func (h Host) ProcessorCpuLoadInfo() { var pcli *[]ProcessorCpuLoadInfo var numcpu C.natural_t var nummsg C.mach_msg_type_number_t if C.host_processor_info(C.host_t(h), C.PROCESSOR_CPU_LOAD_INFO, &numcpu, (*C.processor_info_array_t)(unsafe.Pointer(pcli)), &nummsg) != 0 { // } }
func perCPUTimes() ([]CPUTimesStat, error) { var ( count C.mach_msg_type_number_t cpuload *C.processor_cpu_load_info_data_t ncpu C.natural_t ) status := C.host_processor_info(C.host_t(C.mach_host_self()), C.PROCESSOR_CPU_LOAD_INFO, &ncpu, (*C.processor_info_array_t)(unsafe.Pointer(&cpuload)), &count) if status != C.KERN_SUCCESS { return nil, fmt.Errorf("host_processor_info error=%d", status) } // jump through some cgo casting hoops and ensure we properly free // the memory that cpuload points to target := C.vm_map_t(C.mach_task_self_) address := C.vm_address_t(uintptr(unsafe.Pointer(cpuload))) defer C.vm_deallocate(target, address, C.vm_size_t(ncpu)) // the body of struct processor_cpu_load_info // aka processor_cpu_load_info_data_t var cpu_ticks [C.CPU_STATE_MAX]uint32 // copy the cpuload array to a []byte buffer // where we can binary.Read the data size := int(ncpu) * binary.Size(cpu_ticks) buf := C.GoBytes(unsafe.Pointer(cpuload), C.int(size)) bbuf := bytes.NewBuffer(buf) var ret []CPUTimesStat for i := 0; i < int(ncpu); i++ { err := binary.Read(bbuf, binary.LittleEndian, &cpu_ticks) if err != nil { return nil, err } c := CPUTimesStat{ CPU: fmt.Sprintf("cpu%d", i), User: float64(cpu_ticks[C.CPU_STATE_USER]) / ClocksPerSec, System: float64(cpu_ticks[C.CPU_STATE_SYSTEM]) / ClocksPerSec, Nice: float64(cpu_ticks[C.CPU_STATE_NICE]) / ClocksPerSec, Idle: float64(cpu_ticks[C.CPU_STATE_IDLE]) / ClocksPerSec, } ret = append(ret, c) } return ret, nil }
func (self *CpuList) Get() error { var count C.mach_msg_type_number_t var cpuload *C.processor_cpu_load_info_data_t var ncpu C.natural_t status := C.host_processor_info(C.host_t(C.mach_host_self()), C.PROCESSOR_CPU_LOAD_INFO, &ncpu, (*C.processor_info_array_t)(unsafe.Pointer(&cpuload)), &count) if status != C.KERN_SUCCESS { return fmt.Errorf("host_processor_info error=%d", status) } // jump through some cgo casting hoops and ensure we properly free // the memory that cpuload points to target := C.vm_map_t(C.mach_task_self_) address := C.vm_address_t(uintptr(unsafe.Pointer(cpuload))) defer C.vm_deallocate(target, address, C.vm_size_t(ncpu)) // the body of struct processor_cpu_load_info // aka processor_cpu_load_info_data_t var cpu_ticks [C.CPU_STATE_MAX]uint32 // copy the cpuload array to a []byte buffer // where we can binary.Read the data size := int(ncpu) * binary.Size(cpu_ticks) buf := C.GoBytes(unsafe.Pointer(cpuload), C.int(size)) bbuf := bytes.NewBuffer(buf) self.List = make([]Cpu, 0, ncpu) for i := 0; i < int(ncpu); i++ { cpu := Cpu{} err := binary.Read(bbuf, binary.LittleEndian, &cpu_ticks) if err != nil { return err } cpu.User = uint64(cpu_ticks[C.CPU_STATE_USER]) cpu.Sys = uint64(cpu_ticks[C.CPU_STATE_SYSTEM]) cpu.Idle = uint64(cpu_ticks[C.CPU_STATE_IDLE]) cpu.Nice = uint64(cpu_ticks[C.CPU_STATE_NICE]) self.List = append(self.List, cpu) } return nil }
// stolen from https://github.com/cloudfoundry/gosigar func getCPUDetailedTimes() ([]CPUTimesStat, error) { var count C.mach_msg_type_number_t var cpuload *C.processor_cpu_load_info_data_t var ncpu C.natural_t status := C.host_processor_info(C.host_t(C.mach_host_self()), C.PROCESSOR_CPU_LOAD_INFO, &ncpu, (*C.processor_info_array_t)(unsafe.Pointer(&cpuload)), &count) if status != C.KERN_SUCCESS { return nil, fmt.Errorf("host_processor_info error=%d", status) } // jump through some cgo casting hoops and ensure we properly free // the memory that cpuload points to target := C.vm_map_t(C.mach_task_self_) address := C.vm_address_t(uintptr(unsafe.Pointer(cpuload))) defer C.vm_deallocate(target, address, C.vm_size_t(ncpu)) // the body of struct processor_cpu_load_info // aka processor_cpu_load_info_data_t var cpu_ticks = make([]uint32, C.CPU_STATE_MAX) // copy the cpuload array to a []byte buffer // where we can binary.Read the data size := int(ncpu) * binary.Size(cpu_ticks) buf := C.GoBytes(unsafe.Pointer(cpuload), C.int(size)) bbuf := bytes.NewBuffer(buf) var ret []CPUTimesStat = make([]CPUTimesStat, 0, ncpu+1) for i := 0; i < int(ncpu); i++ { err := binary.Read(bbuf, binary.LittleEndian, &cpu_ticks) if err != nil { return nil, err } cpu := CPUTimesStat{ CPU: strconv.Itoa(i)} fillCPUStats(cpu_ticks, &cpu) ret = append(ret, cpu) } return ret, nil }
func (c *statCollector) Update(ch chan<- prometheus.Metric) error { var ( count C.mach_msg_type_number_t cpuload *C.processor_cpu_load_info_data_t ncpu C.natural_t ) status := C.host_processor_info(C.host_t(C.mach_host_self()), C.PROCESSOR_CPU_LOAD_INFO, &ncpu, (*C.processor_info_array_t)(unsafe.Pointer(&cpuload)), &count) if status != C.KERN_SUCCESS { return fmt.Errorf("host_processor_info error=%d", status) } // jump through some cgo casting hoops and ensure we properly free // the memory that cpuload points to target := C.vm_map_t(C.mach_task_self_) address := C.vm_address_t(uintptr(unsafe.Pointer(cpuload))) defer C.vm_deallocate(target, address, C.vm_size_t(ncpu)) // the body of struct processor_cpu_load_info // aka processor_cpu_load_info_data_t var cpu_ticks [C.CPU_STATE_MAX]uint32 // copy the cpuload array to a []byte buffer // where we can binary.Read the data size := int(ncpu) * binary.Size(cpu_ticks) buf := (*[1 << 30]byte)(unsafe.Pointer(cpuload))[:size:size] bbuf := bytes.NewBuffer(buf) for i := 0; i < int(ncpu); i++ { err := binary.Read(bbuf, binary.LittleEndian, &cpu_ticks) if err != nil { return err } for k, v := range map[string]int{ "user": C.CPU_STATE_USER, "system": C.CPU_STATE_SYSTEM, "nice": C.CPU_STATE_NICE, "idle": C.CPU_STATE_IDLE, } { ch <- prometheus.MustNewConstMetric(c.cpu, prometheus.CounterValue, float64(cpu_ticks[v])/ClocksPerSec, "cpu"+strconv.Itoa(i), k) } } return nil }