| #------------------------------------------------------------- |
| # |
| # Licensed to the Apache Software Foundation (ASF) under one |
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| # distributed with this work for additional information |
| # regarding copyright ownership. The ASF licenses this file |
| # to you under the Apache License, Version 2.0 (the |
| # "License"); you may not use this file except in compliance |
| # with the License. You may obtain a copy of the License at |
| # |
| # 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. |
| # |
| #------------------------------------------------------------- |
| |
| /* |
| * Max Pooling layer. |
| * |
| * This implementation is intended to be a simple, reference version. |
| */ |
| |
| forward = function(matrix[double] X, int C, int Hin, int Win, int Hf, int Wf, |
| int strideh, int stridew, int padh, int padw) |
| return (matrix[double] out, int Hout, int Wout) { |
| /* |
| * Computes the forward pass for a 2D spatial max pooling layer. |
| * The input data has N examples, each represented as a 3D volume |
| * unrolled into a single vector. |
| * |
| * This implementation is intended to be a simple, reference version. |
| * |
| * Inputs: |
| * - X: Inputs, of shape (N, C*Hin*Win). |
| * - C: Number of input channels (dimensionality of input depth). |
| * - Hin: Input height. |
| * - Win: Input width. |
| * - Hf: Filter height. |
| * - Wf: Filter width. |
| * - strideh: Stride over height. |
| * - stridew: Stride over width. |
| * - padh: Padding for top and bottom sides. |
| * A typical value is 0. |
| * - padw: Padding for left and right sides. |
| * A typical value is 0. |
| * |
| * Outputs: |
| * - out: Outputs, of shape (N, C*Hout*Wout). |
| * - Hout: Output height. |
| * - Wout: Output width. |
| */ |
| N = nrow(X) |
| Hout = as.integer(floor((Hin + 2*padh - Hf)/strideh + 1)) |
| Wout = as.integer(floor((Win + 2*padw - Wf)/stridew + 1)) |
| |
| # Create output volume |
| out = matrix(0, rows=N, cols=C*Hout*Wout) |
| |
| # Max pooling |
| parfor (n in 1:N, check=0) { # all examples |
| Xn = matrix(X[n,], rows=C, cols=Hin*Win) |
| |
| # Pad image |
| pad_value = -1/0 |
| Xn_padded = matrix(pad_value, rows=C, cols=(Hin+2*padh)*(Win+2*padw)) # zeros |
| parfor (c in 1:C) { |
| Xn_slice = matrix(Xn[c,], rows=Hin, cols=Win) # depth slice C reshaped |
| Xn_padded_slice = matrix(Xn_padded[c,], rows=Hin+2*padh, cols=Win+2*padw) |
| Xn_padded_slice[padh+1:padh+Hin, padw+1:padw+Win] = Xn_slice |
| Xn_padded[c,] = matrix(Xn_padded_slice, rows=1, cols=(Hin+2*padh)*(Win+2*padw)) # reshape |
| } |
| img = Xn_padded # shape (C, (Hin+2*padh)*(Win+2*padw)) |
| |
| parfor (c in 1:C, check=0) { # all channels |
| img_slice = matrix(img[c,], rows=Hin+2*padh, cols=Win+2*padw) |
| parfor (hout in 1:Hout, check=0) { # all output rows |
| hin = (hout-1) * strideh + 1 |
| parfor (wout in 1:Wout, check=0) { # all output columns |
| win = (wout-1) * stridew + 1 |
| out[n, (c-1)*Hout*Wout + (hout-1)*Wout + wout] = max(img_slice[hin:hin+Hf-1, |
| win:win+Wf-1]) |
| } |
