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nvrl/fluxo-rs:main nvrl/fluxo-rs:feature/events nvrl/fluxo-rs:release/0.3.1
nvrl/fluxo-rs:v0.5.4 nvrl/fluxo-rs:v0.5.3 nvrl/fluxo-rs:v0.5.2 nvrl/fluxo-rs:v0.5.1 nvrl/fluxo-rs:v0.5.0 nvrl/fluxo-rs:v0.4.3 nvrl/fluxo-rs:v0.4.2 nvrl/fluxo-rs:v0.4.1 nvrl/fluxo-rs:v0.3.3 nvrl/fluxo-rs:v0.3.2 nvrl/fluxo-rs:v0.3.1 nvrl/fluxo-rs:v0.3.0 nvrl/fluxo-rs:v0.2.0
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compare: nvrl/fluxo-rs:v0.5.1
Branches Tags
nvrl/fluxo-rs:main nvrl/fluxo-rs:feature/events nvrl/fluxo-rs:release/0.3.1
nvrl/fluxo-rs:v0.5.4 nvrl/fluxo-rs:v0.5.3 nvrl/fluxo-rs:v0.5.2 nvrl/fluxo-rs:v0.5.1 nvrl/fluxo-rs:v0.5.0 nvrl/fluxo-rs:v0.4.3 nvrl/fluxo-rs:v0.4.2 nvrl/fluxo-rs:v0.4.1 nvrl/fluxo-rs:v0.3.3 nvrl/fluxo-rs:v0.3.2 nvrl/fluxo-rs:v0.3.1 nvrl/fluxo-rs:v0.3.0 nvrl/fluxo-rs:v0.2.0

3 Commits
5c5d0148f8 ... v0.5.1

Author SHA1 Message Date
nvrl f89833a62e missing docs
Release / Build and Release (push) Successful in 2m54s
Details
2026-04-05 11:56:58 +02:00
nvrl 198986efac cleanup of gpu and config gen 2026-04-05 11:42:08 +02:00
nvrl d1178ff8ba implemented signals for mpris 2026-04-05 11:40:31 +02:00
17 changed files with 571 additions and 259 deletions
Expand all files Collapse all files
Cargo.lock
Generated
+1 -1
View File
@@ -572,7 +572,7 @@ checksum = "1d674e81391d1e1ab681a28d99df07927c6d4aa5b027d7da16ba32d1d21ecd99"
[[package]]
name = "fluxo-rs"
version = "0.5.0"
version = "0.5.1"
dependencies = [
"anyhow",
"bluer",
Cargo.toml
+1 -1
View File
@@ -1,6 +1,6 @@
[package]
name = "fluxo-rs"
version = "0.5.0"
version = "0.5.1"
edition = "2024"
[features]
src/config.rs
+56 -32
View File
@@ -1,8 +1,16 @@
//! Configuration loading + top-level `Config` struct.
//!
//! Every module section `#[derive(Deserialize)]`s its own struct with `serde`
//! defaults, so missing TOML sections/fields simply fall back to baked-in
//! values. The live `Config` is held behind an `Arc<RwLock<_>>` by the daemon
//! and replaced atomically on reload (see [`crate::daemon::reload_config`]).
use serde::Deserialize;
use std::fs;
use std::path::PathBuf;
use tracing::{debug, info, warn};
/// Top-level parsed `config.toml`. Each field corresponds to a `[section]`.
#[derive(Deserialize, Default, Clone)]
pub struct Config {
#[serde(default)]
@@ -56,8 +64,10 @@ pub struct Config {
pub dnd: DndConfig,
}
/// Process-wide settings that aren't tied to a single module.
#[derive(Deserialize, Clone)]
pub struct GeneralConfig {
/// Shell command spawned by [`crate::utils::show_menu`] for interactive pickers.
pub menu_command: String,
}
@@ -69,6 +79,9 @@ impl Default for GeneralConfig {
}
}
/// Which Waybar `SIGRTMIN+N` signal each module should trigger, if any.
///
/// `None` disables signalling for that module entirely.
#[allow(dead_code)]
#[derive(Deserialize, Default, Clone)]
pub struct SignalsConfig {
@@ -89,6 +102,7 @@ pub struct SignalsConfig {
pub dnd: Option<i32>,
}
/// Network module config. `format` tokens: `interface`, `ip`, `rx`, `tx`.
#[derive(Deserialize, Clone)]
pub struct NetworkConfig {
#[serde(default = "default_true")]
@@ -105,6 +119,7 @@ impl Default for NetworkConfig {
}
}
/// CPU module config. `format` tokens: `usage`, `temp`.
#[derive(Deserialize, Clone)]
pub struct CpuConfig {
#[serde(default = "default_true")]
@@ -121,6 +136,7 @@ impl Default for CpuConfig {
}
}
/// Memory module config. `format` tokens: `used`, `total` (gigabytes).
#[derive(Deserialize, Clone)]
pub struct MemoryConfig {
#[serde(default = "default_true")]
@@ -137,6 +153,7 @@ impl Default for MemoryConfig {
}
}
/// GPU module config with per-vendor format strings.
#[derive(Deserialize, Clone)]
pub struct GpuConfig {
#[serde(default = "default_true")]
@@ -159,6 +176,7 @@ impl Default for GpuConfig {
}
}
/// Sys module config. `format` tokens: `uptime`, `load1`, `load5`, `load15`, `procs`.
#[derive(Deserialize, Clone)]
pub struct SysConfig {
#[serde(default = "default_true")]
@@ -175,6 +193,7 @@ impl Default for SysConfig {
}
}
/// Disk module config. `format` tokens: `mount`, `used`, `total`.
#[derive(Deserialize, Clone)]
pub struct DiskConfig {
#[serde(default = "default_true")]
@@ -191,6 +210,7 @@ impl Default for DiskConfig {
}
}
/// Btrfs pool module config. `format` tokens: `used`, `total`.
#[derive(Deserialize, Clone)]
pub struct PoolConfig {
#[serde(default = "default_true")]
@@ -207,6 +227,7 @@ impl Default for PoolConfig {
}
}
/// Battery/power module config. `format` tokens: `percentage`, `icon`.
#[derive(Deserialize, Clone)]
pub struct PowerConfig {
#[serde(default = "default_true")]
@@ -223,6 +244,7 @@ impl Default for PowerConfig {
}
}
/// Audio module config, one format per (sink|source) × (muted|unmuted) state.
#[derive(Deserialize, Clone)]
pub struct AudioConfig {
#[serde(default = "default_true")]
@@ -245,6 +267,8 @@ impl Default for AudioConfig {
}
}
/// Bluetooth module config. Plugin line tokens: `alias`, `left`, `right`,
/// `anc`, `mac`. Plain connect line tokens: `alias`.
#[derive(Deserialize, Clone)]
pub struct BtConfig {
#[serde(default = "default_true")]
@@ -267,6 +291,7 @@ impl Default for BtConfig {
}
}
/// Gamemode indicator config (active/inactive glyphs).
#[derive(Deserialize, Clone)]
pub struct GameConfig {
#[serde(default = "default_true")]
@@ -285,6 +310,8 @@ impl Default for GameConfig {
}
}
/// MPRIS module config. `format` tokens: `artist`, `title`, `album`,
/// `status_icon`. Optional marquee scrolling when `scroll = true`.
#[derive(Deserialize, Clone)]
pub struct MprisConfig {
#[serde(default = "default_true")]
@@ -321,6 +348,7 @@ impl Default for MprisConfig {
}
}
/// Backlight module config. `format` tokens: `percentage`, `icon`.
#[derive(Deserialize, Clone)]
pub struct BacklightConfig {
#[serde(default = "default_true")]
@@ -337,6 +365,7 @@ impl Default for BacklightConfig {
}
}
/// Keyboard layout module config. `format` tokens: `layout`.
