/*
This file is part of Ingen.
Copyright 2007-2012 David Robillard
Ingen is free software: you can redistribute it and/or modify it under the
terms of the GNU Affero General Public License as published by the Free
Software Foundation, either version 3 of the License, or any later version.
Ingen is distributed in the hope that it will be useful, but WITHOUT ANY
WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR
A PARTICULAR PURPOSE. See the GNU Affero General Public License for details.
You should have received a copy of the GNU Affero General Public License
along with Ingen. If not, see .
*/
#include
#include
#include
#include
#include "lv2/lv2plug.in/ns/ext/resize-port/resize-port.h"
#include "lv2/lv2plug.in/ns/ext/morph/morph.h"
#include "raul/log.hpp"
#include "raul/Maid.hpp"
#include "raul/Array.hpp"
#include "ingen/URIMap.hpp"
#include "ingen/URIs.hpp"
#include "Driver.hpp"
#include "Engine.hpp"
#include "InputPort.hpp"
#include "LV2Node.hpp"
#include "LV2Plugin.hpp"
#include "OutputPort.hpp"
#include "ProcessContext.hpp"
using namespace std;
namespace Ingen {
namespace Server {
/** Partially construct a LV2Node.
*
* Object is not usable until instantiate() is called with success.
* (It _will_ crash!)
*/
LV2Node::LV2Node(LV2Plugin* plugin,
const string& name,
bool polyphonic,
PatchImpl* parent,
SampleRate srate)
: NodeImpl(plugin, name, polyphonic, parent, srate)
, _lv2_plugin(plugin)
, _instances(NULL)
, _prepared_instances(NULL)
, _worker_iface(NULL)
{
assert(_lv2_plugin);
}
LV2Node::~LV2Node()
{
delete _instances;
}
SharedPtr
LV2Node::make_instance(URIs& uris,
SampleRate rate,
uint32_t voice,
bool preparing)
{
LilvInstance* inst = lilv_plugin_instantiate(
_lv2_plugin->lilv_plugin(), rate, _features->array());
if (!inst) {
Raul::error(Raul::fmt("Failed to instantiate <%1%>\n")
% _lv2_plugin->uri());
return SharedPtr();
}
const LV2_Morph_Interface* morph_iface = (const LV2_Morph_Interface*)
lilv_instance_get_extension_data(inst, LV2_MORPH__interface);
for (uint32_t p = 0; p < num_ports(); ++p) {
PortImpl* const port = _ports->at(p);
Buffer* const buffer = (preparing)
? port->prepared_buffer(voice).get()
: port->buffer(voice).get();
if (port->is_morph() && port->is_a(PortType::CV)) {
Raul::info(Raul::fmt("Morphing %1% to CV\n") % port->path());
if (morph_iface) {
morph_iface->morph_port(
inst->lv2_handle, p, uris.lv2_CVPort, NULL);
}
}
if (buffer) {
if (port->is_a(PortType::CV) || port->is_a(PortType::CONTROL)) {
buffer->set_block(port->value().get_float(), 0, buffer->nframes() - 1);
} else {
buffer->clear();
}
}
}
if (morph_iface) {
for (uint32_t p = 0; p < num_ports(); ++p) {
PortImpl* const port = _ports->at(p);
if (port->is_auto_morph()) {
LV2_URID type = morph_iface->port_type(
inst->lv2_handle, p, NULL);
if (type == _uris.lv2_ControlPort) {
port->set_type(PortType::CONTROL, 0);
Raul::info(Raul::fmt("Auto-morphed %1% to control\n")
% port->path());
} else if (type == _uris.lv2_CVPort) {
port->set_type(PortType::CV, 0);
Raul::info(Raul::fmt("Auto-morphed %1% to CV\n")
% port->path());
} else {
Raul::error(Raul::fmt("%1% auto-morphed to unknown type %2%\n")
% port->path() % type);
return SharedPtr();
}
}
}
}
return SharedPtr(inst, lilv_instance_free);
}
bool
LV2Node::prepare_poly(BufferFactory& bufs, uint32_t poly)
{
if (!_polyphonic)
poly = 1;
NodeImpl::prepare_poly(bufs, poly);
if (_polyphony == poly)
return true;
const SampleRate rate = bufs.engine().driver()->sample_rate();
assert(!_prepared_instances);
_prepared_instances = new Instances(poly, *_instances, SharedPtr());
for (uint32_t i = _polyphony; i < _prepared_instances->size(); ++i) {
SharedPtr inst = make_instance(bufs.uris(), rate, i, true);
if (!inst) {
return false;
}
_prepared_instances->at(i) = inst;
if (_activated) {
lilv_instance_activate(inst.get());
}
}
return true;
}
bool
LV2Node::apply_poly(ProcessContext& context, Raul::Maid& maid, uint32_t poly)
{
if (!_polyphonic)
poly = 1;
if (_prepared_instances) {
maid.push(_instances);
_instances = _prepared_instances;
_prepared_instances = NULL;
}
assert(poly <= _instances->size());
return NodeImpl::apply_poly(context, maid, poly);
}
/** Instantiate self from LV2 plugin descriptor.
