| #------------------------------------------------------------- |
| # |
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| # to you under the Apache License, Version 2.0 (the |
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| # http://www.apache.org/licenses/LICENSE-2.0 |
| # |
| # Unless required by applicable law or agreed to in writing, |
| # software distributed under the License is distributed on an |
| # "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY |
| # KIND, either express or implied. See the License for the |
| # specific language governing permissions and limitations |
| # under the License. |
| # |
| #------------------------------------------------------------- |
| |
| /* |
| * MNIST LeNet Example |
| */ |
| # Imports |
| source("nn/layers/affine.dml") as affine |
| source("nn/layers/conv2d_builtin.dml") as conv2d |
| source("nn/layers/cross_entropy_loss.dml") as cross_entropy_loss |
| source("nn/layers/dropout.dml") as dropout |
| source("nn/layers/l2_reg.dml") as l2_reg |
| source("nn/layers/max_pool2d_builtin.dml") as max_pool2d |
| source("nn/layers/relu.dml") as relu |
| source("nn/layers/softmax.dml") as softmax |
| source("nn/optim/sgd_nesterov.dml") as sgd_nesterov |
| |
| train = function(matrix[double] X, matrix[double] Y, |
| matrix[double] X_val, matrix[double] Y_val, |
| int C, int Hin, int Win, int epochs) |
| return (matrix[double] W1, matrix[double] b1, |
| matrix[double] W2, matrix[double] b2, |
| matrix[double] W3, matrix[double] b3, |
| matrix[double] W4, matrix[double] b4) { |
| /* |
| * Trains a convolutional net using the "LeNet" architecture. |
| * |
| * The input matrix, X, has N examples, each represented as a 3D |
| * volume unrolled into a single vector. The targets, Y, have K |
| * classes, and are one-hot encoded. |
| * |
| * Inputs: |
| * - X: Input data matrix, of shape (N, C*Hin*Win). |
| * - Y: Target matrix, of shape (N, K). |
| * - X_val: Input validation data matrix, of shape (N, C*Hin*Win). |
| * - Y_val: Target validation matrix, of shape (N, K). |
| * - C: Number of input channels (dimensionality of input depth). |
| * - Hin: Input height. |
| * - Win: Input width. |
| * - epochs: Total number of full training loops over the full data set. |
| * |
| * Outputs: |
| * - W1: 1st layer weights (parameters) matrix, of shape (F1, C*Hf*Wf). |
| * - b1: 1st layer biases vector, of shape (F1, 1). |
| * - W2: 2nd layer weights (parameters) matrix, of shape (F2, F1*Hf*Wf). |
| * - b2: 2nd layer biases vector, of shape (F2, 1). |
| * - W3: 3rd layer weights (parameters) matrix, of shape (F2*(Hin/4)*(Win/4), N3). |
| * - b3: 3rd layer biases vector, of shape (1, N3). |
| * - W4: 4th layer weights (parameters) matrix, of shape (N3, K). |
| * - b4: 4th layer biases vector, of shape (1, K). |
| */ |
| N = nrow(X) |
| K = ncol(Y) |
| |
| # Create network: |
| # conv1 -> relu1 -> pool1 -> conv2 -> relu2 -> pool2 -> affine3 -> relu3 -> affine4 -> softmax |
| Hf = 5 # filter height |
| Wf = 5 # filter width |
| stride = 1 |
| pad = 2 # For same dimensions, (Hf - stride) / 2 |
| |
| F1 = 32 # num conv filters in conv1 |
| F2 = 64 # num conv filters in conv2 |
| N3 = 512 # num nodes in affine3 |
| # Note: affine4 has K nodes, which is equal to the number of target dimensions (num classes) |