#[derive(Deserialize, Clone)]
pub struct KeyboardConfig {
#[serde(default = "default_true")]
@@ -353,6 +382,7 @@ impl Default for KeyboardConfig {
}
}
/// Do-Not-Disturb indicator config (dnd/normal glyphs).
#[derive(Deserialize, Clone)]
pub struct DndConfig {
#[serde(default = "default_true")]
@@ -397,41 +427,31 @@ impl Config {
/// Check if a module is enabled in the configuration.
/// Returns false if the module is explicitly disabled; true if enabled or unknown.
pub fn is_module_enabled(&self, module_name: &str) -> bool {
match module_name {
#[cfg(feature = "mod-network")]
"net" | "network" => self.network.enabled,
#[cfg(feature = "mod-hardware")]
"cpu" => self.cpu.enabled,
#[cfg(feature = "mod-hardware")]
"mem" | "memory" => self.memory.enabled,
#[cfg(feature = "mod-hardware")]
"gpu" => self.gpu.enabled,
#[cfg(feature = "mod-hardware")]
"sys" => self.sys.enabled,
#[cfg(feature = "mod-hardware")]
"disk" => self.disk.enabled,
#[cfg(feature = "mod-hardware")]
"pool" | "btrfs" => self.pool.enabled,
#[cfg(feature = "mod-hardware")]
"power" => self.power.enabled,
#[cfg(feature = "mod-hardware")]
"game" => self.game.enabled,
#[cfg(feature = "mod-audio")]
"vol" | "audio" | "mic" => self.audio.enabled,
#[cfg(feature = "mod-bt")]
"bt" | "bluetooth" => self.bt.enabled,
#[cfg(feature = "mod-dbus")]
"mpris" => self.mpris.enabled,
#[cfg(feature = "mod-dbus")]
"backlight" => self.backlight.enabled,
#[cfg(feature = "mod-dbus")]
"kbd" | "keyboard" => self.keyboard.enabled,
#[cfg(feature = "mod-dbus")]
"dnd" => self.dnd.enabled,
_ => true,
macro_rules! gen_enabled_match {
($( { $feature:literal, $field:ident, $state:ty, [$($name:literal),+], [$($sig_name:literal),+], $module:path, $signal:ident, [$($default_arg:literal),*], $config:ident } )*) => {
match module_name {
$(
#[cfg(feature = $feature)]
$($name)|+ => self.$config.enabled,
)*
// Dispatch-only modules (no watch channel)
#[cfg(feature = "mod-audio")]
"mic" => self.audio.enabled,
#[cfg(feature = "mod-hardware")]
"pool" | "btrfs" => self.pool.enabled,
#[cfg(feature = "mod-hardware")]
"power" => self.power.enabled,
#[cfg(feature = "mod-hardware")]
"game" => self.game.enabled,
_ => true,
}
};
}
for_each_watched_module!(gen_enabled_match)
}
/// Warn-log any `{token}` placeholders used in format strings that the
/// corresponding module does not know how to fill in.
pub fn validate(&self) {
#[cfg(feature = "mod-network")]
validate_format(
@@ -508,6 +528,8 @@ impl Config {
}
}
/// Resolve the default config path: `$XDG_CONFIG_HOME/fluxo/config.toml`
/// (or `~/.config/fluxo/config.toml`).
pub fn default_config_path() -> PathBuf {
let config_dir = std::env::var("XDG_CONFIG_HOME")
.map(PathBuf::from)
@@ -518,6 +540,8 @@ pub fn default_config_path() -> PathBuf {
config_dir.join("fluxo/config.toml")
}
/// Load and validate the config, falling back to [`Config::default`] when
/// the file is missing or malformed. Never panics.
pub fn load_config(custom_path: Option<PathBuf>) -> Config {
let config_path = custom_path.unwrap_or_else(default_config_path);
src/daemon.rs
+59 -17
View File
@@ -1,3 +1,18 @@
//! Daemon entry point: orchestrates polling tasks, signal handling, config
//! hot-reloading, and the IPC server.
//!
//! Layout of [`run_daemon`]:
//!
//! 1. **Channels** — `watch::channel()` pairs for every module that pushes
//! state from a background task.
//! 2. **Polling / event tasks** — one per module; each writes into its sender,
//! the signaler and request handlers read from the matching receiver.
//! 3. **Config watchers** — filesystem notifier + `SIGHUP` handler refresh the
//! [`Config`] in place so modules see updates immediately.
//! 4. **Signaler** — watches all state receivers and pokes Waybar.
//! 5. **IPC loop** — `UnixListener` accepting client requests; each connection
//! dispatches to [`crate::registry::dispatch`] and returns JSON.
use crate::config::Config;
use crate::ipc::socket_path;
#[cfg(feature = "mod-audio")]
@@ -31,7 +46,11 @@ use tokio::time::{Duration, sleep};
use tokio_util::sync::CancellationToken;
use tracing::{debug, error, info};
/// Spawn a health-tracked polling loop. `$poll_expr` is awaited each cycle.
/// Spawn a health-tracked polling loop.
///
/// Each iteration: skip if in backoff, else await `$poll_expr` and feed the
/// `Result` to [`crate::health::handle_poll_result`]. The loop breaks when
/// `$token` is cancelled.
macro_rules! spawn_poll_loop {
($name:expr, $interval:expr, $health:expr, $token:expr, $poll_expr:expr) => {
tokio::spawn(async move {
@@ -51,7 +70,10 @@ macro_rules! spawn_poll_loop {
};
}
/// Spawn a health-tracked polling loop with an extra trigger channel for early wake-up.
/// Spawn a health-tracked polling loop with an extra trigger channel.
///
/// Identical to [`spawn_poll_loop`] but `$trigger` can wake the loop early —
/// used by the Bluetooth daemon when a client forces an immediate refresh.
macro_rules! spawn_poll_loop_triggered {
($name:expr, $interval:expr, $health:expr, $token:expr, $trigger:expr, $poll_expr:expr) => {
tokio::spawn(async move {
@@ -72,7 +94,10 @@ macro_rules! spawn_poll_loop_triggered {
};
}
/// Spawn a simple polling loop without health tracking.
/// Spawn a polling loop with no health tracking.
///
/// Used for internal daemons (hardware fast/slow) whose poll functions are
/// infallible and whose failures don't drive client-visible backoff.
macro_rules! spawn_poll_loop_simple {
($name:expr, $interval:expr, $token:expr, $poll_expr:expr) => {
tokio::spawn(async move {
@@ -104,6 +129,11 @@ fn get_config_path(custom_path: Option<PathBuf>) -> PathBuf {
custom_path.unwrap_or_else(crate::config::default_config_path)
}
/// Run the daemon to completion.
///
/// Sets up the socket, spawns all enabled module tasks, hooks up config
/// hot-reloading, and finally enters the IPC accept loop. Returns only on
/// a fatal error or `Ctrl+C`.
pub async fn run_daemon(config_path: Option<PathBuf>) -> Result<()> {
let sock_path = socket_path();
@@ -191,7 +221,8 @@ pub async fn run_daemon(config_path: Option<PathBuf>) -> Result<()> {
path: sock_path.clone(),
};
// Signal handling for graceful shutdown
// Ctrl+C triggers a graceful shutdown by cancelling this token; every
// spawned polling task checks it in its `select!`.
let cancel_token = CancellationToken::new();
let token_clone = cancel_token.clone();
tokio::spawn(async move {
@@ -204,7 +235,6 @@ pub async fn run_daemon(config_path: Option<PathBuf>) -> Result<()> {
let config = Arc::new(RwLock::new(crate::config::load_config(config_path.clone())));
spawn_config_watchers(&config, &resolved_config_path);
// 1. Network Task
#[cfg(feature = "mod-network")]
if config.read().await.network.enabled {
let mut daemon = NetworkDaemon::new();
@@ -219,7 +249,7 @@ pub async fn run_daemon(config_path: Option<PathBuf>) -> Result<()> {
);
}
// 2. Fast Hardware Task (CPU, Mem, Load)
// Fast-cycle hardware (cpu/mem/load) polled at 1 Hz.
