// *********************************************************
// -(set up new device and monitor)-------------------------
void impmap_update_output_vector_positions(impmap *x)
{
int i, k=0, count;
int num_outputs = mapper_device_num_signals(x->device, MAPPER_DIR_OUTGOING) - 1;
// store output signal pointers
mapper_signal signals[num_outputs];
mapper_signal *psig = mapper_device_signals(x->device, MAPPER_DIR_OUTGOING);
i = 0;
while (psig) {
if (*psig != x->dummy_output)
signals[i++] = *psig;
psig = mapper_signal_query_next(psig);
}
// sort output signal pointer array
qsort(signals, num_outputs, sizeof(mapper_signal), compare_signal_names);
// set offsets and user_data
for (i = 0; i < num_outputs; i++) {
x->signals_out[i].offset = k;
mapper_signal_set_user_data(signals[i], &x->signals_out[i]);
k += mapper_signal_length(signals[i]);
}
count = k < MAX_LIST ? k : MAX_LIST;
if (count != x->size_out && x->num_snapshots) {
post("implicitmap: output vector size has changed - resetting snapshots!");
impmap_clear_snapshots(x);
}
x->size_out = count;
}
// *********************************************************
// -(query handler)-----------------------------------------
void impmap_on_query(mapper_signal sig, mapper_id instance, const void *value,
int count, mapper_timetag_t *time)
{
t_signal_ref *ref = mapper_signal_user_data(sig);
if (!ref) {
post("implicitmap: no user data for signal '%s' in on_input()",
mapper_signal_name(sig));
}
impmap *x = ref->x;
int i, len = mapper_signal_length(sig);
float *valf = (float*)value;
for (i = 0; i < len; i++) {
if (ref->offset + i >= MAX_LIST) {
post("mapper: Maximum vector length exceeded!");
break;
}
if (valf)
x->snapshots->outputs[ref->offset + i] = valf[i];
}
x->query_count --;
if (x->query_count == 0) {
clock_unset(x->timeout);
impmap_output_snapshot(x);
}
}
// *********************************************************
// -(anything)----------------------------------------------
void impmap_list(impmap *x, t_symbol *s, int argc, t_atom *argv)
{
if (x->mute)
return;
if (argc != x->size_out) {
post("vector size mismatch");
return;
}
int i = 0;
mapper_timetag_now(&x->tt);
mapper_device_start_queue(x->device, x->tt);
mapper_signal *psig = mapper_device_signals(x->device, MAPPER_DIR_OUTGOING);
while (psig) {
if (*psig == x->dummy_output) {
psig = mapper_signal_query_next(psig);
continue;
}
t_signal_ref *ref = mapper_signal_user_data(*psig);
int len = mapper_signal_length(*psig);
float v[len];
for (i = 0; i < len; i++) {
v[i] = atom_getfloat(argv + ref->offset + i);
}
mapper_signal_update(*psig, v, 1, x->tt);
psig = mapper_signal_query_next(psig);
}
mapper_device_send_queue(x->device, x->tt);
outlet_anything(x->outlet2, gensym("out"), argc, argv);
}
void query_response_handler(mapper_signal sig, mapper_id instance,
const void *value, int count,
mapper_timetag_t *timetag)
{
int i;
if (value) {
eprintf("--> source got query response: %s ", mapper_signal_name(sig));
for (i = 0; i < mapper_signal_length(sig) * count; i++)
eprintf("%i ", ((int*)value)[i]);
eprintf("\n");
}
else {
eprintf("--> source got empty query response: %s\n",
mapper_signal_name(sig));
}
received++;
}
// *********************************************************
// -(input handler)-----------------------------------------
void impmap_on_input(mapper_signal sig, mapper_id instance, const void *value,
int count, mapper_timetag_t *time)
{
t_signal_ref *ref = mapper_signal_user_data(sig);
if (!ref) {
post("implicitmap: no user data for signal '%s' in on_input()",
mapper_signal_name(sig));
}
impmap *x = ref->x;
int i, len = mapper_signal_length(sig);
float *valf = (float*)value;