| |
| [W1, b1] = conv2d::init(F1, C, Hf, Wf) # inputs: (N, C*Hin*Win) |
| [W2, b2] = conv2d::init(F2, F1, Hf, Wf) # inputs: (N, F1*(Hin/2)*(Win/2)) |
| [W3, b3] = affine::init(F2*(Hin/2/2)*(Win/2/2), N3) # inputs: (N, F2*(Hin/2/2)*(Win/2/2)) |
| [W4, b4] = affine::init(N3, K) # inputs: (N, N3) |
| W4 = W4 / sqrt(2) # different initialization, since being fed into softmax, instead of relu |
| |
| # Initialize SGD w/ Nesterov momentum optimizer |
| lr = 0.01 # learning rate |
| mu = 0.9 #0.5 # momentum |
| decay = 0.95 # learning rate decay constant |
| vW1 = sgd_nesterov::init(W1); vb1 = sgd_nesterov::init(b1) |
| vW2 = sgd_nesterov::init(W2); vb2 = sgd_nesterov::init(b2) |
| vW3 = sgd_nesterov::init(W3); vb3 = sgd_nesterov::init(b3) |
| vW4 = sgd_nesterov::init(W4); vb4 = sgd_nesterov::init(b4) |
| |
| # Regularization |
| lambda = 5e-04 |
| |
| # Optimize |
| print("Starting optimization") |
| batch_size = 64 |
| iters = ceil(N / batch_size) |
| for (e in 1:epochs) { |
| for(i in 1:iters) { |
| # Get next batch |
| beg = ((i-1) * batch_size) %% N + 1 |
| end = min(N, beg + batch_size - 1) |
| X_batch = X[beg:end,] |
| y_batch = Y[beg:end,] |
| |
| # Compute forward pass |
| ## layer 1: conv1 -> relu1 -> pool1 |
| [outc1, Houtc1, Woutc1] = conv2d::forward(X_batch, W1, b1, C, Hin, Win, Hf, Wf, |
| stride, stride, pad, pad) |
| outr1 = relu::forward(outc1) |
| [outp1, Houtp1, Woutp1] = max_pool2d::forward(outr1, F1, Houtc1, Woutc1, Hf=2, Wf=2, |
| strideh=2, stridew=2, padh=0, padw=0) |
| ## layer 2: conv2 -> relu2 -> pool2 |
| [outc2, Houtc2, Woutc2] = conv2d::forward(outp1, W2, b2, F1, Houtp1, Woutp1, Hf, Wf, |
| stride, stride, pad, pad) |
| outr2 = relu::forward(outc2) |
| [outp2, Houtp2, Woutp2] = max_pool2d::forward(outr2, F2, Houtc2, Woutc2, Hf=2, Wf=2, |
| strideh=2, stridew=2, padh=0, padw=0) |
| ## layer 3: affine3 -> relu3 -> dropout |
| outa3 = affine::forward(outp2, W3, b3) |
| outr3 = relu::forward(outa3) |
| [outd3, maskd3] = dropout::forward(outr3, 0.5, -1) |
| ## layer 4: affine4 -> softmax |
| outa4 = affine::forward(outd3, W4, b4) |
| probs = softmax::forward(outa4) |
| |
| # Compute loss & accuracy for training & validation data every 100 iterations. |
| if (i %% 100 == 0) { |
| # Compute training loss & accuracy |
| loss_data = cross_entropy_loss::forward(probs, y_batch) |
| loss_reg_W1 = l2_reg::forward(W1, lambda) |
| loss_reg_W2 = l2_reg::forward(W2, lambda) |
| loss_reg_W3 = l2_reg::forward(W3, lambda) |
| loss_reg_W4 = l2_reg::forward(W4, lambda) |
| loss = loss_data + loss_reg_W1 + loss_reg_W2 + loss_reg_W3 + loss_reg_W4 |
| accuracy = mean(rowIndexMax(probs) == rowIndexMax(y_batch)) |
| |
| # Compute validation loss & accuracy |
| probs_val = predict(X_val, C, Hin, Win, W1, b1, W2, b2, W3, b3, W4, b4) |
| loss_val = cross_entropy_loss::forward(probs_val, Y_val) |
| accuracy_val = mean(rowIndexMax(probs_val) == rowIndexMax(Y_val)) |
| |
| # Output results |
| print("Epoch: " + e + ", Iter: " + i + ", Train Loss: " + loss + ", Train Accuracy: " |
| + accuracy + ", Val Loss: " + loss_val + ", Val Accuracy: " + accuracy_val) |
| } |
| |
| # Compute data backward pass |
| ## loss: |
| dprobs = cross_entropy_loss::backward(probs, y_batch) |
| ## layer 4: affine4 -> softmax |
| douta4 = softmax::backward(dprobs, outa4) |