#[cfg(feature = "mod-hardware")]
{
let cfg = config.read().await;
@@ -237,7 +267,7 @@ pub async fn run_daemon(config_path: Option<PathBuf>) -> Result<()> {
}
}
// 3. Slow Hardware Task (GPU, Disks)
// Slow-cycle hardware (gpu/disks) polled every 5 s — expensive to sample.
#[cfg(feature = "mod-hardware")]
{
let cfg = config.read().await;
@@ -255,7 +285,6 @@ pub async fn run_daemon(config_path: Option<PathBuf>) -> Result<()> {
}
}
// 4. Bluetooth Task
#[cfg(feature = "mod-bt")]
if config.read().await.bt.enabled {
let mut daemon = BtDaemon::new();
@@ -270,41 +299,38 @@ pub async fn run_daemon(config_path: Option<PathBuf>) -> Result<()> {
});
}
// 5. Audio Thread (Event driven)
// Event-driven subsystems — these spawn their own threads internally and
// push into their watch sender as events arrive (no polling loop).
#[cfg(feature = "mod-audio")]
if config.read().await.audio.enabled {
let audio_daemon = AudioDaemon::new();
audio_daemon.start(&audio_tx, audio_cmd_rx);
}
// 5.1 Backlight Thread (Event driven)
#[cfg(feature = "mod-dbus")]
if config.read().await.backlight.enabled {
let backlight_daemon = BacklightDaemon::new();
backlight_daemon.start(backlight_tx);
}
// 5.2 Keyboard Thread (Event driven)
#[cfg(feature = "mod-dbus")]
if config.read().await.keyboard.enabled {
let keyboard_daemon = KeyboardDaemon::new();
keyboard_daemon.start(keyboard_tx);
}
// 5.3 DND Thread (Event driven)
#[cfg(feature = "mod-dbus")]
if config.read().await.dnd.enabled {
let dnd_daemon = DndDaemon::new();
dnd_daemon.start(dnd_tx);
}
// 5.4 MPRIS Thread
#[cfg(feature = "mod-dbus")]
if config.read().await.mpris.enabled {
let mpris_daemon = MprisDaemon::new();
mpris_daemon.start(mpris_tx);
// Scroll ticker for MPRIS marquee animation
// Ticks the scroll offset forward for the marquee animation.
let scroll_config = Arc::clone(&config);
let scroll_rx = receivers.mpris.clone();
let scroll_state = Arc::clone(&mpris_scroll);
@@ -319,7 +345,6 @@ pub async fn run_daemon(config_path: Option<PathBuf>) -> Result<()> {
});
}
// 6. Waybar Signaler Task
let signaler = WaybarSignaler::new();
let sig_config = Arc::clone(&config);
let sig_receivers = receivers.clone();
@@ -332,8 +357,14 @@ pub async fn run_daemon(config_path: Option<PathBuf>) -> Result<()> {
run_ipc_loop(listener, receivers, config, config_path, cancel_token).await
}
/// Spawn background tasks that hot-reload the daemon's [`Config`].
///
/// Installs a `notify`-based filesystem watcher on the config file's parent
/// directory, plus a `SIGHUP` handler — either triggers a reload of the
/// shared `Arc<RwLock<Config>>`.
fn spawn_config_watchers(config: &Arc<RwLock<Config>>, resolved_path: &std::path::Path) {
// File watcher (hot reload on modify/create)
// `notify` recursively tracks the parent dir so atomic-write editors
// (which rename a new file into place) still get picked up.
let watcher_config = Arc::clone(config);
let watcher_path = resolved_path.to_path_buf();
tokio::spawn(async move {
@@ -359,6 +390,7 @@ fn spawn_config_watchers(config: &Arc<RwLock<Config>>, resolved_path: &std::path
loop {
tokio::select! {
_ = ev_rx.recv() => {
// Coalesce rapid editor writes into one reload.
sleep(Duration::from_millis(100)).await;
while ev_rx.try_recv().is_ok() {}
reload_config(&watcher_config, Some(watcher_path.clone())).await;
@@ -367,7 +399,6 @@ fn spawn_config_watchers(config: &Arc<RwLock<Config>>, resolved_path: &std::path
}
});
// SIGHUP handler
let hup_config = Arc::clone(config);
let hup_path = resolved_path.to_path_buf();
tokio::spawn(async move {
@@ -381,6 +412,12 @@ fn spawn_config_watchers(config: &Arc<RwLock<Config>>, resolved_path: &std::path
});
}
/// Accept loop for the client Unix socket.
///
/// Each client request spawns a short-lived task that reads one line, looks
/// up the module via [`crate::registry::dispatch`], and writes the JSON
/// response back. Broken-pipe errors are logged at `debug` — they just mean
/// the client timed out before we responded.
async fn run_ipc_loop(
listener: UnixListener,
receivers: AppReceivers,
@@ -447,6 +484,7 @@ async fn run_ipc_loop(
Ok(())
}
/// Re-read the configuration file and swap it into the shared lock.
pub async fn reload_config(config_lock: &Arc<RwLock<Config>>, path: Option<PathBuf>) {
info!("Reloading configuration...");
let new_config = crate::config::load_config(path);
@@ -455,6 +493,10 @@ pub async fn reload_config(config_lock: &Arc<RwLock<Config>>, path: Option<PathB
info!("Configuration reloaded successfully.");
}
/// Evaluate a module with its signaler-default args and return the JSON body.
///
/// Used by the [`crate::signaler`] to decide whether the module's output has
/// actually changed before sending Waybar a signal.
pub async fn evaluate_module_for_signaler(
module_name: &str,
state: &AppReceivers,
src/error.rs
+10
View File
@@ -1,5 +1,11 @@
//! Error types used across the crate.
use thiserror::Error;
/// Canonical error type for all fluxo subsystems.
///
/// Errors are categorised so that [`FluxoError::is_transient`] can distinguish
/// temporary runtime failures (retried with backoff) from permanent ones.
#[derive(Error, Debug)]
#[allow(dead_code)]
pub enum FluxoError {
@@ -41,6 +47,9 @@ pub enum FluxoError {
}
impl FluxoError {
/// Returns `true` for errors that represent likely-transient failures
/// (IO, external systems, hardware) and should trigger exponential backoff
/// rather than permanent cooldown.
pub fn is_transient(&self) -> bool {
matches!(
self,
@@ -54,4 +63,5 @@ impl FluxoError {
}
}
/// Crate-wide `Result` alias using [`FluxoError`].
pub type Result<T> = std::result::Result<T, FluxoError>;
src/health.rs
+15
View File
@@ -1,3 +1,10 @@
//! Per-module health tracking and exponential backoff.
//!
//! Both the IPC request handler (for on-demand module evaluation) and the
//! background polling loops consult this module. Transient errors increment a
//! failure counter that grows the cooldown window; permanent errors trigger an
//! immediate long cooldown.
use crate::output::WaybarOutput;
use crate::state::{AppReceivers, ModuleHealth};
use std::collections::HashMap;
@@ -101,6 +108,10 @@ pub async fn handle_poll_result(
}
}
/// Serialise a response to return while a module is cooling down.
