/*
This file is part of Ingen.
Copyright 2007-2016 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 "Buffer.hpp"
#include "BufferRef.hpp"
#include "Driver.hpp"
#include "DuplexPort.hpp"
#include "Engine.hpp"
#include "EnginePort.hpp"
#include "PortType.hpp"
#include "PostProcessor.hpp"
#include "RunContext.hpp"
#include "ThreadManager.hpp"
#include "types.hpp"
#include "ingen/AtomReader.hpp"
#include "ingen/AtomSink.hpp"
#include "ingen/AtomWriter.hpp"
#include "ingen/Configuration.hpp"
#include "ingen/EngineBase.hpp"
#include "ingen/FilePath.hpp"
#include "ingen/Forge.hpp"
#include "ingen/Interface.hpp"
#include "ingen/Log.hpp"
#include "ingen/Node.hpp"
#include "ingen/Parser.hpp"
#include "ingen/Serialiser.hpp"
#include "ingen/Store.hpp"
#include "ingen/URI.hpp"
#include "ingen/URIs.hpp"
#include "ingen/World.hpp"
#include "ingen/ingen.h"
#include "ingen/memory.hpp"
#include "ingen/runtime_paths.hpp"
#include "lv2/atom/atom.h"
#include "lv2/atom/util.h"
#include "lv2/buf-size/buf-size.h"
#include "lv2/core/lv2.h"
#include "lv2/log/log.h"
#include "lv2/log/logger.h"
#include "lv2/options/options.h"
#include "lv2/state/state.h"
#include "lv2/urid/urid.h"
#include "raul/Maid.hpp"
#include "raul/Path.hpp"
#include "raul/RingBuffer.hpp"
#include "raul/Semaphore.hpp"
#include "raul/Symbol.hpp"
#include "serd/serd.h"
#include "sord/sordmm.hpp"
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
namespace ingen {
class Atom;
namespace server {
class GraphImpl;
/** Record of a graph in this bundle. */
struct LV2Graph : public Parser::ResourceRecord {
explicit LV2Graph(Parser::ResourceRecord record);
LV2_Descriptor descriptor;
};
/** Ingen LV2 library. */
class Lib
{
public:
explicit Lib(const char* bundle_path);
using Graphs = std::vector>;
Graphs graphs;
};
inline size_t
ui_ring_size(SampleCount block_length)
{
return std::max(static_cast(8192u),
static_cast(block_length) * 16u);
}
class LV2Driver : public Driver, public ingen::AtomSink
{
public:
LV2Driver(Engine& engine,
SampleCount block_length,
size_t seq_size,
SampleCount sample_rate)
: _engine(engine)
, _main_sem(0)
, _reader(engine.world().uri_map(),
engine.world().uris(),
engine.world().log(),
*engine.world().interface())
, _writer(engine.world().uri_map(),
engine.world().uris(),
*this)
, _from_ui(ui_ring_size(block_length))
, _to_ui(ui_ring_size(block_length))
, _block_length(block_length)
, _seq_size(seq_size)
, _sample_rate(sample_rate)
{}
bool dynamic_ports() const override { return !_instantiated; }
void pre_process_port(RunContext& ctx, EnginePort* port) {
const URIs& uris = _engine.world().uris();
const SampleCount nframes = ctx.nframes();
DuplexPort* graph_port = port->graph_port();
Buffer* graph_buf = graph_port->buffer(0).get();
void* lv2_buf = port->buffer();
if (graph_port->is_a(PortType::AUDIO) || graph_port->is_a(PortType::CV)) {
graph_port->set_driver_buffer(lv2_buf, nframes * sizeof(float));
} else if (graph_port->buffer_type() == uris.atom_Sequence) {
graph_port->set_driver_buffer(lv2_buf,
lv2_atom_total_size(
static_cast(lv2_buf)));
if (graph_port->symbol() == "control") { // TODO: Safe to use index?