| [doutd3, dW4, db4] = affine::backward(douta4, outr3, W4, b4) |
| ## layer 3: affine3 -> relu3 -> dropout |
| doutr3 = dropout::backward(doutd3, outr3, 0.5, maskd3) |
| douta3 = relu::backward(doutr3, outa3) |
| [doutp2, dW3, db3] = affine::backward(douta3, outp2, W3, b3) |
| ## layer 2: conv2 -> relu2 -> pool2 |
| doutr2 = max_pool2d::backward(doutp2, Houtp2, Woutp2, outr2, F2, Houtc2, Woutc2, Hf=2, Wf=2, |
| strideh=2, stridew=2, padh=0, padw=0) |
| doutc2 = relu::backward(doutr2, outc2) |
| [doutp1, dW2, db2] = conv2d::backward(doutc2, Houtc2, Woutc2, outp1, W2, b2, F1, |
| Houtp1, Woutp1, Hf, Wf, stride, stride, pad, pad) |
| ## layer 1: conv1 -> relu1 -> pool1 |
| doutr1 = max_pool2d::backward(doutp1, Houtp1, Woutp1, outr1, F1, Houtc1, Woutc1, Hf=2, Wf=2, |
| strideh=2, stridew=2, padh=0, padw=0) |
| doutc1 = relu::backward(doutr1, outc1) |
| [dX_batch, dW1, db1] = conv2d::backward(doutc1, Houtc1, Woutc1, X_batch, W1, b1, C, Hin, Win, |
| Hf, Wf, stride, stride, pad, pad) |
| |
| # Compute regularization backward pass |
| dW1_reg = l2_reg::backward(W1, lambda) |
| dW2_reg = l2_reg::backward(W2, lambda) |
| dW3_reg = l2_reg::backward(W3, lambda) |
| dW4_reg = l2_reg::backward(W4, lambda) |
| dW1 = dW1 + dW1_reg |
| dW2 = dW2 + dW2_reg |
| dW3 = dW3 + dW3_reg |
| dW4 = dW4 + dW4_reg |
| |
| # Optimize with SGD w/ Nesterov momentum |
| [W1, vW1] = sgd_nesterov::update(W1, dW1, lr, mu, vW1) |
| [b1, vb1] = sgd_nesterov::update(b1, db1, lr, mu, vb1) |
| [W2, vW2] = sgd_nesterov::update(W2, dW2, lr, mu, vW2) |
| [b2, vb2] = sgd_nesterov::update(b2, db2, lr, mu, vb2) |
| [W3, vW3] = sgd_nesterov::update(W3, dW3, lr, mu, vW3) |
| [b3, vb3] = sgd_nesterov::update(b3, db3, lr, mu, vb3) |
| [W4, vW4] = sgd_nesterov::update(W4, dW4, lr, mu, vW4) |
| [b4, vb4] = sgd_nesterov::update(b4, db4, lr, mu, vb4) |
| } |
| # Anneal momentum towards 0.999 |
| #mu = mu + (0.999 - mu)/(1+epochs-e) |
| # Decay learning rate |
| lr = lr * decay |
| } |
| } |
| |
| predict = function(matrix[double] X, int C, int Hin, int Win, |
| matrix[double] W1, matrix[double] b1, |
| matrix[double] W2, matrix[double] b2, |
| matrix[double] W3, matrix[double] b3, |
| matrix[double] W4, matrix[double] b4) |
| return (matrix[double] probs) { |
| /* |
| * Computes the class probability predictions of a convolutional |
| * net using the "LeNet" architecture. |
| * |
| * The input matrix, X, has N examples, each represented as a 3D |
| * volume unrolled into a single vector. |
| * |
| * Inputs: |
| * - X: Input data matrix, of shape (N, C*Hin*Win). |
| * - C: Number of input channels (dimensionality of input depth). |
| * - Hin: Input height. |
| * - Win: Input width. |
| * - W1: 1st layer weights (parameters) matrix, of shape (F1, C*Hf*Wf). |
| * - b1: 1st layer biases vector, of shape (F1, 1). |
| * - W2: 2nd layer weights (parameters) matrix, of shape (F2, F1*Hf*Wf). |
| * - b2: 2nd layer biases vector, of shape (F2, 1). |
| * - W3: 3rd layer weights (parameters) matrix, of shape (F2*(Hin/4)*(Win/4), N3). |
| * - b3: 3rd layer biases vector, of shape (1, N3). |
| * - W4: 4th layer weights (parameters) matrix, of shape (N3, K). |
| * - b4: 4th layer biases vector, of shape (1, K). |
| * |
| * Outputs: |
| * - probs: Class probabilities, of shape (N, K). |
| */ |