///
/// If a cached successful output exists, it is returned with a `warning` CSS
/// class appended; otherwise a generic "Cooling down" placeholder is emitted.
pub fn backoff_response(module_name: &str, cached: Option<WaybarOutput>) -> String {
if let Some(mut cached) = cached {
let class = cached.class.unwrap_or_default();
@@ -113,6 +124,10 @@ pub fn backoff_response(module_name: &str, cached: Option<WaybarOutput>) -> Stri
)
}
/// Serialise a fallback response for a module that errored this request.
///
/// Prefers showing the last successful cached output (with a `warning` class)
/// over a bare error text, to keep the bar visually stable.
pub fn error_response(
module_name: &str,
e: &crate::error::FluxoError,
src/ipc.rs
+11 -1
View File
@@ -1,8 +1,16 @@
//! Client/daemon Unix socket IPC.
//!
//! Requests are newline-terminated `module arg1 arg2...` lines; responses are
//! the daemon's JSON payload written until EOF.
use std::io::{Read, Write};
use std::os::unix::net::UnixStream;
use std::time::Duration;
use tracing::debug;
/// Returns the path to the daemon's Unix socket.
///
/// Prefers `$XDG_RUNTIME_DIR/fluxo.sock`, falling back to `/tmp/fluxo.sock`.
pub fn socket_path() -> String {
if let Ok(dir) = std::env::var("XDG_RUNTIME_DIR") {
format!("{}/fluxo.sock", dir)
@@ -11,13 +19,15 @@ pub fn socket_path() -> String {
}
}
/// Send a module invocation to the daemon and return its response body.
///
/// Blocks for up to 5 seconds waiting for the daemon to reply.
pub fn request_data(module: &str, args: &[&str]) -> anyhow::Result<String> {
let sock = socket_path();
debug!(module, ?args, "Connecting to daemon socket: {}", sock);
let mut stream = UnixStream::connect(&sock)?;
stream.set_read_timeout(Some(Duration::from_secs(5)))?;
// Send module and args
let mut request = module.to_string();
for arg in args {
request.push(' ');
src/macros.rs
+7
View File
@@ -1,3 +1,10 @@
//! Central declarative macro that registers every watched module.
//!
//! Every piece of per-module boilerplate (AppReceivers field, IPC dispatch arm,
//! signaler future binding, signaler select arm, config enabled-lookup, default
//! signaler args) is generated from this single table. Adding a new module is
//! a one-line edit here plus writing the module file itself.
/// Central module registry. Defines all modules with watch channels in one place.
///
/// Invoke with a callback macro name. The callback receives repeated entries of the form:
src/main.rs
+30 -11
View File
@@ -1,3 +1,17 @@
//! `fluxo` — high-performance daemon/client for Waybar custom modules.
//!
//! The binary has two faces:
//! * `fluxo daemon` — starts a long-lived process that polls system state
//! (network, cpu, audio, bluetooth, …) on background tasks and exposes the
//! results over a Unix socket. It also sends `SIGRTMIN+N` signals to Waybar
//! when module output changes, so the bar refreshes instantly.
//! * `fluxo <module> [args]` — a tiny client that asks the daemon to evaluate
//! a single module and prints the Waybar-compatible JSON to stdout.
//!
//! Modules are feature-gated at compile time (`mod-audio`, `mod-bt`, `mod-dbus`,
//! `mod-hardware`, `mod-network`) and registered centrally via the
//! [`for_each_watched_module!`] macro in [`mod@macros`].
#[macro_use]
mod macros;
mod config;
@@ -79,14 +93,15 @@ fn main() {
}
if let Some(module) = &cli.module {
// Special case for client-side Bluetooth menu which requires UI
// Bluetooth menu is handled client-side: it needs access to the user's
// menu command (rofi/dmenu/wofi) which the daemon has no business spawning.
#[cfg(feature = "mod-bt")]
if module == "bt" && cli.args.first().map(|s| s.as_str()) == Some("menu") {
let config = config::load_config(None);
let mut items = Vec::new();
// Parse menu_data to get connected and paired devices
let mut connected: Vec<(String, String)> = Vec::new(); // (alias, mac)
// Ask the daemon for the device list; tuples are (alias, mac).
let mut connected: Vec<(String, String)> = Vec::new();
let mut paired: Vec<(String, String)> = Vec::new();
if let Ok(json_str) = ipc::request_data("bt", &["menu_data"])
@@ -106,9 +121,7 @@ fn main() {
}
}
// Per-device sections for connected devices
for (alias, mac) in &connected {
// Get modes for this specific device
if let Ok(json_str) = ipc::request_data("bt", &["get_modes", mac])
&& let Ok(val) = serde_json::from_str::<serde_json::Value>(&json_str)
&& let Some(modes_str) = val.get("text").and_then(|t| t.as_str())
@@ -121,7 +134,6 @@ fn main() {
items.push(format!("Disconnect {} [{}]", alias, mac));
}
// Separator and paired devices for connecting
if !paired.is_empty() {
items.push("--- Connect Device ---".to_string());
for (alias, mac) in &paired {
@@ -134,7 +146,7 @@ fn main() {
utils::show_menu("BT Menu: ", &items, &config.general.menu_command)
{
if selected.contains(": Mode: ") {
// "<alias>: Mode: <mode> [<MAC>]"
// Parse "<alias>: Mode: <mode> [<MAC>]".
if let Some(bracket_start) = selected.rfind('[')
&& let Some(bracket_end) = selected.rfind(']')
{
@@ -149,7 +161,7 @@ fn main() {
}
}
} else if selected.starts_with("Disconnect ") {
// "Disconnect <alias> [<MAC>]"
// Parse "Disconnect <alias> [<MAC>]".
if let Some(bracket_start) = selected.rfind('[')
&& let Some(bracket_end) = selected.rfind(']')
{
@@ -157,7 +169,7 @@ fn main() {
handle_ipc_response(ipc::request_data("bt", &["disconnect", mac]));
}
} else if selected == "--- Connect Device ---" {
// separator, do nothing
// section header
} else if let Some(mac_start) = selected.rfind('(')
&& let Some(mac_end) = selected.rfind(')')
{
@@ -171,8 +183,8 @@ fn main() {
return;
}
// Generic module dispatch
// Translate module-specific shorthand targets
// `vol` and `mic` both dispatch to the audio module; we just prepend
// the "sink" / "source" argument so the server picks the right device.
let (actual_module, actual_args) = if module == "vol" {
let mut new_args = vec!["sink".to_string()];
new_args.extend(cli.args.clone());
@@ -193,6 +205,13 @@ fn main() {
}
}
/// Post-process the daemon's response for direct output to Waybar.
///
/// Normal spaces are replaced with figure-spaces (U+2007) so Waybar's
/// proportional font does not jitter between updates, and the text is wrapped
/// in zero-width spaces (U+200B) as a cosmetic padding trick. Markup strings
/// (containing `<`) pass through untouched. On IPC failure an `error` output
/// is emitted and the client exits non-zero.
fn handle_ipc_response(response: anyhow::Result<String>) {
match response {
Ok(json_str) => match serde_json::from_str::<serde_json::Value>(&json_str) {
src/modules/hardware.rs
+125 -108
View File
@@ -143,122 +143,139 @@ impl HardwareDaemon {
async fn poll_gpu(&mut self, gpu: &mut crate::state::GpuState) {
gpu.active = false;
if (self.gpu_vendor.as_deref() == Some("NVIDIA") || self.gpu_vendor.is_none())
&& let Ok(output) = tokio::process::Command::new("nvidia-smi")
.args([
"--query-gpu=utilization.gpu,memory.used,memory.total,temperature.gpu,name",
"--format=csv,noheader,nounits",
])
.output()
.await
&& output.status.success()
{
let stdout = String::from_utf8_lossy(&output.stdout);
if let Some(line) = stdout.lines().next() {
let parts: Vec<&str> = line.split(',').collect();
if parts.len() >= 5 {
gpu.active = true;
gpu.vendor = "NVIDIA".to_string();
gpu.usage = parts[0].trim().parse().unwrap_or(0.0);
gpu.vram_used = parts[1].trim().parse::<f64>().unwrap_or(0.0) / 1024.0;
gpu.vram_total = parts[2].trim().parse::<f64>().unwrap_or(0.0) / 1024.0;
gpu.temp = parts[3].trim().parse().unwrap_or(0.0);
gpu.model = parts[4].trim().to_string();
match self.gpu_vendor.as_deref() {
Some("NVIDIA") => {
Self::poll_nvidia(gpu).await;
}
Some("AMD") => {
Self::poll_amd(gpu);
}
Some("Intel") => {
Self::poll_intel(gpu);
}
_ => {
// Detection pass: try each vendor, cache the first that responds.
