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denoland-deno/ext/node/ops/os/cpus.rs

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// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license.
use deno_core::serde::Serialize;
#[derive(Debug, Default, Serialize, Clone)]
pub struct CpuTimes {
pub user: u64,
pub nice: u64,
pub sys: u64,
pub idle: u64,
pub irq: u64,
}
#[derive(Debug, Default, Serialize, Clone)]
pub struct CpuInfo {
pub model: String,
/* in MHz */
pub speed: u64,
pub times: CpuTimes,
}
impl CpuInfo {
pub fn new() -> Self {
Self::default()
}
}
#[cfg(target_os = "macos")]
pub fn cpu_info() -> Option<Vec<CpuInfo>> {
let mut model: [u8; 512] = [0; 512];
let mut size = std::mem::size_of_val(&model);
// Safety: Assumes correct behavior of platform-specific syscalls and data structures.
// Relies on specific sysctl names and sysconf parameter existence.
unsafe {
let ticks = libc::sysconf(libc::_SC_CLK_TCK);
let multiplier = 1000u64 / ticks as u64;
if libc::sysctlbyname(
"machdep.cpu.brand_string\0".as_ptr() as *const libc::c_char,
model.as_mut_ptr() as _,
&mut size,
std::ptr::null_mut(),
0,
) != 0
&& libc::sysctlbyname(
"hw.model\0".as_ptr() as *const libc::c_char,
model.as_mut_ptr() as _,
&mut size,
std::ptr::null_mut(),
0,
) != 0
{
return None;
}
let mut cpu_speed: u64 = 0;
let mut cpu_speed_size = std::mem::size_of_val(&cpu_speed);
libc::sysctlbyname(
"hw.cpufrequency\0".as_ptr() as *const libc::c_char,
&mut cpu_speed as *mut _ as *mut libc::c_void,
&mut cpu_speed_size,
std::ptr::null_mut(),
0,
);
if cpu_speed == 0 {
// https://github.com/libuv/libuv/pull/3679
//
// hw.cpufrequency sysctl seems to be missing on darwin/arm64
// so we instead hardcode a plausible value. This value matches
// what the mach kernel will report when running Rosetta apps.
cpu_speed = 2_400_000_000;
}
let mut num_cpus: libc::natural_t = 0;
let mut info: *mut libc::processor_cpu_load_info_data_t =
std::ptr::null_mut();
let mut msg_type: libc::mach_msg_type_number_t = 0;
if libc::host_processor_info(
libc::mach_host_self(),
libc::PROCESSOR_CPU_LOAD_INFO,
&mut num_cpus,
&mut info as *mut _ as *mut libc::processor_info_array_t,
&mut msg_type,
) != 0
{
return None;
}
let mut cpus = vec![CpuInfo::new(); num_cpus as usize];
let info = std::slice::from_raw_parts(info, num_cpus as usize);
let model = std::ffi::CStr::from_ptr(model.as_ptr() as _)
.to_string_lossy()
.into_owned();
for (i, cpu) in cpus.iter_mut().enumerate() {
cpu.times.user =
info[i].cpu_ticks[libc::CPU_STATE_USER as usize] as u64 * multiplier;
cpu.times.nice =
info[i].cpu_ticks[libc::CPU_STATE_NICE as usize] as u64 * multiplier;
cpu.times.sys =
info[i].cpu_ticks[libc::CPU_STATE_SYSTEM as usize] as u64 * multiplier;
cpu.times.idle =
info[i].cpu_ticks[libc::CPU_STATE_IDLE as usize] as u64 * multiplier;
cpu.times.irq = 0;
2024-06-14 07:40:57 -04:00
cpu.model.clone_from(&model);
cpu.speed = cpu_speed / 1000000;
}
libc::vm_deallocate(
libc::mach_task_self(),
info.as_ptr() as libc::vm_address_t,
msg_type as _,
);
Some(cpus)
}
}
#[cfg(target_os = "windows")]
pub fn cpu_info() -> Option<Vec<CpuInfo>> {
use windows_sys::Wdk::System::SystemInformation::NtQuerySystemInformation;
use windows_sys::Wdk::System::SystemInformation::SystemProcessorPerformanceInformation;
use windows_sys::Win32::System::WindowsProgramming::SYSTEM_PROCESSOR_PERFORMANCE_INFORMATION;
use std::os::windows::ffi::OsStrExt;
use std::os::windows::ffi::OsStringExt;
fn encode_wide(s: &str) -> Vec<u16> {
std::ffi::OsString::from(s)
.encode_wide()
.chain(Some(0))
.collect()
}
// Safety: Assumes correct behavior of platform-specific syscalls and data structures.
