mozilla-central/third_party/rust/alsa/src/seq.rs

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//! MIDI sequencer I/O and enumeration
use libc::{c_uint, c_int, c_short, c_uchar, c_void, c_long, size_t, pollfd};
use super::error::*;
use crate::alsa;
use super::{Direction, poll};
use std::{ptr, fmt, mem, slice, time, cell};
use std::str::{FromStr, Split};
use std::ffi::{CStr};
use std::borrow::Cow;
// Workaround for improper alignment of snd_seq_ev_ext_t in alsa-sys
#[repr(packed)]
struct EvExtPacked {
len: c_uint,
ptr: *mut c_void,
}
///
/// To access the functions `event_input`, `event_input_pending` and `set_input_buffer_size`,
/// you first have to obtain an instance of `Input` by calling `input()`. Only one instance of
/// `Input` may exist at any time for a given `Seq`.
pub struct Seq(*mut alsa::snd_seq_t, cell::Cell<bool>);
unsafe impl Send for Seq {}
impl Drop for Seq {
fn drop(&mut self) { unsafe { alsa::snd_seq_close(self.0) }; }
}
impl Seq {
fn check_has_input(&self) {
if self.1.get() { panic!("No additional Input object allowed")}
}
/// Opens the sequencer.
///
/// If name is None, "default" will be used. That's almost always what you usually want to use anyway.
pub fn open(name: Option<&CStr>, dir: Option<Direction>, nonblock: bool) -> Result<Seq> {
let n2 = name.unwrap_or(unsafe { CStr::from_bytes_with_nul_unchecked(b"default\0") });
let mut h = ptr::null_mut();
let mode = if nonblock { alsa::SND_SEQ_NONBLOCK } else { 0 };
let streams = match dir {
None => alsa::SND_SEQ_OPEN_DUPLEX,
Some(Direction::Playback) => alsa::SND_SEQ_OPEN_OUTPUT,
Some(Direction::Capture) => alsa::SND_SEQ_OPEN_INPUT,
};
acheck!(snd_seq_open(&mut h, n2.as_ptr(), streams, mode))
.map(|_| Seq(h, cell::Cell::new(false)))
}
pub fn set_client_name(&self, name: &CStr) -> Result<()> {
acheck!(snd_seq_set_client_name(self.0, name.as_ptr())).map(|_| ())
}
pub fn set_client_event_filter(&self, event_type: i32) -> Result<()> {
acheck!(snd_seq_set_client_event_filter(self.0, event_type as c_int)).map(|_| ())
}
pub fn set_client_pool_output(&self, size: u32) -> Result<()> {
acheck!(snd_seq_set_client_pool_output(self.0, size as size_t)).map(|_| ())
}
pub fn set_client_pool_input(&self, size: u32) -> Result<()> {
acheck!(snd_seq_set_client_pool_input(self.0, size as size_t)).map(|_| ())
}
pub fn set_client_pool_output_room(&self, size: u32) -> Result<()> {
acheck!(snd_seq_set_client_pool_output_room(self.0, size as size_t)).map(|_| ())
}
pub fn client_id(&self) -> Result<i32> {
acheck!(snd_seq_client_id(self.0)).map(|q| q as i32)
}
pub fn drain_output(&self) -> Result<i32> {
acheck!(snd_seq_drain_output(self.0)).map(|q| q as i32)
}
pub fn get_any_client_info(&self, client: i32) -> Result<ClientInfo> {
let c = ClientInfo::new()?;
acheck!(snd_seq_get_any_client_info(self.0, client, c.0)).map(|_| c)
}
pub fn get_any_port_info(&self, a: Addr) -> Result<PortInfo> {
let c = PortInfo::new()?;
acheck!(snd_seq_get_any_port_info(self.0, a.client as c_int, a.port as c_int, c.0)).map(|_| c)
}
pub fn create_port(&self, port: &PortInfo) -> Result<()> {
acheck!(snd_seq_create_port(self.0, port.0)).map(|_| ())
}
pub fn create_simple_port(&self, name: &CStr, caps: PortCap, t: PortType) -> Result<i32> {
acheck!(snd_seq_create_simple_port(self.0, name.as_ptr(), caps.bits() as c_uint, t.bits() as c_uint)).map(|q| q as i32)
}
pub fn set_port_info(&self, port: i32, info: &mut PortInfo) -> Result<()> {
acheck!(snd_seq_set_port_info(self.0, port, info.0)).map(|_| ())
}
pub fn delete_port(&self, port: i32) -> Result<()> {
acheck!(snd_seq_delete_port(self.0, port as c_int)).map(|_| ())
}
pub fn subscribe_port(&self, info: &PortSubscribe) -> Result<()> {
acheck!(snd_seq_subscribe_port(self.0, info.0)).map(|_| ())
}
pub fn unsubscribe_port(&self, sender: Addr, dest: Addr) -> Result<()> {
let z = PortSubscribe::new()?;
z.set_sender(sender);
z.set_dest(dest);
acheck!(snd_seq_unsubscribe_port(self.0, z.0)).map(|_| ())
}
pub fn control_queue(&self, q: i32, t: EventType, value: i32, e: Option<&mut Event>) -> Result<()> {
assert!(EvQueueControl::<()>::has_data(t) || EvQueueControl::<i32>::has_data(t) || EvQueueControl::<u32>::has_data(t));
let p = e.map(|e| &mut e.0 as *mut _).unwrap_or(ptr::null_mut());
acheck!(snd_seq_control_queue(self.0, q as c_int, t as c_int, value as c_int, p)).map(|_| ())
}
pub fn event_output(&self, e: &mut Event) -> Result<u32> {
e.ensure_buf();
acheck!(snd_seq_event_output(self.0, &mut e.0)).map(|q| q as u32)
}
pub fn event_output_buffer(&self, e: &mut Event) -> Result<u32> {
e.ensure_buf();
acheck!(snd_seq_event_output_buffer(self.0, &mut e.0)).map(|q| q as u32)
}
pub fn event_output_direct(&self, e: &mut Event) -> Result<u32> {
e.ensure_buf();
acheck!(snd_seq_event_output_direct(self.0, &mut e.0)).map(|q| q as u32)
}
pub fn get_queue_tempo(&self, q: i32) -> Result<QueueTempo> {
let value = QueueTempo::new()?;
acheck!(snd_seq_get_queue_tempo(self.0, q as c_int, value.0)).map(|_| value)
}
pub fn set_queue_tempo(&self, q: i32, value: &QueueTempo) -> Result<()> {
acheck!(snd_seq_set_queue_tempo(self.0, q as c_int, value.0)).map(|_| ())
}
pub fn get_queue_status(&self, q: i32) -> Result<QueueStatus> {
let value = QueueStatus::new()?;
acheck!(snd_seq_get_queue_status(self.0, q as c_int, value.0)).map(|_| value)
}
pub fn free_queue(&self, q: i32) -> Result<()> { acheck!(snd_seq_free_queue(self.0, q)).map(|_| ()) }
pub fn alloc_queue(&self) -> Result<i32> { acheck!(snd_seq_alloc_queue(self.0)).map(|q| q as i32) }
pub fn alloc_named_queue(&self, n: &CStr) -> Result<i32> {
acheck!(snd_seq_alloc_named_queue(self.0, n.as_ptr())).map(|q| q as i32)
}
pub fn sync_output_queue(&self) -> Result<()> {
acheck!(snd_seq_sync_output_queue(self.0)).map(|_| ())
}
pub fn drop_output(&self) -> Result<()> {
acheck!(snd_seq_drop_output(self.0)).map(|_| ())
}
/// Call this function to obtain an instance of `Input` to access the functions `event_input`,
/// `event_input_pending` and `set_input_buffer_size`. See the documentation of `Input` for details.
pub fn input(&self) -> Input {
Input::new(self)
}
pub fn remove_events(&self, condition: RemoveEvents) -> Result<()> {
acheck!(snd_seq_remove_events(self.0, condition.0)).map(|_| ())
}
}
/// Struct for receiving input events from a sequencer. The methods offered by this
/// object may modify the internal input buffer of the sequencer, which must not happen
/// while an `Event` is alive that has been obtained from a call to `event_input` (which
/// takes `Input` by mutable reference for this reason). This is because the event might
/// directly reference the sequencer's input buffer for variable-length messages (e.g. Sysex).
///
/// Note: Only one `Input` object is allowed in scope at a time.
pub struct Input<'a>(&'a Seq);
impl<'a> Drop for Input<'a> {
fn drop(&mut self) { (self.0).1.set(false) }
}
impl<'a> Input<'a> {
fn new(s: &'a Seq) -> Input<'a> {
s.check_has_input();
s.1.set(true);
Input(s)
}
pub fn event_input(&mut self) -> Result<Event> {
// The returned event might reference the input buffer of the `Seq`.