auto* seq = reinterpret_cast(lv2_buf);
bool enqueued = false;
LV2_ATOM_SEQUENCE_FOREACH (seq, ev)
{
if (AtomReader::is_message(uris, &ev->body)) {
enqueued = enqueue_message(&ev->body) || enqueued;
}
}
if (enqueued) {
// Enqueued a message for processing, raise semaphore
_main_sem.post();
}
}
}
if (graph_port->is_input()) {
graph_port->monitor(ctx);
} else {
graph_buf->prepare_write(ctx);
}
}
static void post_process_port(RunContext&, EnginePort* port) {
DuplexPort* graph_port = port->graph_port();
// No copying necessary, host buffers are used directly
// Reset graph port buffer pointer to no longer point to the Jack buffer
if (graph_port->is_driver_port()) {
graph_port->set_driver_buffer(nullptr, 0);
}
}
void run(uint32_t nframes) {
_engine.locate(_frame_time, nframes);
// Notify buffer is a Chunk with size set to the available space
_notify_capacity =
static_cast(_ports[1]->buffer())->atom.size;
for (auto& p : _ports) {
pre_process_port(_engine.run_context(), p);
}
_engine.run(nframes);
if (_engine.post_processor()->pending()) {
_main_sem.post();
}
flush_to_ui(_engine.run_context());
for (auto& p : _ports) {
post_process_port(_engine.run_context(), p);
}
_frame_time += nframes;
}
void deactivate() override {
_engine.quit();
_main_sem.post();
}
virtual void set_root_graph(GraphImpl* graph) { _root_graph = graph; }
virtual GraphImpl* root_graph() { return _root_graph; }
EnginePort* get_port(const raul::Path& path) override {
for (auto& p : _ports) {
if (p->graph_port()->path() == path) {
return p;
}
}
return nullptr;
}
/** Add a port. Called only during init or restore. */
void add_port(RunContext&, EnginePort* port) override {
const uint32_t index = port->graph_port()->index();
if (_ports.size() <= index) {
_ports.resize(index + 1);
}
_ports[index] = port;
}
/** Remove a port. Called only during init or restore. */
void remove_port(RunContext&, EnginePort* port) override {
const uint32_t index = port->graph_port()->index();
_ports[index] = nullptr;
}
/** Unused since LV2 has no dynamic ports. */
void register_port(EnginePort& port) override {}
/** Unused since LV2 has no dynamic ports. */
void unregister_port(EnginePort& port) override {}
/** Unused since LV2 has no dynamic ports. */
void rename_port(const raul::Path& old_path,
const raul::Path& new_path) override {}
/** Unused since LV2 has no dynamic ports. */
void port_property(const raul::Path& path,
const URI& uri,
const Atom& value) override {}
EnginePort* create_port(DuplexPort* graph_port) override {
graph_port->set_is_driver_port(*_engine.buffer_factory());
return new EnginePort(graph_port);
}
void append_time_events(RunContext&, Buffer& buffer) override {
const URIs& uris = _engine.world().uris();
auto* seq = static_cast(_ports[0]->buffer());
LV2_ATOM_SEQUENCE_FOREACH (seq, ev) {
if (ev->body.type == uris.atom_Object) {
const LV2_Atom_Object* obj =
reinterpret_cast(&ev->body);
if (obj->body.otype == uris.time_Position) {
buffer.append_event(ev->time.frames,
ev->body.size,
ev->body.type,
reinterpret_cast(&ev->body + 1));
}
}
}
}
int real_time_priority() override { return 60; }
/** Called in run thread for events received at control input port. */
bool enqueue_message(const LV2_Atom* atom) {
if (_from_ui.write(lv2_atom_total_size(atom), atom) == 0) {
#ifndef NDEBUG
_engine.log().error("Control input buffer overflow\n");
#endif
return false;
}
return true;
}
raul::Semaphore& main_sem() { return _main_sem; }
/** AtomSink::write implementation called by the PostProcessor in the main
* thread to write responses to the UI.