*
* Implemented as a seperate function (rather than in the constructor) to
* allow graceful error-catching of broken plugins.
*
* Returns whether or not plugin was successfully instantiated. If return
* value is false, this object may not be used.
*/
bool
LV2Node::instantiate(BufferFactory& bufs)
{
const Ingen::URIs& uris = bufs.uris();
SharedPtr info = _lv2_plugin->lv2_info();
const LilvPlugin* plug = _lv2_plugin->lilv_plugin();
Ingen::Forge& forge = bufs.forge();
const uint32_t num_ports = lilv_plugin_get_num_ports(plug);
_ports = new Raul::Array(num_ports, NULL);
bool ret = true;
float* min_values = new float[num_ports];
float* max_values = new float[num_ports];
float* def_values = new float[num_ports];
lilv_plugin_get_port_ranges_float(plug, min_values, max_values, def_values);
// Get all the necessary information about ports
for (uint32_t j = 0; j < num_ports; ++j) {
const LilvPort* id = lilv_plugin_get_port_by_index(plug, j);
// LV2 port symbols are guaranteed to be unique, valid C identifiers
const std::string port_sym = lilv_node_as_string(
lilv_port_get_symbol(plug, id));
if (!Raul::Symbol::is_valid(port_sym)) {
Raul::error(Raul::fmt("<%1%> port %2% has invalid symbol `%3'\n")
% _lv2_plugin->uri() % j % port_sym);
ret = false;
break;
}
// Get port type
Raul::Atom val;
PortType port_type = PortType::UNKNOWN;
LV2_URID buffer_type = 0;
bool is_morph = false;
bool is_auto_morph = false;
if (lilv_port_is_a(plug, id, info->lv2_ControlPort)) {
if (lilv_port_is_a(plug, id, info->morph_MorphPort)) {
is_morph = true;
LilvNodes* types = lilv_port_get_value(
plug, id, info->morph_supportsType);
LILV_FOREACH(nodes, i, types) {
const LilvNode* type = lilv_nodes_get(types, i);
if (lilv_node_equals(type, info->lv2_CVPort)) {
port_type = PortType::CV;
buffer_type = uris.atom_Sound;
}
}
lilv_nodes_free(types);
}
if (port_type == PortType::UNKNOWN) {
port_type = PortType::CONTROL;
buffer_type = uris.atom_Float;
}
} else if (lilv_port_is_a(plug, id, info->lv2_CVPort)) {
port_type = PortType::CV;
buffer_type = uris.atom_Sound;
} else if (lilv_port_is_a(plug, id, info->lv2_AudioPort)) {
port_type = PortType::AUDIO;
buffer_type = uris.atom_Sound;
} else if (lilv_port_is_a(plug, id, info->atom_AtomPort)) {
port_type = PortType::ATOM;
}
if (lilv_port_is_a(plug, id, info->morph_AutoMorphPort)) {
is_auto_morph = true;
}
// Get buffer type if necessary (atom ports)
if (!buffer_type) {
LilvNodes* types = lilv_port_get_value(
plug, id, info->atom_bufferType);
LILV_FOREACH(nodes, i, types) {
const LilvNode* type = lilv_nodes_get(types, i);
if (lilv_node_is_uri(type)) {
buffer_type = bufs.engine().world()->uri_map().map_uri(
lilv_node_as_uri(type));
}
}
lilv_nodes_free(types);
}
uint32_t port_buffer_size = bufs.default_size(buffer_type);
if (port_type == PortType::ATOM) {
// Get default value, and its length
LilvNodes* defaults = lilv_port_get_value(plug, id, info->lv2_default);
LILV_FOREACH(nodes, i, defaults) {
const LilvNode* d = lilv_nodes_get(defaults, i);
if (lilv_node_is_string(d)) {
const char* str_val = lilv_node_as_string(d);
const uint32_t str_val_len = strlen(str_val);
val = forge.alloc(str_val);
port_buffer_size = std::max(port_buffer_size, str_val_len);
}
}
lilv_nodes_free(defaults);
// Get minimum size, if set in data
LilvNodes* sizes = lilv_port_get_value(plug, id, info->rsz_minimumSize);
LILV_FOREACH(nodes, i, sizes) {
const LilvNode* d = lilv_nodes_get(sizes, i);
if (lilv_node_is_int(d)) {
uint32_t size_val = lilv_node_as_int(d);
port_buffer_size = std::max(port_buffer_size, size_val);
}
}
lilv_nodes_free(sizes);
Raul::info(Raul::fmt("Atom port %1% buffer size %2%\n")
% path() % port_buffer_size);
}
enum { UNKNOWN, INPUT, OUTPUT } direction = UNKNOWN;
if (lilv_port_is_a(plug, id, info->lv2_InputPort)) {
direction = INPUT;
} else if (lilv_port_is_a(plug, id, info->lv2_OutputPort)) {
direction = OUTPUT;