Self::poll_nvidia(gpu).await;
if gpu.active {
self.gpu_vendor = Some("NVIDIA".to_string());
return;
}
}
}
if self.gpu_vendor.as_deref() == Some("AMD")
|| self.gpu_vendor.as_deref() == Some("Intel")
|| self.gpu_vendor.is_none()
{
for i in 0..=3 {
let base = format!("/sys/class/drm/card{}/device", i);
if (self.gpu_vendor.as_deref() == Some("AMD") || self.gpu_vendor.is_none())
&& let Ok(usage_str) =
std::fs::read_to_string(format!("{}/gpu_busy_percent", base))
{
gpu.active = true;
gpu.vendor = "AMD".to_string();
gpu.usage = usage_str.trim().parse().unwrap_or(0.0);
if let Ok(mem_used) =
std::fs::read_to_string(format!("{}/mem_info_vram_used", base))
{
gpu.vram_used = mem_used.trim().parse::<f64>().unwrap_or(0.0)
/ 1024.0
/ 1024.0
/ 1024.0;
}
if let Ok(mem_total) =
std::fs::read_to_string(format!("{}/mem_info_vram_total", base))
{
gpu.vram_total = mem_total.trim().parse::<f64>().unwrap_or(0.0)
/ 1024.0
/ 1024.0
/ 1024.0;
}
if let Ok(entries) = std::fs::read_dir(format!("{}/hwmon", base)) {
for entry in entries.flatten() {
let temp_path = entry.path().join("temp1_input");
if let Ok(temp_str) = std::fs::read_to_string(temp_path) {
gpu.temp = temp_str.trim().parse::<f64>().unwrap_or(0.0) / 1000.0;
break;
}
}
}
gpu.model = "AMD GPU".to_string();
Self::poll_amd(gpu);
if gpu.active {
self.gpu_vendor = Some("AMD".to_string());
return;
}
if self.gpu_vendor.as_deref() == Some("Intel") || self.gpu_vendor.is_none() {
let freq_path =
if std::path::Path::new(&format!("{}/gt_cur_freq_mhz", base)).exists() {
Some(format!("{}/gt_cur_freq_mhz", base))
} else if std::path::Path::new(&format!(
"/sys/class/drm/card{}/gt_cur_freq_mhz",
i
))
.exists()
{
Some(format!("/sys/class/drm/card{}/gt_cur_freq_mhz", i))
} else {
None
};
if let Some(path) = freq_path
&& let Ok(freq_str) = std::fs::read_to_string(&path)
{
gpu.active = true;
gpu.vendor = "Intel".to_string();
let cur_freq = freq_str.trim().parse::<f64>().unwrap_or(0.0);
let mut max_freq = 0.0;
let max_path = path.replace("gt_cur_freq_mhz", "gt_max_freq_mhz");
if let Ok(max_str) = std::fs::read_to_string(max_path) {
max_freq = max_str.trim().parse::<f64>().unwrap_or(0.0);
}
gpu.usage = if max_freq > 0.0 {
(cur_freq / max_freq) * 100.0
} else {
0.0
};
gpu.temp = 0.0;
gpu.vram_used = 0.0;
gpu.vram_total = 0.0;
gpu.model = format!("Intel iGPU ({}MHz)", cur_freq);
self.gpu_vendor = Some("Intel".to_string());
return;
}
Self::poll_intel(gpu);
if gpu.active {
self.gpu_vendor = Some("Intel".to_string());
}
}
}
}
async fn poll_nvidia(gpu: &mut crate::state::GpuState) {
let Ok(output) = tokio::process::Command::new("nvidia-smi")
.args([
"--query-gpu=utilization.gpu,memory.used,memory.total,temperature.gpu,name",
"--format=csv,noheader,nounits",
])
.output()
.await
else {
return;
};
if !output.status.success() {
return;
}
let stdout = String::from_utf8_lossy(&output.stdout);
if let Some(line) = stdout.lines().next() {
let parts: Vec<&str> = line.split(',').collect();
if parts.len() >= 5 {
gpu.active = true;
gpu.vendor = "NVIDIA".to_string();
gpu.usage = parts[0].trim().parse().unwrap_or(0.0);
gpu.vram_used = parts[1].trim().parse::<f64>().unwrap_or(0.0) / 1024.0;
gpu.vram_total = parts[2].trim().parse::<f64>().unwrap_or(0.0) / 1024.0;
gpu.temp = parts[3].trim().parse().unwrap_or(0.0);
gpu.model = parts[4].trim().to_string();
}
}
}
fn poll_amd(gpu: &mut crate::state::GpuState) {
for i in 0..=3 {
let base = format!("/sys/class/drm/card{}/device", i);
let Ok(usage_str) = std::fs::read_to_string(format!("{}/gpu_busy_percent", base))
else {
continue;
};
gpu.active = true;
gpu.vendor = "AMD".to_string();
gpu.usage = usage_str.trim().parse().unwrap_or(0.0);
if let Ok(mem_used) = std::fs::read_to_string(format!("{}/mem_info_vram_used", base)) {
gpu.vram_used =
mem_used.trim().parse::<f64>().unwrap_or(0.0) / 1024.0 / 1024.0 / 1024.0;
}
if let Ok(mem_total) = std::fs::read_to_string(format!("{}/mem_info_vram_total", base))
{
gpu.vram_total =
mem_total.trim().parse::<f64>().unwrap_or(0.0) / 1024.0 / 1024.0 / 1024.0;
}
if let Ok(entries) = std::fs::read_dir(format!("{}/hwmon", base)) {
for entry in entries.flatten() {
let temp_path = entry.path().join("temp1_input");
if let Ok(temp_str) = std::fs::read_to_string(temp_path) {
gpu.temp = temp_str.trim().parse::<f64>().unwrap_or(0.0) / 1000.0;
break;
}
}
}
gpu.model = "AMD GPU".to_string();
return;
}
}
fn poll_intel(gpu: &mut crate::state::GpuState) {
for i in 0..=3 {
let base = format!("/sys/class/drm/card{}/device", i);
let freq_path = if std::path::Path::new(&format!("{}/gt_cur_freq_mhz", base)).exists() {
Some(format!("{}/gt_cur_freq_mhz", base))
} else if std::path::Path::new(&format!("/sys/class/drm/card{}/gt_cur_freq_mhz", i))
.exists()
{
Some(format!("/sys/class/drm/card{}/gt_cur_freq_mhz", i))
} else {
None
};
if let Some(path) = freq_path
&& let Ok(freq_str) = std::fs::read_to_string(&path)
{
gpu.active = true;
gpu.vendor = "Intel".to_string();
let cur_freq = freq_str.trim().parse::<f64>().unwrap_or(0.0);
let mut max_freq = 0.0;
let max_path = path.replace("gt_cur_freq_mhz", "gt_max_freq_mhz");
if let Ok(max_str) = std::fs::read_to_string(max_path) {
max_freq = max_str.trim().parse::<f64>().unwrap_or(0.0);
}
gpu.usage = if max_freq > 0.0 {
(cur_freq / max_freq) * 100.0
} else {
0.0
};
gpu.temp = 0.0;
gpu.vram_used = 0.0;
gpu.vram_total = 0.0;
gpu.model = format!("Intel iGPU ({}MHz)", cur_freq);
return;
}
}
}
}
src/modules/mod.rs
+21
View File
@@ -1,3 +1,17 @@
//! Waybar module implementations.
