跟踪可用和已用的内存方法
💡在出现低内存警告时对应用进行埋点,包括内存的使用及统计信息,并在应用重新运行时将这些信息上报给服务器。使用这些信息来识别出应用发生内存溢出的常见场景和边缘情况。
示例代码
// HPMemoryAnalyzer.h
#import <Foundation/Foundation.h>
/**
跟踪可用和已用的内存
*/
@interface HPMemoryAnalyzer : NSObject
vm_size_t getUsedMemory();
vm_size_t getFreeMemory();
@end
// HPMemoryAnalyzer.m
#import "HPMemoryAnalyzer.h"
#import <mach/mach.h>
vm_size_t getUsedMemory() {
task_basic_info_data_t info;
mach_msg_type_number_t size = sizeof(info);
kern_return_t kerr = task_info(mach_task_self(), TASK_BASIC_INFO, (task_info_t)&info, &size);
if (kerr == KERN_SUCCESS) {
return info.resident_size;
}else {
return 0;
}
}
vm_size_t getFreeMemory() {
mach_port_t host = mach_host_self();
mach_msg_type_number_t size = sizeof(vm_statistics_data_t) / sizeof(integer_t);
vm_size_t pagesize;
vm_statistics_data_t vmstat;
host_page_size(host, &pagesize);
host_statistics(host, HOST_VM_INFO, (host_info_t)&vmstat, &size);
return vmstat.free_count * pagesize;
}
@implementation HPMemoryAnalyzer
@end另外,YYKit 框架中也集成了关于获取应用内存使用量、CPU 使用量的相关方法:
// UIApplication+YYAdd.h
/// Current thread real memory used in byte. (-1 when error occurs)
@property (nonatomic, readonly) int64_t memoryUsage;
/// Current thread CPU usage, 1.0 means 100%. (-1 when error occurs)
@property (nonatomic, readonly) float cpuUsage;
// UIApplication+YYAdd.m
- (int64_t)memoryUsage {
struct task_basic_info info;
mach_msg_type_number_t size = sizeof(info);
kern_return_t kern = task_info(mach_task_self(), TASK_BASIC_INFO, (task_info_t)&info, &size);
if (kern != KERN_SUCCESS) return -1;
return info.resident_size;
}
- (float)cpuUsage {
kern_return_t kr;
task_info_data_t tinfo;
mach_msg_type_number_t task_info_count;
task_info_count = TASK_INFO_MAX;
kr = task_info(mach_task_self(), TASK_BASIC_INFO, (task_info_t)tinfo, &task_info_count);
if (kr != KERN_SUCCESS) {
return -1;
}
thread_array_t thread_list;
mach_msg_type_number_t thread_count;
thread_info_data_t thinfo;
mach_msg_type_number_t thread_info_count;
thread_basic_info_t basic_info_th;
kr = task_threads(mach_task_self(), &thread_list, &thread_count);
if (kr != KERN_SUCCESS) {
return -1;
}
long tot_sec = 0;
long tot_usec = 0;
float tot_cpu = 0;
int j;
for (j = 0; j < thread_count; j++) {
thread_info_count = THREAD_INFO_MAX;
kr = thread_info(thread_list[j], THREAD_BASIC_INFO,
(thread_info_t)thinfo, &thread_info_count);
if (kr != KERN_SUCCESS) {
return -1;
}
basic_info_th = (thread_basic_info_t)thinfo;
if (!(basic_info_th->flags & TH_FLAGS_IDLE)) {
tot_sec = tot_sec + basic_info_th->user_time.seconds + basic_info_th->system_time.seconds;
tot_usec = tot_usec + basic_info_th->system_time.microseconds + basic_info_th->system_time.microseconds;
tot_cpu = tot_cpu + basic_info_th->cpu_usage / (float)TH_USAGE_SCALE;
}
}
kr = vm_deallocate(mach_task_self(), (vm_offset_t)thread_list, thread_count * sizeof(thread_t));
assert(kr == KERN_SUCCESS);
return tot_cpu;
}除了 UIApplication+YYAdd 中这两个方法,你会发现 UIDevice+YYAdd 中还有更丰富的方法,包括获取设备信息、磁盘空间、内存信息、CPU 信息学。
电池电量与代码感知
一个智能的应用会考虑到电池的电量和自身的状态,从而决定是否要真正执行资源密集消耗型的操作。另外一个有价值的点是对充电的判断,确定设备是否处于充电状态。
例如:每次更新 iOS 系统时,系统会判断当前设备电量是否低于 50%,如果低于这个值,系统是不会执行更新系统的任务的,它会提示用户先充电之后再更新系统。
示例代码
传入执行特定操作需要的最低电量级别。该级别是浮点数,范围在 0~100 之间(100 表示电池完全充满)
-(BOOL)shouldProceedWithMinLevel:(int)minLevel
{
UIDevice *device = [UIDevice currentDevice];
device.batteryMonitoringEnabled = YES;
UIDeviceBatteryState state = device.batteryState;
if(state == UIDeviceBatteryStateCharging || state == UIDeviceBatteryStateFull) {
return YES;
}
int batteryLevel = (int) (device.batteryLevel * 100);
if(batteryLevel >= minLevel) {
return YES;
}
return NO;
}谨慎使用电量的最佳实践
- 最小化硬件使用。换句话说,尽可能晚地与硬件打交道,并且一旦完成任务立即结束使用。
- 在进行密集型任务前,检查电池电量和充电状态。
- 在电量低时,提示用户是否确定要执行任务,并在用户同意后再执行。
- 或提供设置的选项,允许用户定义电量的阈值,以便在执行密集型操作前提示用户。
参考
- Gaurav Vaish. 高性能 iOS 应用开发 [M]. 北京:人民邮电出版社,2017. 66-67