*/
bool write(const LV2_Atom* atom, int32_t default_id) override {
// Called from post-processor in main thread
while (_to_ui.write(lv2_atom_total_size(atom), atom) == 0) {
// Overflow, wait until ring is drained next cycle
_to_ui_overflow = true;
_to_ui_overflow_sem.wait();
_to_ui_overflow = false;
}
return true;
}
void consume_from_ui() {
const uint32_t read_space = _from_ui.read_space();
void* buf = nullptr;
for (uint32_t read = 0; read < read_space;) {
LV2_Atom atom;
if (!_from_ui.read(sizeof(LV2_Atom), &atom)) {
_engine.log().rt_error("Error reading head from from-UI ring\n");
break;
}
buf = realloc(buf, sizeof(LV2_Atom) + atom.size);
memcpy(buf, &atom, sizeof(LV2_Atom));
if (!_from_ui.read(atom.size,
static_cast(buf) + sizeof(LV2_Atom))) {
_engine.log().rt_error(
"Error reading body from from-UI ring\n");
break;
}
_reader.write(static_cast(buf));
read += sizeof(LV2_Atom) + atom.size;
}
free(buf);
}
void flush_to_ui(RunContext&) {
if (_ports.size() < 2) {
_engine.log().rt_error("Standard control ports are not present\n");
return;
}
auto* seq = static_cast(_ports[1]->buffer());
if (!seq) {
_engine.log().rt_error("Notify output not connected\n");
return;
}
// Initialise output port buffer to an empty Sequence
seq->atom.type = _engine.world().uris().atom_Sequence;
seq->atom.size = sizeof(LV2_Atom_Sequence_Body);
const uint32_t read_space = _to_ui.read_space();
for (uint32_t read = 0; read < read_space;) {
LV2_Atom atom;
if (!_to_ui.peek(sizeof(LV2_Atom), &atom)) {
_engine.log().rt_error("Error reading head from to-UI ring\n");
break;
}
if (seq->atom.size + lv2_atom_pad_size(
sizeof(LV2_Atom_Event) + atom.size)
> _notify_capacity) {
break; // Output port buffer full, resume next time
}
auto* ev = reinterpret_cast(
reinterpret_cast(seq) +
lv2_atom_total_size(&seq->atom));
ev->time.frames = 0; // TODO: Time?
ev->body = atom;
_to_ui.skip(sizeof(LV2_Atom));
if (!_to_ui.read(ev->body.size, LV2_ATOM_BODY(&ev->body))) {
_engine.log().rt_error("Error reading body from to-UI ring\n");
break;
}
read += lv2_atom_total_size(&ev->body);
seq->atom.size += lv2_atom_pad_size(
sizeof(LV2_Atom_Event) + ev->body.size);
}
if (_to_ui_overflow) {
_to_ui_overflow_sem.post();
}
}
SampleCount block_length() const override { return _block_length; }
size_t seq_size() const override { return _seq_size; }
SampleCount sample_rate() const override { return _sample_rate; }
SampleCount frame_time() const override { return _frame_time; }
AtomReader& reader() { return _reader; }
AtomWriter& writer() { return _writer; }
using Ports = std::vector;
Ports& ports() { return _ports; }
void set_instantiated(bool instantiated) { _instantiated = instantiated; }
private:
Engine& _engine;
Ports _ports;
raul::Semaphore _main_sem;
AtomReader _reader;
AtomWriter _writer;
raul::RingBuffer _from_ui;
raul::RingBuffer _to_ui;
GraphImpl* _root_graph{nullptr};
uint32_t _notify_capacity{0};
SampleCount _block_length;
size_t _seq_size;
SampleCount _sample_rate;
SampleCount _frame_time{0};
raul::Semaphore _to_ui_overflow_sem{0};
bool _to_ui_overflow{false};
bool _instantiated{false};
};
struct IngenPlugin {
std::unique_ptr world;
std::shared_ptr engine;
std::unique_ptr main;
LV2_URID_Map* map = nullptr;
int argc = 0;
char** argv = nullptr;
};
extern "C" {
static void
ingen_lv2_main(const std::shared_ptr& engine,
const std::shared_ptr& driver)
{
while (true) {
// Wait until there is work to be done
driver->main_sem().wait();
// Convert pending messages to events and push to pre processor
driver->consume_from_ui();
// Run post processor and maid to finalise events from last time
if (!engine->main_iteration()) {
return;
}
}
}
static Lib::Graphs
find_graphs(const URI& manifest_uri)
{
Sord::World world;
Parser parser;
const std::set resources = parser.find_resources(
world,
manifest_uri,
URI(INGEN__Graph));
Lib::Graphs graphs;
for (const auto& r : resources) {