for (i = 0; i < len; i++) {
if (ref->offset + i >= MAX_LIST) {
post("implicitmap: Maximum vector length exceeded!");
break;
}
maxpd_atom_set_float(x->buffer_in + ref->offset + i, valf ? valf[i] : 0);
}
x->new_in = 1;
}
// *********************************************************
// -(randomize)---------------------------------------------
void impmap_randomize(impmap *x)
{
int i;
float rand_val;
if (x->ready) {
mapper_timetag_now(&x->tt);
mapper_device_start_queue(x->device, x->tt);
mapper_signal *psig = mapper_device_signals(x->device, MAPPER_DIR_OUTGOING);
while (psig) {
if (*psig == x->dummy_output) {
psig = mapper_signal_query_next(psig);
continue;
}
t_signal_ref *ref = mapper_signal_user_data(*psig);
if (mapper_signal_type(*psig) != 'f')
continue;
int length = mapper_signal_length(*psig);
float v[length];
float *min = (float*)mapper_signal_minimum(*psig);
float *max = (float*)mapper_signal_maximum(*psig);
for (i = 0; i < length; i++) {
rand_val = (float)rand() / (float)RAND_MAX;
if (min && max) {
v[i] = rand_val * (max[i] - min[i]) + min[i];
}
else {
// if ranges have not been declared, assume normalized between 0 and 1
v[i] = rand_val;
}
maxpd_atom_set_float(x->buffer_out + ref->offset + i, v[i]);
}
mapper_signal_update(*psig, v, 1, x->tt);
psig = mapper_signal_query_next(psig);
}
mapper_device_send_queue(x->device, x->tt);
outlet_anything(x->outlet2, gensym("out"), x->size_out, x->buffer_out);
}
}
// *********************************************************
// -(connection handler)------------------------------------
void impmap_on_map(mapper_device dev, mapper_map map, mapper_record_event e)
{
// if connected involves current generic signal, create a new generic signal
impmap *x = (void*)mapper_device_user_data(dev);
if (!x) {
post("error in connect handler: user_data is NULL");
return;
}
if (!x->ready) {
post("error in connect handler: device not ready");
return;
}
// retrieve devices and signals
mapper_slot slot = mapper_map_slot(map, MAPPER_LOC_SOURCE, 0);
mapper_signal src_sig = mapper_slot_signal(slot);
mapper_device src_dev = mapper_signal_device(src_sig);
slot = mapper_map_slot(map, MAPPER_LOC_DESTINATION, 0);
mapper_signal dst_sig = mapper_slot_signal(slot);
mapper_device dst_dev = mapper_signal_device(dst_sig);
// sanity check: don't allow self-connections
if (src_dev == dst_dev) {
mapper_map_release(map);
return;
}
char full_name[256];
if (e == MAPPER_ADDED) {
if (src_dev == x->device) {
snprintf(full_name, 256, "%s/%s", mapper_device_name(dst_dev),
mapper_signal_name(dst_sig));
if (strcmp(mapper_signal_name(src_sig), full_name) == 0) {
// <thisDev>:<dstDevName>/<dstSigName> -> <dstDev>:<dstSigName>
return;
}
if (mapper_device_num_signals(x->device, MAPPER_DIR_OUTGOING) >= MAX_LIST) {
post("Max outputs reached!");
return;
}
// unmap the generic signal
mapper_map_release(map);
// add a matching output signal
int i, length = mapper_signal_length(dst_sig);
char type = mapper_signal_type(dst_sig);
void *min = mapper_signal_minimum(dst_sig);
void *max = mapper_signal_maximum(dst_sig);
float *minf = 0, *maxf = 0;
if (type == 'f') {
minf = (float*)min;
maxf = (float*)max;
}
else {
if (min) {
minf = alloca(length * sizeof(float));
if (type == 'i') {
int *mini = (int*)min;
for (i = 0; i < length; i++)
minf[i] = (float)mini[i];
}
else if (type == 'd') {
double *mind = (double*)min;
for (i = 0; i < length; i++)
minf[i] = (float)mind[i];
}
else
minf = 0;
}
if (max) {
maxf = alloca(length * sizeof(float));
if (type == 'i') {
int *maxi = (int*)max;
for (i = 0; i < length; i++)
maxf[i] = (float)maxi[i];
}
else if (type == 'd') {
double *maxd = (double*)max;
for (i = 0; i < length; i++)