unsafe {
let mut system_info: winapi::um::sysinfoapi::SYSTEM_INFO =
std::mem::zeroed();
winapi::um::sysinfoapi::GetSystemInfo(&mut system_info);
let cpu_count = system_info.dwNumberOfProcessors as usize;
let mut cpus = vec![CpuInfo::new(); cpu_count];
let mut sppi: Vec<SYSTEM_PROCESSOR_PERFORMANCE_INFORMATION> =
vec![std::mem::zeroed(); cpu_count];
let sppi_size = std::mem::size_of_val(&sppi[0]) * cpu_count;
let mut result_size = 0;
let status = NtQuerySystemInformation(
SystemProcessorPerformanceInformation,
sppi.as_mut_ptr() as *mut _,
sppi_size as u32,
&mut result_size,
);
if status != 0 {
return None;
}
assert_eq!(result_size, sppi_size as u32);
for i in 0..cpu_count {
let key_name =
format!("HARDWARE\\DESCRIPTION\\System\\CentralProcessor\\{}", i);
let key_name = encode_wide(&key_name);
let mut processor_key: windows_sys::Win32::System::Registry::HKEY =
std::mem::zeroed();
let err = windows_sys::Win32::System::Registry::RegOpenKeyExW(
windows_sys::Win32::System::Registry::HKEY_LOCAL_MACHINE,
key_name.as_ptr(),
0,
windows_sys::Win32::System::Registry::KEY_QUERY_VALUE,
&mut processor_key,
);
if err != 0 {
return None;
}
let mut cpu_speed = 0;
let mut cpu_speed_size = std::mem::size_of_val(&cpu_speed) as u32;
let err = windows_sys::Win32::System::Registry::RegQueryValueExW(
processor_key,
encode_wide("~MHz").as_ptr() as *mut _,
std::ptr::null_mut(),
std::ptr::null_mut(),
&mut cpu_speed as *mut _ as *mut _,
&mut cpu_speed_size,
);
if err != 0 {
return None;
}
let cpu_brand: [u16; 512] = [0; 512];
let mut cpu_brand_size = std::mem::size_of_val(&cpu_brand) as u32;
let err = windows_sys::Win32::System::Registry::RegQueryValueExW(
processor_key,
encode_wide("ProcessorNameString").as_ptr() as *mut _,
std::ptr::null_mut(),
std::ptr::null_mut(),
cpu_brand.as_ptr() as *mut _,
&mut cpu_brand_size,
);
windows_sys::Win32::System::Registry::RegCloseKey(processor_key);
if err != 0 {
return None;
}
let cpu_brand =
std::ffi::OsString::from_wide(&cpu_brand[..cpu_brand_size as usize])
.into_string()
.unwrap();
cpus[i].model = cpu_brand;
cpus[i].speed = cpu_speed as u64;
cpus[i].times.user = sppi[i].UserTime as u64 / 10000;
cpus[i].times.sys =
(sppi[i].KernelTime - sppi[i].IdleTime) as u64 / 10000;
cpus[i].times.idle = sppi[i].IdleTime as u64 / 10000;
/* InterruptTime is Reserved1[1] */
cpus[i].times.irq = sppi[i].Reserved1[1] as u64 / 10000;
cpus[i].times.nice = 0;
}
Some(cpus)
}
}
#[cfg(any(target_os = "android", target_os = "linux"))]
pub fn cpu_info() -> Option<Vec<CpuInfo>> {
use std::io::BufRead;
let mut cpus = vec![CpuInfo::new(); 8192]; /* Kernel maximum */
let fp = std::fs::File::open("/proc/stat").ok()?;
let reader = std::io::BufReader::new(fp);
let mut count = 0;
// Skip the first line which tracks total CPU time across all cores
for (i, line) in reader.lines().skip(1).enumerate() {
let line = line.ok()?;
if !line.starts_with("cpu") {
break;
}
count = i + 1;
let mut fields = line.split_whitespace();
fields.next()?;
let user = fields.next()?.parse::<u64>().ok()?;
let nice = fields.next()?.parse::<u64>().ok()?;
let sys = fields.next()?.parse::<u64>().ok()?;
let idle = fields.next()?.parse::<u64>().ok()?;
let irq = fields.next()?.parse::<u64>().ok()?;
cpus[i].times.user = user;
cpus[i].times.nice = nice;
cpus[i].times.sys = sys;
cpus[i].times.idle = idle;
cpus[i].times.irq = irq;
}
let fp = std::fs::File::open("/proc/cpuinfo").ok()?;
let reader = std::io::BufReader::new(fp);
let mut j = 0;
for line in reader.lines() {
let line = line.ok()?;
if !line.starts_with("model name") {
continue;
}
let mut fields = line.splitn(2, ':');
fields.next()?;
let model = fields.next()?.trim();
cpus[j].model = model.to_string();
j += 1;
}
while j < count {
cpus[j].model = "unknown".to_string();
j += 1;
}
cpus.truncate(count);
Some(cpus)
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn test_cpu_info() {
let info = cpu_info();
assert!(info.is_some());
let info = info.unwrap();
assert!(!info.is_empty());
for cpu in info {
assert!(!cpu.model.is_empty());
assert!(cpu.times.user > 0);
assert!(cpu.times.sys > 0);
assert!(cpu.times.idle > 0);
}
}
}