Hi,
I want to quantize genann library from double/float network type to int16_t . Still I have not got the right output , see this code :
In genann.h
In genann.c using genann_act_linear function :Code:typedef int16_t genann_t; #define GENANN_MAX 10000
Can you help me fix it ?Code:void genann_train(genann const *ann, genann_t const *inputs, genann_t const *desired_outputs, float learning_rate) { /* To begin with, we must run the network forward. */ genann_run(ann, inputs); float quant_factor = GENANN_MAX; int h, j, k; /* First set the output layer deltas. */ { genann_t const *o = ann->output + ann->inputs + ann->hidden * ann->hidden_layers; /* First output. */ genann_t *d = ann->delta + ann->hidden * ann->hidden_layers; /* First delta. */ genann_t const *t = desired_outputs; /* First desired output. */ /* Set output layer deltas. */ if (genann_act_output == genann_act_linear || ann->activation_output == genann_act_linear) { for (j = 0; j < ann->outputs; ++j) { //*d++ = *t++ - *o++; float output = (float)(*o++ * quant_factor); float target = (float)(*t++ * quant_factor); float delta = target - output; *d++ = delta; } } else { for (j = 0; j < ann->outputs; ++j) { float output = (float)(*o++ * quant_factor); float target = (float)(*t++ * quant_factor); float delta = (target - output) * output * (quant_factor - output); *d++ = delta; } } } /* Set hidden layer deltas, start on last layer and work backwards. */ /* Note that loop is skipped in the case of hidden_layers == 0. */ for (h = ann->hidden_layers - 1; h >= 0; --h) { /* Find first output and delta in this layer. */ genann_t const *o = ann->output + ann->inputs + (h * ann->hidden); genann_t *d = ann->delta + (h * ann->hidden); /* Find first delta in following layer (which may be hidden or output). */ genann_t const * const dd = ann->delta + ((h+1) * ann->hidden); /* Find first weight in following layer (which may be hidden or output). */ genann_t const * const ww = ann->weight + ((ann->inputs+1) * ann->hidden) + ((ann->hidden+1) * ann->hidden * (h)); for (j = 0; j < ann->hidden; ++j) { float delta = 0; for (k = 0; k < (h == ann->hidden_layers-1 ? ann->outputs : ann->hidden); ++k) { const float forward_delta = dd[k]; const int windex = k * (ann->hidden + 1) + (j + 1); const float forward_weight = ww[windex]; delta += forward_delta * forward_weight; } float output = (float)(*o++ * quant_factor); *d++ = (genann_t)((float)output * (1.0-output) * ((float)delta * (1.0 / quant_factor))); } } /* Train the output layer */ for (int l = 0; l < ann->outputs; ++l) { float delta = ann->delta[ann->hidden * ann->hidden_layers + l]; genann_t *w; w = ann->weight + (ann->hidden_layers ? ((ann->inputs + 1) * ann->hidden + (ann->hidden + 1) * ann->hidden * (ann->hidden_layers - 1)) : 0) + l * (ann->hidden + 1); *w += delta * learning_rate * -1.0; for (int m = 0; m < ann->hidden; ++m) { int windex = m + (ann->hidden_layers ? (ann->hidden * (ann->hidden_layers - 1)) : 0); w[m+1] += delta * learning_rate * ann->output[windex]; } } /* Train the hidden layers. */ for (int n = ann->hidden_layers - 1; n >= 0; --n) { /* Find first delta in this layer. */ genann_t const *d = ann->delta + (n * ann->hidden); /* Find first input to this layer. */ genann_t const *i = ann->output + (n ? (ann->inputs + ann->hidden * (n-1)) : 0); /* Find first weight to this layer. */ genann_t *w = ann->weight + (n ? ((ann->inputs+1) * ann->hidden + (ann->hidden+1) * (ann->hidden) * (n-1)) : 0); for (int q = 0; q < ann->hidden; ++q) { *w += *d * learning_rate * -1.0; ++w; for (int r = 1; r < (n == 0 ? ann->inputs : ann->hidden) + 1; ++r) { *w += *d * learning_rate * i[r-1]; ++w; } ++d; } } }
