCCL_STEPS];
  const int tid = threadIdx.x;
  uint64_t head = LOAD(send_head);
  const int w = tid / WARP_SIZE;
  const int nw = blockDim.x / WARP_SIZE;
  const int t = tid % WARP_SIZE;
  uint64_t t0;
  for (int i = 0; i < NCCL_STEPS; i++)
    sendBuff[i] = data + (i/SLICE_STEPS)*N;
  do {
    if (tid == 0) while (LOAD(send_tail) + NCCL_STEPS < head + SLICE_STEPS);
    __syncthreads();
    if (tid == 0) t0 = __rtc64();
    DataSourceOrSink<USE_UNROLL, 0>(w, nw, t, sendBuff[head%NCCL_STEPS], N, head, 0);
    __syncthreads();
    head += SLICE_STEPS;
    if (tid == 0) {
      STORE(send_head, head);
      *source_cycle += (__rtc64() - t0);
      *source_bytes += N;
    }
  } while (head < end);
}

class sendrecvChannel {
protected:
  int id;
  hipStream_t stream;

public:
  sendrecvChannel(int id) : id(id) {
    hipStreamCreate(&stream);
  }

  virtual ~sendrecvChannel() {
    hipStreamDestroy(stream);
  }

  virtual void launchKernel(uint64_t end) = 0;
  virtual void printProgress(uint64_t total_time) = 0;
  virtual bool netProxy() = 0;
};

class sendChannel : public sendrecvChannel {
private:
  struct sockaddr_in netConnectAddr;
  void* netSendComm;
  int netSendDev;
  char *sendDevBuffer;
  char *sendHostBuffer, *d_sendHostBuffer;
  void *sendDevHandle;
  void *sendHostHandle;
  int sendBuffSize;
  uint64_t *sendHead, *sendTail, *sourceCycle, *sourceBytes;
  struct timeval send_tvs;
  uint64_t send_sizes;
  int send_active_req;
  float send_bw_cumulative;
  int send_bw_count;
  uint64_t send_byte;
  bool runSend;
  bool use_gdr_read;
  int sliceSteps;
  struct ibtestProxyArgs args;

  ncclResult_t connect(char* ip, uint16_t port) {
    inet_pton(AF_INET, ip, &netConnectAddr.sin_addr);
    if (port)
      netConnectAddr.sin_port = htons(port);
    else
      netConnectAddr.sin_port = htons(23456);

    netConnectAddr.sin_family = AF_INET;
    printf("Connecting to %s:%d\n", ip, ntohs(netConnectAddr.sin_port));

    printf("GDR Read %s\n", use_gdr_read ? "enabled" : "disabled");

    if (use_gdr_read) {
      NCCLCHECK(ncclCudaCalloc(&sendDevBuffer, sendBuffSize, 1));
      printf("Allocated sendDevBuffer %p of %d bytes, sliceSteps %d\n",
                sendDevBuffer, sendBuffSize, sliceSteps);
    }
    else {
      NCCLCHECK(ncclCudaHostCalloc(&sendHostBuffer, sendBuffSize));
      d_sendHostBuffer = sendHostBuffer;
      int status[1] = {-1};
      if (!move_pages(0, 1, (void **)&sendHostBuffer, NULL, status, 0))
        printf("Allocated sendHostBuffer %p of %d bytes on node %d, sliceSteps %d\n",
          sendHostBuffer, sendBuffSize, status[0], sliceSteps);
    }

    NCCLCHECK(ncclCudaHostCalloc(&sendHead, 1));
    NCCLCHECK(ncclCudaHostCalloc(&sendTail, 1));
    NCCLCHECK(ncclCudaHostCalloc(&sourceCycle, 1));
    NCCLCHECK(ncclCudaHostCalloc(&sourceBytes, 1));
    netSendDev = 0;
    NCCLCHECK(ncclNetConnect(netSendDev, &netConnectAddr, &netSendComm));

    if (use_gdr_read) {
      NCCLCHECK(ncclNetRegMr(netSendComm, sendDevBuffer, sendBuffSize, NCCL_PTR_CUDA, &sendDevHandle));
    } else {
      NCCLCHECK(ncclNetRegMr(netSendComm, sendHostBuffer, sendBuffSize, NCCL_PTR_HOST, &sendHostHandle));
    }

