Esempio n. 1
0
int main(int argc, char** argv){
  NNet network;
  network.setSeed(0);

  NNet::Layer* inputLayer = new NNet::Layer(2);
  network.addLayer(inputLayer);
  network.addLayer(NNet::sigmoidFunc, 2000, -IW, IW);
  network.addLayer(NNet::sigmoidFunc, 2000, -IW, IW);
  network.addLayer(NNet::sigmoidFunc, 2000, -IW, IW);
  network.addLayer(NNet::sigmoidFunc, 2, -IW, IW);

  NNet::Layer* outputLayer = network.backLayer(0);

  // normally we would train the network before executing it, for the
  // sake of demonstration, this step is omitted. See examples/nnet_train.

  // test the performance by executing it on the C++ side
  double t1 = NSys::now();
  inputLayer->neuron(0)->input(0.25);
  inputLayer->neuron(1)->input(0.70);
  double dt = NSys::now() - t1;
  cout << "c++ time is: " << dt << endl;

  cout << "output[0]= " << outputLayer->neuron(0)->output() << endl;
  cout << "output[1]= " << outputLayer->neuron(1)->output() << endl;

  // an NNModule holds compiled neural networks
  NNModule module;
  t1 = NSys::now();

  // compile the neural network to run with 8 threads, giving it the
  // name "test"
  module.compile("test", network, 8);
  dt = NSys::now() - t1;
  cout << "compile time is: " << dt << endl;

  // the input and output layers must be a NPLVector of double's and
  // of the length which matches the C++ side network as constructed
  // above
  typedef NPLVector<double, 2> Vec2;

  Vec2 inputs;
  inputs[0] = 0.25;
  inputs[1] = 0.70;

  Vec2 outputs;

  t1 = NSys::now();
  // execute the network
  module.run("test", &inputs, &outputs);
  dt = NSys::now() - t1;
  cout << "run time is: " << dt << endl;

  // verify that these outputs match our first outputs
  cout << "outputs: " << outputs << endl;

  // delete the resources used by the compiled neural network named "test"
  module.remove("test");

  return 0;
}
Esempio n. 2
0
  bool compile(const nstr& name,
               NNet& network,
               size_t threads){

    RunNetwork* runNetwork = new RunNetwork;

    NNet::Layer* inputLayer = network.layer(0);

    size_t numLayers = network.numLayers();

    RunLayer* lastRunLayer = 0;

    for(size_t l = 1; l < numLayers; ++l){
      RunLayer* runLayer = new RunLayer;
      runLayer->queue = new Queue(threads);

      size_t inputLayerSize = inputLayer->size();

      NNet::Layer* layer = network.layer(l);

      size_t layerSize  = layer->size();

      if(l > 1){
        runLayer->inputVecStart = lastRunLayer->outputVecStart;
        runLayer->inputVec = lastRunLayer->outputVec;
      }

      if(l < numLayers - 1){
        double* outputVecPtrStart;
        double* outputVecPtr;
        allocVector(layerSize, &outputVecPtrStart, &outputVecPtr);
        runLayer->outputVecStart = outputVecPtrStart;
        runLayer->outputVec = outputVecPtr;
      }

      TypeVec args;
      args.push_back(getPointer(doubleVecType(inputLayerSize)));
      args.push_back(getPointer(doubleVecType(inputLayerSize)));
      args.push_back(getPointer(doubleType()));
      args.push_back(int32Type());

      FunctionType* ft = FunctionType::get(voidType(), args, false);
      
      Function* f = 
        Function::Create(ft, Function::ExternalLinkage,
                         name.c_str(), &module_);

      BasicBlock* entry = BasicBlock::Create(context_, "entry", f);
      
      builder_.SetInsertPoint(entry);

      auto aitr = f->arg_begin();
      
      Value* inputVecPtr = aitr;
      inputVecPtr->setName("input_vec_ptr");

      ++aitr;
      Value* weightVecPtr = aitr;
      weightVecPtr->setName("weight_vec_ptr");

      ++aitr;
      Value* outputVecPtr = aitr;
      outputVecPtr->setName("output_vec_ptr");

      ++aitr;
      Value* outputIndex = aitr;
      outputIndex->setName("output_index");

      Value* inputVec = 
        builder_.CreateLoad(inputVecPtr, "input_vec");

      Value* weightVec = 
        builder_.CreateLoad(weightVecPtr, "weight_vec");

      Value* mulVec = 
        builder_.CreateFMul(inputVec, weightVec, "mul_vec");
      
      Value* sumActivation = 
        builder_.CreateExtractElement(mulVec, getInt32(0), "sum_elem");

      for(size_t i = 1; i < inputLayerSize; ++i){
        Value* elem = 
          builder_.CreateExtractElement(mulVec, getInt32(i), "sum_elem");
        
        sumActivation = 
          builder_.CreateFAdd(sumActivation, elem, "sum_activation");
      }

      Value* output = 
        getActivationOutput(layer->neuron(0), sumActivation);

      Value* outputElement = 
        builder_.CreateGEP(outputVecPtr, outputIndex, "out_elem");

      builder_.CreateStore(output, outputElement);

      builder_.CreateRetVoid(); 

      runLayer->f = f;

      runLayer->fp = (void (*)(void*, void*, void*, int))
        engine_->getPointerToFunction(f);

      for(size_t j = 0; j < layerSize; ++j){
        NNet::Neuron* nj = layer->neuron(j);

        RunNeuron* runNeuron = new RunNeuron;
        runNeuron->layer = runLayer;
        runNeuron->outputIndex = j;

        double* weightVecPtrStart;
        double* weightVecPtr;
        allocVector(inputLayerSize, &weightVecPtrStart, &weightVecPtr);
        runNeuron->weightVecStart = weightVecPtrStart;
        runNeuron->weightVec = weightVecPtr;

        for(size_t i = 0; i < inputLayerSize; ++i){
          NNet::Neuron* ni = inputLayer->neuron(i);
          weightVecPtr[i] = nj->weight(ni);
        }

        runLayer->queue->add(runNeuron);
      }

      runNetwork->layerVec.push_back(runLayer);

      inputLayer = layer;
      lastRunLayer = runLayer;
    }

    networkMap_.insert(make_pair(name, runNetwork));

    return true;
  }