graphs.push_back(std::make_shared(r));
}
return graphs;
}
static LV2_Handle
ingen_instantiate(const LV2_Descriptor* descriptor,
double rate,
const char* bundle_path,
const LV2_Feature*const* features)
{
// Get features from features array
LV2_URID_Map* map = nullptr;
LV2_URID_Unmap* unmap = nullptr;
LV2_Log_Log* log = nullptr;
const LV2_Options_Option* options = nullptr;
for (int i = 0; features[i]; ++i) {
if (!strcmp(features[i]->URI, LV2_URID__map)) {
map = static_cast(features[i]->data);
} else if (!strcmp(features[i]->URI, LV2_URID__unmap)) {
unmap = static_cast(features[i]->data);
} else if (!strcmp(features[i]->URI, LV2_LOG__log)) {
log = static_cast(features[i]->data);
} else if (!strcmp(features[i]->URI, LV2_OPTIONS__options)) {
options = static_cast(features[i]->data);
}
}
LV2_Log_Logger logger;
lv2_log_logger_init(&logger, map, log);
if (!map) {
lv2_log_error(&logger, "host did not provide URI map feature\n");
return nullptr;
}
if (!unmap) {
lv2_log_error(&logger, "host did not provide URI unmap feature\n");
return nullptr;
}
set_bundle_path(bundle_path);
const std::string manifest_path = ingen::bundle_file_path("manifest.ttl");
SerdNode manifest_node =
serd_node_new_file_uri(reinterpret_cast(
manifest_path.c_str()),
nullptr,
nullptr,
true);
const Lib::Graphs graphs = find_graphs(URI(reinterpret_cast(manifest_node.buf)));
serd_node_free(&manifest_node);
const LV2Graph* graph = nullptr;
for (const auto& g : graphs) {
if (g->uri == descriptor->URI) {
graph = g.get();
break;
}
}
if (!graph) {
lv2_log_error(&logger, "could not find graph <%s>\n", descriptor->URI);
return nullptr;
}
auto* plugin = new IngenPlugin();
plugin->map = map;
plugin->world = std::make_unique(map, unmap, log);
plugin->world->load_configuration(plugin->argc, plugin->argv);
const LV2_URID bufsz_max = map->map(map->handle, LV2_BUF_SIZE__maxBlockLength);
const LV2_URID bufsz_seq = map->map(map->handle, LV2_BUF_SIZE__sequenceSize);
const LV2_URID atom_Int = map->map(map->handle, LV2_ATOM__Int);
int32_t block_length = 0;
int32_t seq_size = 0;
if (options) {
for (const LV2_Options_Option* o = options; o->key; ++o) {
if (o->key == bufsz_max && o->type == atom_Int) {
block_length = *static_cast(o->value);
} else if (o->key == bufsz_seq && o->type == atom_Int) {
seq_size = *static_cast(o->value);
}
}
}
if (block_length == 0) {
block_length = 4096;
plugin->world->log().warn("No maximum block length given\n");
}
if (seq_size == 0) {
seq_size = 16384;
plugin->world->log().warn("No maximum sequence size given\n");
}
plugin->world->log().info(
"Block: %1% frames, Sequence: %2% bytes\n",
block_length, seq_size);
plugin->world->conf().set(
"queue-size",
plugin->world->forge().make(std::max(block_length, seq_size) * 4));
auto engine = std::make_shared(*plugin->world);
plugin->engine = engine;
plugin->world->set_engine(engine);
const std::shared_ptr interface = engine->interface();
plugin->world->set_interface(interface);
ThreadManager::set_flag(THREAD_PRE_PROCESS);
ThreadManager::single_threaded = true;
auto* driver = new LV2Driver(*engine, block_length, seq_size, rate);
engine->set_driver(std::shared_ptr(driver));
engine->activate();
ThreadManager::single_threaded = true;
const std::lock_guard lock{plugin->world->rdf_mutex()};
// Locate to time 0 to process initialization events
engine->locate(0, block_length);
engine->post_processor()->set_end_time(block_length);
// Parse graph, filling the queue with events to create it
plugin->world->interface()->bundle_begin();
plugin->world->parser()->parse_file(*plugin->world,
*plugin->world->interface(),
graph->filename);
plugin->world->interface()->bundle_end();
// Drain event queue
while (engine->pending_events()) {
engine->process_all_events();
engine->post_processor()->process();
engine->maid()->cleanup();
}
/* Register client after loading graph so the to-ui ring does not overflow.