// Therefore we mutably borrow the `Input` structure, preventing any
// other function call that might change the input buffer while the
// event is alive.
let mut z = ptr::null_mut();
acheck!(snd_seq_event_input((self.0).0, &mut z))?;
unsafe { Event::extract (&mut *z, "snd_seq_event_input") }
}
pub fn event_input_pending(&self, fetch_sequencer: bool) -> Result<u32> {
acheck!(snd_seq_event_input_pending((self.0).0, if fetch_sequencer {1} else {0})).map(|q| q as u32)
}
pub fn set_input_buffer_size(&self, size: u32) -> Result<()> {
acheck!(snd_seq_set_input_buffer_size((self.0).0, size as size_t)).map(|_| ())
}
pub fn drop_input(&self) -> Result<()> {
acheck!(snd_seq_drop_input((self.0).0)).map(|_| ())
}
}
fn polldir(o: Option<Direction>) -> c_short {
match o {
None => poll::Flags::IN | poll::Flags::OUT,
Some(Direction::Playback) => poll::Flags::OUT,
Some(Direction::Capture) => poll::Flags::IN,
}.bits()
}
impl<'a> poll::Descriptors for (&'a Seq, Option<Direction>) {
fn count(&self) -> usize {
unsafe { alsa::snd_seq_poll_descriptors_count((self.0).0, polldir(self.1)) as usize }
}
fn fill(&self, p: &mut [pollfd]) -> Result<usize> {
let z = unsafe { alsa::snd_seq_poll_descriptors((self.0).0, p.as_mut_ptr(), p.len() as c_uint, polldir(self.1)) };
from_code("snd_seq_poll_descriptors", z).map(|_| z as usize)
}
fn revents(&self, p: &[pollfd]) -> Result<poll::Flags> {
let mut r = 0;
let z = unsafe { alsa::snd_seq_poll_descriptors_revents((self.0).0, p.as_ptr() as *mut pollfd, p.len() as c_uint, &mut r) };
from_code("snd_seq_poll_descriptors_revents", z).map(|_| poll::Flags::from_bits_truncate(r as c_short))
}
}
pub struct ClientInfo(*mut alsa::snd_seq_client_info_t);
unsafe impl Send for ClientInfo {}
impl Drop for ClientInfo {
fn drop(&mut self) {
unsafe { alsa::snd_seq_client_info_free(self.0) };
}
}
impl ClientInfo {
fn new() -> Result<Self> {
let mut p = ptr::null_mut();
acheck!(snd_seq_client_info_malloc(&mut p)).map(|_| ClientInfo(p))
}
// Not sure if it's useful for this one to be public.
fn set_client(&self, client: i32) {
unsafe { alsa::snd_seq_client_info_set_client(self.0, client as c_int) };
}
pub fn get_client(&self) -> i32 {
unsafe { alsa::snd_seq_client_info_get_client(self.0) as i32 }
}
pub fn get_name(&self) -> Result<&str> {
let c = unsafe { alsa::snd_seq_client_info_get_name(self.0) };
from_const("snd_seq_client_info_get_name", c)
}
}
impl fmt::Debug for ClientInfo {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "ClientInfo({},{:?})", self.get_client(), self.get_name())
}
}
#[derive(Copy, Clone)]
/// Iterates over clients connected to the seq API (both kernel and userspace clients).
pub struct ClientIter<'a>(&'a Seq, i32);
impl<'a> ClientIter<'a> {
pub fn new(seq: &'a Seq) -> Self { ClientIter(seq, -1) }
}
impl<'a> Iterator for ClientIter<'a> {
type Item = ClientInfo;
fn next(&mut self) -> Option<Self::Item> {
let z = ClientInfo::new().unwrap();
z.set_client(self.1);
let r = unsafe { alsa::snd_seq_query_next_client((self.0).0, z.0) };
if r < 0 { self.1 = -1; return None };
self.1 = z.get_client();
Some(z)
}
}
pub struct PortInfo(*mut alsa::snd_seq_port_info_t);
unsafe impl Send for PortInfo {}
impl Drop for PortInfo {
fn drop(&mut self) {
unsafe { alsa::snd_seq_port_info_free(self.0) };
}
}
impl PortInfo {
fn new() -> Result<Self> {
let mut p = ptr::null_mut();
acheck!(snd_seq_port_info_malloc(&mut p)).map(|_| PortInfo(p))
}
/// Creates a new PortInfo with all fields set to zero.
pub fn empty() -> Result<Self> {
let z = Self::new()?;
unsafe { ptr::write_bytes(z.0 as *mut u8, 0, alsa::snd_seq_port_info_sizeof()) };
Ok(z)
}
pub fn get_client(&self) -> i32 {
unsafe { alsa::snd_seq_port_info_get_client(self.0) as i32 }
}
pub fn get_port(&self) -> i32 {
unsafe { alsa::snd_seq_port_info_get_port(self.0) as i32 }
}
// Not sure if it's useful for this one to be public.
fn set_client(&self, client: i32) {
unsafe { alsa::snd_seq_port_info_set_client(self.0, client as c_int) };
}
// Not sure if it's useful for this one to be public.
fn set_port(&self, port: i32) {
unsafe { alsa::snd_seq_port_info_set_port(self.0, port as c_int) };
}
pub fn get_name(&self) -> Result<&str> {
let c = unsafe { alsa::snd_seq_port_info_get_name(self.0) };
from_const("snd_seq_port_info_get_name", c)
}
pub fn set_name(&mut self, name: &CStr) {
// Note: get_name returns an interior reference, so this one must take &mut self
unsafe { alsa::snd_seq_port_info_set_name(self.0, name.as_ptr()) };
}
pub fn get_capability(&self) -> PortCap {
PortCap::from_bits_truncate(unsafe { alsa::snd_seq_port_info_get_capability(self.0) as u32 })
}
pub fn get_type(&self) -> PortType {
PortType::from_bits_truncate(unsafe { alsa::snd_seq_port_info_get_type(self.0) as u32 })
}
pub fn set_capability(&self, c: PortCap) {
unsafe { alsa::snd_seq_port_info_set_capability(self.0, c.bits() as c_uint) }
}
pub fn set_type(&self, c: PortType) {
unsafe { alsa::snd_seq_port_info_set_type(self.0, c.bits() as c_uint) }
}
/// Returns an Addr containing this PortInfo's client and port id.
pub fn addr(&self) -> Addr {
Addr {
client: self.get_client(),
port: self.get_port(),
}
}
pub fn get_midi_channels(&self) -> i32 { unsafe { alsa::snd_seq_port_info_get_midi_channels(self.0) as i32 } }
pub fn get_midi_voices(&self) -> i32 { unsafe { alsa::snd_seq_port_info_get_midi_voices(self.0) as i32 } }
pub fn get_synth_voices(&self) -> i32 { unsafe { alsa::snd_seq_port_info_get_synth_voices(self.0) as i32 } }
pub fn get_read_use(&self) -> i32 { unsafe { alsa::snd_seq_port_info_get_read_use(self.0) as i32 } }
pub fn get_write_use(&self) -> i32 { unsafe { alsa::snd_seq_port_info_get_write_use(self.0) as i32 } }
pub fn get_port_specified(&self) -> bool { unsafe { alsa::snd_seq_port_info_get_port_specified(self.0) == 1 } }
pub fn get_timestamping(&self) -> bool { unsafe { alsa::snd_seq_port_info_get_timestamping(self.0) == 1 } }
pub fn get_timestamp_real(&self) -> bool { unsafe { alsa::snd_seq_port_info_get_timestamp_real(self.0) == 1 } }
pub fn get_timestamp_queue(&self) -> i32 { unsafe { alsa::snd_seq_port_info_get_timestamp_queue(self.0) as i32 } }
pub fn set_midi_channels(&self, value: i32) { unsafe { alsa::snd_seq_port_info_set_midi_channels(self.0, value as c_int) } }
pub fn set_midi_voices(&self, value: i32) { unsafe { alsa::snd_seq_port_info_set_midi_voices(self.0, value as c_int) } }
pub fn set_synth_voices(&self, value: i32) { unsafe { alsa::snd_seq_port_info_set_synth_voices(self.0, value as c_int) } }
pub fn set_port_specified(&self, value: bool) { unsafe { alsa::snd_seq_port_info_set_port_specified(self.0, if value { 1 } else { 0 } ) } }
pub fn set_timestamping(&self, value: bool) { unsafe { alsa::snd_seq_port_info_set_timestamping(self.0, if value { 1 } else { 0 } ) } }
pub fn set_timestamp_real(&self, value: bool) { unsafe { alsa::snd_seq_port_info_set_timestamp_real(self.0, if value { 1 } else { 0 } ) } }
pub fn set_timestamp_queue(&self, value: i32) { unsafe { alsa::snd_seq_port_info_set_timestamp_queue(self.0, value as c_int) } }
}
impl fmt::Debug for PortInfo {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "PortInfo({}:{},{:?})", self.get_client(), self.get_port(), self.get_name())
}
}
#[derive(Copy, Clone)]
/// Iterates over clients connected to the seq API (both kernel and userspace clients).
