| | |
|---|
| | | return l; |
|---|
| | | } |
|---|
| | | |
|---|
| | | void softmax_array(float *input, int n, float temp, float *output) |
|---|
| | | void softmax_tree(float *input, int batch, int inputs, float temp, tree *hierarchy, float *output) |
|---|
| | | { |
|---|
| | | int i; |
|---|
| | | float sum = 0; |
|---|
| | | float largest = -FLT_MAX; |
|---|
| | | for(i = 0; i < n; ++i){ |
|---|
| | | if(input[i] > largest) largest = input[i]; |
|---|
| | | } |
|---|
| | | for(i = 0; i < n; ++i){ |
|---|
| | | sum += exp(input[i]/temp-largest/temp); |
|---|
| | | } |
|---|
| | | if(sum) sum = largest/temp+log(sum); |
|---|
| | | else sum = largest-100; |
|---|
| | | for(i = 0; i < n; ++i){ |
|---|
| | | output[i] = exp(input[i]/temp-sum); |
|---|
| | | int b; |
|---|
| | | for(b = 0; b < batch; ++b){ |
|---|
| | | int i; |
|---|
| | | int count = 0; |
|---|
| | | for(i = 0; i < hierarchy->groups; ++i){ |
|---|
| | | int group_size = hierarchy->group_size[i]; |
|---|
| | | softmax(input+b*inputs + count, group_size, temp, output+b*inputs + count); |
|---|
| | | count += group_size; |
|---|
| | | } |
|---|
| | | } |
|---|
| | | } |
|---|
| | | |
|---|
| | |
|---|
| | | int b; |
|---|
| | | int inputs = l.inputs / l.groups; |
|---|
| | | int batch = l.batch * l.groups; |
|---|
| | | for(b = 0; b < batch; ++b){ |
|---|
| | | softmax_array(state.input+b*inputs, inputs, l.temperature, l.output+b*inputs); |
|---|
| | | if(l.softmax_tree){ |
|---|
| | | softmax_tree(state.input, batch, inputs, l.temperature, l.softmax_tree, l.output); |
|---|
| | | } else { |
|---|
| | | for(b = 0; b < batch; ++b){ |
|---|
| | | softmax(state.input+b*inputs, inputs, l.temperature, l.output+b*inputs); |
|---|
| | | } |
|---|
| | | } |
|---|
| | | } |
|---|
| | | |
|---|
| | |
|---|
| | | } |
|---|
| | | } |
|---|
| | | |
|---|
| | | #ifdef GPU |
|---|
| | | |
|---|
| | | void pull_softmax_layer_output(const softmax_layer layer) |
|---|
| | | { |
|---|
| | | cuda_pull_array(layer.output_gpu, layer.output, layer.inputs*layer.batch); |
|---|
| | | } |
|---|
| | | |
|---|
| | | void forward_softmax_layer_gpu(const softmax_layer l, network_state state) |
|---|
| | | { |
|---|
| | | int inputs = l.inputs / l.groups; |
|---|
| | | int batch = l.batch * l.groups; |
|---|
| | | if(l.softmax_tree){ |
|---|
| | | int i; |
|---|
| | | int count = 0; |
|---|
| | | for (i = 0; i < l.softmax_tree->groups; ++i) { |
|---|
| | | int group_size = l.softmax_tree->group_size[i]; |
|---|
| | | softmax_gpu(state.input+count, group_size, inputs, batch, l.temperature, l.output_gpu + count); |
|---|
| | | count += group_size; |
|---|
| | | } |
|---|
| | | } else { |
|---|
| | | softmax_gpu(state.input, inputs, inputs, batch, l.temperature, l.output_gpu); |
|---|
| | | } |
|---|
| | | } |
|---|
| | | |
|---|
| | | void backward_softmax_layer_gpu(const softmax_layer layer, network_state state) |
|---|
| | | { |
|---|
| | | axpy_ongpu(layer.batch*layer.inputs, 1, layer.delta_gpu, 1, state.delta, 1); |
|---|
| | | } |
|---|
| | | |
|---|
| | | #endif |
|---|