Since we are not yet rolling, it won't be drained, causing a deadlock. */
const std::shared_ptr client{&driver->writer(), NullDeleter};
interface->set_respondee(client);
engine->register_client(client);
driver->set_instantiated(true);
return static_cast(plugin);
}
static void
ingen_connect_port(LV2_Handle instance, uint32_t port, void* data)
{
auto* me = static_cast(instance);
Engine* engine = static_cast(me->world->engine().get());
const auto driver = std::static_pointer_cast(engine->driver());
if (port < driver->ports().size()) {
driver->ports().at(port)->set_buffer(data);
} else {
engine->log().rt_error("Connect to non-existent port\n");
}
}
static void
ingen_activate(LV2_Handle instance)
{
auto* me = static_cast(instance);
auto engine = std::static_pointer_cast(me->world->engine());
const auto driver = std::static_pointer_cast(engine->driver());
engine->activate();
me->main = std::make_unique(ingen_lv2_main, engine, driver);
}
static void
ingen_run(LV2_Handle instance, uint32_t sample_count)
{
auto* me = static_cast(instance);
auto engine = std::static_pointer_cast(me->world->engine());
const auto driver = std::static_pointer_cast(engine->driver());
ThreadManager::set_flag(THREAD_PROCESS);
ThreadManager::set_flag(THREAD_IS_REAL_TIME);
driver->run(sample_count);
}
static void
ingen_deactivate(LV2_Handle instance)
{
auto* me = static_cast(instance);
me->world->engine()->deactivate();
if (me->main) {
me->main->join();
me->main.reset();
}
}
static void
ingen_cleanup(LV2_Handle instance)
{
auto* me = static_cast(instance);
me->world->set_engine(nullptr);
me->world->set_interface(nullptr);
if (me->main) {
me->main->join();
me->main.reset();
}
auto world = std::move(me->world);
delete me;
}
static void
get_state_features(const LV2_Feature* const* features,
LV2_State_Map_Path** map,
LV2_State_Make_Path** make)
{
for (int i = 0; features[i]; ++i) {
if (map && !strcmp(features[i]->URI, LV2_STATE__mapPath)) {
*map = static_cast(features[i]->data);
} else if (make && !strcmp(features[i]->URI, LV2_STATE__makePath)) {
*make = static_cast(features[i]->data);
}
}
}
static LV2_State_Status
ingen_save(LV2_Handle instance,
LV2_State_Store_Function store,
LV2_State_Handle handle,
uint32_t flags,
const LV2_Feature* const* features)
{
auto* plugin = static_cast(instance);
LV2_State_Map_Path* map_path = nullptr;
LV2_State_Make_Path* make_path = nullptr;
get_state_features(features, &map_path, &make_path);
if (!map_path || !make_path || !plugin->map) {
plugin->world->log().error("Missing state:mapPath, state:makePath, or urid:Map\n");
return LV2_STATE_ERR_NO_FEATURE;
}
const LV2_URID ingen_file = plugin->map->map(plugin->map->handle, INGEN__file);
const LV2_URID atom_Path = plugin->map->map(plugin->map->handle,
LV2_ATOM__Path);
char* real_path = make_path->path(make_path->handle, "main.ttl");
char* state_path = map_path->abstract_path(map_path->handle, real_path);
auto root = plugin->world->store()->find(raul::Path("/"));
{
const std::lock_guard lock{plugin->world->rdf_mutex()};
plugin->world->serialiser()->start_to_file(
root->second->path(), FilePath{real_path});
plugin->world->serialiser()->serialise(root->second);
plugin->world->serialiser()->finish();
}
store(handle,
ingen_file,
state_path,
strlen(state_path) + 1,
atom_Path,
LV2_STATE_IS_POD);
free(state_path);
free(real_path);
return LV2_STATE_SUCCESS;
}
static LV2_State_Status
ingen_restore(LV2_Handle instance,