    return ncclSuccess;
  }

  ncclResult_t teardown() {
    NCCLCHECK(ncclCudaHostFree(sourceCycle));
    NCCLCHECK(ncclCudaHostFree(sourceBytes));
    NCCLCHECK(ncclCudaHostFree(sendHead));
    NCCLCHECK(ncclCudaHostFree(sendTail));
    if (use_gdr_read) {
      NCCLCHECK(ncclNetDeregMr(netSendComm, sendDevHandle));
      CUDACHECK(hipFree(sendDevBuffer));
    } else {
      NCCLCHECK(ncclNetDeregMr(netSendComm, sendHostHandle));
      NCCLCHECK(ncclCudaHostFree(sendHostBuffer));
    }
    NCCLCHECK(ncclNetCloseSend(netSendComm));
    return ncclSuccess;
  }

public:
  sendChannel(int id, bool gdr_read, char* ip, uint16_t port) : sendrecvChannel(id), use_gdr_read(gdr_read) {
    sendBuffSize = DEFAULT_BUFFSIZE;
    sliceSteps = SLICE_STEPS;
    connect(ip, port);
  }

  ~sendChannel() {
    teardown();
  }

  bool netProxy() {
    char* localBuff = use_gdr_read ? sendDevBuffer : sendHostBuffer;
    void* mhandle = use_gdr_read ? sendDevHandle : sendHostHandle;
    int stepSize = sendBuffSize / NCCL_STEPS;
    int sliceSize = stepSize * args.sliceSteps;
    if (!runSend) return runSend;
    if (args.head < args.end) {
      if (args.tail < args.end && args.tail < args.head + NCCL_STEPS) {
        if (args.tail < LOAD(sendHead)) {
          int buffSlot = args.tail%NCCL_STEPS;
          NCCLCHECK(ncclNetIsend(netSendComm, localBuff+buffSlot*stepSize, sliceSize, mhandle, args.requests+buffSlot));
          if (args.requests[buffSlot] != NULL) {
            if (send_active_req == 0) {
              gettimeofday(&send_tvs, NULL);
              send_sizes = 0;
            }
            send_active_req ++;
            send_sizes += sliceSize;
            send_byte += sliceSize;
            __sync_synchronize();
            args.tail += args.sliceSteps;
            args.idle = 0;
          }
        }
      }
      if (args.head < args.tail) {
        int done;
        int buffSlot = args.head%NCCL_STEPS;
        NCCLCHECK(ncclNetTest(args.requests[buffSlot], &done, NULL));
        if (done) {
          send_active_req --;
          if (send_active_req == 0) {
            struct timeval tv;
            gettimeofday(&tv, NULL);
            send_bw_cumulative += (float)send_sizes/((tv.tv_sec - send_tvs.tv_sec)*1000*1000 + tv.tv_usec - send_tvs.tv_usec)/1000.0;
            send_bw_count ++;
          }
          args.head += args.sliceSteps;
          STORE(sendTail, args.head);
          args.idle = 0;
        }
      }
    }
    else
      runSend = false;
    return runSend;
  }

  void launchKernel(uint64_t end) {
    *sendHead = 0; *sendTail = 0; *sourceCycle = 0; *sourceBytes = 0;
    send_sizes = 0; send_bw_cumulative = 0; send_bw_count =0; send_byte = 0;
    memset(&args, 0, sizeof(struct ibtestProxyArgs));
    args.head = 0;
    args.tail = 0;
    args.end = end;
    args.sliceSteps = SLICE_STEPS;
    hipLaunchKernelGGL(DataSourceKernel, dim3(1, 1, 1), dim3(256, 1, 1), 0, stream,
      end, (Pack128 *)(use_gdr_read ? sendDevBuffer : d_sendHostBuffer), sendHead, sendTail, sourceCycle, sourceBytes);
    runSend = true;
  }

  void printProgress(uint64_t total_time) {
    if (send_byte) printf("# Send[%d] %3ld%% %6.2f GB/s (%ld bytes %ld us) Proxy %6.2f GB/s (%d mmts) Kernel %6.2f GB/s (%ld bytes)\n",
      id, args.head*100/args.end, (total_time) ? (double)send_byte/total_time/1000.0 : 0,
      send_byte, total_time, send_bw_count ? (float)send_bw_cumulative/send_bw_count : 0, send_bw_count,
      *sourceCycle ? (double)(*sourceBytes)*sizeof(Pack128)/((double)(*sourceCycle)/VEGA_GPU_RTC_FREQUENCY*1.0E9) : 0, *sourceBytes*sizeof(Pack128));
  }
};