pub struct PortIter<'a>(&'a Seq, i32, i32);
impl<'a> PortIter<'a> {
pub fn new(seq: &'a Seq, client: i32) -> Self { PortIter(seq, client, -1) }
}
impl<'a> Iterator for PortIter<'a> {
type Item = PortInfo;
fn next(&mut self) -> Option<Self::Item> {
let z = PortInfo::new().unwrap();
z.set_client(self.1);
z.set_port(self.2);
let r = unsafe { alsa::snd_seq_query_next_port((self.0).0, z.0) };
if r < 0 { self.2 = -1; return None };
self.2 = z.get_port();
Some(z)
}
}
bitflags! {
#[repr(transparent)]
#[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)]
pub struct PortCap: u32 {
const READ = 1<<0;
const WRITE = 1<<1;
const SYNC_READ = 1<<2;
const SYNC_WRITE = 1<<3;
const DUPLEX = 1<<4;
const SUBS_READ = 1<<5;
const SUBS_WRITE = 1<<6;
const NO_EXPORT = 1<<7;
}
}
bitflags! {
#[repr(transparent)]
#[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)]
pub struct PortType: u32 {
const SPECIFIC = (1<<0);
const MIDI_GENERIC = (1<<1);
const MIDI_GM = (1<<2);
const MIDI_GS = (1<<3);
const MIDI_XG = (1<<4);
const MIDI_MT32 = (1<<5);
const MIDI_GM2 = (1<<6);
const SYNTH = (1<<10);
const DIRECT_SAMPLE = (1<<11);
const SAMPLE = (1<<12);
const HARDWARE = (1<<16);
const SOFTWARE = (1<<17);
const SYNTHESIZER = (1<<18);
const PORT = (1<<19);
const APPLICATION = (1<<20);
}
}
bitflags! {
#[repr(transparent)]
#[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)]
pub struct Remove: u32 {
const INPUT = (1<<0);
const OUTPUT = (1<<1);
const DEST = (1<<2);
const DEST_CHANNEL = (1<<3);
const TIME_BEFORE = (1<<4);
const TIME_AFTER = (1<<5);
const TIME_TICK = (1<<6);
const EVENT_TYPE = (1<<7);
const IGNORE_OFF = (1<<8);
const TAG_MATCH = (1<<9);
}
}
#[derive(Debug, Clone, Copy, Eq, PartialEq, Ord, PartialOrd, Hash, Default)]
pub struct Addr {
pub client: i32,
pub port: i32,
}
impl FromStr for Addr {
type Err = Box<dyn std::error::Error>;
fn from_str(s: &str) -> std::result::Result<Self, Self::Err> {
let mut split: Split<'_, char> = s.trim().split(':');
let client = split.next()
.ok_or("no client provided")?
.parse::<i32>()?;
let port = split.next()
.ok_or("no port provided")?
.parse::<i32>()?;
match split.next() {
Some(_) => {
Err("too many arguments".into())
},
None => {
Ok(Addr { client, port })
}
}
}
}
impl Addr {
pub fn system_timer() -> Addr { Addr { client: alsa::SND_SEQ_CLIENT_SYSTEM as i32, port: alsa::SND_SEQ_PORT_SYSTEM_TIMER as i32 } }
pub fn system_announce() -> Addr { Addr { client: alsa::SND_SEQ_CLIENT_SYSTEM as i32, port: alsa::SND_SEQ_PORT_SYSTEM_ANNOUNCE as i32 } }
pub fn broadcast() -> Addr { Addr { client: alsa::SND_SEQ_ADDRESS_BROADCAST as i32, port: alsa::SND_SEQ_ADDRESS_BROADCAST as i32 } }
}
pub struct PortSubscribe(*mut alsa::snd_seq_port_subscribe_t);
unsafe impl Send for PortSubscribe {}
impl Drop for PortSubscribe {
fn drop(&mut self) { unsafe { alsa::snd_seq_port_subscribe_free(self.0) }; }
}
impl PortSubscribe {
fn new() -> Result<Self> {
let mut p = ptr::null_mut();
acheck!(snd_seq_port_subscribe_malloc(&mut p)).map(|_| PortSubscribe(p))
}
/// Creates a new PortSubscribe with all fields set to zero.
pub fn empty() -> Result<Self> {
let z = Self::new()?;
unsafe { ptr::write_bytes(z.0 as *mut u8, 0, alsa::snd_seq_port_subscribe_sizeof()) };
Ok(z)
}
pub fn get_sender(&self) -> Addr { unsafe {
let z = alsa::snd_seq_port_subscribe_get_sender(self.0);
Addr { client: (*z).client as i32, port: (*z).port as i32 }
} }
pub fn get_dest(&self) -> Addr { unsafe {
let z = alsa::snd_seq_port_subscribe_get_dest(self.0);
Addr { client: (*z).client as i32, port: (*z).port as i32 }
} }
pub fn get_queue(&self) -> i32 { unsafe { alsa::snd_seq_port_subscribe_get_queue(self.0) as i32 } }
pub fn get_exclusive(&self) -> bool { unsafe { alsa::snd_seq_port_subscribe_get_exclusive(self.0) == 1 } }
pub fn get_time_update(&self) -> bool { unsafe { alsa::snd_seq_port_subscribe_get_time_update(self.0) == 1 } }
pub fn get_time_real(&self) -> bool { unsafe { alsa::snd_seq_port_subscribe_get_time_real(self.0) == 1 } }
pub fn set_sender(&self, value: Addr) {
let z = alsa::snd_seq_addr_t { client: value.client as c_uchar, port: value.port as c_uchar };
unsafe { alsa::snd_seq_port_subscribe_set_sender(self.0, &z) };
}
pub fn set_dest(&self, value: Addr) {
let z = alsa::snd_seq_addr_t { client: value.client as c_uchar, port: value.port as c_uchar };
unsafe { alsa::snd_seq_port_subscribe_set_dest(self.0, &z) };
}
pub fn set_queue(&self, value: i32) { unsafe { alsa::snd_seq_port_subscribe_set_queue(self.0, value as c_int) } }
pub fn set_exclusive(&self, value: bool) { unsafe { alsa::snd_seq_port_subscribe_set_exclusive(self.0, if value { 1 } else { 0 } ) } }
pub fn set_time_update(&self, value: bool) { unsafe { alsa::snd_seq_port_subscribe_set_time_update(self.0, if value { 1 } else { 0 } ) } }
pub fn set_time_real(&self, value: bool) { unsafe { alsa::snd_seq_port_subscribe_set_time_real(self.0, if value { 1 } else { 0 } ) } }
}
#[derive(Copy, Clone)]
pub enum QuerySubsType {
READ = alsa::SND_SEQ_QUERY_SUBS_READ as isize,
WRITE = alsa::SND_SEQ_QUERY_SUBS_WRITE as isize,
}
//(kept private, functionality exposed by PortSubscribeIter)
struct QuerySubscribe(*mut alsa::snd_seq_query_subscribe_t);
unsafe impl Send for QuerySubscribe {}
impl Drop for QuerySubscribe {
fn drop(&mut self) { unsafe { alsa::snd_seq_query_subscribe_free(self.0) } }
}
impl QuerySubscribe {
pub fn new() -> Result<Self> {
let mut q = ptr::null_mut();
acheck!(snd_seq_query_subscribe_malloc(&mut q)).map(|_| QuerySubscribe(q))
}
pub fn get_index(&self) -> i32 { unsafe { alsa::snd_seq_query_subscribe_get_index(self.0) as i32 } }
pub fn get_addr(&self) -> Addr { unsafe {
let a = &(*alsa::snd_seq_query_subscribe_get_addr(self.0));
Addr { client: a.client as i32, port: a.port as i32 }
} }
pub fn get_queue(&self) -> i32 { unsafe { alsa::snd_seq_query_subscribe_get_queue(self.0) as i32 } }
pub fn get_exclusive(&self) -> bool { unsafe { alsa::snd_seq_query_subscribe_get_exclusive(self.0) == 1 } }
pub fn get_time_update(&self) -> bool { unsafe { alsa::snd_seq_query_subscribe_get_time_update(self.0) == 1 } }
pub fn get_time_real(&self) -> bool { unsafe { alsa::snd_seq_query_subscribe_get_time_real(self.0) == 1 } }
pub fn set_root(&self, value: Addr) { unsafe {
let a = alsa::snd_seq_addr_t { client: value.client as c_uchar, port: value.port as c_uchar};
alsa::snd_seq_query_subscribe_set_root(self.0, &a);
} }
pub fn set_type(&self, value: QuerySubsType) { unsafe {
alsa::snd_seq_query_subscribe_set_type(self.0, value as alsa::snd_seq_query_subs_type_t)
} }
pub fn set_index(&self, value: i32) { unsafe { alsa::snd_seq_query_subscribe_set_index(self.0, value as c_int) } }
}
#[derive(Copy, Clone)]
/// Iterates over port subscriptions for a given client:port/type.
