I have seen one can define a custom loss layer for example EuclideanLoss in caffe like this:

import caffe
import numpy as np

    class EuclideanLossLayer(caffe.Layer):
        Compute the Euclidean Loss in the same manner as the C++ 
        to demonstrate the class interface for developing layers in Python.

        def setup(self, bottom, top):
            # check input pair
            if len(bottom) != 2:
                raise Exception("Need two inputs to compute distance.")

        def reshape(self, bottom, top):
            # check input dimensions match
            if bottom[0].count != bottom[1].count:
                raise Exception("Inputs must have the same dimension.")
            # difference is shape of inputs
            self.diff = np.zeros_like(bottom[0].data, dtype=np.float32)
            # loss output is scalar

        def forward(self, bottom, top):
            self.diff[...] = bottom[0].data - bottom[1].data
            top[0].data[...] = np.sum(self.diff**2) / bottom[0].num / 2.

        def backward(self, top, propagate_down, bottom):
            for i in range(2):
                if not propagate_down[i]:
                if i == 0:
                    sign = 1
                    sign = -1
                bottom[i].diff[...] = sign * self.diff / bottom[i].num

However, I have a few question regarding that code:

If I want to customise this layer and change the computation of the loss in this line:

top[0].data[...] = np.sum(self.diff**2) / bottom[0].num / 2.

Lets say to:

channelsAxis = bottom[0].data.shape[1]
self.diff[...] = np.sum(bottom[0].data, axis=channelAxis) - np.sum(bottom[1].data, axis=channelAxis)
top[0].data[...] = np.sum(self.diff**2) / bottom[0].num / 2.

How do I have to change the backward function? For EuclideanLoss it is:

bottom[i].diff[...] = sign * self.diff / bottom[i].num

How does it have to look for my described loss?

What is the sign for?

  • what weight and bias is there in Euclidean loss?? – Shai Jun 21 '17 at 11:16
  • I am sorry, I confused myself a little bit as well. I have updated the question! @Shai – user4911648 Jun 21 '17 at 11:25
  • related: stackoverflow.com/a/33797142/1714410 – Shai Jun 21 '17 at 11:30
  • top[0].data[...] = euclidean_weight * euclidean + other_weight * other is not the right way to do this. You can have a regular Euclidean loss layer with loss_weight: euclidean_weight and your own "OtherLoss" layer with loss_weight: other_weight. – Shai Jun 21 '17 at 11:32
  • 1
    bottom[i].data is an np.array of shape (num, channel, height, width). bottom[i].data.shape[0] == bottom[i].num – Shai Jun 21 '17 at 12:42

Although it can be a very educating exercise to implement the loss you are after as a "Python" layer, you can get the same loss using existing layers. All you need is to add a "Reduction" layer for each of your blobs before calling the regular "EuclideanLoss" layer:

layer {
  type: "Reduction"
  name: "rx1"
  bottom: "x1"
  top: "rx1"
  reduction_param { axis: 1 operation: SUM }
layer {
  type: "Reduction"
  name: "rx2"
  bottom: "x2"
  top: "rx2"
  reduction_param { axis: 1 operation: SUM }
layer {
  type: "EuclideanLoss"
  name: "loss"
  bottom: "rx1"
  bottom: "rx2"
  top: "loss"

Based on your comment, if you only want to sum over the channel dimension and leave all other dimensions unchanged, you can use fixed 1x1 conv (as you suggested):

layer {
  type: "Convolution"
  name: "rx1"
  bottom: "x1"
  top: "rx1"
  param { lr_mult: 0 decay_mult: 0 } # make this layer *fixed*
  convolution_param {
    num_output: 1
    kernel_size: 1
    bias_term: 0  # no need for bias
    weight_filler: { type: "constant" value: 1 } # sum
  • Okay, that is perfect! And now I can easily add weight_loss and have two EuclideanLosses am I right? – user4911648 Jun 21 '17 at 13:53
  • @thigi exactly. getting to know existing layers can allow you to be quite lazy ;) – Shai Jun 21 '17 at 13:54
  • I have thought about the solution and it is wrong! It sums over all values rather than over all channels values. So but I want to create the sum like this: y = channel1 + channel2 + channel3 ... channelN. So the sum over the channels, rather than all axes. Could you help me with that? I think one can use a Convolution layer with num_output = 1 and weight_filler = constant, value = 1 would that be correct? Could you update your answer? – user4911648 Jun 22 '17 at 7:22
  • question – user4911648 Jun 22 '17 at 7:36
  • Okay, thank you! What I do not understand, if the input lets say has 16 channels, how does the summation work? I thought caffe was treating each channel separately in convolution layers? Could you quickly extend your answer with a short expalanation? That would just be for a better understanding :) @Shai – user4911648 Jun 22 '17 at 7:45

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