class recvChannel : public sendrecvChannel {
private:
  struct sockaddr_in netListenAddr;
  void* netListenComm;
  void* netRecvComm;
  int netRecvDev;
  char *recvDevBuffer;
  char *recvHostBuffer, *d_recvHostBuffer;
  void *recvDevHandle;
  void *recvHostHandle;
  int recvBuffSize;
  uint64_t *recvHead, *recvTail, *recvErrorCount, *sinkCycle, *sinkBytes;
  struct timeval recv_tvs;
  uint64_t recv_sizes;
  int recv_active_req;
  float recv_bw_cumulative;
  int recv_bw_count;
  uint64_t recv_byte;
  bool runRecv;
  bool use_gdr_write;
  int sliceSteps;
  struct ibtestProxyArgs args;

  ncclResult_t listen() {
    printf("GDR Write %s\n", use_gdr_write ? "enabled" : "disabled");

    if (use_gdr_write) {
      NCCLCHECK(ncclCudaCalloc(&recvDevBuffer, recvBuffSize, 1));
      printf("Allocated recvDevBuffer %p of %d bytes, sliceSteps %d\n",
                recvDevBuffer, recvBuffSize, sliceSteps);
    }
    else {
      NCCLCHECK(ncclCudaHostCalloc(&recvHostBuffer, recvBuffSize));
      d_recvHostBuffer = recvHostBuffer;
      int status[1] = {-1};
      if (!move_pages(0, 1, (void **)&recvHostBuffer, NULL, status, 0))
        printf("Allocated recvHostBuffer %p of %d bytes on node %d, sliceSteps %d\n",
          recvHostBuffer, recvBuffSize, status[0], sliceSteps);
    }

    NCCLCHECK(ncclCudaHostCalloc(&recvHead, 1));
    NCCLCHECK(ncclCudaHostCalloc(&recvTail, 1));
    NCCLCHECK(ncclCudaHostCalloc(&recvErrorCount, 1));
    NCCLCHECK(ncclCudaHostCalloc(&sinkCycle, 1));
    NCCLCHECK(ncclCudaHostCalloc(&sinkBytes, 1));
    netRecvDev = 0;
    NCCLCHECK(ncclNetListen(netRecvDev, (void *)&netListenAddr, &netListenComm));
    char ip[INET_ADDRSTRLEN];
    uint16_t port;
    inet_ntop(AF_INET, &netListenAddr.sin_addr, ip, sizeof(ip));
    port = htons(netListenAddr.sin_port);
    printf("Listening on socket %s:%d\n", ip, port);

    NCCLCHECK(ncclNetAccept(netListenComm, &netRecvComm));
    NCCLCHECK(ncclNetCloseListen(netListenComm));

    if (use_gdr_write) {
      NCCLCHECK(ncclNetRegMr(netRecvComm, recvDevBuffer, recvBuffSize, NCCL_PTR_CUDA, &recvDevHandle));
    } else {
      NCCLCHECK(ncclNetRegMr(netRecvComm, recvHostBuffer, recvBuffSize, NCCL_PTR_HOST, &recvHostHandle));
    }

    return ncclSuccess;
  }

  ncclResult_t teardown() {
    NCCLCHECK(ncclCudaHostFree(sinkCycle));
    NCCLCHECK(ncclCudaHostFree(sinkBytes));
    NCCLCHECK(ncclCudaHostFree(recvErrorCount));
    NCCLCHECK(ncclCudaHostFree(recvHead));
    NCCLCHECK(ncclCudaHostFree(recvTail));
    if (use_gdr_write) {
      NCCLCHECK(ncclNetDeregMr(netRecvComm, recvDevHandle));
      CUDACHECK(hipFree(recvDevBuffer));
    } else {
      NCCLCHECK(ncclNetDeregMr(netRecvComm, recvHostHandle));
      NCCLCHECK(ncclCudaHostFree(recvHostBuffer));
    }
    NCCLCHECK(ncclNetCloseRecv(netRecvComm));
    return ncclSuccess;
  }

public:
  recvChannel(int id, bool gdr_write) : sendrecvChannel(id), use_gdr_write(gdr_write) {
    recvBuffSize = DEFAULT_BUFFSIZE;
    sliceSteps = SLICE_STEPS;
    listen();
  }