pub struct PortSubscribeIter<'a> {
seq: &'a Seq,
addr: Addr,
query_subs_type: QuerySubsType,
index: i32
}
impl<'a> PortSubscribeIter<'a> {
pub fn new(seq: &'a Seq, addr: Addr, query_subs_type: QuerySubsType) -> Self {
PortSubscribeIter {seq, addr, query_subs_type, index: 0 }
}
}
impl<'a> Iterator for PortSubscribeIter<'a> {
type Item = PortSubscribe;
fn next(&mut self) -> Option<Self::Item> {
let query = QuerySubscribe::new().unwrap();
query.set_root(self.addr);
query.set_type(self.query_subs_type);
query.set_index(self.index);
let r = unsafe { alsa::snd_seq_query_port_subscribers((self.seq).0, query.0) };
if r < 0 {
self.index = 0;
return None;
}
self.index = query.get_index() + 1;
let vtr = PortSubscribe::new().unwrap();
match self.query_subs_type {
QuerySubsType::READ => {
vtr.set_sender(self.addr);
vtr.set_dest(query.get_addr());
},
QuerySubsType:: WRITE => {
vtr.set_sender(query.get_addr());
vtr.set_dest(self.addr);
}
};
vtr.set_queue(query.get_queue());
vtr.set_exclusive(query.get_exclusive());
vtr.set_time_update(query.get_time_update());
vtr.set_time_real(query.get_time_real());
Some(vtr)
}
}
///
/// Fields of the event is not directly exposed. Instead call `Event::new` to set data (which can be, e g, an EvNote).
/// Use `get_type` and `get_data` to retrieve data.
///
/// The lifetime parameter refers to the lifetime of an associated external buffer that might be used for
/// variable-length messages (e.g. SysEx).
pub struct Event<'a>(alsa::snd_seq_event_t, EventType, Option<Cow<'a, [u8]>>);
unsafe impl<'a> Send for Event<'a> {}
impl<'a> Event<'a> {
/// Creates a new event. For events that carry variable-length data (e.g. Sysex), `new_ext` has to be used instead.
pub fn new<D: EventData>(t: EventType, data: &D) -> Event<'static> {
assert!(!Event::has_ext_data(t), "event type must not carry variable-length data");
let mut z = Event(unsafe { mem::zeroed() }, t, None);
(z.0).type_ = t as c_uchar;
(z.0).flags |= Event::get_length_flag(t);
debug_assert!(D::has_data(t));
data.set_data(&mut z);
z
}
/// Creates a new event carrying variable-length data. This is required for event types `Sysex`, `Bounce`, and the `UsrVar` types.
pub fn new_ext<D: Into<Cow<'a, [u8]>>>(t: EventType, data: D) -> Event<'a> {
assert!(Event::has_ext_data(t), "event type must carry variable-length data");
let mut z = Event(unsafe { mem::zeroed() }, t, Some(data.into()));
(z.0).type_ = t as c_uchar;
(z.0).flags |= Event::get_length_flag(t);
z
}
/// Consumes this event and returns an (otherwise unchanged) event where the externally referenced
/// buffer for variable length messages (e.g. SysEx) has been copied into the event.
/// The returned event has a static lifetime, i e, it's decoupled from the original buffer.
pub fn into_owned(self) -> Event<'static> {
Event(self.0, self.1, self.2.map(|cow| Cow::Owned(cow.into_owned())))
}
fn get_length_flag(t: EventType) -> u8 {
match t {
EventType::Sysex => alsa::SND_SEQ_EVENT_LENGTH_VARIABLE,
EventType::Bounce => alsa::SND_SEQ_EVENT_LENGTH_VARIABLE, // not clear whether this should be VARIABLE or VARUSR
EventType::UsrVar0 => alsa::SND_SEQ_EVENT_LENGTH_VARUSR,
EventType::UsrVar1 => alsa::SND_SEQ_EVENT_LENGTH_VARUSR,
EventType::UsrVar2 => alsa::SND_SEQ_EVENT_LENGTH_VARUSR,
EventType::UsrVar3 => alsa::SND_SEQ_EVENT_LENGTH_VARUSR,
EventType::UsrVar4 => alsa::SND_SEQ_EVENT_LENGTH_VARUSR,
_ => alsa::SND_SEQ_EVENT_LENGTH_FIXED
}
}
fn has_ext_data(t: EventType) -> bool {
Event::get_length_flag(t) != alsa::SND_SEQ_EVENT_LENGTH_FIXED
}
/// Extracts event type and data. Produces a result with an arbitrary lifetime, hence the unsafety.
unsafe fn extract<'any>(z: &mut alsa::snd_seq_event_t, func: &'static str) -> Result<Event<'any>> {
let t = EventType::from_c_int((*z).type_ as c_int, func)?;
let ext_data = if Event::has_ext_data(t) {
assert_ne!((*z).flags & alsa::SND_SEQ_EVENT_LENGTH_MASK, alsa::SND_SEQ_EVENT_LENGTH_FIXED);
Some(Cow::Borrowed({
let zz: &EvExtPacked = &*(&(*z).data as *const alsa::snd_seq_event__bindgen_ty_1 as *const _);
slice::from_raw_parts((*zz).ptr as *mut u8, (*zz).len as usize)
}))
} else {
None
};
Ok(Event(ptr::read(z), t, ext_data))
}
/// Ensures that the ev.ext union element points to the correct resize_buffer for events
/// with variable length content
fn ensure_buf(&mut self) {
if !Event::has_ext_data(self.1) { return; }
let slice: &[u8] = match self.2 {
Some(Cow::Owned(ref mut vec)) => &vec[..],
Some(Cow::Borrowed(buf)) => buf,
// The following case is always a logic error in the program, thus panicking is okay.
None => panic!("event type requires variable-length data, but none was provided")
};
let z: &mut EvExtPacked = unsafe { &mut *(&mut self.0.data as *mut alsa::snd_seq_event__bindgen_ty_1 as *mut _) };
z.len = slice.len() as c_uint;
z.ptr = slice.as_ptr() as *mut c_void;
}
#[inline]
pub fn get_type(&self) -> EventType { self.1 }
/// Extract the event data from an event.
/// Use `get_ext` instead for events carrying variable-length data.
pub fn get_data<D: EventData>(&self) -> Option<D> { if D::has_data(self.1) { Some(D::get_data(self)) } else { None } }
/// Extract the variable-length data carried by events of type `Sysex`, `Bounce`, or the `UsrVar` types.
pub fn get_ext(&self) -> Option<&[u8]> {
if Event::has_ext_data(self.1) {
match self.2 {
Some(Cow::Owned(ref vec)) => Some(&vec[..]),
Some(Cow::Borrowed(buf)) => Some(buf),
// The following case is always a logic error in the program, thus panicking is okay.
