package cpu import ( "context" "fmt" "reflect" "regexp" "runtime" "strconv" "strings" "unsafe" "github.com/shirou/gopsutil/v3/internal/common" "github.com/tklauser/go-sysconf" "golang.org/x/sys/unix" ) var ( ClocksPerSec = float64(128) cpuMatch = regexp.MustCompile(`^CPU:`) originMatch = regexp.MustCompile(`Origin\s*=\s*"(.+)"\s+Id\s*=\s*(.+)\s+Stepping\s*=\s*(.+)`) featuresMatch = regexp.MustCompile(`Features=.+<(.+)>`) featuresMatch2 = regexp.MustCompile(`Features2=[a-f\dx]+<(.+)>`) cpuEnd = regexp.MustCompile(`^Trying to mount root`) cpuTimesSize int emptyTimes cpuTimes ) func init() { clkTck, err := sysconf.Sysconf(sysconf.SC_CLK_TCK) // ignore errors if err == nil { ClocksPerSec = float64(clkTck) } } func timeStat(name string, t *cpuTimes) *TimesStat { return &TimesStat{ User: float64(t.User) / ClocksPerSec, Nice: float64(t.Nice) / ClocksPerSec, System: float64(t.Sys) / ClocksPerSec, Idle: float64(t.Idle) / ClocksPerSec, Irq: float64(t.Intr) / ClocksPerSec, CPU: name, } } func Times(percpu bool) ([]TimesStat, error) { return TimesWithContext(context.Background(), percpu) } func TimesWithContext(ctx context.Context, percpu bool) ([]TimesStat, error) { if percpu { buf, err := unix.SysctlRaw("kern.cp_times") if err != nil { return nil, err } // We can't do this in init due to the conflict with cpu.init() if cpuTimesSize == 0 { cpuTimesSize = int(reflect.TypeOf(cpuTimes{}).Size()) } ncpus := len(buf) / cpuTimesSize ret := make([]TimesStat, 0, ncpus) for i := 0; i < ncpus; i++ { times := (*cpuTimes)(unsafe.Pointer(&buf[i*cpuTimesSize])) if *times == emptyTimes { // CPU not present continue } ret = append(ret, *timeStat(fmt.Sprintf("cpu%d", len(ret)), times)) } return ret, nil } buf, err := unix.SysctlRaw("kern.cp_time") if err != nil { return nil, err } times := (*cpuTimes)(unsafe.Pointer(&buf[0])) return []TimesStat{*timeStat("cpu-total", times)}, nil } // Returns only one InfoStat on DragonflyBSD. The information regarding core // count, however is accurate and it is assumed that all InfoStat attributes // are the same across CPUs. func Info() ([]InfoStat, error) { return InfoWithContext(context.Background()) } func InfoWithContext(ctx context.Context) ([]InfoStat, error) { const dmesgBoot = "/var/run/dmesg.boot" c, err := parseDmesgBoot(dmesgBoot) if err != nil { return nil, err } var u32 uint32 if u32, err = unix.SysctlUint32("hw.clockrate"); err != nil { return nil, err } c.Mhz = float64(u32) var num int var buf string if buf, err = unix.Sysctl("hw.cpu_topology.tree"); err != nil { return nil, err } num = strings.Count(buf, "CHIP") c.Cores = int32(strings.Count(string(buf), "CORE") / num) if c.ModelName, err = unix.Sysctl("hw.model"); err != nil { return nil, err } ret := make([]InfoStat, num) for i := 0; i < num; i++ { ret[i] = c } return ret, nil } func parseDmesgBoot(fileName string) (InfoStat, error) { c := InfoStat{} lines, _ := common.ReadLines(fileName) for _, line := range lines { if matches := cpuEnd.FindStringSubmatch(line); matches != nil { break } else if matches := originMatch.FindStringSubmatch(line); matches != nil { c.VendorID = matches[1] t, err := strconv.ParseInt(matches[2], 10, 32) if err != nil { return c, fmt.Errorf("unable to parse DragonflyBSD CPU stepping information from %q: %v", line, err) } c.Stepping = int32(t) } else if matches := featuresMatch.FindStringSubmatch(line); matches != nil { for _, v := range strings.Split(matches[1], ",") { c.Flags = append(c.Flags, strings.ToLower(v)) } } else if matches := featuresMatch2.FindStringSubmatch(line); matches != nil { for _, v := range strings.Split(matches[1], ",") { c.Flags = append(c.Flags, strings.ToLower(v)) } } } return c, nil } func CountsWithContext(ctx context.Context, logical bool) (int, error) { return runtime.NumCPU(), nil }