void soft_buffer_in_port<B>::rt_process (rt_process_context& ctx)
{
typedef typename B::value_type frame_type;
if (_requested)
_envelope.release ();
_envelope.update (); // Hack, skips one frame
if (_requested && (!this->rt_connected () ||
_envelope.finished ()))
{
this->_rt_connect (_request_source);
if (_request_source)
_envelope.press ();
_requested = false;
}
base_type::rt_process (ctx);
if (this->rt_in_available ())
{
_envelope.update (range (_local_buffer));
synth::blend (const_range (base_type::rt_get_in ()),
range (_local_buffer),
_stable_value,
range (_local_buffer));
}
else
{
_envelope.update (ctx.block_size ());
sound::fill_frames (range (_local_buffer),
frame_type (_stable_value));
}
}
void node_noise::update_noise (sample* buf)
{
const sample_buffer* ampl_buf = get_input <sample_buffer>(LINK_CONTROL, IN_C_AMPLITUDE);
const sample_buffer* trig_buf = get_input <sample_buffer>(LINK_CONTROL, IN_C_TRIGGER);
link_envelope mod_env = get_in_envelope (LINK_CONTROL, IN_C_AMPLITUDE);
link_envelope trig_env = get_in_envelope (LINK_CONTROL, IN_C_TRIGGER);
const sample* ampl = ampl_buf ? (const sample*) &const_range (*ampl_buf)[0] : NULL;
int n_samp = get_info().block_size;
sample* out = buf;
if (m_param_type == NOISE_PINK)
if (ampl)
while (n_samp--)
*out++ = update_pink () * (m_param_ampl + m_param_ampl * *ampl++);
else
while (n_samp--)
*out++ = update_pink () * m_param_ampl;
else
if (ampl)
while (n_samp--)
*out++ = update_white () * (m_param_ampl + m_param_ampl * *ampl++);
else
while (n_samp--)
*out++ = update_white () * m_param_ampl;
/* Modulate amplitude with trigger envelope. */
if (trig_buf) {
n_samp = get_info().block_size;
out = buf;
const sample* trig = (const sample*) &const_range (*trig_buf)[0];
trig_env = get_in_envelope (LINK_CONTROL, IN_C_TRIGGER);
while (n_samp--) {
float env_val = (float) (audio_sample) trig_env.update();
*out = *out * ((1.0f - env_val) + (env_val * *trig));
++out;
++trig;
}
}
}
void deps_object::test<2>()
{
typedef LLDependencies<std::string, int> NameIndexDeps;
NameIndexDeps nideps;
const NameIndexDeps& const_nideps(nideps);
nideps.add("def", 2, list_of("ghi"));
nideps.add("ghi", 3);
nideps.add("abc", 1, list_of("def"));
NameIndexDeps::range range(nideps.get_range());
ensure_equals(range.begin()->first, "abc");
ensure_equals(range.begin()->second, 1);
range.begin()->second = 0;
range.begin()->second = 1;
NameIndexDeps::const_range const_range(const_nideps.get_range());
NameIndexDeps::const_iterator const_iterator(const_range.begin());
++const_iterator;
ensure_equals(const_iterator->first, "def");
ensure_equals(const_iterator->second, 2);
// NameIndexDeps::node_range node_range(nideps.get_node_range());
// ensure_equals(instance_from_range<std::vector<int> >(node_range), make< std::vector<int> >(list_of(1)(2)(3)));
// *node_range.begin() = 0;
// *node_range.begin() = 1;
NameIndexDeps::const_node_range const_node_range(const_nideps.get_node_range());
ensure_equals(instance_from_range<std::vector<int> >(const_node_range), make< std::vector<int> >(list_of(1)(2)(3)));
NameIndexDeps::const_key_range const_key_range(const_nideps.get_key_range());
ensure_equals(instance_from_range<StringList>(const_key_range), make<StringList>(list_of("abc")("def")("ghi")));
NameIndexDeps::sorted_range sorted(const_nideps.sort());
NameIndexDeps::sorted_iterator sortiter(sorted.begin());
ensure_equals(sortiter->first, "ghi");
ensure_equals(sortiter->second, 3);
// test all iterator-flavored versions of get_after_range()
StringList def(make<StringList>(list_of("def")));
ensure("empty abc before list", is_empty(nideps.get_before_range(nideps.get_range().begin())));
ensure_equals(instance_from_range<StringList>(nideps.get_after_range(nideps.get_range().begin())),
def);
ensure_equals(instance_from_range<StringList>(const_nideps.get_after_range(const_nideps.get_range().begin())),
def);
// ensure_equals(instance_from_range<StringList>(nideps.get_after_range(nideps.get_node_range().begin())),
// def);
ensure_equals(instance_from_range<StringList>(const_nideps.get_after_range(const_nideps.get_node_range().begin())),
def);
ensure_equals(instance_from_range<StringList>(nideps.get_after_range(nideps.get_key_range().begin())),
def);
// advance from "ghi" to "def", which must come after "ghi"
++sortiter;
ensure_equals(instance_from_range<StringList>(const_nideps.get_after_range(sortiter)),
make<StringList>(list_of("ghi")));
}
void node_sampler::read (audio_buffer& buf, int start, int end)
{
const sample_buffer* rate = get_input<sample_buffer> (
node0::LINK_CONTROL, IN_C_RATE);
const sample* rate_buf = rate ? (const sample*) &const_range (*rate) [0] : 0;
float base_factor =
(float) m_reader->frame_rate () / get_info ().sample_rate * m_param_rate;
int must_read;
int nread;
float factor;
bool backwards = false;;
bool high_latency = false;
if (m_update_mutex.try_lock ())
{
m_scaler.set_tempo (m_param_tempo);
m_scaler.set_pitch (m_param_pitch);
m_update_mutex.unlock ();
}
if (m_param_tempo != 1.0f ||
m_param_pitch != 1.0f)
high_latency = true;
if (base_factor < 0) {
backwards = true;
base_factor = -base_factor;
}
factor = base_factor;
assert(end >= start);
while(m_scaler.available() < static_cast<std::size_t>(
(high_latency ?
