// Clippy doesn't understand it when we use a unit in our `check_null_ptr!()` maccro, even if we // explicitly pattern match on that unit #![allow(clippy::unused_unit)] use clap_sys::events::{ clap_event_header, clap_event_note, clap_event_param_mod, clap_event_param_value, clap_input_events, clap_output_events, CLAP_CORE_EVENT_SPACE_ID, CLAP_EVENT_MIDI, CLAP_EVENT_NOTE_EXPRESSION, CLAP_EVENT_NOTE_OFF, CLAP_EVENT_NOTE_ON, CLAP_EVENT_PARAM_MOD, CLAP_EVENT_PARAM_VALUE, }; use clap_sys::ext::params::{ clap_param_info, clap_plugin_params, CLAP_EXT_PARAMS, CLAP_PARAM_IS_BYPASS, CLAP_PARAM_IS_STEPPED, }; use clap_sys::ext::thread_check::{clap_host_thread_check, CLAP_EXT_THREAD_CHECK}; use clap_sys::host::clap_host; use clap_sys::id::clap_id; use clap_sys::plugin::clap_plugin; use clap_sys::process::{ clap_process, clap_process_status, CLAP_PROCESS_CONTINUE, CLAP_PROCESS_CONTINUE_IF_NOT_QUIET, CLAP_PROCESS_ERROR, }; use crossbeam::atomic::AtomicCell; use crossbeam::queue::ArrayQueue; use lazy_static::lazy_static; use parking_lot::{RwLock, RwLockWriteGuard}; use std::cmp; use std::collections::{HashMap, VecDeque}; use std::ffi::{c_void, CStr}; use std::os::raw::c_char; use std::ptr; use std::sync::atomic::{AtomicBool, AtomicU32, Ordering}; use std::thread::{self, ThreadId}; use super::context::WrapperProcessContext; use super::descriptor::PluginDescriptor; use super::util::ClapPtr; use crate::buffer::Buffer; use crate::event_loop::{EventLoop, MainThreadExecutor, TASK_QUEUE_CAPACITY}; use crate::param::internals::ParamPtr; use crate::plugin::{BufferConfig, BusConfig, ClapPlugin, NoteEvent, ProcessStatus}; use crate::wrapper::util::{hash_param_id, process_wrapper, strlcpy}; /// Right now the wrapper adds its own bypass parameter. /// /// TODO: Actually use this parameter. pub const BYPASS_PARAM_ID: &str = "bypass"; lazy_static! { pub static ref BYPASS_PARAM_HASH: u32 = hash_param_id(BYPASS_PARAM_ID); } #[repr(C)] pub struct Wrapper { // Keep the vtable as the first field so we can do a simple pointer cast pub clap_plugin: clap_plugin, /// The wrapped plugin instance. plugin: RwLock

, /// The current IO configuration, modified through the `clap_plugin_audio_ports_config` /// extension. current_bus_config: AtomicCell, /// The current buffer configuration, containing the sample rate and the maximum block size. /// Will be set in `clap_plugin::activate()`. current_buffer_config: AtomicCell>, /// Whether the plugin is currently bypassed. This is not yet integrated with the `Plugin` /// trait. bypass_state: AtomicBool, /// The incoming events for the plugin, if `P::ACCEPTS_MIDI` is set. /// /// TODO: Maybe load these lazily at some point instead of needing to spool them all to this /// queue first input_events: RwLock>, /// The current latency in samples, as set by the plugin through the [ProcessContext]. uses the /// latency extnesion /// /// TODO: Implement the latency extension. pub current_latency: AtomicU32, /// Contains slices for the plugin's outputs. You can't directly create a nested slice form /// apointer to pointers, so this needs to be preallocated in the setup call and kept around /// between process calls. This buffer owns the vector, because otherwise it would need to store /// a mutable reference to the data contained in this mutex. pub output_buffer: RwLock>, // We'll query all of the host's extensions upfront host_callback: ClapPtr, thread_check: Option>, /// Needs to be boxed because the plugin object is supposed to contain a static reference to /// this. plugin_descriptor: Box>, clap_plugin_params: clap_plugin_params, // These fiels are exactly the same as their VST3 wrapper counterparts. // /// The keys from `param_map` in a stable order. param_hashes: Vec, /// A mapping from parameter ID hashes (obtained from the