//!
//! Each submodule exposes a [`WaybarModule`] type (CPU, network, audio, …)
//! and is feature-gated by a `mod-<kind>` flag. The [`WaybarModule`] trait is
//! what [`crate::registry::dispatch`] uses to evaluate a module on demand.
//!
//! Modules come in two flavours:
//!
//! * **Watched** — the daemon spawns a background polling/event task that
//! pushes state into a `watch::Receiver`, which the module reads lock-free
//! (network, cpu, audio, bluetooth, …).
//! * **Dispatch-only** — evaluated on demand only, without a watch channel
//! (power, game, btrfs).
#[cfg(feature = "mod-audio")]
pub mod audio;
#[cfg(feature = "mod-dbus")]
@@ -36,7 +50,14 @@ use crate::error::Result as FluxoResult;
use crate::output::WaybarOutput;
use crate::state::AppReceivers;
/// Common interface implemented by every Waybar module.
///
/// Given the current daemon config, the shared state receivers, and any
/// caller-supplied arguments, a module produces a single [`WaybarOutput`].
/// Implementations must be cheap to evaluate — they are invoked on every
/// client request and on every signaler state change.
pub trait WaybarModule {
/// Evaluate the module and return its rendered output.
fn run(
&self,
config: &Config,
src/modules/mpris.rs
+119 -81
View File
@@ -201,103 +201,141 @@ impl MprisDaemon {
}
async fn listen_loop(tx: &watch::Sender<MprisState>) -> anyhow::Result<()> {
use futures::StreamExt;
let connection = Connection::session().await?;
info!("Connected to D-Bus for MPRIS monitoring");
// Periodically poll for the active player and update the MPRIS state.
// This avoids complex dynamic signal tracking across ephemeral player instances.
let dbus_proxy = DBusProxy::new(&connection).await?;
loop {
// Discovery pass: find an active MPRIS player.
let names = dbus_proxy.list_names().await?;
let mut active_player = None;
let active_player = names
.into_iter()
.find(|n| n.starts_with("org.mpris.MediaPlayer2."));
for name in names {
if name.starts_with("org.mpris.MediaPlayer2.") {
active_player = Some(name);
break; // Just grab the first active player for now
let Some(player_name) = active_player else {
send_stopped_if_changed(tx);
// No player — wait and re-discover.
tokio::time::sleep(Duration::from_secs(5)).await;
continue;
};
let player_proxy = match MprisPlayerProxy::builder(&connection)
.destination(player_name.clone())?
.build()
.await
{
Ok(p) => p,
Err(_) => {
tokio::time::sleep(Duration::from_secs(2)).await;
continue;
}
}
};
if let Some(player_name) = active_player {
if let Ok(player_proxy) = MprisPlayerProxy::builder(&connection)
.destination(player_name.clone())?
.build()
.await
{
let status = player_proxy.playback_status().await.unwrap_or_default();
let metadata = player_proxy.metadata().await.unwrap_or_default();
// Initial fetch and then signal-driven updates via PropertiesChanged.
update_from_player(&player_proxy, tx).await;
let is_playing = status == "Playing";
let is_paused = status == "Paused";
let is_stopped = status == "Stopped";
let mut status_stream = player_proxy.receive_playback_status_changed().await;
let mut metadata_stream = player_proxy.receive_metadata_changed().await;
let mut artist = String::new();
let mut title = String::new();
let mut album = String::new();
if let Some(v) = metadata.get("xesam:artist") {
if let Ok(arr) = zbus::zvariant::Array::try_from(v) {
let mut artists = Vec::new();
for i in 0..arr.len() {
if let Ok(Some(s)) = arr.get::<&str>(i) {
artists.push(s.to_string());
}
}
artist = artists.join(", ");
} else if let Ok(a) = <&str>::try_from(v) {
artist = a.to_string();
loop {
tokio::select! {
Some(_) = status_stream.next() => {
update_from_player(&player_proxy, tx).await;
}
Some(_) = metadata_stream.next() => {
update_from_player(&player_proxy, tx).await;
}
_ = tokio::time::sleep(Duration::from_secs(10)) => {
// Heartbeat: verify the player is still on the bus.
let current = dbus_proxy.list_names().await.unwrap_or_default();
if !current.iter().any(|n| n == &player_name) {
break;
}
}
if let Some(v) = metadata.get("xesam:title")
&& let Ok(t) = <&str>::try_from(v)
{
title = t.to_string();
}
if let Some(v) = metadata.get("xesam:album")
&& let Ok(a) = <&str>::try_from(v)
{
album = a.to_string();
}
// Only send if changed
let current = tx.borrow();
if current.is_playing != is_playing
|| current.is_paused != is_paused
|| current.is_stopped != is_stopped
|| current.title != title
|| current.artist != artist
|| current.album != album
{
drop(current); // Drop borrow before send
let _ = tx.send(MprisState {
is_playing,
is_paused,
is_stopped,
artist,
title,
album,
});
}
}
} else {
let current = tx.borrow();
if !current.is_stopped || !current.title.is_empty() {
drop(current);
let _ = tx.send(MprisState {
is_playing: false,
is_paused: false,
is_stopped: true,
artist: String::new(),
title: String::new(),
album: String::new(),
});
}
}
tokio::time::sleep(tokio::time::Duration::from_secs(2)).await;
}
}
}
async fn update_from_player(player: &MprisPlayerProxy<'_>, tx: &watch::Sender<MprisState>) {
let status = player.playback_status().await.unwrap_or_default();
let metadata = player.metadata().await.unwrap_or_default();
let is_playing = status == "Playing";
let is_paused = status == "Paused";
let is_stopped = status == "Stopped";
let (artist, title, album) = parse_metadata(&metadata);
let current = tx.borrow();
if current.is_playing != is_playing
|| current.is_paused != is_paused
|| current.is_stopped != is_stopped
|| current.title != title
|| current.artist != artist
|| current.album != album
{
drop(current);
let _ = tx.send(MprisState {
is_playing,
is_paused,
is_stopped,
artist,
title,
album,
});
}
}
fn parse_metadata(
metadata: &std::collections::HashMap<String, zbus::zvariant::Value<'_>>,
) -> (String, String, String) {
let mut artist = String::new();
let mut title = String::new();
let mut album = String::new();
if let Some(v) = metadata.get("xesam:artist") {
if let Ok(arr) = zbus::zvariant::Array::try_from(v) {
let mut artists = Vec::new();
for i in 0..arr.len() {
if let Ok(Some(s)) = arr.get::<&str>(i) {
artists.push(s.to_string());
}
}
artist = artists.join(", ");
} else if let Ok(a) = <&str>::try_from(v) {
artist = a.to_string();
}
}
if let Some(v) = metadata.get("xesam:title")
&& let Ok(t) = <&str>::try_from(v)
{
title = t.to_string();
}
if let Some(v) = metadata.get("xesam:album")
&& let Ok(a) = <&str>::try_from(v)
{
album = a.to_string();
}
(artist, title, album)
}
fn send_stopped_if_changed(tx: &watch::Sender<MprisState>) {
let current = tx.borrow();
if !current.is_stopped || !current.title.is_empty() {
drop(current);
let _ = tx.send(MprisState {
is_playing: false,
is_paused: false,
is_stopped: true,
artist: String::new(),
title: String::new(),
album: String::new(),
});
}
}
src/output.rs
+10
View File
@@ -1,12 +1,22 @@
//! JSON payload returned to Waybar custom modules.
use serde::{Deserialize, Serialize};
/// A Waybar custom module return value.
