triton/examples/cpp/conv.cpp

#include <cstring>
#include <cstdio>
#include "common.hpp"
#include "triton/jit.h"
#include "triton/driver/backend.h"
#include "triton/driver/stream.h"
#include "triton/dnn/conv.h"

int main() {
  // initialize default compute device
  auto context = triton::driver::backend::contexts::get_default();
  triton::jit jit(context);
  triton::dnn::conv::type ty = triton::dnn::conv::WGRAD;
  // initialization
  int32_t B = 4, NF = 32;
  int32_t D = 1, H = 24, W = 240;
  int32_t NC = 32, T = 1, R = 3, S = 3;
  int32_t pad_d = 0, pad_h = 1, pad_w = 1;
  triton::dnn::conv configuration(B, NC, D, H, W, T, R, S, NF, 1, 1, 1, pad_d, pad_h, pad_w, ty);
  // convolution configuration
  std::vector<float> hc(configuration.c_size());
  std::vector<float> rc(configuration.c_size());
  std::vector<float> ha(configuration.a_size());
  std::vector<float> hb(configuration.b_size());
  srand(0);
  for(size_t i = 0; i < ha.size(); i++)
    ha[i] = (float)rand()/RAND_MAX;
  for(size_t i = 0; i < hb.size(); i++)
    hb[i] = (float)rand()/RAND_MAX;
  for(size_t i = 0; i < hc.size(); i++)
    hc[i] = 0;
  rc = hc;
  triton::driver::buffer* dc = triton::driver::buffer::create(context, hc.size()*4);
  triton::driver::buffer* da = triton::driver::buffer::create(context, ha.size()*4);
  triton::driver::buffer* db = triton::driver::buffer::create(context, hb.size()*4);
  triton::driver::stream* stream = triton::driver::stream::create(context);
  stream->write(da, true, 0, ha);
  stream->write(db, true, 0, hb);
  stream->write(dc, true, 0, hc);
  stream->synchronize();
  // look-up table
  std::vector<int> h_delta, h_masks;
  if(ty != triton::dnn::conv::WGRAD){
    configuration.build_deltas(h_delta);
    configuration.build_masks(h_masks);
  }
  // benchmark a given convolution kernel
  auto benchmark = [&](triton::driver::kernel* kernel,
                       triton::jit::launch_information info) {
    unsigned TM = info.global_range_size[0];
    unsigned TN = info.global_range_size[1];
    unsigned nthreads = info.num_threads;
    std::array<size_t, 3> grid = configuration.get_grid(TM, TN);
    if(ty != triton::dnn::conv::WGRAD){
      triton::driver::buffer* delta = jit.get_buffer("delta");
      triton::driver::buffer* masks = jit.get_buffer("masks");
      stream->write(delta, false, 0, h_delta.size()*4, h_delta.data());
      stream->write(masks, false, 0, h_masks.size()*4, h_masks.data());
    }
    stream->synchronize();
    configuration.set_arg(kernel, da, db, dc);
    stream->enqueue(kernel, grid, {nthreads, 1, 1});
    stream->synchronize();
    double ts = bench([&](){stream->enqueue(kernel, grid, {nthreads, 1, 1});},
                      [&](){ stream->synchronize(); }, *context->device());
    return configuration.get_nflops() / ts * 1e-3;
  };
  std::string src = configuration.src();
//  jit.autotune("conv", src.c_str(), benchmark);
  jit.add_module("conv", src.c_str(), configuration.default_params());
  triton::driver::kernel* kernel = jit.get_function("conv");
  triton::jit::launch_information info = jit.get_launch_info("conv");
  std::cout << "Performance: " << benchmark(kernel, info) << " TFLOPS " << std::endl;
  stream->read(dc, true, 0, hc);
  configuration.cpu_ref(rc.data(), ha.data(), hb.data());
  for(size_t i = 0; i < hc.size(); i++){
    if(std::abs(hc[i] - rc[i])/std::max(hc[i], rc[i]) > 1e-4){
      std::cout << i << " " << hc[i] << " " << rc[i] << std::endl;
      exit(EXIT_FAILURE);
    }
  }
  std::cout << "Pass!" << std::endl;
}