int luajack_get_cycle_times (luajack_t *client, jack_nframes_t *current_frames, jack_time_t *current_usecs, jack_time_t *next_usecs, float *period_usecs)
{
cud_t *cud = get_cud(client);
if(!cud) return 0;
return jack_get_cycle_times(cud->client,
current_frames, current_usecs, next_usecs, period_usecs);
}
// rt
static int
_process(jack_nframes_t nsamples, void *data)
{
prog_t *handle = data;
bin_t *bin = &handle->bin;
sp_app_t *app = bin->app;
#if defined(JACK_HAS_CYCLE_TIMES)
clock_gettime(CLOCK_REALTIME, &handle->ntp);
handle->ntp.tv_sec += JAN_1970; // convert NTP to OSC time
jack_nframes_t offset = jack_frames_since_cycle_start(handle->client);
float T;
jack_get_cycle_times(handle->client, &handle->cycle.cur_frames,
&handle->cycle.cur_usecs, &handle->cycle.nxt_usecs, &T);
(void)T;
handle->cycle.ref_frames = handle->cycle.cur_frames + offset;
// calculate apparent period
double diff = 1e-6 * (handle->cycle.nxt_usecs - handle->cycle.cur_usecs);
// calculate apparent samples per period
handle->cycle.dT = nsamples / diff;
handle->cycle.dTm1 = 1.0 / handle->cycle.dT;
#endif
// get transport position
jack_position_t pos;
jack_transport_state_t rolling = jack_transport_query(handle->client, &pos) == JackTransportRolling;
int trans_changed = (rolling != handle->trans.rolling)
|| (pos.frame != handle->trans.frame)
|| (pos.beats_per_bar != handle->trans.beats_per_bar)
|| (pos.beat_type != handle->trans.beat_type)
|| (pos.ticks_per_beat != handle->trans.ticks_per_beat)
|| (pos.beats_per_minute != handle->trans.beats_per_minute);
const size_t sample_buf_size = sizeof(float) * nsamples;
const sp_app_system_source_t *sources = sp_app_get_system_sources(app);
const sp_app_system_sink_t *sinks = sp_app_get_system_sinks(app);
if(sp_app_bypassed(app)) // aka loading state
{
//fprintf(stderr, "app is bypassed\n");
// clear output buffers
for(const sp_app_system_sink_t *sink=sinks;
sink->type != SYSTEM_PORT_NONE;
sink++)
{
switch(sink->type)
{
case SYSTEM_PORT_NONE:
case SYSTEM_PORT_CONTROL:
case SYSTEM_PORT_COM:
break;
case SYSTEM_PORT_AUDIO:
case SYSTEM_PORT_CV:
{
void *out_buf = jack_port_get_buffer(sink->sys_port, nsamples);
memset(out_buf, 0x0, sample_buf_size);
break;
}
case SYSTEM_PORT_MIDI:
case SYSTEM_PORT_OSC:
{
void *out_buf = jack_port_get_buffer(sink->sys_port, nsamples);
jack_midi_clear_buffer(out_buf);
break;
}
}
}
bin_process_pre(bin, nsamples, true);
bin_process_post(bin);
return 0;
}
//TODO use __builtin_assume_aligned
// fill input buffers
for(const sp_app_system_source_t *source=sources;
source->type != SYSTEM_PORT_NONE;
source++)
{
switch(source->type)
{
case SYSTEM_PORT_NONE:
case SYSTEM_PORT_CONTROL:
break;
case SYSTEM_PORT_AUDIO:
case SYSTEM_PORT_CV:
{
const void *in_buf = jack_port_get_buffer(source->sys_port, nsamples);
memcpy(source->buf, in_buf, sample_buf_size);
break;
}
case SYSTEM_PORT_MIDI:
{
void *in_buf = jack_port_get_buffer(source->sys_port, nsamples);
void *seq_in = source->buf;
LV2_Atom_Forge *forge = &handle->forge;
LV2_Atom_Forge_Frame frame;
lv2_atom_forge_set_buffer(forge, seq_in, SEQ_SIZE);
LV2_Atom_Forge_Ref ref = lv2_atom_forge_sequence_head(forge, &frame, 0);
if(ref && trans_changed)
ref = _trans_event(handle, forge, rolling, &pos);
int n = jack_midi_get_event_count(in_buf);
for(int i=0; i<n; i++)
{
jack_midi_event_t mev;
jack_midi_event_get(&mev, in_buf, i);
//add jack midi event to in_buf
if(ref)
ref = lv2_atom_forge_frame_time(forge, mev.time);
if(ref)
ref = lv2_atom_forge_atom(forge, mev.size, handle->midi_MidiEvent);
if(ref)
ref = lv2_atom_forge_raw(forge, mev.buffer, mev.size);
if(ref)
lv2_atom_forge_pad(forge, mev.size);
}
if(ref)
lv2_atom_forge_pop(forge, &frame);
else
lv2_atom_sequence_clear(seq_in);
break;
}
case SYSTEM_PORT_OSC:
{
void *in_buf = jack_port_get_buffer(source->sys_port, nsamples);
void *seq_in = source->buf;
LV2_Atom_Forge *forge = &handle->forge;