string parameter IDs) to pointers to /// parameters belonging to the plugin. As long as `plugin` does not get recreated, these /// addresses will remain stable, as they are obtained from a pinned object. param_by_hash: HashMap, /// The default normalized parameter value for every parameter in `param_ids`. We need to store /// this in case the host requeries the parmaeter later. This is also indexed by the hash so we /// can retrieve them later for the UI if needed. param_defaults_normalized: HashMap, /// Mappings from string parameter indentifiers to parameter hashes. Useful for debug logging /// and when storing and restorign plugin state. param_id_to_hash: HashMap<&'static str, u32>, /// The inverse mapping from [Self::param_by_hash]. This is needed to be able to have an /// ergonomic parameter setting API that uses references to the parameters instead of having to /// add a setter function to the parameter (or even worse, have it be completely untyped). param_ptr_to_hash: HashMap, /// A queue of tasks that still need to be performed. Because CLAP lets the plugin request a /// host callback directly, we don't need to use the OsEventLoop we use in our other plugin /// implementations. Instead, we'll post tasks to this queue, ask the host to call /// [Self::on_main_thread] on the main thread, and then continue to pop tasks off this queue /// there until it is empty. tasks: ArrayQueue, /// The ID of the main thread. In practice this is the ID of the thread that created this /// object. If the host supports the thread check extension (and [Self::thread_check] thus /// contains a value), then that extension is used instead. main_thread_id: ThreadId, } /// Tasks that can be sent from the plugin to be executed on the main thread in a non-blocking /// realtime safe way. Instead of using a random thread or the OS' event loop like in the Linux /// implementation, this uses [clap_host::request_callback()] instead. #[derive(Debug, Clone)] pub enum Task { /// Inform the host that the latency has changed. LatencyChanged, } /// The types of CLAP parameter updates for events. pub enum ClapParamUpdate { /// Set the parameter to this plain value. In our wrapper the plain values are the normalized /// values multiplied by the step count for discrete parameters. PlainValueSet(f64), /// Add a delta to the parameter's current plain value (so again, multiplied by the step size). PlainValueMod(f64), } /// Because CLAP has this [clap_host::request_host_callback()] function, we don't need to use /// `OsEventLoop` and can instead just request a main thread callback directly. impl EventLoop> for Wrapper

{ fn new_and_spawn(_executor: std::sync::Weak) -> Self { panic!("What are you doing"); } fn do_maybe_async(&self, task: Task) -> bool { if self.is_main_thread() { unsafe { self.execute(task) }; true } else { let success = self.tasks.push(task).is_ok(); if success { // CLAP lets us use the host's event loop instead of having to implement our own let host = &self.host_callback; unsafe { (host.request_callback)(&**host) }; } success } } fn is_main_thread(&self) -> bool { // If the host supports the thread check interface then we'll use that, otherwise we'll // check if this is the same thread as the one that created the plugin instance. match &self.thread_check { Some(thread_check) => unsafe { (thread_check.is_main_thread)(&*self.host_callback) }, None => thread::current().id() == self.main_thread_id, } } } impl MainThreadExecutor for Wrapper

{ unsafe fn execute(&self, task: Task) { todo!("Implement latency changes for CLAP") } } impl Wrapper