maxf[i] = (float)maxd[i];
}
else
maxf = 0;
}
}
src_sig = mapper_device_add_output_signal(x->device, full_name,
length, 'f', 0, minf, maxf);
if (!src_sig) {
post("error creating new source signal!");
return;
}
mapper_signal_set_callback(src_sig, impmap_on_query);
// map the new signal
map = mapper_map_new(1, &src_sig, 1, &dst_sig);
mapper_map_set_mode(map, MAPPER_MODE_EXPRESSION);
mapper_map_set_expression(map, "y=x");
mapper_map_push(map);
impmap_update_output_vector_positions(x);
//output numOutputs
maxpd_atom_set_int(&x->msg_buffer,
mapper_device_num_signals(x->device, MAPPER_DIR_OUTGOING) - 1);
outlet_anything(x->outlet3, gensym("numOutputs"), 1, &x->msg_buffer);
}
else if (dst_dev == x->device) {
snprintf(full_name, 256, "%s/%s", mapper_device_name(src_dev),
mapper_signal_name(src_sig));
if (strcmp(mapper_signal_name(dst_sig), full_name) == 0) {
// <srcDevName>:<srcSigName> -> <thisDev>:<srcDevName>/<srcSigName>
return;
}
if (mapper_device_num_signals(x->device, MAPPER_DIR_INCOMING) >= MAX_LIST) {
post("Max inputs reached!");
return;
}
// unmap the generic signal
mapper_map_release(map);
// add a matching input signal
int i, length = mapper_signal_length(src_sig);
char type = mapper_signal_type(src_sig);
void *min = mapper_signal_minimum(src_sig);
void *max = mapper_signal_maximum(src_sig);
float *minf = 0, *maxf = 0;
if (type == 'f') {
minf = (float*)min;
maxf = (float*)max;
}
else {
if (min) {
minf = alloca(length * sizeof(float));
if (type == 'i') {
int *mini = (int*)min;
for (i = 0; i < length; i++)
minf[i] = (float)mini[i];
}
else if (type == 'd') {
double *mind = (double*)min;
for (i = 0; i < length; i++)
minf[i] = (float)mind[i];
}
else
minf = 0;
}
if (max) {
maxf = alloca(length * sizeof(float));
if (type == 'i') {
int *maxi = (int*)max;
for (i = 0; i < length; i++)
maxf[i] = (float)maxi[i];
}
else if (type == 'd') {
double *maxd = (double*)max;
for (i = 0; i < length; i++)
maxf[i] = (float)maxd[i];
}
else
maxf = 0;
}
}
dst_sig = mapper_device_add_input_signal(x->device, full_name,
length, 'f', 0, minf, maxf,
impmap_on_input, 0);
if (!dst_sig) {
post("error creating new destination signal!");
return;
}
// map the new signal
map = mapper_map_new(1, &src_sig, 1, &dst_sig);
mapper_map_set_mode(map, MAPPER_MODE_EXPRESSION);
mapper_map_set_expression(map, "y=x");
mapper_map_push(map);
impmap_update_input_vector_positions(x);
//output numInputs
maxpd_atom_set_int(&x->msg_buffer,
mapper_device_num_signals(x->device, MAPPER_DIR_INCOMING) - 1);
outlet_anything(x->outlet3, gensym("numInputs"), 1, &x->msg_buffer);
}
}
else if (e == MAPPER_REMOVED) {
if (src_sig == x->dummy_input || src_sig == x->dummy_output
|| dst_sig == x->dummy_input || dst_sig == x->dummy_output)
return;
if (src_dev == x->device) {
snprintf(full_name, 256, "%s/%s", mapper_device_name(dst_dev),
mapper_signal_name(dst_sig));
if (strcmp(mapper_signal_name(src_sig), full_name) != 0)
return;
// remove signal
mapper_device_remove_signal(x->device, src_sig);
impmap_update_input_vector_positions(x);
//output numOutputs
maxpd_atom_set_int(&x->msg_buffer,
mapper_device_num_signals(x->device, MAPPER_DIR_OUTGOING) - 1);
outlet_anything(x->outlet3, gensym("numOutputs"), 1, &x->msg_buffer);
}
else if (dst_dev == x->device) {
snprintf(full_name, 256, "%s/%s", mapper_device_name(src_dev),
mapper_signal_name(src_sig));
if (strcmp(mapper_signal_name(dst_sig), full_name) != 0)
return;
// remove signal
mapper_device_remove_signal(x->device, dst_sig);
impmap_update_input_vector_positions(x);
//output numInputs
maxpd_atom_set_int(&x->msg_buffer,
mapper_device_num_signals(x->device, MAPPER_DIR_INCOMING) - 1);