TIME_STRETCH_MIN_SAMPLES :
end - start))) {
if (rate)
factor = base_factor + base_factor * rate_buf[(int) m_ctrl_pos];
if (backwards != m_fetcher.is_backwards ())
m_fetcher.set_backwards (backwards);
if (factor < 0.2)
factor = 0.2;
must_read = high_latency ? get_info ().block_size : SMALL_BLOCK_SIZE;
if (factor * m_param_tempo < 1.0)
must_read = (float)must_read * factor * m_param_tempo;
else
must_read = must_read;
m_update_mutex.lock();
nread = m_fetcher.take (sub_range (range (m_inbuf), 0, must_read));
if (nread)
{
m_ctrl_pos += (float) nread / (factor * m_param_tempo);
if (m_ctrl_pos >= get_info ().block_size)
m_ctrl_pos = base::phase(m_ctrl_pos) +
((int) m_ctrl_pos % get_info ().block_size);
m_scaler.set_rate (factor);
m_scaler.update (sub_range (range (m_inbuf), 0, nread));
}
m_update_mutex.unlock();
}
m_update_mutex.lock();
m_scaler.receive (sub_range (range (m_inbuf), 0, end - start));
m_update_mutex.unlock();
copy_and_convert_frames (sub_range (range (m_inbuf), 0, end - start),
sub_range (range (buf), start, end - start));
}
void node_sampler::do_update (const node0* caller, int caller_port_type, int caller_port)
{
audio_buffer* out = get_output<audio_buffer> (node0::LINK_AUDIO, OUT_A_OUTPUT);
const sample_buffer* trig = get_input<sample_buffer> (node0::LINK_CONTROL, IN_C_TRIGGER);
const sample* trig_buf = trig ? (const sample*) &const_range(*trig)[0] : 0;
link_envelope trig_env = get_in_envelope (LINK_CONTROL, IN_C_TRIGGER);
/* Read the data. */
size_t start = 0;
size_t end = get_info ().block_size;
if (m_reader)
{
while (start < get_info ().block_size) {
if (m_restart) {
if (trig_buf && trig_buf[start] != 0.0f) {
restart();
m_restart = false;
}
}
if (trig)
end = synth::find_hill (const_range (*trig), start);
read(*out, start, end);
float env_val = (float) (audio_sample) trig_env.update (end - start);
if (env_val == 1.0f && trig_buf && trig_buf[end - 1] == 0.0f)
m_restart = true;
start = end;
}
} else
fill_frames (range (*out), audio_frame (0));
/* Set amplitude. */
transform_frames (
range (*out), range (*out),
[&] (audio_frame in) -> audio_frame {
static_transform (in, in, [&] (audio_sample in) -> audio_sample {
return in * this->m_param_ampl;
});
return in;
});
/* Apply trigger envelope. */
if (trig_buf) {
for (size_t i = 0; i < get_info ().num_channels; ++i) {
sample* buf = (sample*) &range (*out)[0][i];
int n_samp = get_info ().block_size;
trig_buf = (const sample*) &const_range (*trig)[0];
trig_env = get_in_envelope (LINK_CONTROL, IN_C_TRIGGER);
while (n_samp--) {
float env_val = (float) (audio_sample) trig_env.update();
*buf = *buf * ((1.0f - env_val) + (env_val * *trig_buf));
++buf;
++trig_buf;
}
}
}
}
result_type operator () (const Buffer& img) const
{
return result_type (const_range (img));
}