LV2_State_Retrieve_Function retrieve,
LV2_State_Handle handle,
uint32_t flags,
const LV2_Feature* const* features)
{
auto* plugin = static_cast(instance);
LV2_State_Map_Path* map_path = nullptr;
get_state_features(features, &map_path, nullptr);
if (!map_path) {
plugin->world->log().error("Missing state:mapPath\n");
return LV2_STATE_ERR_NO_FEATURE;
}
const LV2_URID ingen_file = plugin->map->map(plugin->map->handle, INGEN__file);
size_t size = 0;
uint32_t type = 0;
uint32_t valflags = 0;
// Get abstract path to graph file
const char* path = static_cast(
retrieve(handle, ingen_file, &size, &type, &valflags));
if (!path) {
return LV2_STATE_ERR_NO_PROPERTY;
}
// Convert to absolute path
char* real_path = map_path->absolute_path(map_path->handle, path);
if (!real_path) {
return LV2_STATE_ERR_UNKNOWN;
}
#if 0
// Remove existing root graph contents
std::shared_ptr engine = plugin->engine;
for (const auto& b : engine->root_graph()->blocks()) {
plugin->world->interface()->del(b.uri());
}
const uint32_t n_ports = engine->root_graph()->num_ports_non_rt();
for (int32_t i = n_ports - 1; i >= 0; --i) {
PortImpl* port = engine->root_graph()->port_impl(i);
if (port->symbol() != "control" && port->symbol() != "notify") {
plugin->world->interface()->del(port->uri());
}
}
#endif
// Load new graph
const std::lock_guard lock{plugin->world->rdf_mutex()};
plugin->world->parser()->parse_file(
*plugin->world, *plugin->world->interface(), real_path);
free(real_path);
return LV2_STATE_SUCCESS;
}
static const void*
ingen_extension_data(const char* uri)
{
static const LV2_State_Interface state = { ingen_save, ingen_restore };
if (!strcmp(uri, LV2_STATE__interface)) {
return &state;
}
return nullptr;
}
LV2Graph::LV2Graph(Parser::ResourceRecord record)
: Parser::ResourceRecord(std::move(record))
, descriptor()
{
descriptor.URI = uri.c_str();
descriptor.instantiate = ingen_instantiate;
descriptor.connect_port = ingen_connect_port;
descriptor.activate = ingen_activate;
descriptor.run = ingen_run;
descriptor.deactivate = ingen_deactivate;
descriptor.cleanup = ingen_cleanup;
descriptor.extension_data = ingen_extension_data;
}
Lib::Lib(const char* bundle_path)
{
ingen::set_bundle_path(bundle_path);
const std::string manifest_path = ingen::bundle_file_path("manifest.ttl");
SerdNode manifest_node =
serd_node_new_file_uri(reinterpret_cast(
manifest_path.c_str()),
nullptr,
nullptr,
true);
graphs = find_graphs(URI(reinterpret_cast(manifest_node.buf)));
serd_node_free(&manifest_node);
}
static void
lib_cleanup(LV2_Lib_Handle handle)
{
Lib* lib = static_cast(handle);
delete lib;
}
static const LV2_Descriptor*
lib_get_plugin(LV2_Lib_Handle handle, uint32_t index)
{
Lib* lib = static_cast(handle);
return index < lib->graphs.size() ? &lib->graphs[index]->descriptor : nullptr;
}
} // extern "C"
} // namespace server
} // namespace ingen
extern "C" {
/** LV2 plugin library entry point */
LV2_SYMBOL_EXPORT
const LV2_Lib_Descriptor*
lv2_lib_descriptor(const char* bundle_path,
const LV2_Feature*const* features)
{
static const uint32_t desc_size = sizeof(LV2_Lib_Descriptor);
auto* lib = new ingen::server::Lib(bundle_path);
// FIXME: memory leak. I think the LV2_Lib_Descriptor API is botched :(
auto* desc = static_cast(malloc(desc_size));
desc->handle = lib;
desc->size = desc_size;
desc->cleanup = ingen::server::lib_cleanup;
desc->get_plugin = ingen::server::lib_get_plugin;
return desc;
}
}