outlet_anything(x->outlet3, gensym("numInputs"), 1, &x->msg_buffer);
}
}
}
// *********************************************************
// -(new)---------------------------------------------------
void *impmap_new(t_symbol *s, int argc, t_atom *argv)
{
impmap *x = NULL;
long i;
const char *alias = NULL;
const char *iface = NULL;
#ifdef MAXMSP
if ((x = object_alloc(mapper_class))) {
x->outlet3 = listout((t_object *)x);
x->outlet2 = listout((t_object *)x);
x->outlet1 = listout((t_object *)x);
#else
if (x = (impmap *) pd_new(mapper_class) ) {
x->outlet1 = outlet_new(&x->ob, gensym("list"));
x->outlet2 = outlet_new(&x->ob, gensym("list"));
x->outlet3 = outlet_new(&x->ob, gensym("list"));
#endif
x->name = strdup("implicitmap");
for (i = 0; i < argc; i++) {
if ((argv + i)->a_type == A_SYM) {
if(strcmp(maxpd_atom_get_string(argv+i), "@alias") == 0) {
if ((argv+i+1)->a_type == A_SYM) {
alias = maxpd_atom_get_string(argv+i+1);
i++;
}
}
else if(strcmp(maxpd_atom_get_string(argv+i), "@interface") == 0) {
if ((argv+i+1)->a_type == A_SYM) {
iface = maxpd_atom_get_string(argv+i+1);
i++;
}
}
}
}
if (alias) {
free(x->name);
x->name = *alias == '/' ? strdup(alias+1) : strdup(alias);
}
if (impmap_setup_mapper(x, iface)) {
post("implicitmap: Error initializing.");
}
else {
x->ready = 0;
x->mute = 0;
x->new_in = 0;
x->query_count = 0;
x->num_snapshots = 0;
x->snapshots = 0;
// initialize input and output buffers
for (i = 0; i < MAX_LIST; i++) {
maxpd_atom_set_float(x->buffer_in+i, 0);
maxpd_atom_set_float(x->buffer_out+i, 0);
x->signals_in[i].x = x;
x->signals_out[i].x = x;
}
x->size_in = 0;
x->size_out = 0;
#ifdef MAXMSP
x->clock = clock_new(x, (method)impmap_poll); // Create the timing clock
x->timeout = clock_new(x, (method)impmap_output_snapshot);
#else
x->clock = clock_new(x, (t_method)impmap_poll);
x->timeout = clock_new(x, (t_method)impmap_output_snapshot);
#endif
clock_delay(x->clock, INTERVAL); // Set clock to go off after delay
}
}
return (x);
}
// *********************************************************
// -(free)--------------------------------------------------
void impmap_free(impmap *x)
{
if (x->clock) {
clock_unset(x->clock); // Remove clock routine from the scheduler
clock_free(x->clock); // Frees memory used by clock
}
if (x->device) {
mapper_device_free(x->device);
}
if (x->name) {
free(x->name);
}
impmap_clear_snapshots(x);
}
// *********************************************************
// -(print properties)--------------------------------------
void impmap_print_properties(impmap *x)
{
if (x->ready) {
//output name
maxpd_atom_set_string(&x->msg_buffer, mapper_device_name(x->device));
outlet_anything(x->outlet3, gensym("name"), 1, &x->msg_buffer);
mapper_network net = mapper_device_network(x->device);
//output interface
maxpd_atom_set_string(&x->msg_buffer, (char *)mapper_network_interface(net));
outlet_anything(x->outlet3, gensym("interface"), 1, &x->msg_buffer);
//output IP
const struct in_addr *ip = mapper_network_ip4(net);
if (ip) {
maxpd_atom_set_string(&x->msg_buffer, inet_ntoa(*ip));
outlet_anything(x->outlet3, gensym("IP"), 1, &x->msg_buffer);
}
//output port
maxpd_atom_set_int(&x->msg_buffer, mapper_device_port(x->device));
outlet_anything(x->outlet3, gensym("port"), 1, &x->msg_buffer);
//output numInputs
maxpd_atom_set_int(&x->msg_buffer, mapper_device_num_signals(x->device, MAPPER_DIR_INCOMING) - 1);
outlet_anything(x->outlet3, gensym("numInputs"), 1, &x->msg_buffer);
//output numOutputs
maxpd_atom_set_int(&x->msg_buffer, mapper_device_num_signals(x->device, MAPPER_DIR_OUTGOING) - 1);
outlet_anything(x->outlet3, gensym("numOutputs"), 1, &x->msg_buffer);
}
}
