nn/nn_old.js

var NN = {};

NN.TrainingSet = {};
NN.TrainingSet.Instances = [];
NN.TrainingSet.Create = function()
{
    var obj = {};

    obj.Input = [];
    obj.Output = [];
    obj.Order = [];
    
    NN.TrainingSet.Instances.push(obj);
    return obj;
};
NN.TrainingSet.AddPoint = function(inTrainingSet, inType, inData)
{
    inTrainingSet.Input.push(inData);
    inTrainingSet.Output.push(inType);
    inTrainingSet.Order.push(inTrainingSet.Order.length);
};
NN.TrainingSet.AddCloud = function(inTrainingSet, inLabel, inCloud)
{
    var i;
    for(i=0; i<inCloud.length; i++)
    {
        NN.TrainingSet.AddPoint(inTrainingSet, inLabel, inCloud[i]);
    }
};
NN.TrainingSet.Randomize = function(inTrainingSet)
{
      var newOrder = [];
      var selection;
      while(inTrainingSet.Order.length != 0)
      {
          selection = Math.floor(inTrainingSet.Order.length * Math.random());
          inTrainingSet.Order.splice(selection, 1);
          newOrder.push(selection);
      }
      inTrainingSet.Order = newOrder;
};


NN.Layer = {};
NN.Layer.Create = function(sizeIn, sizeOut)
{
    var i;
    var min = [];
    var max = [];
    var obj = {};
    
    sizeIn++;
    
    obj.Forward = {};
    for(i=0; i<sizeIn; i++)
    {
        min.push(-1);
        max.push(1);
    }
    obj.Forward.Matrix = M.Box([min, max], sizeOut);
    obj.Forward.StageInput = [];
    obj.Forward.StageAffine = [];
    obj.Forward.StageSigmoid = [];
    obj.Forward.StageDerivative = [];
    
    obj.Backward = {};
    obj.Backward.Matrix = M.Transpose(obj.Forward.Matrix);
    obj.Backward.StageInput = [];
    obj.Backward.StageDerivative = [];
    obj.Backward.StageAffine = [];
    
    return obj;
};
NN.Layer.Forward = function(inLayer, inInput)
{
    inLayer.Forward.StageInput = M.Pad(inInput); // Pad the input
    inLayer.Forward.StageAffine = M.Transform(inLayer.Forward.Matrix, inLayer.Forward.StageInput);
    inLayer.Forward.StageSigmoid = M.Sigmoid(inLayer.Forward.StageAffine);
    
    return inLayer.Forward.StageSigmoid;
};
NN.Layer.Error = function(inLayer, inTarget)
{
    return M.Subtract(inLayer.Forward.StageSigmoid, inTarget);
};
NN.Layer.Backward = function(inLayer, inInput)
{
    /* We need the derivative of the forward pass, but only during the backward pass.
    That's why-- even though it "belongs" to the forward pass-- it is being calculated here. */
    inLayer.Forward.StageDerivative = M.Derivative(inLayer.Forward.StageSigmoid);
    
    /* This transpose matrix is for sending the error back to a previous layer.
    And again, even though it is derived directly from the forward matrix, it is only needed during the backward pass so we calculate it here.*/
    inLayer.Backward.Matrix = M.Transpose(inLayer.Forward.Matrix);
    
    /* When the error vector arrives at a layer, it always needs to be multiplied (read 'supressed') by the derivative of
    what the layer output earlier during the forward pass.
    So despite its name, Backward.StageDerivative contains the result of this *multiplication* and not some new derivative calculation.*/
    inLayer.Backward.StageInput = inInput;
    inLayer.Backward.StageDerivative = M.Multiply(inLayer.Backward.StageInput, inLayer.Forward.StageDerivative);
    inLayer.Backward.StageAffine = M.Transform(inLayer.Backward.Matrix, inLayer.Backward.StageDerivative);
    
    return M.Unpad(inLayer.Backward.StageAffine);// Unpad the output
};
NN.Layer.Adjust = function(inLayer, inLearningRate)
{
    var deltas;
    var vector;
    var scalar;
    var i, j;
    