None => panic!("event type requires variable-length data, but none was found")
}
} else {
None
}
}
pub fn set_subs(&mut self) {
self.0.dest.client = alsa::SND_SEQ_ADDRESS_SUBSCRIBERS;
self.0.dest.port = alsa::SND_SEQ_ADDRESS_UNKNOWN;
}
pub fn set_source(&mut self, p: i32) { self.0.source.port = p as u8 }
pub fn set_dest(&mut self, d: Addr) { self.0.dest.client = d.client as c_uchar; self.0.dest.port = d.port as c_uchar; }
pub fn set_tag(&mut self, t: u8) { self.0.tag = t as c_uchar; }
pub fn set_queue(&mut self, q: i32) { self.0.queue = q as c_uchar; }
pub fn get_source(&self) -> Addr { Addr { client: self.0.source.client as i32, port: self.0.source.port as i32 } }
pub fn get_dest(&self) -> Addr { Addr { client: self.0.dest.client as i32, port: self.0.dest.port as i32 } }
pub fn get_tag(&self) -> u8 { self.0.tag as u8 }
pub fn get_queue(&self) -> i32 { self.0.queue as i32 }
pub fn schedule_real(&mut self, queue: i32, relative: bool, rtime: time::Duration) {
self.0.flags &= !(alsa::SND_SEQ_TIME_STAMP_MASK | alsa::SND_SEQ_TIME_MODE_MASK);
self.0.flags |= alsa::SND_SEQ_TIME_STAMP_REAL | (if relative { alsa::SND_SEQ_TIME_MODE_REL } else { alsa::SND_SEQ_TIME_MODE_ABS });
self.0.queue = queue as u8;
let t = unsafe { &mut self.0.time.time };
t.tv_sec = rtime.as_secs() as c_uint;
t.tv_nsec = rtime.subsec_nanos() as c_uint;
}
pub fn schedule_tick(&mut self, queue: i32, relative: bool, ttime: u32) {
self.0.flags &= !(alsa::SND_SEQ_TIME_STAMP_MASK | alsa::SND_SEQ_TIME_MODE_MASK);
self.0.flags |= alsa::SND_SEQ_TIME_STAMP_TICK | (if relative { alsa::SND_SEQ_TIME_MODE_REL } else { alsa::SND_SEQ_TIME_MODE_ABS });
self.0.queue = queue as u8;
let t = unsafe { &mut self.0.time.tick };
*t = ttime as c_uint;
}
pub fn set_direct(&mut self) { self.0.queue = alsa::SND_SEQ_QUEUE_DIRECT }
pub fn get_relative(&self) -> bool { (self.0.flags & alsa::SND_SEQ_TIME_MODE_REL) != 0 }
pub fn get_time(&self) -> Option<time::Duration> {
if (self.0.flags & alsa::SND_SEQ_TIME_STAMP_REAL) != 0 {
let d = self.0.time;
let t = unsafe { &d.time };
Some(time::Duration::new(t.tv_sec as u64, t.tv_nsec as u32))
} else { None }
}
pub fn get_tick(&self) -> Option<u32> {
if (self.0.flags & alsa::SND_SEQ_TIME_STAMP_REAL) == 0 {
let d = self.0.time;
let t = unsafe { &d.tick };
Some(*t)
} else { None }
}
/// Returns true if the message is high priority.
pub fn get_priority(&self) -> bool { (self.0.flags & alsa::SND_SEQ_PRIORITY_HIGH) != 0 }
pub fn set_priority(&mut self, is_high_prio: bool) {
if is_high_prio { self.0.flags |= alsa::SND_SEQ_PRIORITY_HIGH; }
else { self.0.flags &= !alsa::SND_SEQ_PRIORITY_HIGH; }
}
}
impl<'a> Clone for Event<'a> {
fn clone(&self) -> Self { Event(unsafe { ptr::read(&self.0) }, self.1, self.2.clone()) }
}
impl<'a> fmt::Debug for Event<'a> {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
let mut x = f.debug_tuple("Event");
x.field(&self.1);
if let Some(z) = self.get_data::<EvNote>() { x.field(&z); }
if let Some(z) = self.get_data::<EvCtrl>() { x.field(&z); }
if let Some(z) = self.get_data::<Addr>() { x.field(&z); }
if let Some(z) = self.get_data::<Connect>() { x.field(&z); }
if let Some(z) = self.get_data::<EvQueueControl<()>>() { x.field(&z); }
if let Some(z) = self.get_data::<EvQueueControl<i32>>() { x.field(&z); }
if let Some(z) = self.get_data::<EvQueueControl<u32>>() { x.field(&z); }
if let Some(z) = self.get_data::<EvQueueControl<time::Duration>>() { x.field(&z); }
if let Some(z) = self.get_data::<EvResult>() { x.field(&z); }
if let Some(z) = self.get_data::<[u8; 12]>() { x.field(&z); }
if let Some(z) = self.get_ext() { x.field(&z); }
x.finish()
}
}
/// Internal trait implemented for different event type structs (`EvNote`, `EvCtrl`, etc).
///
/// Use it through `Event::get_data` and `Event::new`.
pub trait EventData {
#[doc(hidden)]
fn get_data(ev: &Event) -> Self;
#[doc(hidden)]
fn has_data(e: EventType) -> bool;
#[doc(hidden)]
fn set_data(&self, ev: &mut Event);
}
impl EventData for () {
fn get_data(_: &Event) -> Self {}
fn has_data(e: EventType) -> bool {
matches!(e,
EventType::TuneRequest |
EventType::Reset |
EventType::Sensing |
EventType::None)
}
fn set_data(&self, _: &mut Event) {}
}
impl EventData for [u8; 12] {
fn get_data(ev: &Event) -> Self {
let d = unsafe { ptr::read(&ev.0.data) };
let z = unsafe { &d.raw8 };
z.d
}
fn has_data(e: EventType) -> bool {
matches!(e,
EventType::Echo |
EventType::Oss |
EventType::Usr0 |
EventType::Usr1 |
EventType::Usr2 |
EventType::Usr3 |
EventType::Usr4 |
EventType::Usr5 |
EventType::Usr6 |
EventType::Usr7 |
EventType::Usr8 |
EventType::Usr9)
}
fn set_data(&self, ev: &mut Event) {
let z = unsafe { &mut ev.0.data.raw8 };
z.d = *self;
}
}
#[derive(Copy, Clone, Debug, PartialEq, Eq, Ord, PartialOrd, Hash, Default)]
pub struct EvNote {
pub channel: u8,
pub note: u8,
pub velocity: u8,
pub off_velocity: u8,
pub duration: u32,
}
impl EventData for EvNote {
fn get_data(ev: &Event) -> Self {
let z: &alsa::snd_seq_ev_note_t = unsafe { &*(&ev.0.data as *const alsa::snd_seq_event__bindgen_ty_1 as *const _) };
EvNote { channel: z.channel as u8, note: z.note as u8, velocity: z.velocity as u8, off_velocity: z.off_velocity as u8, duration: z.duration as u32 }
}
fn has_data(e: EventType) -> bool {
matches!(e,
EventType::Note |
EventType::Noteon |
EventType::Noteoff |
EventType::Keypress)
}
fn set_data(&self, ev: &mut Event) {
let z: &mut alsa::snd_seq_ev_note_t = unsafe { &mut *(&mut ev.0.data as *mut alsa::snd_seq_event__bindgen_ty_1 as *mut _) };
z.channel = self.channel as c_uchar;
z.note = self.note as c_uchar;
z.velocity = self.velocity as c_uchar;
z.off_velocity = self.off_velocity as c_uchar;
z.duration = self.duration as c_uint;
}
}
#[derive(Copy, Clone, Debug, PartialEq, Eq, Ord, PartialOrd, Hash, Default)]
pub struct EvCtrl {
pub channel: u8,
pub param: u32,
pub value: i32,
}
impl EventData for EvCtrl {
fn get_data(ev: &Event) -> Self {
let z: &alsa::snd_seq_ev_ctrl_t = unsafe { &*(&ev.0.data as *const alsa::snd_seq_event__bindgen_ty_1 as *const _) };
EvCtrl { channel: z.channel as u8, param: z.param as u32, value: z.value as i32 }
}
fn has_data(e: EventType) -> bool {
matches!(e,
EventType::Controller |
EventType::Pgmchange |
EventType::Chanpress |
EventType::Pitchbend |
EventType::Control14 |
EventType::Nonregparam |
EventType::Regparam |
EventType::Songpos |
EventType::Songsel |
EventType::Qframe |
EventType::Timesign |
EventType::Keysign)
}
fn set_data(&self, ev: &mut Event) {
let z: &mut alsa::snd_seq_ev_ctrl_t = unsafe { &mut *(&mut ev.0.data as *mut alsa::snd_seq_event__bindgen_ty_1 as *mut _) };
z.channel = self.channel as c_uchar;
z.param = self.param as c_uint;
z.value = self.value as c_int;
}
}
impl EventData for Addr {
fn get_data(ev: &Event) -> Self {
let z: &alsa::snd_seq_addr_t = unsafe { &*(&ev.0.data as *const alsa::snd_seq_event__bindgen_ty_1 as *const _) };
Addr { client: z.client as i32, port: z.port as i32 }
}
fn has_data(e: EventType) -> bool {
matches!(e,
EventType::ClientStart |
EventType::ClientExit |
EventType::ClientChange |
EventType::PortStart |
EventType::PortExit |
EventType::PortChange)
}
fn set_data(&self, ev: &mut Event) {
let z: &mut alsa::snd_seq_addr_t = unsafe { &mut *(&mut ev.0.data as *mut alsa::snd_seq_event__bindgen_ty_1 as *mut _) };
z.client = self.client as c_uchar;
z.port = self.port as c_uchar;
}
}
#[derive(Copy, Clone, Debug, PartialEq, Eq, Ord, PartialOrd, Hash, Default)]
pub struct Connect {
pub sender: Addr,
pub dest: Addr,
}
impl EventData for Connect {
fn get_data(ev: &Event) -> Self {
let d = unsafe { ptr::read(&ev.0.data) };
let z = unsafe { &d.connect };
Connect {
sender: Addr { client: z.sender.client as i32, port: z.sender.port as i32 },
dest: Addr { client: z.dest.client as i32, port: z.dest.port as i32 }
}
}
fn has_data(e: EventType) -> bool {
matches!(e,
EventType::PortSubscribed |
EventType::PortUnsubscribed)
}
fn set_data(&self, ev: &mut Event) {
let z = unsafe { &mut ev.0.data.connect };
z.sender.client = self.sender.client as c_uchar;
z.sender.port = self.sender.port as c_uchar;
z.dest.client = self.dest.client as c_uchar;
z.dest.port = self.dest.port as c_uchar;
}
}
#[derive(Copy, Clone, Debug, PartialEq, Eq, Ord, PartialOrd, Hash, Default)]
///
/// Note: This struct is generic, but what types of T are required for the different EvQueueControl messages is
/// not very well documented in alsa-lib. Right now, Tempo is i32, Tick, SetposTick and SyncPos are u32, SetposTime is time::Duration,
/// and the rest is (). If I guessed wrong, let me know.
