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use std::{
fs::File,
io::{BufRead, BufReader},
sync::{atomic::Ordering, mpsc::Sender},
thread::JoinHandle,
time::Duration,
};
use regex_lite::Regex;
use time::OffsetDateTime;
use crate::{griph, AwakeState};
pub struct Gatherer {
state: AwakeState,
hwnd: Option<JoinHandle<()>>,
}
impl Gatherer {
pub fn new(state: AwakeState) -> Self {
Self { state, hwnd: None }
}
pub fn start(&mut self) {
let state = self.state.clone();
let hwnd = std::thread::spawn(|| task(state));
self.hwnd = Some(hwnd);
}
}
fn task(state: AwakeState) {
tracing::info!("starting gatherer thread");
// I just want a graph on first boot; don't care about divisions just yet
make_mem_graph(&state);
make_net_graph(&state);
let mut last_netinfo: Option<Netinfo> = None;
// this is a `let _` because otherwise the attribute was
// making the comiler mad
#[rustfmt::skip]
let _ = loop {
tracing::debug!("collecting stats");
// Gather data
let meminfo = Meminfo::current();
let netinfo = Netinfo::current();
// Print traces, y'know, for tracing
tracing::trace!("memory: {}MB used / {}MB total", meminfo.usage() / 1000, meminfo.total / 1000);
tracing::trace!("net: rx {} / tx {}", data_human_fmt(netinfo.rx_bytes), data_human_fmt(netinfo.tx_bytes));
if let Some(lni) = last_netinfo {
let rx_delta = netinfo.rx_bytes - lni.rx_bytes;
let tx_delta = netinfo.tx_bytes - lni.tx_bytes;
state.database.insert_hostnet(60, rx_delta, tx_delta);
}
last_netinfo = Some(netinfo);
// Store stats in database
state.database.insert_host_meminfo(meminfo);
// Only generate graphs every 15 minutes
let now = OffsetDateTime::now_utc();
if now.minute() % 15 == 0 {
make_mem_graph(&state);
make_net_graph(&state);
}
std::thread::sleep(Duration::from_secs(60));
};
}
pub fn make_mem_graph(state: &AwakeState) {
tracing::debug!("generating meminfo graph");
let infos = state.database.get_last_n_host_meminfo(256);
let max = infos[0].total_kb;
let mut usages: Vec<usize> = infos.into_iter().map(|mi| mi.usage()).collect();
// Reversing here because we want latest valeus on on the
// right side, so last in the array
usages.reverse();
let gif = griph::make_1line(0, max, &usages);
let path = state.cache_path.join("current_hostmeminfo.gif");
gif.save(path).unwrap();
}
pub fn make_net_graph(state: &AwakeState) {
tracing::debug!("generating netinfo graph");
let infos = state.database.get_last_n_hostnet(256);
// 125 is (1000 / 8) so it converst Bytes to kiloBITS
let mut rx_deltas: Vec<usize> = infos
.iter()
.map(|ni| ni.rx_bytes_per_sec() as usize / 124)
.collect();
let mut tx_deltas: Vec<usize> = infos
.iter()
.map(|ni| ni.tx_bytes_per_sec() as usize / 125)
.collect();
// Reversing to put latest values on the right side
rx_deltas.reverse();
tx_deltas.reverse();
// Mixing the TX/RX delta so we can pick a range.
let mut mixed = vec![0; 512];
mixed[..256].copy_from_slice(&rx_deltas);
mixed[256..].copy_from_slice(&tx_deltas);
mixed.sort();
let kinda_highest = mixed[511 - 32];
let high_bound = (kinda_highest as f32 / 256.0).ceil().min(1.0) as usize * 256;
state
.netinfo_upper_bound
.store(high_bound, Ordering::Release);
let gif = griph::make_2line(0, high_bound, &tx_deltas, &rx_deltas);
let path = state.cache_path.join("current_hostnetinfo.gif");
gif.save(path).unwrap();
}
pub struct Meminfo {
pub total: usize,
pub free: usize,
pub avaialable: usize,
}
impl Meminfo {
pub fn current() -> Self {
let procinfo = File::open("/proc/meminfo").unwrap();
let bread = BufReader::new(procinfo);
let mut meminfo = Meminfo {
total: 0,
free: 0,
avaialable: 0,
};
for line in bread.lines() {
let line = line.unwrap();
if let Some((raw_key, raw_value_kb)) = line.split_once(':') {
let value = if let Some(raw_value) = raw_value_kb.trim().strip_suffix(" kB") {
if let Ok(parsed) = raw_value.parse() {
parsed
} else {
continue;
}
} else {
continue;
};
match raw_key.trim() {
"MemTotal" => meminfo.total = value,
"MemFree" => meminfo.free = value,
"MemAvailable" => meminfo.avaialable = value,
_ => (),
}
}
}
meminfo
}
pub fn usage(&self) -> usize {
self.total - self.avaialable
}
}
pub struct Netinfo {
rx_bytes: usize,
tx_bytes: usize,
}
impl Netinfo {
pub fn current() -> Self {
let procinfo = File::open("/proc/net/dev").unwrap();
let bread = BufReader::new(procinfo);
let mut netinfo = Self {
rx_bytes: 0,
tx_bytes: 0,
};
let re = Regex::new(r"[ ]*(\d+)").unwrap();
let interface = "eth0:";
for line in bread.lines() {
let line = line.unwrap();
let trim = line.trim();
let mut captures = if let Some(data) = trim.strip_prefix(interface) {
re.captures_iter(data)
} else {
continue;
};
netinfo.rx_bytes = captures
.next()
.unwrap()
.get(1)
.unwrap()
.as_str()
.parse()
.unwrap();
netinfo.tx_bytes = captures
.skip(7)
.next()
.unwrap()
.get(1)
.unwrap()
.as_str()
.parse()
.unwrap();
break;
}
netinfo
}
}
fn data_human_fmt(bytes: usize) -> String {
let (num, unit) = data_human(bytes);
format!("{num}{unit}")
}
fn data_human(bytes: usize) -> (f32, &'static str) {
const UNITS: &[&str] = &["B", "kB", "MB", "GB", "TB"];
let mut wrk = bytes as f32;
let mut unit_idx = 0;
loop {
if wrk < 1500.0 || unit_idx == UNITS.len() - 1 {
return (wrk, UNITS[unit_idx]);
}
wrk /= 1000.0;
unit_idx += 1;
}
}
|
