use std::collections::HashMap; use std::fs::File; use std::io::{BufRead, BufReader, Read}; use std::mem; use std::path::{Path, PathBuf}; use std::sync::atomic::{AtomicUsize, Ordering}; use std::sync::Once; use libc; macro_rules! debug { ($($args:expr),*) => ({ if false { //if true { println!($($args),*); } }); } macro_rules! some { ($e:expr) => ({ match $e { Some(v) => v, None => { debug!("NONE: {:?}", stringify!($e)); return None; } } }) } pub fn get_num_cpus() -> usize { match cgroups_num_cpus() { Some(n) => n, None => logical_cpus(), } } fn logical_cpus() -> usize { let mut set: libc::cpu_set_t = unsafe { mem::zeroed() }; if unsafe { libc::sched_getaffinity(0, mem::size_of::(), &mut set) } == 0 { let mut count: u32 = 0; for i in 0..libc::CPU_SETSIZE as usize { if unsafe { libc::CPU_ISSET(i, &set) } { count += 1 } } count as usize } else { let cpus = unsafe { libc::sysconf(libc::_SC_NPROCESSORS_ONLN) }; if cpus < 1 { 1 } else { cpus as usize } } } pub fn get_num_physical_cpus() -> usize { let file = match File::open("/proc/cpuinfo") { Ok(val) => val, Err(_) => return get_num_cpus(), }; let reader = BufReader::new(file); let mut map = HashMap::new(); let mut physid: u32 = 0; let mut cores: usize = 0; let mut chgcount = 0; for line in reader.lines().filter_map(|result| result.ok()) { let mut it = line.split(':'); let (key, value) = match (it.next(), it.next()) { (Some(key), Some(value)) => (key.trim(), value.trim()), _ => continue, }; if key == "physical id" { match value.parse() { Ok(val) => physid = val, Err(_) => break, }; chgcount += 1; } if key == "cpu cores" { match value.parse() { Ok(val) => cores = val, Err(_) => break, }; chgcount += 1; } if chgcount == 2 { map.insert(physid, cores); chgcount = 0; } } let count = map.into_iter().fold(0, |acc, (_, cores)| acc + cores); if count == 0 { get_num_cpus() } else { count } } /// Cached CPUs calculated from cgroups. /// /// If 0, check logical cpus. // Allow deprecation warnings, we want to work on older rustc #[allow(warnings)] static CGROUPS_CPUS: AtomicUsize = ::std::sync::atomic::ATOMIC_USIZE_INIT; fn cgroups_num_cpus() -> Option { #[allow(warnings)] static ONCE: Once = ::std::sync::ONCE_INIT; ONCE.call_once(init_cgroups); let cpus = CGROUPS_CPUS.load(Ordering::Acquire); if cpus > 0 { Some(cpus) } else { None } } fn init_cgroups() { // Should only be called once debug_assert!(CGROUPS_CPUS.load(Ordering::SeqCst) == 0); match load_cgroups("/proc/self/cgroup", "/proc/self/mountinfo") { Some(quota) => { if quota == 0 { return; } let logical = logical_cpus(); let count = ::std::cmp::min(quota, logical); CGROUPS_CPUS.store(count, Ordering::SeqCst); } None => return, } } fn load_cgroups(cgroup_proc: P1, mountinfo_proc: P2) -> Option where P1: AsRef, P2: AsRef, { let subsys = some!(Subsys::load_cpu(cgroup_proc)); let mntinfo = some!(MountInfo::load_cpu(mountinfo_proc)); let cgroup = some!(Cgroup::translate(mntinfo, subsys)); cgroup.cpu_quota() } struct Cgroup { base: PathBuf, } struct MountInfo { root: String, mount_point: String, } struct Subsys { base: String, } impl Cgroup { fn new(dir: PathBuf) -> Cgroup { Cgroup { base: dir, } } fn translate(mntinfo: MountInfo, subsys: Subsys) -> Option { // Translate the subsystem directory via the host paths. debug!( "subsys = {:?}; root = {:?}; mount_point = {:?}", subsys.base, mntinfo.root, mntinfo.mount_point ); let rel_from_root = some!(Path::new(&subsys.base).strip_prefix(&mntinfo.root).ok()); debug!("rel_from_root: {:?}", rel_from_root); // join(mp.MountPoint, relPath) let mut path = PathBuf::from(mntinfo.mount_point); path.push(rel_from_root); Some(Cgroup::new(path)) } fn cpu_quota(&self) -> Option { let quota_us = some!(self.quota_us()); let period_us = some!