本文详细解析了muduo网络库中Timestamp类的设计与实现,包括类的定义、成员函数说明及其实现细节,并通过测试代码验证了其功能。
今天开始学习陈硕先生的muduo网络库,moduo网络库得到很多好评,陈硕先生自己也说核心代码不超过5000行,所以我觉得有必要拿过来好好学习下,学习的时候在源码上面添加一些自己的注释,方便日后理解,首先看看UTC时间戳,源码目录为base文件夹:
Timestamp.h
//UTC时间戳
//类声明文件
#ifndef MUDUO_BASE_TIMESTAMP_H
#define MUDUO_BASE_TIMESTAMP_H
#include <muduo/base/copyable.h>
#include <muduo/base/Types.h>
#include <boost/operators.hpp>
namespace muduo
{
// Time stamp in UTC, in microseconds resolution.
//时间起始点是1970 1月1号0:0:0
// This class is immutable.
// It's recommended to pass it by value, since it's passed in register on x64.
//继承两个类
//muduo::copyable空基类,标识类,值类型
//boost::less_than_comparable<Timestamp>要求实现< 号运算符
//可自动实现>,<=,>=
//这是一种模板语言编程思想
class Timestamp : public muduo::copyable, public boost::less_than_comparable<Timestamp>
{
public:
//
// Constucts an invalid Timestamp.
//
Timestamp(): microSecondsSinceEpoch_(0)
{
}
// Constucts a Timestamp at specific time
// @param microSecondsSinceEpoch
explicit Timestamp(int64_t microSecondsSinceEpoch);
//两个时间戳进行交换
void swap(Timestamp& that)
{
std::swap(microSecondsSinceEpoch_, that.microSecondsSinceEpoch_);
}
// default copy/assignment/dtor are Okay
string toString() const;
string toFormattedString() const;
bool valid() const { return microSecondsSinceEpoch_ > 0; }
// for internal usage.
int64_t microSecondsSinceEpoch() const { return microSecondsSinceEpoch_; }
time_t secondsSinceEpoch() const
{ return static_cast<time_t>(microSecondsSinceEpoch_ / kMicroSecondsPerSecond); }
//Get time of now.
//获取当前时间
static Timestamp now();
//获取一个失效的时间,看第一个构造函数那里
static Timestamp invalid();
static const int kMicroSecondsPerSecond = 1000 * 1000;
private:
int64_t microSecondsSinceEpoch_;
};
//其他的号会自己实现
inline bool operator<(Timestamp lhs, Timestamp rhs)
{
return lhs.microSecondsSinceEpoch() < rhs.microSecondsSinceEpoch();
}
inline bool operator==(Timestamp lhs, Timestamp rhs)
{
return lhs.microSecondsSinceEpoch() == rhs.microSecondsSinceEpoch();
}
//Gets time difference of two timestamps, result in seconds.
//
// @param high, low
// @return (high-low) in seconds
// @c double has 52-bit precision, enough for one-microseciond
// resolution for next 100 years.
//用于计算两个时间的差
inline double timeDifference(Timestamp high, Timestamp low)
{
int64_t diff = high.microSecondsSinceEpoch() - low.microSecondsSinceEpoch();//这里得到的是微秒
return static_cast<double>(diff) / Timestamp::kMicroSecondsPerSecond;//转化为秒数
//kMicroSecondsPerSecond为上面定义的一个常量
}
// Add @c seconds to given timestamp.