  ~recvChannel() {
    teardown();
  }

  bool netProxy() {
    char* localBuff = use_gdr_write ? recvDevBuffer : recvHostBuffer;
    void* mhandle = use_gdr_write ? recvDevHandle : recvHostHandle;
    int stepSize = recvBuffSize / NCCL_STEPS;
    if (!runRecv) return runRecv;
    if (args.head < args.end) {
      if ((args.tail < args.head + NCCL_STEPS) && (args.tail < LOAD(recvTail) + NCCL_STEPS) && (args.tail < args.end)) {
        int buffSlot = args.tail%NCCL_STEPS;
        int sliceSize = stepSize * args.sliceSteps;
        NCCLCHECK(ncclNetIrecv(netRecvComm, localBuff+buffSlot*stepSize, sliceSize, mhandle, args.requests+buffSlot));
        if (args.requests[buffSlot] != NULL) {
          if (recv_active_req == 0) {
            gettimeofday(&recv_tvs, NULL);
            recv_sizes = 0;
          }
          recv_active_req ++;
          args.tail += args.sliceSteps;
          args.idle = 0;
        }
      }
      if (args.tail > args.head) {
        int buffSlot = args.head%NCCL_STEPS;
        int done, size;
        NCCLCHECK(ncclNetTest(args.requests[buffSlot], &done, &size));
        if (done) {
          recv_active_req --;
          recv_sizes += size;
          if (recv_active_req == 0) {
            struct timeval tv;
            gettimeofday(&tv, NULL);
            recv_bw_cumulative += (float)recv_sizes/((tv.tv_sec - recv_tvs.tv_sec)*1000*1000 + tv.tv_usec - recv_tvs.tv_usec)/1000.0;
            recv_bw_count ++;
          }
          args.head += args.sliceSteps;
          recv_byte += size;
          NCCLCHECK(ncclNetIflush(netRecvComm, localBuff+buffSlot*stepSize, size, mhandle, args.requests+buffSlot));
          STORE(recvHead, args.head);
          args.idle = 0;
        }
      }
    } else {
      runRecv = false;
    }
    return runRecv;
  }

  void launchKernel(uint64_t end) {
    *recvHead = 0; *recvTail = 0; *recvErrorCount = 0; *sinkCycle = 0, *sinkBytes = 0;
    recv_sizes = 0; recv_bw_cumulative = 0; recv_bw_count =0; recv_byte = 0;
    memset(&args, 0, sizeof(struct ibtestProxyArgs));
    args.head = 0;
    args.tail = 0;
    args.end = end;
    args.sliceSteps = SLICE_STEPS;
    hipLaunchKernelGGL(DataSinkKernel, dim3(1, 1, 1), dim3(256, 1, 1), 0, stream,
      end, (Pack128 *)(use_gdr_write ? recvDevBuffer : d_recvHostBuffer), recvHead, recvTail, recvErrorCount, sinkCycle, sinkBytes);
    runRecv = true;
  }

  void printProgress(uint64_t total_time) {
    if (recv_byte) printf("# Recv[%d] %3ld%% %6.2f GB/s (%ld bytes %ld us) Proxy %6.2f GB/s (%d mmts) Kernel %6.2f GB/s (%ld bytes) Errors %ld\n",
      id, args.head*100/args.end, (total_time) ? (double)recv_byte/total_time/1000.0 : 0,
      recv_byte, total_time, recv_bw_count ? (float)recv_bw_cumulative/recv_bw_count : 0, recv_bw_count,
      *sinkCycle ? (double)(*sinkBytes)*sizeof(Pack128)/((double)(*sinkCycle)/VEGA_GPU_RTC_FREQUENCY*1.0E9) : 0, *sinkBytes*sizeof(Pack128),
      *recvErrorCount);
  }
};