{ pub fn new(host_callback: *const clap_host) -> Self { let plugin_descriptor = Box::new(PluginDescriptor::default()); assert!(!host_callback.is_null()); let host_callback = unsafe { ClapPtr::new(host_callback) }; let thread_check = unsafe { query_host_extension::(&host_callback, CLAP_EXT_THREAD_CHECK) }; let mut wrapper = Self { clap_plugin: clap_plugin { // This needs to live on the heap because the plugin object contains a direct // reference to the manifest as a value. We could share this between instances of // the plugin using an `Arc`, but this doesn't consume a lot of memory so it's not a // huge deal. desc: plugin_descriptor.clap_plugin_descriptor(), // We already need to use pointer casts in the factory, so might as well continue // doing that here plugin_data: ptr::null_mut(), init: Self::init, destroy: Self::destroy, activate: Self::activate, deactivate: Self::deactivate, start_processing: Self::start_processing, stop_processing: Self::stop_processing, process: Self::process, get_extension: Self::get_extension, on_main_thread: Self::on_main_thread, }, plugin: RwLock::new(P::default()), current_bus_config: AtomicCell::new(BusConfig { num_input_channels: P::DEFAULT_NUM_INPUTS, num_output_channels: P::DEFAULT_NUM_OUTPUTS, }), current_buffer_config: AtomicCell::new(None), bypass_state: AtomicBool::new(false), input_events: RwLock::new(VecDeque::with_capacity(512)), current_latency: AtomicU32::new(0), output_buffer: RwLock::new(Buffer::default()), host_callback, thread_check, plugin_descriptor, clap_plugin_params: clap_plugin_params { count: Self::ext_params_count, get_info: Self::ext_params_get_info, get_value: Self::ext_params_get_value, value_to_text: Self::ext_params_value_to_text, text_to_value: Self::ext_params_text_to_value, flush: Self::ext_params_flush, }, param_hashes: Vec::new(), param_by_hash: HashMap::new(), param_defaults_normalized: HashMap::new(), param_id_to_hash: HashMap::new(), param_ptr_to_hash: HashMap::new(), tasks: ArrayQueue::new(TASK_QUEUE_CAPACITY), main_thread_id: thread::current().id(), }; // This is a mapping from the parameter IDs specified by the plugin to pointers to thsoe // parameters. Since the object returned by `params()` is pinned, these pointers are safe to // dereference as long as `wrapper.plugin` is alive let param_map = wrapper.plugin.read().params().param_map(); let param_ids = wrapper.plugin.read().params().param_ids(); nih_debug_assert!( !param_map.contains_key(BYPASS_PARAM_ID), "The wrapper already adds its own bypass parameter" ); // Only calculate these hashes once, and in the stable order defined by the plugin let param_id_hashes_ptrs: Vec<_> = param_ids .iter() .filter_map(|id| { let param_ptr = param_map.get(id)?; Some((id, hash_param_id(id), param_ptr)) }) .collect(); wrapper.param_hashes = param_id_hashes_ptrs .iter() .map(|&(_, hash, _)| hash) .collect(); wrapper.param_by_hash = param_id_hashes_ptrs .iter() .map(|&(_, hash, ptr)| (hash, *ptr)) .collect(); wrapper.param_defaults_normalized = param_id_hashes_ptrs .iter() .map(|&(_, hash, ptr)| (hash, unsafe { ptr.normalized_value() })) .collect(); wrapper.param_id_to_hash = param_id_hashes_ptrs .iter() .map(|&(id, hash, _)| (*id, hash)) .collect(); wrapper.param_ptr_to_hash = param_id_hashes_ptrs .into_iter() .map(|(_, hash, ptr)| (*ptr, hash)) .collect(); wrapper } fn make_process_context(&self) -> WrapperProcessContext<'_, P> { WrapperProcessContext { plugin: self, input_events_guard: self.input_events.write(), } } /// Convenience function for setting a value for a parameter as triggered by a VST3 parameter /// update. The same rate is for updating parameter smoothing. /// /// # Note /// /// These values are CLAP plain values, which include a step count multiplier for discrete /// parameter values. pub fn update_plain_value_by_hash( &self, hash: u32, update: ClapParamUpdate, sample_rate: Option, ) -> bool { if hash == *BYPASS_PARAM_HASH { match update { ClapParamUpdate::PlainValueSet(clap_plain_value) => self .bypass_state .store(clap_plain_value >= 0.5, Ordering::SeqCst), ClapParamUpdate::PlainValueMod(clap_plain_mod) => { if clap_plain_mod > 0.0 { self.bypass_state.store(true, Ordering::SeqCst) } else if clap_plain_mod < 0.0 { self.bypass_state.store(false, Ordering::SeqCst) } } } true } else if let Some(param_ptr) = self.param_by_hash.get(&hash) { let normalized_value = match update { ClapParamUpdate::PlainValueSet(clap_plain_value) => { clap_plain_value as f32 / unsafe { param_ptr.step_count() }.unwrap_or(1) as f32 } ClapParamUpdate::PlainValueMod(clap_plain_mod) => { let current_normalized_value = unsafe { param_ptr.normalized_value() }; current_normalized_value + (clap_plain_mod as f32 / unsafe { param_ptr.step_count() }.unwrap_or(1) as f32) } }; // Also update the parameter's smoothing if applicable match (param_ptr, sample_rate) { (_, Some(sample_rate)) => unsafe { param_ptr.set_normalized_value(normalized_value); param_ptr.update_smoother(sample_rate, false); }, _ => unsafe { param_ptr.set_normalized_value(normalized_value) }, } true } else { false } } /// Handle an incoming CLAP event. You must clear [Self::input_events] first before calling this /// from the process function. /// /// To save on mutex operations when handing MIDI events, the lock guard for the input events /// need to be passed into this function. pub unsafe fn handle_event( &self, event: *const clap_event_header, input_events: &mut RwLockWriteGuard>, ) { let raw_event = &*event; match (raw_event.space_id, raw_event.type_) { // TODO: Implement the event filter // TODO: Handle sample accurate parameter changes, possibly in a similar way to the // smoothing (CLAP_CORE_EVENT_SPACE_ID, CLAP_EVENT_PARAM_VALUE) => { let event = &*(event as *const clap_event_param_value); self.update_plain_value_by_hash( event.param_id, ClapParamUpdate::PlainValueSet(event.value), self.current_buffer_config.load().map(|c| c.sample_rate), ); } (CLAP_CORE_EVENT_SPACE_ID, CLAP_EVENT_PARAM_MOD) => { let event = &*(event as *const clap_event_param_mod); self.update_plain_value_by_hash( event.param_id, ClapParamUpdate::PlainValueMod(event.amount), self.current_buffer_config.load().map(|c| c.sample_rate), ); } (CLAP_CORE_EVENT_SPACE_ID, CLAP_EVENT_NOTE_ON) => { if P::ACCEPTS_MIDI { let event = &*(event as *const clap_event_note); input_events.push_back(NoteEvent::NoteOn { timing: raw_event.time, channel: event.channel as u8, note: event.key as u8, velocity: (event.velocity * 127.0).round() as u8, }); } } (CLAP_CORE_EVENT_SPACE_ID, CLAP_EVENT_NOTE_OFF) => { if P::ACCEPTS_MIDI { let event = &*(event as *const clap_event_note); input_events.push_back(NoteEvent::NoteOff { timing: raw_event.time, channel: event.channel as u8, note: event.key as u8, velocity: (event.velocity * 127.0).round() as u8, }); } } (CLAP_CORE_EVENT_SPACE_ID, CLAP_EVENT_NOTE_EXPRESSION) => { if P::ACCEPTS_MIDI { // TODO: Implement pressure and other expressions along with MIDI CCs } } (CLAP_CORE_EVENT_SPACE_ID, CLAP_EVENT_MIDI) => { if P::ACCEPTS_MIDI { // TODO: Implement raw MIDI handling once we add CCs } } // TODO: Make sure this only gets logged in debug mode _ => nih_log!( "Unhandled CLAP event type {} for namespace {}", raw_event.type_, raw_event.space_id ), } } unsafe extern "C" fn init(_plugin: *const clap_plugin) -> bool { // We don't need any special initialization true } unsafe extern "C" fn destroy(plugin: *const clap_plugin) { Box::from_raw(plugin as *mut Self); } unsafe extern "C" fn activate( plugin: *const clap_plugin, sample_rate: f64, _min_frames_count: u32, max_frames_count: u32, ) -> bool { let wrapper = &*(plugin as *const Self); let bus_config = wrapper.current_bus_config.load(); let buffer_config = BufferConfig { sample_rate: sample_rate as f32, max_buffer_size: max_frames_count, }; // Befure