| } |
| } |
| } |
| } |
| |
| backward = function(matrix[double] dout, int Hout, int Wout, matrix[double] X, |
| int C, int Hin, int Win, int Hf, int Wf, |
| int strideh, int stridew, int padh, int padw) |
| return (matrix[double] dX) { |
| /* |
| * Computes the backward pass for a 2D spatial max pooling layer. |
| * The input data has N examples, each represented as a 3D volume |
| * unrolled into a single vector. |
| * |
| * Inputs: |
| * - dout: Gradient wrt `out` from upstream, of |
| * shape (N, C*Hout*Wout). |
| * - Hout: Output height. |
| * - Wout: Output width. |
| * - X: Inputs, of shape (N, C*Hin*Win). |
| * - C: Number of input channels (dimensionality of input depth). |
| * - Hin: Input height. |
| * - Win: Input width. |
| * - Hf: Filter height. |
| * - Wf: Filter width. |
| * - strideh: Stride over height. |
| * - stridew: Stride over width. |
| * - padh: Padding for top and bottom sides. |
| * A typical value is 0. |
| * - padw: Padding for left and right sides. |
| * A typical value is 0. |
| * |
| * Outputs: |
| * - dX: Gradient wrt `X`, of shape (N, C*Hin*Win). |
| */ |
| N = nrow(X) |
| |
| # Create gradient volume |
| dX = matrix(0, rows=N, cols=C*Hin*Win) |
| |
| # Gradient of max pooling |
| for (n in 1:N) { # all examples |
| Xn = matrix(X[n,], rows=C, cols=Hin*Win) |
| |
| # Pad image |
| pad_value = -1/0 |
| Xn_padded = matrix(pad_value, rows=C, cols=(Hin+2*padh)*(Win+2*padw)) # zeros |
| parfor (c in 1:C) { |
| Xn_slice = matrix(Xn[c,], rows=Hin, cols=Win) # depth slice C reshaped |
| Xn_padded_slice = matrix(Xn_padded[c,], rows=Hin+2*padh, cols=Win+2*padw) |
| Xn_padded_slice[padh+1:padh+Hin, padw+1:padw+Win] = Xn_slice |
| Xn_padded[c,] = matrix(Xn_padded_slice, rows=1, cols=(Hin+2*padh)*(Win+2*padw)) # reshape |
| } |
| img = Xn_padded |
| |
| dimg = matrix(0, rows=C, cols=(Hin+2*padh)*(Win+2*padw)) |
| for (c in 1:C) { # all channels |
| img_slice = matrix(img[c,], rows=Hin+2*padh, cols=Win+2*padw) |
| dimg_slice = matrix(0, rows=Hin+2*padh, cols=Win+2*padw) |
| for (hout in 1:Hout, check=0) { # all output rows |
| hin = (hout-1) * strideh + 1 |
| for (wout in 1:Wout) { # all output columns |
| win = (wout-1) * stridew + 1 |
| img_slice_patch = img_slice[hin:hin+Hf-1, win:win+Wf-1] |
| max_val_ind = img_slice_patch == max(img_slice_patch) # max value indicator matrix |
| # gradient passes through only for the max value(s) in this patch |
| dimg_slice_patch = max_val_ind * dout[n, (c-1)*Hout*Wout + (hout-1)*Wout + wout] |
| dimg_slice[hin:hin+Hf-1, win:win+Wf-1] = dimg_slice[hin:hin+Hf-1, win:win+Wf-1] |
| + dimg_slice_patch |
| } |
| } |
| dimg[c,] = matrix(dimg_slice, rows=1, cols=(Hin+2*padh)*(Win+2*padw)) |
| } |
| |
| # Unpad derivs on input |
| dXn = matrix(0, rows=C, cols=Hin*Win) |
| parfor (c in 1:C, check=0) { |
| dXn_padded_slice = matrix(dimg[c,], rows=(Hin+2*padh), cols=(Win+2*padw)) |
| dXn_slice = dXn_padded_slice[padh+1:padh+Hin, padw+1:padw+Win] |
| dXn[c,] = matrix(dXn_slice, rows=1, cols=Hin*Win) |
| } |
| dX[n,] = matrix(dXn, rows=1, cols=C*Hin*Win) |
| } |
| } |
| |