| N = nrow(X) |
| |
| # Network: |
| # conv1 -> relu1 -> pool1 -> conv2 -> relu2 -> pool2 -> affine3 -> relu3 -> affine4 -> softmax |
| Hf = 5 # filter height |
| Wf = 5 # filter width |
| stride = 1 |
| pad = 2 # For same dimensions, (Hf - stride) / 2 |
| |
| F1 = nrow(W1) # num conv filters in conv1 |
| F2 = nrow(W2) # num conv filters in conv2 |
| N3 = ncol(W3) # num nodes in affine3 |
| K = ncol(W4) # num nodes in affine4, equal to number of target dimensions (num classes) |
| |
| # Compute predictions over mini-batches |
| probs = matrix(0, rows=N, cols=K) |
| batch_size = 64 |
| iters = ceil(N / batch_size) |
| for(i in 1:iters) { |
| # Get next batch |
| beg = ((i-1) * batch_size) %% N + 1 |
| end = min(N, beg + batch_size - 1) |
| X_batch = X[beg:end,] |
| |
| # Compute forward pass |
| ## layer 1: conv1 -> relu1 -> pool1 |
| [outc1, Houtc1, Woutc1] = conv2d::forward(X_batch, W1, b1, C, Hin, Win, Hf, Wf, stride, stride, |
| pad, pad) |
| outr1 = relu::forward(outc1) |
| [outp1, Houtp1, Woutp1] = max_pool2d::forward(outr1, F1, Houtc1, Woutc1, Hf=2, Wf=2, |
| strideh=2, stridew=2, padh=0, padw=0) |
| ## layer 2: conv2 -> relu2 -> pool2 |
| [outc2, Houtc2, Woutc2] = conv2d::forward(outp1, W2, b2, F1, Houtp1, Woutp1, Hf, Wf, |
| stride, stride, pad, pad) |
| outr2 = relu::forward(outc2) |
| [outp2, Houtp2, Woutp2] = max_pool2d::forward(outr2, F2, Houtc2, Woutc2, Hf=2, Wf=2, |
| strideh=2, stridew=2, padh=0, padw=0) |
| ## layer 3: affine3 -> relu3 |
| outa3 = affine::forward(outp2, W3, b3) |
| outr3 = relu::forward(outa3) |
| ## layer 4: affine4 -> softmax |
| outa4 = affine::forward(outr3, W4, b4) |
| probs_batch = softmax::forward(outa4) |
| |
| # Store predictions |
| probs[beg:end,] = probs_batch |
| } |
| } |
| |
| eval = function(matrix[double] probs, matrix[double] Y) |
| return (double loss, double accuracy) { |
| /* |
| * Evaluates a convolutional net using the "LeNet" architecture. |
| * |
| * The probs matrix contains the class probability predictions |
| * of K classes over N examples. The targets, Y, have K classes, |
| * and are one-hot encoded. |
| * |
| * Inputs: |
| * - probs: Class probabilities, of shape (N, K). |
| * - Y: Target matrix, of shape (N, K). |
| * |
| * Outputs: |
| * - loss: Scalar loss, of shape (1). |
| * - accuracy: Scalar accuracy, of shape (1). |
| */ |
| # Compute loss & accuracy |
| loss = cross_entropy_loss::forward(probs, Y) |
| correct_pred = rowIndexMax(probs) == rowIndexMax(Y) |
| accuracy = mean(correct_pred) |
| } |
| |
| generate_dummy_data = function() |
| return (matrix[double] X, matrix[double] Y, int C, int Hin, int Win) { |
| /* |
| * Generate a dummy dataset similar to the MNIST dataset. |
| * |
| * Outputs: |
| * - X: Input data matrix, of shape (N, D). |
| * - Y: Target matrix, of shape (N, K). |
| * - C: Number of input channels (dimensionality of input depth). |
| * - Hin: Input height. |
| * - Win: Input width. |
| */ |
| # Generate dummy input data |
| N = 1024 # num examples |
| C = 1 # num input channels |
| Hin = 28 # input height |
| Win = 28 # input width |
| K = 10 # num target classes |
| X = rand(rows=N, cols=C*Hin*Win, pdf="normal") |
| classes = round(rand(rows=N, cols=1, min=1, max=K, pdf="uniform")) |
| Y = table(seq(1, N), classes) # one-hot encoding |
| } |
| |