    for(i=0; i<inLayer.Forward.StageInput.length; i++)
    {
        deltas = M.Outer(inLayer.Forward.StageInput[i], inLayer.Backward.StageDerivative[i]);
        deltas = M.Scale(deltas, inLearningRate);
        
        inLayer.Forward.Matrix = M.Subtract(inLayer.Forward.Matrix, deltas);
    }
};
NN.Layer.Stochastic = function(inLayer, inTrainingSet, inIterations)
{
    /* this method is ONLY for testing individual layers, and does not translate to network-level training */
    var i, j;
    var current;
    var error;
    for(i=0; i<inIterations; i++)
    {
        NN.TrainingSet.Randomize(inTrainingSet);
        for(j=0; j<inTrainingSet.Order.length; j++)
        {
            current = inTrainingSet.Order[j];
            NN.Layer.Forward(inLayer, [inTrainingSet.Input[current]]);
            error = M.Subtract(inLayer.Forward.StageSigmoid, [inTrainingSet.Output[current]]);
            NN.Layer.Backward(inLayer, error);
            NN.Layer.Adjust(inLayer, 0.1);
        }
    }
};

NN.Network = {};
NN.Network.Instances = [];
NN.Network.Create = function()
{
    var obj = {};
    var i;    
    
    obj.Layers = [];
    obj.LearningRate = 0.8;
    obj.Error = [];
    
    for(i=0; i<arguments.length-1; i++)
    {
        obj.Layers.push(NN.Layer.Create(arguments[i], arguments[i+1]));
    }
    
    NN.Network.Instances.push(obj);
    return obj;
};
NN.Network.Observe = function(inNetwork, inBatch)
{
      var input = M.Clone(inBatch);
      var i;
      for(i=0; i<inNetwork.Layers.length; i++)
      {
          input = NN.Layer.Forward(inNetwork.Layers[i], input);
      }
      return inNetwork.Layers[inNetwork.Layers.length-1].Forward.StageSigmoid;
};
NN.Network.Error = function(inNetwork, inTraining)
{
      return M.Subtract(inNetwork.Layers[inNetwork.Layers.length-1].Forward.StageSigmoid, inTraining);
};
NN.Network.Learn = function(inNetwork, inError)
{
      var input = inError;
      var i;
      for(i=inNetwork.Layers.length-1; i>=0; i--)
      {
          input = NN.Layer.Backward(inNetwork.Layers[i], input);
          NN.Layer.Adjust(inNetwork.Layers[i], inNetwork.LearningRate);
      }
};


NN.Network.Batch = function(inNetwork, inTrainingSet, inIterations)
{
    var i;
    for(i=0; i<inIterations; i++)
    {
        NN.Network.Observe(inNetwork, inTrainingSet.Input);
        inNetwork.Error = NN.Network.Error(inNetwork, inTrainingSet.Output)
        NN.Network.Learn(inNetwork, inNetwork.Error);
    }
};
NN.Network.Stochastic = function(inNetwork, inTrainingSet, inIterations)
{
    var i, j;
    var current;
    
    for(i=0; i<inIterations; i++)
    {
        NN.TrainingSet.Randomize(inTrainingSet);
        for(j=0; j<inTrainingSet.Order.length; j++)
        {
            current = inTrainingSet.Order[j];
            NN.Network.Observe(inNetwork, [inTrainingSet.Input[current]]);
            inNetwork.Error = NN.Network.Error(inNetwork, [inTrainingSet.Output[current]]);
            NN.Network.Learn(inNetwork, inNetwork.Error);
        }
    }
};
setup 2021-07-25 18:17:54 -04:00			`var NN = {};`

			`NN.TrainingSet = {};`
			`NN.TrainingSet.Instances = [];`
			`NN.TrainingSet.Create = function()`
			`{`
			`var obj = {};`