// *********************************************************
// -(inlet/outlet assist - maxmsp only)---------------------
#ifdef MAXMSP
void impmap_assist(impmap *x, void *b, long m, long a, char *s)
{
if (m == ASSIST_INLET) { // inlet
sprintf(s, "OSC input");
}
else { // outlet
if (a == 0) {
sprintf(s, "Mapped OSC inputs");
}
else if (a == 1) {
sprintf(s, "Snapshot data");
}
else {
sprintf(s, "Device information");
}
}
}
#endif
// *********************************************************
// -(snapshot)----------------------------------------------
void impmap_snapshot(impmap *x)
{
// if previous snapshot still in progress, output current snapshot status
if (x->query_count) {
post("still waiting for last snapshot");
return;
}
mapper_signal *psig;
x->query_count = 0;
// allocate a new snapshot
if (x->ready) {
t_snapshot new_snapshot = (t_snapshot)malloc(sizeof(t_snapshot));
new_snapshot->id = x->num_snapshots++;
new_snapshot->next = x->snapshots;
new_snapshot->inputs = calloc(x->size_in, sizeof(float));
new_snapshot->outputs = calloc(x->size_out, sizeof(float));
x->snapshots = new_snapshot;
}
// iterate through input signals and store their current values
psig = mapper_device_signals(x->device, MAPPER_DIR_INCOMING);
while (psig) {
if (*psig != x->dummy_input) {
void *value = (void*)mapper_signal_value(*psig, 0);
t_signal_ref *ref = mapper_signal_user_data(*psig);
int siglength = mapper_signal_length(*psig);
int length = ref->offset + siglength < MAX_LIST ? siglength : MAX_LIST - ref->offset;
// we can simply use memcpy here since all our signals are type 'f'
memcpy(&x->snapshots->inputs[ref->offset], value, length * sizeof(float));
}
psig = mapper_signal_query_next(psig);
}
mapper_timetag_now(&x->tt);
mapper_device_start_queue(x->device, x->tt);
// iterate through output signals and query the remote ends
psig = mapper_device_signals(x->device, MAPPER_DIR_OUTGOING);
while (psig) {
if (*psig != x->dummy_output) {
// query the remote value
x->query_count += mapper_signal_query_remotes(*psig, MAPPER_NOW);
}
psig = mapper_signal_query_next(psig);
}
mapper_device_send_queue(x->device, x->tt);
post("sent %i queries", x->query_count);
if (x->query_count)
clock_delay(x->timeout, 1000); // Set clock to go off after delay
}
// *********************************************************
// -(snapshot)----------------------------------------------
void impmap_output_snapshot(impmap *x)
{
if (x->query_count) {
post("query timeout! setting query count to 0 and outputting current values.");
x->query_count = 0;
}
maxpd_atom_set_int(x->buffer_in, x->snapshots->id+1);
outlet_anything(x->outlet3, gensym("numSnapshots"), 1, x->buffer_in);
maxpd_atom_set_float_array(x->buffer_in, x->snapshots->inputs, x->size_in);
outlet_anything(x->outlet2, gensym("in"), x->size_in, x->buffer_in);
maxpd_atom_set_float_array(x->buffer_out, x->snapshots->outputs, x->size_out);
outlet_anything(x->outlet2, gensym("out"), x->size_out, x->buffer_out);
maxpd_atom_set_int(x->buffer_in, x->snapshots->id);
outlet_anything(x->outlet2, gensym("snapshot"), 1, x->buffer_in);
}
// *********************************************************
// -(mute output)-------------------------------------------
void impmap_mute_output(impmap *x, t_symbol *s, int argc, t_atom *argv)
{
if (argc) {
if (argv->a_type == A_FLOAT)
x->mute = (int)atom_getfloat(argv);
#ifdef MAXMSP
else if (argv->a_type == A_LONG)
x->mute = atom_getlong(argv);
#endif
}
}
// *********************************************************
// -(process)-----------------------------------------------
void impmap_process(impmap *x)
{
outlet_anything(x->outlet2, gensym("process"), 0, 0);
}