#define FOR_EACH \
  for (std::list<sendrecvChannel*>::iterator it = sendrecvChans.begin(); it != sendrecvChans.end(); it++)

int main(int argc,char* argv[])
{
  struct ncclComm *comm;
  bool isSource;
  bool use_gdr_read = false, use_gdr_write = true;
  int port;
  std::list<sendrecvChannel*> sendrecvChans;
  int nc = 1;
  uint64_t iterations = 1;

  NCCLCHECK(initNet());
  int ndev;
  NCCLCHECK(ncclNetDevices(&ndev));
  if (ndev == 0) {
    printf("No IB devices found.\n");
    return 0;
  }
  else
    printf("Found %d IB devices\n", ndev);

  char *gpu = getCmdOption(argv, argv + argc, "-g");
  if (gpu) {
    printf("Select GPU %s\n", gpu);
    CUDACHECK(hipSetDevice(atol(gpu)));
  }

  char *c = getCmdOption(argv, argv + argc, "-c");
  if (c) {
    printf("Number of channels %s\n", c);
    nc = atol(c);
  }

  char *iters = getCmdOption(argv, argv + argc, "-i");
  if (iters) {
    iterations = atol(iters);
    printf("Running %ld iterations\n", iterations);
  }

  char *gdr_read = getCmdOption(argv, argv + argc, "-r");
  if (gdr_read) {
    use_gdr_read = atol(gdr_read);
  }

  char *gdr_write = getCmdOption(argv, argv + argc, "-w");
  if (gdr_write) {
    use_gdr_write = atol(gdr_write);
  }

  char *node = getCmdOption(argv, argv + argc, "-n");
  if (node) {
#if 0
    unsigned long nodemask = 1;
    nodemask <<= atol(node);
    set_mempolicy(MPOL_PREFERRED, (const unsigned long*)&nodemask, 16);
    printf("Select node %s for preferred memory allocation\n", node);
#else
    int ret = numa_run_on_node(atol(node));
    if (ret != 0)
      printf("Failed to run on numa node %s\n", node);
    else
      printf("thread is set to run on numa node %ld\n", atol(node));
#endif
  }

  if (cmdOptionExists(argv, argv + argc, "-d")) {
    char *ip = getCmdOption(argv, argv + argc, "-d");
    char *p = getCmdOption(argv, argv + argc, "-p");
    uint16_t port = 23456;
    if (p) port = atol(p);
    for (int i = 0; i < nc; i++) sendrecvChans.push_back(new sendChannel(i, use_gdr_read, ip, port++));
    isSource = true;
  } else {
    for (int i = 0; i < nc; i++) sendrecvChans.push_back(new recvChannel(i, use_gdr_write));
    isSource = false;
  }

  printf("Running warm up...");
  FOR_EACH (*it)->launchKernel(NCCL_STEPS);

  bool run;
  do {
    run = false;
    FOR_EACH run |= (*it)->netProxy();
  } while (run);

  CUDACHECK(hipDeviceSynchronize());
  printf("completed\n");

  // reset all counters after warm up cycle
  FOR_EACH (*it)->launchKernel(NCCL_STEPS*iterations*DEFAULT_CYCLES);

  struct timeval tv_start, tv_end, tv_prev;
  gettimeofday(&tv_start, NULL);
  gettimeofday(&tv_prev, NULL);

  do {
    run = false;
    FOR_EACH run |= (*it)->netProxy();

    gettimeofday(&tv_end, NULL);
    uint64_t timelap = ((uint64_t)(tv_end.tv_sec - tv_prev.tv_sec)*1000*1000 + tv_end.tv_usec - tv_prev.tv_usec);
    if (timelap > 100000UL) {
      uint64_t total_time = ((uint64_t)(tv_end.tv_sec - tv_start.tv_sec)*1000*1000 + tv_end.tv_usec - tv_start.tv_usec);
      FOR_EACH (*it)->printProgress(total_time);
      gettimeofday(&tv_prev, NULL);
    }
  } while (run);

  CUDACHECK(hipDeviceSynchronize());

  gettimeofday(&tv_end, NULL);
  uint64_t total_time = ((uint64_t)(tv_end.tv_sec - tv_start.tv_sec)*1000*1000 + tv_end.tv_usec - tv_start.tv_usec);

  FOR_EACH (*it)->printProgress(total_time);
  FOR_EACH delete *it;

  return 0;
}