initializing the plugin, make sure all smoothers are set the the default values for param in wrapper.param_by_hash.values() { param.update_smoother(buffer_config.sample_rate, true); } if wrapper.plugin.write().initialize( &bus_config, &buffer_config, &mut wrapper.make_process_context(), ) { // Preallocate enough room in the output slices vector so we can convert a `*mut *mut // f32` to a `&mut [&mut f32]` in the process call wrapper.output_buffer.write().with_raw_vec(|output_slices| { output_slices.resize_with(bus_config.num_output_channels as usize, || &mut []) }); // Also store this for later, so we can reinitialize the plugin after restoring state wrapper.current_buffer_config.store(Some(buffer_config)); true } else { false } } unsafe extern "C" fn deactivate(_plugin: *const clap_plugin) { // We currently don't do anything here } unsafe extern "C" fn start_processing(_plugin: *const clap_plugin) -> bool { // We currently don't do anything here true } unsafe extern "C" fn stop_processing(_plugin: *const clap_plugin) { // We currently don't do anything here } unsafe extern "C" fn process( plugin: *const clap_plugin, process: *const clap_process, ) -> clap_process_status { check_null_ptr!(CLAP_PROCESS_ERROR, plugin, process); let wrapper = &*(plugin as *const Self); // Panic on allocations if the `assert_process_allocs` feature has been enabled, and make // sure that FTZ is set up correctly process_wrapper(|| { // We need to handle incoming automation and MIDI events. Since we don't support sample // accuration automation yet and there's no way to get the last event for a parameter, // we'll process every incoming event. let process = &*process; if !process.in_events.is_null() { let mut input_events = wrapper.input_events.write(); input_events.clear(); let num_events = ((*process.in_events).size)(&*process.in_events); for event_idx in 0..num_events { let event = ((*process.in_events).get)(&*process.in_events, event_idx); wrapper.handle_event(event, &mut input_events); } } // I don't think this is a thing for CLAP since there's a dedicated flush function, but // might as well protect against this // TOOD: Send the output events when doing a flush if process.audio_outputs_count == 0 || process.frames_count == 0 { nih_log!("CLAP process call event flush"); return CLAP_PROCESS_CONTINUE; } // The setups we suppport are: // - 1 input bus // - 1 output bus // - 1 input bus and 1 output bus nih_debug_assert!( process.audio_inputs_count <= 1 && process.audio_outputs_count <= 1, "The host provides more than one input or output bus" ); // Right now we don't handle any auxiliary outputs check_null_ptr_msg!( "Null pointers passed for audio outputs in process function", CLAP_PROCESS_ERROR, process.audio_outputs, (*process.audio_outputs).data32 ); let audio_outputs = &*process.audio_outputs; let num_output_channels = audio_outputs.channel_count as usize; // This vector has been preallocated to contain enough slices as there are output // channels // TODO: The audio buffers have a latency field, should we use those? // TODO: Like with VST3, should we expose some way to access or set the silence/constant // flags? let mut output_buffer = wrapper.output_buffer.write(); output_buffer.with_raw_vec(|output_slices| { nih_debug_assert_eq!(num_output_channels, output_slices.len()); for (output_channel_idx, output_channel_slice) in output_slices.iter_mut().enumerate() { // SAFETY: These pointers may not be valid outside of this function even though // their lifetime is equal to this structs. This is still safe because they are // only dereferenced here later as part of this process function. *output_channel_slice = std::slice::from_raw_parts_mut( *(audio_outputs.data32 as *mut *mut f32).add(output_channel_idx), process.frames_count as usize, ); } }); // Most hosts process data in place, in which case we don't need to do any copying // ourselves. If the pointers do not alias, then we'll do the copy here and then the // plugin can just do normal in place processing. if !process.audio_inputs.is_null() { // We currently don't support sidechain inputs let audio_inputs = &*process.audio_inputs; let num_input_channels = audio_inputs.channel_count as usize; nih_debug_assert!