pub struct EvQueueControl<T> {
pub queue: i32,
pub value: T,
}
impl EventData for EvQueueControl<()> {
fn get_data(ev: &Event) -> Self {
let d = unsafe { ptr::read(&ev.0.data) };
let z = unsafe { &d.queue };
EvQueueControl { queue: z.queue as i32, value: () }
}
fn has_data(e: EventType) -> bool {
matches!(e,
EventType::Start |
EventType::Continue |
EventType::Stop |
EventType::Clock |
EventType::QueueSkew)
}
fn set_data(&self, ev: &mut Event) {
let z = unsafe { &mut ev.0.data.queue };
z.queue = self.queue as c_uchar;
}
}
impl EventData for EvQueueControl<i32> {
fn get_data(ev: &Event) -> Self { unsafe {
let mut d = ptr::read(&ev.0.data);
let z = &mut d.queue;
EvQueueControl { queue: z.queue as i32, value: z.param.value as i32 }
} }
fn has_data(e: EventType) -> bool {
matches!(e,
EventType::Tempo)
}
fn set_data(&self, ev: &mut Event) { unsafe {
let z = &mut ev.0.data.queue;
z.queue = self.queue as c_uchar;
z.param.value = self.value as c_int;
} }
}
impl EventData for EvQueueControl<u32> {
fn get_data(ev: &Event) -> Self { unsafe {
let mut d = ptr::read(&ev.0.data);
let z = &mut d.queue;
EvQueueControl { queue: z.queue as i32, value: z.param.position as u32 }
} }
fn has_data(e: EventType) -> bool {
matches!(e,
EventType::SyncPos |
EventType::Tick |
EventType::SetposTick)
}
fn set_data(&self, ev: &mut Event) { unsafe {
let z = &mut ev.0.data.queue;
z.queue = self.queue as c_uchar;
z.param.position = self.value as c_uint;
} }
}
impl EventData for EvQueueControl<time::Duration> {
fn get_data(ev: &Event) -> Self { unsafe {
let mut d = ptr::read(&ev.0.data);
let z = &mut d.queue;
let t = &mut z.param.time.time;
EvQueueControl { queue: z.queue as i32, value: time::Duration::new(t.tv_sec as u64, t.tv_nsec as u32) }
} }
fn has_data(e: EventType) -> bool {
matches!(e,
EventType::SetposTime)
}
fn set_data(&self, ev: &mut Event) { unsafe {
let z = &mut ev.0.data.queue;
z.queue = self.queue as c_uchar;
let t = &mut z.param.time.time;
t.tv_sec = self.value.as_secs() as c_uint;
t.tv_nsec = self.value.subsec_nanos() as c_uint;
} }
}
#[derive(Copy, Clone, Debug, PartialEq, Eq, Ord, PartialOrd, Hash, Default)]
///
/// It's called EvResult instead of Result, in order to not be confused with Rust's Result type.
pub struct EvResult {
pub event: i32,
pub result: i32,
}
impl EventData for EvResult {
fn get_data(ev: &Event) -> Self {
let d = unsafe { ptr::read(&ev.0.data) };
let z = unsafe { &d.result };
EvResult { event: z.event as i32, result: z.result as i32 }
}
fn has_data(e: EventType) -> bool {
matches!(e,
EventType::System |
EventType::Result)
}
fn set_data(&self, ev: &mut Event) {
let z = unsafe { &mut ev.0.data.result };
z.event = self.event as c_int;
z.result = self.result as c_int;
}
}
alsa_enum!(
EventType, ALL_EVENT_TYPES[59],
Bounce = SND_SEQ_EVENT_BOUNCE,
Chanpress = SND_SEQ_EVENT_CHANPRESS,
ClientChange = SND_SEQ_EVENT_CLIENT_CHANGE,
ClientExit = SND_SEQ_EVENT_CLIENT_EXIT,
ClientStart = SND_SEQ_EVENT_CLIENT_START,
Clock = SND_SEQ_EVENT_CLOCK,
Continue = SND_SEQ_EVENT_CONTINUE,
Control14 = SND_SEQ_EVENT_CONTROL14,
Controller = SND_SEQ_EVENT_CONTROLLER,
Echo = SND_SEQ_EVENT_ECHO,
Keypress = SND_SEQ_EVENT_KEYPRESS,
Keysign = SND_SEQ_EVENT_KEYSIGN,
None = SND_SEQ_EVENT_NONE,
Nonregparam = SND_SEQ_EVENT_NONREGPARAM,
Note = SND_SEQ_EVENT_NOTE,
Noteoff = SND_SEQ_EVENT_NOTEOFF,
Noteon = SND_SEQ_EVENT_NOTEON,
Oss = SND_SEQ_EVENT_OSS,
Pgmchange = SND_SEQ_EVENT_PGMCHANGE,
Pitchbend = SND_SEQ_EVENT_PITCHBEND,
PortChange = SND_SEQ_EVENT_PORT_CHANGE,
PortExit = SND_SEQ_EVENT_PORT_EXIT,
PortStart = SND_SEQ_EVENT_PORT_START,
PortSubscribed = SND_SEQ_EVENT_PORT_SUBSCRIBED,
PortUnsubscribed = SND_SEQ_EVENT_PORT_UNSUBSCRIBED,
Qframe = SND_SEQ_EVENT_QFRAME,
QueueSkew = SND_SEQ_EVENT_QUEUE_SKEW,
Regparam = SND_SEQ_EVENT_REGPARAM,
Reset = SND_SEQ_EVENT_RESET,
Result = SND_SEQ_EVENT_RESULT,
Sensing = SND_SEQ_EVENT_SENSING,
SetposTick = SND_SEQ_EVENT_SETPOS_TICK,
SetposTime = SND_SEQ_EVENT_SETPOS_TIME,
Songpos = SND_SEQ_EVENT_SONGPOS,
Songsel = SND_SEQ_EVENT_SONGSEL,
Start = SND_SEQ_EVENT_START,
Stop = SND_SEQ_EVENT_STOP,
SyncPos = SND_SEQ_EVENT_SYNC_POS,
Sysex = SND_SEQ_EVENT_SYSEX,
System = SND_SEQ_EVENT_SYSTEM,
Tempo = SND_SEQ_EVENT_TEMPO,
Tick = SND_SEQ_EVENT_TICK,
Timesign = SND_SEQ_EVENT_TIMESIGN,
TuneRequest = SND_SEQ_EVENT_TUNE_REQUEST,
Usr0 = SND_SEQ_EVENT_USR0,
Usr1 = SND_SEQ_EVENT_USR1,
Usr2 = SND_SEQ_EVENT_USR2,
Usr3 = SND_SEQ_EVENT_USR3,
Usr4 = SND_SEQ_EVENT_USR4,
Usr5 = SND_SEQ_EVENT_USR5,
Usr6 = SND_SEQ_EVENT_USR6,
Usr7 = SND_SEQ_EVENT_USR7,
Usr8 = SND_SEQ_EVENT_USR8,
Usr9 = SND_SEQ_EVENT_USR9,
UsrVar0 = SND_SEQ_EVENT_USR_VAR0,
UsrVar1 = SND_SEQ_EVENT_USR_VAR1,
UsrVar2 = SND_SEQ_EVENT_USR_VAR2,
UsrVar3 = SND_SEQ_EVENT_USR_VAR3,
UsrVar4 = SND_SEQ_EVENT_USR_VAR4,
);
pub struct QueueTempo(*mut alsa::snd_seq_queue_tempo_t);
unsafe impl Send for QueueTempo {}
impl Drop for QueueTempo {
fn drop(&mut self) { unsafe { alsa::snd_seq_queue_tempo_free(self.0) } }
}
impl QueueTempo {
fn new() -> Result<Self> {
let mut q = ptr::null_mut();
acheck!(snd_seq_queue_tempo_malloc(&mut q)).map(|_| QueueTempo(q))
}
/// Creates a new QueueTempo with all fields set to zero.