			`obj.Input = [];`
			`obj.Output = [];`
			`obj.Order = [];`

			`NN.TrainingSet.Instances.push(obj);`
			`return obj;`
			`};`
			`NN.TrainingSet.AddPoint = function(inTrainingSet, inType, inData)`
			`{`
			`inTrainingSet.Input.push(inData);`
			`inTrainingSet.Output.push(inType);`
			`inTrainingSet.Order.push(inTrainingSet.Order.length);`
			`};`
			`NN.TrainingSet.AddCloud = function(inTrainingSet, inLabel, inCloud)`
			`{`
			`var i;`
			`for(i=0; i<inCloud.length; i++)`
			`{`
			`NN.TrainingSet.AddPoint(inTrainingSet, inLabel, inCloud[i]);`
			`}`
			`};`
			`NN.TrainingSet.Randomize = function(inTrainingSet)`
			`{`
			`var newOrder = [];`
			`var selection;`
			`while(inTrainingSet.Order.length != 0)`
			`{`
			`selection = Math.floor(inTrainingSet.Order.length * Math.random());`
			`inTrainingSet.Order.splice(selection, 1);`
			`newOrder.push(selection);`
			`}`
			`inTrainingSet.Order = newOrder;`
			`};`


			`NN.Layer = {};`
			`NN.Layer.Create = function(sizeIn, sizeOut)`
			`{`
			`var i;`
			`var min = [];`
			`var max = [];`
			`var obj = {};`

			`sizeIn++;`

			`obj.Forward = {};`
			`for(i=0; i<sizeIn; i++)`
			`{`
			`min.push(-1);`
			`max.push(1);`
			`}`
			`obj.Forward.Matrix = M.Box([min, max], sizeOut);`
			`obj.Forward.StageInput = [];`
			`obj.Forward.StageAffine = [];`
			`obj.Forward.StageSigmoid = [];`
			`obj.Forward.StageDerivative = [];`

			`obj.Backward = {};`
			`obj.Backward.Matrix = M.Transpose(obj.Forward.Matrix);`
			`obj.Backward.StageInput = [];`
			`obj.Backward.StageDerivative = [];`
			`obj.Backward.StageAffine = [];`

			`return obj;`
			`};`
			`NN.Layer.Forward = function(inLayer, inInput)`
			`{`
			`inLayer.Forward.StageInput = M.Pad(inInput); // Pad the input`
			`inLayer.Forward.StageAffine = M.Transform(inLayer.Forward.Matrix, inLayer.Forward.StageInput);`
			`inLayer.Forward.StageSigmoid = M.Sigmoid(inLayer.Forward.StageAffine);`

			`return inLayer.Forward.StageSigmoid;`
			`};`
			`NN.Layer.Error = function(inLayer, inTarget)`
			`{`
			`return M.Subtract(inLayer.Forward.StageSigmoid, inTarget);`
			`};`
			`NN.Layer.Backward = function(inLayer, inInput)`
			`{`
			`/* We need the derivative of the forward pass, but only during the backward pass.`
			`That's why-- even though it "belongs" to the forward pass-- it is being calculated here. */`
			`inLayer.Forward.StageDerivative = M.Derivative(inLayer.Forward.StageSigmoid);`

			`/* This transpose matrix is for sending the error back to a previous layer.`
			`And again, even though it is derived directly from the forward matrix, it is only needed during the backward pass so we calculate it here.*/`
			`inLayer.Backward.Matrix = M.Transpose(inLayer.Forward.Matrix);`

			`/* When the error vector arrives at a layer, it always needs to be multiplied (read 'supressed') by the derivative of`
			`what the layer output earlier during the forward pass.`
			`So despite its name, Backward.StageDerivative contains the result of this multiplication and not some new derivative calculation.*/`
			`inLayer.Backward.StageInput = inInput;`
			`inLayer.Backward.StageDerivative = M.Multiply(inLayer.Backward.StageInput, inLayer.Forward.StageDerivative);`
			`inLayer.Backward.StageAffine = M.Transform(inLayer.Backward.Matrix, inLayer.Backward.StageDerivative);`

			`return M.Unpad(inLayer.Backward.StageAffine);// Unpad the output`
			`};`
			`NN.Layer.Adjust = function(inLayer, inLearningRate)`
			`{`
			`var deltas;`
			`var vector;`
			`var scalar;`
			`var i, j;`