( num_input_channels <= num_output_channels, "Stereo to mono and similar configurations are not supported" ); for input_channel_idx in 0..cmp::min(num_input_channels, num_output_channels) { let output_channel_ptr = *(audio_outputs.data32 as *mut *mut f32).add(input_channel_idx); let input_channel_ptr = *(audio_inputs.data32).add(input_channel_idx); if input_channel_ptr != output_channel_ptr { ptr::copy_nonoverlapping( input_channel_ptr, output_channel_ptr, process.frames_count as usize, ); } } } let mut plugin = wrapper.plugin.write(); let mut context = wrapper.make_process_context(); match plugin.process(&mut output_buffer, &mut context) { ProcessStatus::Error(err) => { nih_debug_assert_failure!("Process error: {}", err); CLAP_PROCESS_ERROR } ProcessStatus::Normal => CLAP_PROCESS_CONTINUE_IF_NOT_QUIET, ProcessStatus::Tail(_) => CLAP_PROCESS_CONTINUE, ProcessStatus::KeepAlive => CLAP_PROCESS_CONTINUE, } // TODO: Handle parameter outputs/automation }) } unsafe extern "C" fn get_extension( plugin: *const clap_plugin, id: *const c_char, ) -> *const c_void { check_null_ptr!(ptr::null(), plugin, id); let wrapper = &*(plugin as *const Self); // TODO: Implement the other useful extensions. Like uh audio inputs. let id = CStr::from_ptr(id); if id == CStr::from_ptr(CLAP_EXT_PARAMS) { &wrapper.clap_plugin_params as *const _ as *const c_void } else { ptr::null() } } unsafe extern "C" fn on_main_thread(plugin: *const clap_plugin) { let wrapper = &*(plugin as *const Self); // [Self::do_maybe_async] posts a task to the queue and asks the host to call this function // on the main thread, so once that's done we can just handle all requests here while let Some(task) = wrapper.tasks.pop() { wrapper.execute(task); } } unsafe extern "C" fn ext_params_count(plugin: *const clap_plugin) -> u32 { check_null_ptr!(0, plugin); let wrapper = &*(plugin as *const Self); // NOTE: We add a bypass parameter ourselves on index `plugin.param_hashes.len()`, so // these indices are all off by one wrapper.param_hashes.len() as u32 + 1 } unsafe extern "C" fn ext_params_get_info( plugin: *const clap_plugin, param_index: i32, param_info: *mut clap_param_info, ) -> bool { check_null_ptr!(false, plugin, param_info); let wrapper = &*(plugin as *const Self); // Parameter index `self.param_ids.len()` is our own bypass parameter if param_index < 0 || param_index > wrapper.param_hashes.len() as i32 { return false; } *param_info = std::mem::zeroed(); // TODO: We don't use the cookies at this point. In theory this would be faster than the ID // hashmap lookup, but for now we'll stay consistent with the VST3 implementation. let param_info = &mut *param_info; if param_index == wrapper.param_hashes.len() as i32 { param_info.id = *BYPASS_PARAM_HASH; param_info.flags = CLAP_PARAM_IS_STEPPED | CLAP_PARAM_IS_BYPASS; param_info.cookie = ptr::null_mut(); strlcpy(&mut param_info.name, "Bypass"); strlcpy(&mut param_info.module, ""); param_info.min_value = 0.0; param_info.max_value = 1.0; param_info.default_value = 0.0; } else { let param_hash = &wrapper.param_hashes[param_index as usize]; let default_value = &wrapper.param_defaults_normalized[param_hash]; let param_ptr = &wrapper.param_by_hash[param_hash]; let step_count = param_ptr.step_count(); param_info.id = *param_hash; param_info.flags = if step_count.is_some() { CLAP_PARAM_IS_STEPPED } else { 0 }; param_info.cookie = ptr::null_mut(); strlcpy(&mut param_info.name, param_ptr.name()); strlcpy(&mut param_info.module, ""); // We don't use the actual minimum and maximum values here because that would not scale // with skewed integer ranges. Instead, just treat all parameters as `[0, 1]` normalized // paramters multiplied by the step size. param_info.min_value = 0.0; // Stepped parameters are unnormalized float parameters since there's no separate step // range option // TODO: This should probably be encapsulated in some way so we don't forget about this in one place // TODO: Like with VST3, this won't actually do the correct thing with skewed stepped parameters param_info.max_value = step_count.unwrap_or(1) as f64; param_info.default_value = *default_value as f64 * step_count.unwrap_or(1) as f64; } true } unsafe extern "C" fn ext_params_get_value( plugin: *const clap_plugin, param_id: clap_id, value: *mut f64, ) -> bool { check_null_ptr!(false, plugin, value); let wrapper = &*(plugin as *const Self); if param_id == *BYPASS_PARAM_HASH { *value = if wrapper.bypass_state.load(Ordering::SeqCst) { 1.0 } else { 0.0 }; true } else if let Some(param_ptr) = wrapper.param_by_hash.get(¶m_id) { // TODO: As explained above, this may do strange things with skewed discrete parameters *value = param_ptr.normalized_value() as f64 * param_ptr.step_count().unwrap_or(1) as f64; true } else { false } } unsafe extern "C" fn ext_params_value_to_text( plugin: *const clap_plugin, param_id: clap_id, value: f64, display: *mut c_char, size: u32, ) -> bool { check_null_ptr!(false, plugin, display); let wrapper = &*(plugin as *const Self); let dest = std::slice::from_raw_parts_mut(display, size as usize); if param_id == *BYPASS_PARAM_HASH { if value > 0.5 { strlcpy(dest, "Bypassed") } else { strlcpy(dest, "Not Bypassed") } true } else if let Some(param_ptr) = wrapper.param_by_hash.get(¶m_id) { strlcpy( dest, // CLAP does not have a separate unit, so we'll include the unit here ¶m_ptr.normalized_value_to_string( value as f32 / param_ptr.step_count().unwrap_or(1) as f32, true, ), ); true } else { false } } unsafe extern "C" fn ext_params_text_to_value( plugin: *const clap_plugin, param_id: clap_id, display: *const c_char, value: *mut f64, ) -> bool { check_null_ptr!(false, plugin, display, value); let wrapper = &*(plugin as *const Self); let display = match CStr::from_ptr(display).to_str() { Ok(s) => s, Err(_) => return false, }; if param_id == *BYPASS_PARAM_HASH { let normalized_valeu = match display { "Bypassed" => 1.0, "Not Bypassed" => 0.0, _ => return false, }; *value = normalized_valeu; true } else if let Some(param_ptr) = wrapper.param_by_hash.get(¶m_id) { let normalized_value = match param_ptr.string_to_normalized_value(display) { Some(v) => v as f64, None => return false, }; *value = normalized_value * param_ptr.step_count().unwrap_or(1) as f64; true } else { false } } unsafe extern "C" fn ext_params_flush( plugin: *const clap_plugin, in_: *const clap_input_events, out: *const clap_output_events, ) { check_null_ptr!((), plugin); let wrapper = &*(plugin as *const Self); if !in_.is_null() { let mut input_events = wrapper.input_events.write(); let num_events = ((*in_).size)(&*in_); for event_idx in 0..num_events { let event = ((*in_).get)(&*in_, event_idx); wrapper.handle_event(event, &mut input_events); } } // TODO: Handle automation/outputs } } /// Convenience function to query an extennsion from the host. /// /// # Safety /// /// The extension type `T` must match the extension's name `name`. unsafe fn query_host_extension( host_callback: &ClapPtr, name: *const c_char, ) -> Option> { let extension_ptr = (host_callback.get_extension)(&**host_callback, name); if !extension_ptr.is_null() { Some(ClapPtr::new(extension_ptr as *const T)) } else { None } }