// @return timestamp+seconds as Timestamp
//在时间的基础上增加多少秒
inline Timestamp addTime(Timestamp timestamp, double seconds)
{
int64_t delta = static_cast<int64_t>(seconds * Timestamp::kMicroSecondsPerSecond);//先把秒转化为微秒
return Timestamp(timestamp.microSecondsSinceEpoch() + delta);//构造一个新的对象加上新的微秒
}
}
#endif // MUDUO_BASE_TIMESTAMP_H
Timestamp.cc
//UTC 时间戳类实现文件
#include <muduo/base/Timestamp.h>
#include <sys/time.h>
#include <stdio.h>
#define __STDC_FORMAT_MACROS
#include <inttypes.h>//PRId64所在的头文件,在C++当中需要定义上面那个宏才可以使用PRId64
#undef __STDC_FORMAT_MACROS
#include <boost/static_assert.hpp>
using namespace muduo;
//编译时断言,在编译的时候检查 该条件是否满足
BOOST_STATIC_ASSERT(sizeof(Timestamp) == sizeof(int64_t));
//构造函数初始化赋值
Timestamp::Timestamp(int64_t microseconds): microSecondsSinceEpoch_(microseconds)
{
}
string Timestamp::toString() const
{
char buf[32] = {0};
int64_t seconds = microSecondsSinceEpoch_ / kMicroSecondsPerSecond;//得到秒数
int64_t microseconds = microSecondsSinceEpoch_ % kMicroSecondsPerSecond;//得到微秒数
//PRId64是为了实现跨平台,32位机器表示64位是lld,64位机器表示64位是ld
snprintf(buf, sizeof(buf)-1, "%" PRId64 ".%06" PRId64 "", seconds, microseconds);
return buf;
}
//把时间转化为一个格式化的字符串
string Timestamp::toFormattedString() const
{
char buf[32] = {0};
time_t seconds = static_cast<time_t>(microSecondsSinceEpoch_ / kMicroSecondsPerSecond);//得到距离1970年那个时间的秒数
int microseconds = static_cast<int>(microSecondsSinceEpoch_ % kMicroSecondsPerSecond);//得到距离1970年那个时间的微秒数
struct tm tm_time;
gmtime_r(&seconds, &tm_time);//gmtime_r将一个秒数转化为结构体
//将时间结构体里面的时间取出来放进buf里面
snprintf(buf, sizeof(buf), "%4d%02d%02d %02d:%02d:%02d.%06d", tm_time.tm_year + 1900, tm_time.tm_mon + 1, tm_time.tm_mday,
tm_time.tm_hour, tm_time.tm_min, tm_time.tm_sec,microseconds);
return buf;
}
//获取当前的时间
Timestamp Timestamp::now()
{
struct timeval tv;
gettimeofday(&tv, NULL);//这里返回一个timeval的结构体,第二个参数是一个时区,这里我们不需要返回
int64_t seconds = tv.tv_sec;
return Timestamp(seconds * kMicroSecondsPerSecond + tv.tv_usec);//得到的是距离19700101的微秒数的一个新的对象
}
//获取一个失效的时间
Timestamp Timestamp::invalid()
{
return Timestamp();
}
测试文件在base/tests下面的Timestamp_unittest.cc
Timestamp_unittest.cc
//UTC 时间戳的测试代码
#include <muduo/base/Timestamp.h>
#include <vector>
#include <stdio.h>
using muduo::Timestamp;
void passByConstReference(const Timestamp& x)
{
printf("%s\n", x.toString().c_str());
}
void passByValue(Timestamp x)
{
printf("%s\n", x.toString().c_str());
}
void benchmark()
{//const常量前面加个K是谷歌推荐的编码规范
const int kNumber = 1000*1000;
std::vector<Timestamp> stamps;
stamps.reserve(kNumber);//先预留kNumber个对象的空间
for (int i = 0; i < kNumber; ++i)
{//插入100w个now,目的是为了计算执行gettimeofday的时间
stamps.push_back(Timestamp::now());
}
//c_str() 以 char* 形式传回 string 内含字符串
printf("%s\n", stamps.front().toString().c_str());//打印第一个插入的时间
printf("%s\n", stamps.back().toString().c_str());//打印最后一个插入的时间
printf("%f\n", timeDifference(stamps.back(), stamps.front()));//计算时间差
int increments[100] = { 0 };
int64_t start = stamps.front().microSecondsSinceEpoch();
for (int i = 1; i < kNumber; ++i)
{
int64_t next = stamps[i].microSecondsSinceEpoch();
int64_t inc = next - start;
start = next;
if (inc < 0)
{
printf("reverse!\n");
}
else if (inc < 100)//时间差小于100
{
++increments[inc];
}
else
{
printf("big gap %d\n", static_cast<int>(inc));
}
}
for (int i = 0; i < 100; ++i)
{
printf("%2d: %d\n", i, increments[i]);
}
}
int main()
{//构造一个时间戳对象,拷贝构造给now对象
Timestamp now(Timestamp::now());
printf("%s\n", now.toString().c_str());//输出当前时间的toString,格式秒,微秒
passByValue(now);
passByConstReference(now);
benchmark();//一个度量时间的函数
}
拿出来单独编译,运行可得到如下的结果:
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