/* Creates a fully recurrent network, where a
single layer contains all neurons. The
input layer maps directly to the first
'num_inputs' of the neurons, and the
output layer is the last 'num_outputs'
neurons.
THE WEIGHTS MATRIX:
+ rank <- current neuron
+ file <- neuron which current connects TO
+ The first 'num_inputs' are inputs
+ The last 'num_outputs' are outputs */
FANN_EXTERNAL struct fann *FANN_API fann_create_fully_recurrent(
unsigned int num_neurons,
unsigned int num_inputs,
unsigned int num_outputs)
{
struct fann *ann = NULL;
struct fann_descr descr;
unsigned int j = 0;
int exit_error=0;
assert(num_outputs <= num_neurons);
/* Create and setup the layers the n-1 hidden layer descriptors*/
if(fann_setup_descr(&descr, 1, num_inputs) != 0)
{
fann_error(NULL, FANN_E_CANT_ALLOCATE_MEM);
return NULL;
}
/* Create single layer with 'num_neurons' MIMO neurons*/
exit_error = fann_setup_layer_descr(
descr.layers_descr,
"fully_recurrent",
num_neurons,
NULL
);
/* Number of outputs from output layer are the number*/
/* of MIMO neurons in it, each MIMO neuron having*/
/* a single output*/
for (j=0; j<descr.layers_descr->num_neurons && ! exit_error; j++)
{
exit_error = fann_setup_neuron_descr(
descr.layers_descr->neurons_descr + j,
1,
"fully_recurrent",
NULL);
if (exit_error)
{
/*FIXME: cleanup neurons*/
break;
}
}
if (exit_error)
{
fann_error(NULL, FANN_E_CANT_ALLOCATE_MEM);
/*FIXME: cleanup layers*/
return NULL;
}
ann = fann_create_from_descr(&descr);
ann->network_type = FANN_NETTYPE_FULLY_RECURRENT;
ann->num_neurons = num_neurons;
ann->num_input = num_inputs;
ann->num_output = num_outputs;
ann->output = ann->first_layer->outputs + ann->first_layer->num_outputs - ann->num_output;
return ann;
}
struct fann * setup_net(struct fann_train_data * data)
{
struct fann *ann;
#if MIMO_FANN
#if OPTIMIZE == 0
ann = fann_create_standard( 3, data->num_input, H_DIM, data->num_output);
fann_set_activation_function_hidden(ann, FANN_SIGMOID_SYMMETRIC);
fann_set_activation_function_output(ann, FANN_SIGMOID_SYMMETRIC);
#endif
#if OPTIMIZE == 1
unsigned int i, j;
struct fann_descr *descr=(struct fann_descr*) calloc(1, sizeof(struct fann_descr));
fann_setup_descr(descr, 2, data->num_input);
i=0;
fann_setup_layer_descr(
&(descr->layers_descr[i]),
"connected_any_any",
1,
NULL
);
for (j=0; j< descr->layers_descr[i].num_neurons; j++)
{
fann_setup_neuron_descr(
descr->layers_descr[i].neurons_descr+j,
H_DIM,
"scalar_rprop_sigmoid_symmetric",
NULL
);
}
i=1;
fann_setup_layer_descr(
&(descr->layers_descr[i]),
"connected_any_any",
1,
NULL
);
for (j=0; j< descr->layers_descr[i].num_neurons; j++)
{
fann_setup_neuron_descr(
descr->layers_descr[i].neurons_descr+j,
data->num_output,
"scalar_rprop_sigmoid_symmetric",
NULL
);
}
ann = fann_create_from_descr( descr );
#endif
#if OPTIMIZE >= 2
{
unsigned int layers[] = { data->num_input, H_DIM, data->num_output };
/*char *type;
asprintf(&type, "%s_%s_%s", vals(implementation), vals(algorithm), vals(activation));*/
ann = fann_create_standard_array_typed(layer_type, neuron_type, 3, layers);
}
#endif
#else /*MIMO_FANN*/
#ifdef SPARSE
ann = fann_create_sparse( SPARSE, 3, data->num_input, H_DIM, data->num_output);
#else
ann = fann_create_standard( 3, data->num_input, H_DIM, data->num_output);
#endif
fann_set_activation_function_hidden(ann, FANN_SIGMOID_SYMMETRIC);
fann_set_activation_function_output(ann, FANN_SIGMOID_SYMMETRIC);
#endif /*MIMO_FANN*/
fann_set_train_stop_function(ann, FANN_STOPFUNC_BIT);
fann_set_bit_fail_limit(ann, 0.01f);
fann_set_activation_steepness_hidden(ann, 1);
fann_set_activation_steepness_output(ann, 1);
#if INIT_WEIGHTS == 1
fann_randomize_weights(ann,0,1);
#endif
#if INIT_WEIGHTS == 2
fann_init_weights(ann, data);
#endif
#ifdef USE_RPROP
fann_set_training_algorithm(ann, FANN_TRAIN_RPROP);
#else
fann_set_training_algorithm(ann, FANN_TRAIN_BATCH);
#endif
return ann;
}