///
/// Serialises to the schema Waybar's `return-type: json` expects — the
/// optional fields are omitted from the output when unset.
#[derive(Serialize, Deserialize, Clone, Debug, Default)]
pub struct WaybarOutput {
/// Primary text shown in the bar.
pub text: String,
/// Tooltip text shown on hover.
#[serde(skip_serializing_if = "Option::is_none")]
pub tooltip: Option<String>,
/// CSS class applied to the module (for styling).
#[serde(skip_serializing_if = "Option::is_none")]
pub class: Option<String>,
/// Optional 0-100 value usable by bar progress indicators.
#[serde(skip_serializing_if = "Option::is_none")]
pub percentage: Option<u8>,
}
src/registry.rs
+14
View File
@@ -1,3 +1,11 @@
//! Central module dispatch: name → [`WaybarModule::run`] lookup.
//!
//! The `dispatch` function is called by the IPC request handler with a module
//! name (e.g. `"cpu"`, `"vol"`) and returns the rendered [`WaybarOutput`]. All
//! per-module match arms are generated by [`for_each_watched_module!`];
//! dispatch-only modules without a watch channel (power/game/btrfs) are
//! listed manually.
use crate::config::Config;
use crate::error::{FluxoError, Result as FluxoResult};
use crate::output::WaybarOutput;
@@ -6,8 +14,14 @@ use crate::state::AppReceivers;
#[allow(unused_imports)]
use crate::modules::WaybarModule;
/// Expands the module registry into a single [`dispatch`] match and a
/// [`signaler_default_args`] lookup.
macro_rules! gen_dispatch {
($( { $feature:literal, $field:ident, $state:ty, [$($name:literal),+], [$($sig_name:literal),+], $module:path, $signal:ident, [$($default_arg:literal),*], $config:ident } )*) => {
/// Look up a module by name and render its [`WaybarOutput`].
///
/// Returns [`FluxoError::Disabled`] when the module is disabled in
/// config, and [`FluxoError::Ipc`] when the name is unknown.
pub async fn dispatch(
module_name: &str,
#[allow(unused)] config: &Config,
src/signaler.rs
+24 -1
View File
@@ -1,3 +1,11 @@
//! Waybar signalling: watch state channels, send `SIGRTMIN+N` on changes.
//!
//! Waybar's custom modules use `signal = N` to rerun their command when they
//! receive `SIGRTMIN+N`. This task subscribes to every watched module's
//! `watch::Receiver`, evaluates the module when its channel fires, and only
//! signals Waybar when the rendered output actually changed. A 50 ms per-signal
//! debounce prevents storms during rapid state churn.
use crate::config::Config;
use crate::state::AppReceivers;
use std::collections::HashMap;
@@ -7,6 +15,10 @@ use tokio::sync::RwLock;
use tokio::time::{Duration, Instant, sleep};
use tracing::{debug, warn};
/// Sends real-time signals to the Waybar process.
///
/// Resolves Waybar's PID lazily and caches it — the PID is invalidated on
/// signal failure (e.g. Waybar was restarted) and rediscovered via `sysinfo`.
pub struct WaybarSignaler {
cached_pid: Option<i32>,
sys: System,
@@ -14,6 +26,7 @@ pub struct WaybarSignaler {
}
impl WaybarSignaler {
/// Create a new signaler with no cached PID.
pub fn new() -> Self {
Self {
cached_pid: None,
@@ -65,9 +78,19 @@ impl WaybarSignaler {
}
}
/// Generates [`WaybarSignaler::run`] from the central module registry.
///
/// For each watched module we emit:
/// * a cfg-gated `watch::Receiver::changed()` future (or `pending::<()>` when
/// the feature is disabled, so the `tokio::select!` arm compiles uniformly),
/// * a `select!` arm that re-evaluates the module and signals Waybar once per
/// changed output.
macro_rules! gen_signaler_run {
($( { $feature:literal, $field:ident, $state:ty, [$($name:literal),+], [$($sig_name:literal),+], $module:path, $signal:ident, [$($default_arg:literal),*], $config:ident } )*) => {
impl WaybarSignaler {
/// Run the signaler event loop forever.
///
/// Consumes `self`; intended to be spawned as a long-lived task.
pub async fn run(mut self, config_lock: Arc<RwLock<Config>>, mut receivers: AppReceivers) {
let mut last_outputs: HashMap<&'static str, String> = HashMap::new();
@@ -128,7 +151,7 @@ macro_rules! gen_signaler_run {
}
_ = sleep(Duration::from_secs(5)) => {
// loop and refresh config
// heartbeat: re-read signals config on each iteration
}
}
}
src/state.rs
+44
View File
@@ -1,11 +1,27 @@
//! Shared state types exchanged between daemon tasks and modules.
//!
//! Every "watched" module has a `watch::Receiver<StateType>` held by
//! [`AppReceivers`]; background tasks write into the paired sender. Readers
//! (the request handler, the signaler) take a cheap snapshot via
//! `Receiver::borrow()` and render their output from it.
use crate::output::WaybarOutput;
use std::collections::HashMap;
use std::sync::Arc;
use tokio::sync::{RwLock, mpsc, watch};
use tokio::time::Instant;
/// Generates the [`AppReceivers`] struct, with one `watch::Receiver` field
/// per watched module (cfg-gated by feature flag).
macro_rules! gen_app_receivers {
($( { $feature:literal, $field:ident, $state:ty, [$($name:literal),+], [$($sig_name:literal),+], $module:path, $signal:ident, [$($default_arg:literal),*], $config:ident } )*) => {
/// Bundle of every watch-channel receiver and control-channel handle.
///
/// Cloned into each IPC request handler and each module daemon so that
/// they can snapshot state without locking. Per-module receivers are
/// generated from [`for_each_watched_module!`]; the remaining fields
/// (`health`, `bt_cycle`, `audio_cmd_tx`, `mpris_scroll_*`) are shared
/// control state.
#[derive(Clone)]
pub struct AppReceivers {
$(
@@ -28,6 +44,7 @@ macro_rules! gen_app_receivers {
}
for_each_watched_module!(gen_app_receivers);
/// Runtime health statistics used for backoff decisions.
#[derive(Clone, Default)]
pub struct ModuleHealth {
pub consecutive_failures: u32,
@@ -36,6 +53,7 @@ pub struct ModuleHealth {
pub last_successful_output: Option<WaybarOutput>,
}
/// Current default audio sink + source plus all available devices.
#[derive(Default, Clone)]
pub struct AudioState {
pub sink: AudioDeviceInfo,
@@ -44,6 +62,7 @@ pub struct AudioState {
pub available_sources: Vec<String>,
}
/// Metadata for one PulseAudio sink or source.
#[derive(Default, Clone)]
pub struct AudioDeviceInfo {
pub name: String,
@@ -53,6 +72,7 @@ pub struct AudioDeviceInfo {
pub channels: u8,
}
/// A single BlueZ device, optionally annotated by a plugin (buds, maestro…).
#[derive(Default, Clone)]
pub struct BtDeviceInfo {
pub device_alias: String,
@@ -61,6 +81,7 @@ pub struct BtDeviceInfo {
pub plugin_data: Vec<(String, String)>,
}
/// Snapshot of the Bluetooth adapter plus every tracked device.