			`for(i=0; i<inLayer.Forward.StageInput.length; i++)`
			`{`
			`deltas = M.Outer(inLayer.Forward.StageInput[i], inLayer.Backward.StageDerivative[i]);`
			`deltas = M.Scale(deltas, inLearningRate);`

			`inLayer.Forward.Matrix = M.Subtract(inLayer.Forward.Matrix, deltas);`
			`}`
			`};`
			`NN.Layer.Stochastic = function(inLayer, inTrainingSet, inIterations)`
			`{`
			`/* this method is ONLY for testing individual layers, and does not translate to network-level training */`
			`var i, j;`
			`var current;`
			`var error;`
			`for(i=0; i<inIterations; i++)`
			`{`
			`NN.TrainingSet.Randomize(inTrainingSet);`
			`for(j=0; j<inTrainingSet.Order.length; j++)`
			`{`
			`current = inTrainingSet.Order[j];`
			`NN.Layer.Forward(inLayer, [inTrainingSet.Input[current]]);`
			`error = M.Subtract(inLayer.Forward.StageSigmoid, [inTrainingSet.Output[current]]);`
			`NN.Layer.Backward(inLayer, error);`
			`NN.Layer.Adjust(inLayer, 0.1);`
			`}`
			`}`
			`};`

			`NN.Network = {};`
			`NN.Network.Instances = [];`
			`NN.Network.Create = function()`
			`{`
			`var obj = {};`
			`var i;`

			`obj.Layers = [];`
			`obj.LearningRate = 0.8;`
			`obj.Error = [];`

			`for(i=0; i<arguments.length-1; i++)`
			`{`
			`obj.Layers.push(NN.Layer.Create(arguments[i], arguments[i+1]));`
			`}`

			`NN.Network.Instances.push(obj);`
			`return obj;`
			`};`
			`NN.Network.Observe = function(inNetwork, inBatch)`
			`{`
			`var input = M.Clone(inBatch);`
			`var i;`
			`for(i=0; i<inNetwork.Layers.length; i++)`
			`{`
			`input = NN.Layer.Forward(inNetwork.Layers[i], input);`
			`}`
			`return inNetwork.Layers[inNetwork.Layers.length-1].Forward.StageSigmoid;`
			`};`
			`NN.Network.Error = function(inNetwork, inTraining)`
			`{`
			`return M.Subtract(inNetwork.Layers[inNetwork.Layers.length-1].Forward.StageSigmoid, inTraining);`
			`};`
			`NN.Network.Learn = function(inNetwork, inError)`
			`{`
			`var input = inError;`
			`var i;`
			`for(i=inNetwork.Layers.length-1; i>=0; i--)`
			`{`
			`input = NN.Layer.Backward(inNetwork.Layers[i], input);`
			`NN.Layer.Adjust(inNetwork.Layers[i], inNetwork.LearningRate);`
			`}`
			`};`


			`NN.Network.Batch = function(inNetwork, inTrainingSet, inIterations)`
			`{`
			`var i;`
			`for(i=0; i<inIterations; i++)`
			`{`
			`NN.Network.Observe(inNetwork, inTrainingSet.Input);`
			`inNetwork.Error = NN.Network.Error(inNetwork, inTrainingSet.Output)`
			`NN.Network.Learn(inNetwork, inNetwork.Error);`
			`}`
			`};`
			`NN.Network.Stochastic = function(inNetwork, inTrainingSet, inIterations)`
			`{`
			`var i, j;`
			`var current;`

			`for(i=0; i<inIterations; i++)`
			`{`
			`NN.TrainingSet.Randomize(inTrainingSet);`
			`for(j=0; j<inTrainingSet.Order.length; j++)`
			`{`
			`current = inTrainingSet.Order[j];`
			`NN.Network.Observe(inNetwork, [inTrainingSet.Input[current]]);`
			`inNetwork.Error = NN.Network.Error(inNetwork, [inTrainingSet.Output[current]]);`
			`NN.Network.Learn(inNetwork, inNetwork.Error);`
			`}`
			`}`
			`};`