LV2_Atom_Forge_Frame frame;
lv2_atom_forge_set_buffer(forge, seq_in, SEQ_SIZE);
LV2_Atom_Forge_Ref ref = lv2_atom_forge_sequence_head(forge, &frame, 0);
if(ref && trans_changed)
ref = _trans_event(handle, forge, rolling, &pos);
int n = jack_midi_get_event_count(in_buf);
for(int i=0; i<n; i++)
{
jack_midi_event_t mev;
jack_midi_event_get(&mev, (void *)in_buf, i);
//add jack osc event to in_buf
if(osc_check_packet(mev.buffer, mev.size))
{
if(ref)
ref = lv2_atom_forge_frame_time(forge, mev.time);
handle->ref = ref;
osc_dispatch_method(mev.buffer, mev.size, methods,
_bundle_in, _bundle_out, handle);
ref = handle->ref;
}
}
if(ref)
lv2_atom_forge_pop(forge, &frame);
else
lv2_atom_sequence_clear(seq_in);
break;
}
case SYSTEM_PORT_COM:
{
void *seq_in = source->buf;
LV2_Atom_Forge *forge = &handle->forge;
LV2_Atom_Forge_Frame frame;
lv2_atom_forge_set_buffer(forge, seq_in, SEQ_SIZE);
LV2_Atom_Forge_Ref ref = lv2_atom_forge_sequence_head(forge, &frame, 0);
const LV2_Atom_Object *obj;
size_t size;
while((obj = varchunk_read_request(bin->app_from_com, &size)))
{
if(ref)
ref = lv2_atom_forge_frame_time(forge, 0);
if(ref)
ref = lv2_atom_forge_raw(forge, obj, size);
if(ref)
lv2_atom_forge_pad(forge, size);
varchunk_read_advance(bin->app_from_com);
}
if(ref)
lv2_atom_forge_pop(forge, &frame);
else
lv2_atom_sequence_clear(seq_in);
break;
}
}
}
// update transport state
handle->trans.rolling = rolling;
handle->trans.frame = rolling
? handle->trans.frame + nsamples
: pos.frame;
handle->trans.beats_per_bar = pos.beats_per_bar;
handle->trans.beat_type = pos.beat_type;
handle->trans.ticks_per_beat = pos.ticks_per_beat;
handle->trans.beats_per_minute = pos.beats_per_minute;
bin_process_pre(bin, nsamples, false);
// fill output buffers
for(const sp_app_system_sink_t *sink=sinks;
sink->type != SYSTEM_PORT_NONE;
sink++)
{
switch(sink->type)
{
case SYSTEM_PORT_NONE:
case SYSTEM_PORT_CONTROL:
break;
case SYSTEM_PORT_AUDIO:
case SYSTEM_PORT_CV:
{
void *out_buf = jack_port_get_buffer(sink->sys_port, nsamples);
memcpy(out_buf, sink->buf, sample_buf_size);
break;
}
case SYSTEM_PORT_MIDI:
{
void *out_buf = jack_port_get_buffer(sink->sys_port, nsamples);
const LV2_Atom_Sequence *seq_out = sink->buf;
// fill midi output buffer
jack_midi_clear_buffer(out_buf);
if(seq_out)
{
LV2_ATOM_SEQUENCE_FOREACH(seq_out, ev)
{
const LV2_Atom *atom = &ev->body;
if(atom->type != handle->midi_MidiEvent)
continue; // ignore non-MIDI events
jack_midi_event_write(out_buf, ev->time.frames,
LV2_ATOM_BODY_CONST(atom), atom->size);
}
}
break;
}
case SYSTEM_PORT_OSC:
{
void *out_buf = jack_port_get_buffer(sink->sys_port, nsamples);
const LV2_Atom_Sequence *seq_out = sink->buf;
// fill midi output buffer
jack_midi_clear_buffer(out_buf);
if(seq_out)
{
LV2_ATOM_SEQUENCE_FOREACH(seq_out, ev)
{
const LV2_Atom_Object *obj = (const LV2_Atom_Object *)&ev->body;
handle->osc_ptr = handle->osc_buf;
handle->osc_end = handle->osc_buf + OSC_SIZE;
osc_atom_event_unroll(&handle->oforge, obj, _bundle_push_cb,
_bundle_pop_cb, _message_cb, handle);
size_t size = handle->osc_ptr
? handle->osc_ptr - handle->osc_buf
: 0;
if(size)
{
jack_midi_event_write(out_buf, ev->time.frames,
handle->osc_buf, size);
}
}
}
break;
}
case SYSTEM_PORT_COM:
{
const LV2_Atom_Sequence *seq_out = sink->buf;
LV2_ATOM_SEQUENCE_FOREACH(seq_out, ev)
{
const LV2_Atom *atom = (const LV2_Atom *)&ev->body;
// try do process events directly
bin->advance_ui = sp_app_from_ui(bin->app, atom);
if(!bin->advance_ui) // queue event in ringbuffer instead
{
//fprintf(stderr, "plugin ui direct is blocked\n");
void *ptr;
size_t size = lv2_atom_total_size(atom);
if((ptr = varchunk_write_request(bin->app_from_app, size)))
{
memcpy(ptr, atom, size);
varchunk_write_advance(bin->app_from_app, size);
}
else
{
//fprintf(stderr, "app_from_ui ringbuffer full\n");
//FIXME
}
}
}
break;
}
}
}
bin_process_post(bin);
return 0;
}