(self.period_us()); // protect against dividing by zero if period_us == 0 { return None; } // Ceil the division, since we want to be able to saturate // the available CPUs, and flooring would leave a CPU un-utilized. Some((quota_us as f64 / period_us as f64).ceil() as usize) } fn quota_us(&self) -> Option { self.param("cpu.cfs_quota_us") } fn period_us(&self) -> Option { self.param("cpu.cfs_period_us") } fn param(&self, param: &str) -> Option { let mut file = some!(File::open(self.base.join(param)).ok()); let mut buf = String::new(); some!(file.read_to_string(&mut buf).ok()); buf.trim().parse().ok() } } impl MountInfo { fn load_cpu>(proc_path: P) -> Option { let file = some!(File::open(proc_path).ok()); let file = BufReader::new(file); file.lines() .filter_map(|result| result.ok()) .filter_map(MountInfo::parse_line) .next() } fn parse_line(line: String) -> Option { let mut fields = line.split(' '); let mnt_root = some!(fields.nth(3)); let mnt_point = some!(fields.nth(0)); if fields.nth(3) != Some("cgroup") { return None; } let super_opts = some!(fields.nth(1)); // We only care about the 'cpu' option if !super_opts.split(',').any(|opt| opt == "cpu") { return None; } Some(MountInfo { root: mnt_root.to_owned(), mount_point: mnt_point.to_owned(), }) } } impl Subsys { fn load_cpu>(proc_path: P) -> Option { let file = some!(File::open(proc_path).ok()); let file = BufReader::new(file); file.lines() .filter_map(|result| result.ok()) .filter_map(Subsys::parse_line) .next() } fn parse_line(line: String) -> Option { // Example format: // 11:cpu,cpuacct:/ let mut fields = line.split(':'); let sub_systems = some!(fields.nth(1)); if !sub_systems.split(',').any(|sub| sub == "cpu") { return None; } fields.next().map(|path| Subsys { base: path.to_owned() }) } } #[cfg(test)] mod tests { use std::path::{Path, PathBuf}; use super::{Cgroup, MountInfo, Subsys}; static FIXTURES_PROC: &'static str = "fixtures/cgroups/proc/cgroups"; static FIXTURES_CGROUPS: &'static str = "fixtures/cgroups/cgroups"; macro_rules! join { ($base:expr, $($path:expr),+) => ({ Path::new($base) $(.join($path))+ }) } #[test] fn test_load_mountinfo() { let path = join!(FIXTURES_PROC, "mountinfo"); let mnt_info = MountInfo::load_cpu(path).unwrap(); assert_eq!(mnt_info.root, "/"); assert_eq!(mnt_info.mount_point, "/sys/fs/cgroup/cpu,cpuacct"); } #[test] fn test_load_subsys() { let path = join!(FIXTURES_PROC, "cgroup"); let subsys = Subsys::load_cpu(path).unwrap(); assert_eq!(subsys.base, "/"); } #[test] fn test_cgroup_mount() { let cases = &[ ( "/", "/sys/fs/cgroup/cpu", "/", Some("/sys/fs/cgroup/cpu"), ), ( "/docker/01abcd", "/sys/fs/cgroup/cpu", "/docker/01abcd", Some("/sys/fs/cgroup/cpu"), ), ( "/docker/01abcd", "/sys/fs/cgroup/cpu", "/docker/01abcd/", Some("/sys/fs/cgroup/cpu"), ), ( "/docker/01abcd", "/sys/fs/cgroup/cpu", "/docker/01abcd/large", Some("/sys/fs/cgroup/cpu/large"), ), // fails ( "/docker/01abcd", "/sys/fs/cgroup/cpu", "/", None, ), ( "/docker/01abcd", "/sys/fs/cgroup/cpu", "/docker", None, ), ( "/docker/01abcd", "/sys/fs/cgroup/cpu", "/elsewhere", None, ), ( "/docker/01abcd", "/sys/fs/cgroup/cpu", "/docker/01abcd-other-dir", None, ), ]; for &(root, mount_point, subsys, expected) in cases.iter() { let mnt_info = MountInfo { root: root.into(), mount_point: mount_point.into(), }; let subsys = Subsys { base: subsys.into(), }; let actual = Cgroup::translate(mnt_info, subsys).map(|c| c.base); let expected = expected.map(|s| PathBuf::from(s)); assert_eq!(actual, expected); } } #[test] fn test_cgroup_cpu_quota() { let cgroup = Cgroup::new(join!(FIXTURES_CGROUPS, "good")); assert_eq!(cgroup.cpu_quota(), Some(6)); } #[test] fn test_cgroup_cpu_quota_divide_by_zero() { let cgroup = Cgroup::new(join!(FIXTURES_CGROUPS, "zero-period")); assert!(cgroup.quota_us().is_some()); assert_eq!(cgroup.period_us(), Some(0)); assert_eq!(cgroup.cpu_quota(), None); } #[test] fn test_cgroup_cpu_quota_ceil() { let cgroup = Cgroup::new(join!(FIXTURES_CGROUPS, "ceil")); assert_eq!(cgroup.cpu_quota(), Some(2)); } }