pub fn empty() -> Result<Self> {
let q = QueueTempo::new()?;
unsafe { ptr::write_bytes(q.0 as *mut u8, 0, alsa::snd_seq_queue_tempo_sizeof()) };
Ok(q)
}
pub fn get_queue(&self) -> i32 { unsafe { alsa::snd_seq_queue_tempo_get_queue(self.0) as i32 } }
pub fn get_tempo(&self) -> u32 { unsafe { alsa::snd_seq_queue_tempo_get_tempo(self.0) as u32 } }
pub fn get_ppq(&self) -> i32 { unsafe { alsa::snd_seq_queue_tempo_get_ppq(self.0) as i32 } }
pub fn get_skew(&self) -> u32 { unsafe { alsa::snd_seq_queue_tempo_get_skew(self.0) as u32 } }
pub fn get_skew_base(&self) -> u32 { unsafe { alsa::snd_seq_queue_tempo_get_skew_base(self.0) as u32 } }
// pub fn set_queue(&self, value: i32) { unsafe { alsa::snd_seq_queue_tempo_set_queue(self.0, value as c_int) } }
pub fn set_tempo(&self, value: u32) { unsafe { alsa::snd_seq_queue_tempo_set_tempo(self.0, value as c_uint) } }
pub fn set_ppq(&self, value: i32) { unsafe { alsa::snd_seq_queue_tempo_set_ppq(self.0, value as c_int) } }
pub fn set_skew(&self, value: u32) { unsafe { alsa::snd_seq_queue_tempo_set_skew(self.0, value as c_uint) } }
pub fn set_skew_base(&self, value: u32) { unsafe { alsa::snd_seq_queue_tempo_set_skew_base(self.0, value as c_uint) } }
}
pub struct QueueStatus(*mut alsa::snd_seq_queue_status_t);
unsafe impl Send for QueueStatus {}
impl Drop for QueueStatus {
fn drop(&mut self) { unsafe { alsa::snd_seq_queue_status_free(self.0) } }
}
impl QueueStatus {
fn new() -> Result<Self> {
let mut q = ptr::null_mut();
acheck!(snd_seq_queue_status_malloc(&mut q)).map(|_| QueueStatus(q))
}
/// Creates a new QueueStatus with all fields set to zero.
pub fn empty() -> Result<Self> {
let q = QueueStatus::new()?;
unsafe { ptr::write_bytes(q.0 as *mut u8, 0, alsa::snd_seq_queue_status_sizeof()) };
Ok(q)
}
pub fn get_queue(&self) -> i32 { unsafe { alsa::snd_seq_queue_status_get_queue(self.0) as i32 } }
pub fn get_events(&self) -> i32 { unsafe { alsa::snd_seq_queue_status_get_events(self.0) as i32 } }
pub fn get_tick_time(&self) -> u32 { unsafe {alsa::snd_seq_queue_status_get_tick_time(self.0) as u32 } }
pub fn get_real_time(&self) -> time::Duration { unsafe {
let t = &(*alsa::snd_seq_queue_status_get_real_time(self.0));
time::Duration::new(t.tv_sec as u64, t.tv_nsec as u32)
} }
pub fn get_status(&self) -> u32 { unsafe { alsa::snd_seq_queue_status_get_status(self.0) as u32 } }
}
pub struct RemoveEvents(*mut alsa::snd_seq_remove_events_t);
unsafe impl Send for RemoveEvents {}
impl Drop for RemoveEvents {
fn drop(&mut self) { unsafe { alsa::snd_seq_remove_events_free(self.0) } }
}
impl RemoveEvents {
pub fn new() -> Result<Self> {
let mut q = ptr::null_mut();
acheck!(snd_seq_remove_events_malloc(&mut q)).map(|_| RemoveEvents(q))
}
pub fn get_condition(&self) -> Remove { unsafe {
Remove::from_bits_truncate(alsa::snd_seq_remove_events_get_condition(self.0) as u32)
} }
pub fn get_queue(&self) -> i32 { unsafe { alsa::snd_seq_remove_events_get_queue(self.0) as i32 } }
pub fn get_time(&self) -> time::Duration { unsafe {
let d = ptr::read(alsa::snd_seq_remove_events_get_time(self.0));
let t = &d.time;
time::Duration::new(t.tv_sec as u64, t.tv_nsec as u32)
} }
pub fn get_dest(&self) -> Addr { unsafe {
let a = &(*alsa::snd_seq_remove_events_get_dest(self.0));
Addr { client: a.client as i32, port: a.port as i32 }
} }
pub fn get_channel(&self) -> i32 { unsafe { alsa::snd_seq_remove_events_get_channel(self.0) as i32 } }
pub fn get_event_type(&self) -> Result<EventType> { unsafe {
EventType::from_c_int(alsa::snd_seq_remove_events_get_event_type(self.0), "snd_seq_remove_events_get_event_type")
} }
pub fn get_tag(&self) -> u8 { unsafe { alsa::snd_seq_remove_events_get_tag(self.0) as u8 } }
pub fn set_condition(&self, value: Remove) { unsafe {
alsa::snd_seq_remove_events_set_condition(self.0, value.bits() as c_uint);
} }
pub fn set_queue(&self, value: i32) { unsafe { alsa::snd_seq_remove_events_set_queue(self.0, value as c_int) } }
pub fn set_time(&self, value: time::Duration) { unsafe {
let mut d: alsa::snd_seq_timestamp_t = mem::zeroed();
let mut t = &mut d.time;
t.tv_sec = value.as_secs() as c_uint;
t.tv_nsec = value.subsec_nanos() as c_uint;
alsa::snd_seq_remove_events_set_time(self.0, &d);
} }
pub fn set_dest(&self, value: Addr) { unsafe {
let a = alsa::snd_seq_addr_t { client: value.client as c_uchar, port: value.port as c_uchar};
alsa::snd_seq_remove_events_set_dest(self.0, &a);
} }
pub fn set_channel(&self, value: i32) { unsafe { alsa::snd_seq_remove_events_set_channel(self.0, value as c_int) } }
pub fn set_event_type(&self, value: EventType) { unsafe { alsa::snd_seq_remove_events_set_event_type(self.0, value as i32); } }
pub fn set_tag(&self, value: u8) { unsafe { alsa::snd_seq_remove_events_set_tag(self.0, value as c_int) } }
}
///
/// Sequencer event <-> MIDI byte stream coder
pub struct MidiEvent(*mut alsa::snd_midi_event_t);
impl Drop for MidiEvent {
fn drop(&mut self) { unsafe { alsa::snd_midi_event_free(self.0) } }
}
impl MidiEvent {
pub fn new(bufsize: u32) -> Result<MidiEvent> {
let mut q = ptr::null_mut();
acheck!(snd_midi_event_new(bufsize as size_t, &mut q)).map(|_| MidiEvent(q))
}
pub fn resize_buffer(&self, bufsize: u32) -> Result<()> { acheck!(snd_midi_event_resize_buffer(self.0, bufsize as size_t)).map(|_| ()) }
/// Note: this corresponds to snd_midi_event_no_status, but on and off are switched.
///
/// Alsa-lib is a bit confusing here. Anyhow, set "enable" to true to enable running status.
pub fn enable_running_status(&self, enable: bool) { unsafe { alsa::snd_midi_event_no_status(self.0, if enable {0} else {1}) } }
/// Resets both encoder and decoder
pub fn init(&self) { unsafe { alsa::snd_midi_event_init(self.0) } }
pub fn reset_encode(&self) { unsafe { alsa::snd_midi_event_reset_encode(self.0) } }
pub fn reset_decode(&self) { unsafe { alsa::snd_midi_event_reset_decode(self.0) } }
pub fn decode(&self, buf: &mut [u8], ev: &mut Event) -> Result<usize> {
ev.ensure_buf();
acheck!(snd_midi_event_decode(self.0, buf.as_mut_ptr() as *mut c_uchar, buf.len() as c_long, &ev.0)).map(|r| r as usize)
}
/// In case of success, returns a tuple of (bytes consumed from buf, found Event).
pub fn encode<'a>(&'a mut self, buf: &[u8]) -> Result<(usize, Option<Event<'a>>)> {
// The ALSA documentation clearly states that the event will be valid as long as the Encoder
// is not messed with (because the data pointer for sysex events may point into the Encoder's
// buffer). We make this safe by taking self by unique reference and coupling it to
// the event's lifetime.
let mut ev = unsafe { mem::zeroed() };
let r = acheck!(snd_midi_event_encode(self.0, buf.as_ptr() as *const c_uchar, buf.len() as c_long, &mut ev))?;
let e = if ev.type_ == alsa::SND_SEQ_EVENT_NONE as u8 {
None
} else {
Some(unsafe { Event::extract(&mut ev, "snd_midi_event_encode") }?)