}
if (port_type == PortType::UNKNOWN || direction == UNKNOWN) {
Raul::error(Raul::fmt("<%1%> port %2% has unknown type or direction\n")
% _lv2_plugin->uri() % port_sym);
ret = false;
break;
}
if (!val.type())
val = forge.make(isnan(def_values[j]) ? 0.0f : def_values[j]);
PortImpl* port = (direction == INPUT)
? static_cast(
new InputPort(bufs, this, port_sym, j, _polyphony,
port_type, buffer_type, val))
: static_cast(
new OutputPort(bufs, this, port_sym, j, _polyphony,
port_type, buffer_type, val));
port->set_morphable(is_morph, is_auto_morph);
if (direction == INPUT && (port_type == PortType::CONTROL
|| port_type == PortType::CV)) {
port->set_value(val);
if (!isnan(min_values[j])) {
port->set_property(uris.lv2_minimum, forge.make(min_values[j]));
port->set_minimum(forge.make(min_values[j]));
}
if (!isnan(max_values[j])) {
port->set_property(uris.lv2_maximum, forge.make(max_values[j]));
port->set_maximum(forge.make(max_values[j]));
}
}
// Inherit certain properties from plugin port
LilvNode* preds[] = { info->lv2_portProperty, info->atom_supports, 0 };
for (int p = 0; preds[p]; ++p) {
LilvNodes* values = lilv_port_get_value(plug, id, preds[p]);
LILV_FOREACH(nodes, v, values) {
const LilvNode* val = lilv_nodes_get(values, v);
if (lilv_node_is_uri(val)) {
port->add_property(lilv_node_as_uri(preds[p]),
forge.alloc_uri(lilv_node_as_uri(val)));
}
}
lilv_nodes_free(values);
}
port->cache_properties();
_ports->at(j) = port;
}
delete[] min_values;
delete[] max_values;
delete[] def_values;
if (!ret) {
delete _ports;
_ports = NULL;
return ret;
}
_features = info->world().lv2_features().lv2_features(&info->world(), this);
// Actually create plugin instances and port buffers.
const SampleRate rate = bufs.engine().driver()->sample_rate();
_instances = new Instances(_polyphony, SharedPtr());
for (uint32_t i = 0; i < _polyphony; ++i) {
_instances->at(i) = make_instance(bufs.uris(), rate, i, false);
if (!_instances->at(i)) {
return false;
}
}
// FIXME: Polyphony + worker?
if (lilv_plugin_has_feature(plug, info->work_schedule)) {
_worker_iface = (const LV2_Worker_Interface*)
lilv_instance_get_extension_data(instance(0),
LV2_WORKER__interface);
}
return ret;
}
void
LV2Node::activate(BufferFactory& bufs)
{
NodeImpl::activate(bufs);
for (uint32_t i = 0; i < _polyphony; ++i)
lilv_instance_activate(instance(i));
}
void
LV2Node::deactivate()
{
NodeImpl::deactivate();
for (uint32_t i = 0; i < _polyphony; ++i)
lilv_instance_deactivate(instance(i));
}
LV2_Worker_Status
LV2Node::work_respond(LV2_Worker_Respond_Handle handle,
uint32_t size,
const void* data)
{
LV2Node* node = (LV2Node*)handle;
LV2Node::Response* r = new LV2Node::Response(size, data);
node->_responses.push_back(*r);
return LV2_WORKER_SUCCESS;
}
void
LV2Node::work(uint32_t size, const void* data)
{
if (_worker_iface) {
LV2_Handle inst = lilv_instance_get_handle(instance(0));
if (_worker_iface->work(inst, work_respond, this, size, data)) {
Raul::error(Raul::fmt("Error calling %1% work method\n") % _path);
}
}
}
void
LV2Node::process(ProcessContext& context)
{
NodeImpl::pre_process(context);
for (uint32_t i = 0; i < _polyphony; ++i)
lilv_instance_run(instance(i), context.nframes());
if (_worker_iface) {
LV2_Handle inst = lilv_instance_get_handle(instance(0));
while (!_responses.empty()) {
Response& r = _responses.front();
_worker_iface->work_response(inst, r.size, r.data);
_responses.pop_front();
context.engine().maid()->push(&r);
}
if (_worker_iface->end_run) {
_worker_iface->end_run(inst);
}
}
NodeImpl::post_process(context);
}
void
LV2Node::set_port_buffer(uint32_t voice,
uint32_t port_num,
BufferRef buf,
SampleCount offset)
{
NodeImpl::set_port_buffer(voice, port_num, buf, offset);
lilv_instance_connect_port(
instance(voice), port_num,
buf ? buf->port_data(_ports->at(port_num)->type(), offset) : NULL);
}
} // namespace Server
} // namespace Ingen