#[derive(Default, Clone)]
pub struct BtState {
pub adapter_powered: bool,
@@ -68,6 +89,10 @@ pub struct BtState {
}
impl BtState {
/// Return the device the client is currently cycled to, if any.
///
/// The `index` is taken modulo `devices.len()` so cycling past the end
/// wraps around naturally.
pub fn active_device(&self, index: usize) -> Option<&BtDeviceInfo> {
if self.devices.is_empty() {
None
@@ -77,6 +102,7 @@ impl BtState {
}
}
/// Per-mountpoint disk usage.
#[derive(Default, Clone)]
pub struct DiskInfo {
pub mount_point: String,
@@ -85,6 +111,7 @@ pub struct DiskInfo {
pub available_bytes: u64,
}
/// Throughput and identity of the active network interface.
#[derive(Default, Clone)]
pub struct NetworkState {
pub rx_mbps: f64,
@@ -93,6 +120,7 @@ pub struct NetworkState {
pub ip: String,
}
/// CPU utilisation and temperature.
#[derive(Clone)]
pub struct CpuState {
pub usage: f64,
@@ -110,12 +138,14 @@ impl Default for CpuState {
}
}
/// RAM usage in gigabytes.
#[derive(Default, Clone)]
pub struct MemoryState {
pub used_gb: f64,
pub total_gb: f64,
}
/// Load averages, uptime, and process count.
#[derive(Default, Clone)]
pub struct SysState {
pub load_1: f64,
@@ -125,6 +155,9 @@ pub struct SysState {
pub process_count: usize,
}
/// GPU snapshot (vendor-agnostic).
///
/// `active` is `false` until detection finds a supported GPU.
#[derive(Clone)]
pub struct GpuState {
pub active: bool,
@@ -150,27 +183,32 @@ impl Default for GpuState {
}
}
/// Do-Not-Disturb toggle state.
#[derive(Default, Clone)]
pub struct DndState {
pub is_dnd: bool,
}
/// Currently active keyboard layout.
#[derive(Default, Clone)]
pub struct KeyboardState {
pub layout: String,
}
/// Display backlight brightness as a 0-100 percentage.
#[derive(Default, Clone)]
pub struct BacklightState {
pub percentage: u8,
}
/// Marquee scroll position for the MPRIS module.
#[derive(Default, Clone)]
pub struct MprisScrollState {
pub offset: usize,
pub full_text: String,
}
/// Currently playing media metadata from an MPRIS player.
#[derive(Default, Clone)]
pub struct MprisState {
pub is_playing: bool,
@@ -181,6 +219,10 @@ pub struct MprisState {
pub album: String,
}
/// Test harness holding a synthetic [`AppReceivers`] plus its senders.
///
/// The senders are kept alive via `_*_tx` fields so test code can drive the
/// watch channels without them being dropped.
#[cfg(test)]
pub struct MockState {
pub receivers: AppReceivers,
@@ -210,6 +252,7 @@ pub struct MockState {
_dnd_tx: watch::Sender<DndState>,
}
/// Plain-data counterpart of [`AppReceivers`] used to seed a [`MockState`].
#[cfg(test)]
#[derive(Default, Clone)]
pub struct AppState {
@@ -240,6 +283,7 @@ pub struct AppState {
pub health: HashMap<String, ModuleHealth>,
}
/// Build a [`MockState`] from a plain [`AppState`] snapshot for unit tests.
#[cfg(test)]
pub fn mock_state(state: AppState) -> MockState {
#[cfg(feature = "mod-network")]
src/utils.rs
+24 -6
View File
@@ -1,23 +1,31 @@
//! Shared helpers: menu spawning, Hyprland socket lookup, and template formatting.
use anyhow::{Context, Result};
use std::io::Write;
use std::process::{Command, Stdio};
/// Pipe `items` into an external menu program (rofi/dmenu/wofi) and return
/// the user's selection.
///
/// The prompt is exposed to the command as `$FLUXO_PROMPT` (preferred) and
/// as a legacy `{prompt}` placeholder that is substituted in the shell string.
pub fn show_menu(prompt: &str, items: &[String], menu_cmd: &str) -> Result<String> {
// Backward compatibility for {prompt}, but environment variable is safer
let cmd_str = menu_cmd.replace("{prompt}", prompt);
let mut child = Command::new("sh")
.arg("-c")
.arg(&cmd_str)
.env("FLUXO_PROMPT", prompt) // Safer shell injection
.env("FLUXO_PROMPT", prompt)
.stdin(Stdio::piped())
.stdout(Stdio::piped())
.stderr(Stdio::null()) // Suppress GTK/Wayland warnings from tools like wofi
// Suppress GTK/Wayland noise from tools like wofi.
.stderr(Stdio::null())
.spawn()
.context("Failed to spawn menu command")?;
if let Some(mut stdin) = child.stdin.take() {
let mut input = items.join("\n");
input.push('\n'); // Ensure trailing newline for wofi/rofi
// Trailing newline is required by wofi/rofi.
input.push('\n');
stdin
.write_all(input.as_bytes())
.context("Failed to write to menu stdin")?;
@@ -37,11 +45,14 @@ pub fn show_menu(prompt: &str, items: &[String], menu_cmd: &str) -> Result<Strin
Ok(selected)
}
/// Resolve the path to a Hyprland IPC socket for the current session.
///
/// Looks under `$XDG_RUNTIME_DIR/hypr/$HYPRLAND_INSTANCE_SIGNATURE/` first,
/// then falls back to `/tmp/hypr/...` for older Hyprland builds.
pub fn get_hyprland_socket(socket_name: &str) -> Result<std::path::PathBuf> {
let signature = std::env::var("HYPRLAND_INSTANCE_SIGNATURE")
.context("HYPRLAND_INSTANCE_SIGNATURE not set")?;
// Try XDG_RUNTIME_DIR first (usually /run/user/1000)
if let Ok(runtime_dir) = std::env::var("XDG_RUNTIME_DIR") {
let path = std::path::PathBuf::from(runtime_dir)
.join("hypr")
@@ -52,7 +63,6 @@ pub fn get_hyprland_socket(socket_name: &str) -> Result<std::path::PathBuf> {
}
}
// Fallback to /tmp
let path = std::path::PathBuf::from("/tmp/hypr")
.join(&signature)
.join(socket_name);
@@ -70,6 +80,7 @@ pub fn get_hyprland_socket(socket_name: &str) -> Result<std::path::PathBuf> {
use regex::Regex;
use std::sync::LazyLock;
/// Bucket `value` into `"normal"`, `"high"`, or `"max"` for CSS class output.
pub fn classify_usage(value: f64, high: f64, max: f64) -> &'static str {
if value > max {
"max"
@@ -80,15 +91,22 @@ pub fn classify_usage(value: f64, high: f64, max: f64) -> &'static str {
}
}
/// A typed value supplied to [`format_template`] — chosen at call site so
/// formatting handles precision and alignment correctly per type.
pub enum TokenValue {
Float(f64),
Int(i64),
String(String),
}
/// Token grammar: `{name}`, `{name:>5}`, `{name:<8.2}`, `{name:^6}`, etc.
pub static TOKEN_RE: LazyLock<Regex> =
LazyLock::new(|| Regex::new(r"\{([a-zA-Z0-9_]+)(?::([<>\^])?(\d+)?(?:\.(\d+))?)?\}").unwrap());
/// Substitute `{name[:align[width[.precision]]]}` tokens in a template string.
///
/// Unknown tokens are left verbatim. Width/alignment/precision follow Rust's
/// `std::fmt` semantics (`<` left, `^` center, `>` right).
pub fn format_template<K>(template: &str, values: &[(K, TokenValue)]) -> String
where
K: AsRef<str>,