};
Ok((r as usize, e))
}
}
#[test]
fn print_seqs() {
use std::ffi::CString;
let s = super::Seq::open(None, None, false).unwrap();
s.set_client_name(&CString::new("rust_test_print_seqs").unwrap()).unwrap();
let clients: Vec<_> = ClientIter::new(&s).collect();
for a in &clients {
let ports: Vec<_> = PortIter::new(&s, a.get_client()).collect();
println!("{:?}: {:?}", a, ports);
}
}
#[test]
fn seq_subscribe() {
use std::ffi::CString;
let s = super::Seq::open(None, None, false).unwrap();
s.set_client_name(&CString::new("rust_test_seq_subscribe").unwrap()).unwrap();
let timer_info = s.get_any_port_info(Addr { client: 0, port: 0 }).unwrap();
assert_eq!(timer_info.get_name().unwrap(), "Timer");
let info = PortInfo::empty().unwrap();
let _port = s.create_port(&info);
let subs = PortSubscribe::empty().unwrap();
subs.set_sender(Addr { client: 0, port: 0 });
subs.set_dest(Addr { client: s.client_id().unwrap(), port: info.get_port() });
s.subscribe_port(&subs).unwrap();
}
#[test]
fn seq_loopback() {
use std::ffi::CString;
let s = super::Seq::open(Some(&CString::new("default").unwrap()), None, false).unwrap();
s.set_client_name(&CString::new("rust_test_seq_loopback").unwrap()).unwrap();
// Create ports
let sinfo = PortInfo::empty().unwrap();
sinfo.set_capability(PortCap::READ | PortCap::SUBS_READ);
sinfo.set_type(PortType::MIDI_GENERIC | PortType::APPLICATION);
s.create_port(&sinfo).unwrap();
let sport = sinfo.get_port();
let dinfo = PortInfo::empty().unwrap();
dinfo.set_capability(PortCap::WRITE | PortCap::SUBS_WRITE);
dinfo.set_type(PortType::MIDI_GENERIC | PortType::APPLICATION);
s.create_port(&dinfo).unwrap();
let dport = dinfo.get_port();
// Connect them
let subs = PortSubscribe::empty().unwrap();
subs.set_sender(Addr { client: s.client_id().unwrap(), port: sport });
subs.set_dest(Addr { client: s.client_id().unwrap(), port: dport });
s.subscribe_port(&subs).unwrap();
println!("Connected {:?} to {:?}", subs.get_sender(), subs.get_dest());
// Send a note!
let note = EvNote { channel: 0, note: 64, duration: 100, velocity: 100, off_velocity: 64 };
let mut e = Event::new(EventType::Noteon, &note);
e.set_subs();
e.set_direct();
e.set_source(sport);
println!("Sending {:?}", e);
s.event_output(&mut e).unwrap();
s.drain_output().unwrap();
// Receive the note!
let mut input = s.input();
let e2 = input.event_input().unwrap();
println!("Receiving {:?}", e2);
assert_eq!(e2.get_type(), EventType::Noteon);
assert_eq!(e2.get_data(), Some(note));
}
#[test]
fn seq_encode_sysex() {
let mut me = MidiEvent::new(16).unwrap();
let sysex = &[0xf0, 1, 2, 3, 4, 5, 6, 7, 0xf7];
let (s, ev) = me.encode(sysex).unwrap();
assert_eq!(s, 9);
let ev = ev.unwrap();
let v = ev.get_ext().unwrap();
assert_eq!(&*v, sysex);
}
#[test]
fn seq_decode_sysex() {
let sysex = [0xf0, 1, 2, 3, 4, 5, 6, 7, 0xf7];
let mut ev = Event::new_ext(EventType::Sysex, &sysex[..]);
let me = MidiEvent::new(0).unwrap();
let mut buffer = vec![0; sysex.len()];
assert_eq!(me.decode(&mut buffer[..], &mut ev).unwrap(), sysex.len());
assert_eq!(buffer, sysex);
}
#[test]
#[should_panic]
fn seq_get_input_twice() {
use std::ffi::CString;
let s = super::Seq::open(None, None, false).unwrap();
s.set_client_name(&CString::new("rust_test_seq_get_input_twice").unwrap()).unwrap();
let input1 = s.input();
let input2 = s.input(); // this should panic
let _ = (input1, input2);
}
#[test]
fn seq_has_data() {
for v in EventType::all() {
let v = *v;
let mut i = 0;
if <() as EventData>::has_data(v) { i += 1; }
if <[u8; 12] as EventData>::has_data(v) { i += 1; }
if Event::has_ext_data(v) { i += 1; }
if EvNote::has_data(v) { i += 1; }
if EvCtrl::has_data(v) { i += 1; }
if Addr::has_data(v) { i += 1; }
if Connect::has_data(v) { i += 1; }
if EvResult::has_data(v) { i += 1; }
if EvQueueControl::<()>::has_data(v) { i += 1; }
if EvQueueControl::<u32>::has_data(v) { i += 1; }
if EvQueueControl::<i32>::has_data(v) { i += 1; }
if EvQueueControl::<time::Duration>::has_data(v) { i += 1; }
if i != 1 { panic!("{:?}: {} has_data", v, i) }
}
}
#[test]
fn seq_remove_events() -> std::result::Result<(), Box<dyn std::error::Error>> {
let info = RemoveEvents::new()?;
info.set_condition(Remove::INPUT | Remove::DEST | Remove::TIME_BEFORE | Remove::TAG_MATCH);
info.set_queue(123);
info.set_time(time::Duration::new(456, 789));
info.set_dest(Addr { client: 212, port: 121 });
info.set_channel(15);
info.set_event_type(EventType::Noteon);
info.set_tag(213);
assert_eq!(info.get_condition(), Remove::INPUT | Remove::DEST | Remove::TIME_BEFORE | Remove::TAG_MATCH);
assert_eq!(info.get_queue(), 123);
assert_eq!(info.get_time(), time::Duration::new(456, 789));
assert_eq!(info.get_dest(), Addr { client: 212, port: 121 });
assert_eq!(info.get_channel(), 15);
assert_eq!(info.get_event_type()?, EventType::Noteon);
assert_eq!(info.get_tag(), 213);
Ok(())
}
#[test]
fn seq_portsubscribeiter() {
let s = super::Seq::open(None, None, false).unwrap();
// Create ports
let sinfo = PortInfo::empty().unwrap();
sinfo.set_capability(PortCap::READ | PortCap::SUBS_READ);
sinfo.set_type(PortType::MIDI_GENERIC | PortType::APPLICATION);
s.create_port(&sinfo).unwrap();
let sport = sinfo.get_port();
let dinfo = PortInfo::empty().unwrap();
dinfo.set_capability(PortCap::WRITE | PortCap::SUBS_WRITE);
dinfo.set_type(PortType::MIDI_GENERIC | PortType::APPLICATION);
s.create_port(&dinfo).unwrap();
let dport = dinfo.get_port();
// Connect them
let subs = PortSubscribe::empty().unwrap();
subs.set_sender(Addr { client: s.client_id().unwrap(), port: sport });
subs.set_dest(Addr { client: s.client_id().unwrap(), port: dport });
s.subscribe_port(&subs).unwrap();
// Query READ subs from sport's point of view
let read_subs: Vec<PortSubscribe> = PortSubscribeIter::new(&s,
Addr {client: s.client_id().unwrap(), port: sport },
QuerySubsType::READ).collect();
assert_eq!(read_subs.len(), 1);
assert_eq!(read_subs[0].get_sender(), subs.get_sender());
assert_eq!(read_subs[0].get_dest(), subs.get_dest());
let write_subs: Vec<PortSubscribe> = PortSubscribeIter::new(&s,
Addr {client: s.client_id().unwrap(), port: sport },
QuerySubsType::WRITE).collect();
assert_eq!(write_subs.len(), 0);
// Now query WRITE subs from dport's point of view
let write_subs: Vec<PortSubscribe> = PortSubscribeIter::new(&s,
Addr {client: s.client_id().unwrap(), port: dport },
QuerySubsType::WRITE).collect();
assert_eq!(write_subs.len(), 1);
assert_eq!(write_subs[0].get_sender(), subs.get_sender());
assert_eq!(write_subs[0].get_dest(), subs.get_dest());
}