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|
// -*- mode:C++; tab-width:8; c-basic-offset:2; indent-tabs-mode:t -*-
// vim: ts=8 sw=2 smarttab
/*
* Ceph - scalable distributed file system
*
* Copyright (C) 2004-2006 Sage Weil <sage@newdream.net>
*
* This is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License version 2.1, as published by the Free Software
* Foundation. See file COPYING.
*
*/
#ifndef CEPH_UTIME_H
#define CEPH_UTIME_H
#include <math.h>
#include <sys/time.h>
#include <time.h>
#include <errno.h>
#if defined(WITH_SEASTAR)
#include <seastar/core/lowres_clock.hh>
#endif
#include "include/compat.h"
#include "include/types.h"
#include "include/timegm.h"
#include "common/strtol.h"
#include "common/ceph_time.h"
#include "common/safe_io.h"
#include "common/SubProcess.h"
#include "include/denc.h"
// --------
// utime_t
inline __u32 cap_to_u32_max(__u64 t) {
return std::min(t, (__u64)std::numeric_limits<uint32_t>::max());
}
/* WARNING: If add member in utime_t, please make sure the encode/decode function
* work well. For little-endian machine, we should make sure there is no padding
* in 32-bit machine and 64-bit machine.
* You should also modify the padding_check function.
*/
class utime_t {
public:
struct {
__u32 tv_sec, tv_nsec;
} tv;
public:
bool is_zero() const {
return (tv.tv_sec == 0) && (tv.tv_nsec == 0);
}
void normalize() {
if (tv.tv_nsec > 1000000000ul) {
tv.tv_sec = cap_to_u32_max(tv.tv_sec + tv.tv_nsec / (1000000000ul));
tv.tv_nsec %= 1000000000ul;
}
}
// cons
utime_t() { tv.tv_sec = 0; tv.tv_nsec = 0; }
utime_t(time_t s, int n) { tv.tv_sec = s; tv.tv_nsec = n; normalize(); }
utime_t(const struct ceph_timespec &v) {
decode_timeval(&v);
}
utime_t(const struct timespec v)
{
// NOTE: this is used by ceph_clock_now() so should be kept
// as thin as possible.
tv.tv_sec = v.tv_sec;
tv.tv_nsec = v.tv_nsec;
}
// conversion from ceph::real_time/coarse_real_time
template <typename Clock, typename std::enable_if_t<
ceph::converts_to_timespec_v<Clock>>* = nullptr>
explicit utime_t(const std::chrono::time_point<Clock>& t)
: utime_t(Clock::to_timespec(t)) {} // forward to timespec ctor
template<class Rep, class Period>
explicit utime_t(const std::chrono::duration<Rep, Period>& dur) {
using common_t = std::common_type_t<Rep, int>;
tv.tv_sec = std::max<common_t>(std::chrono::duration_cast<std::chrono::seconds>(dur).count(), 0);
tv.tv_nsec = std::max<common_t>((std::chrono::duration_cast<std::chrono::nanoseconds>(dur) %
std::chrono::seconds(1)).count(), 0);
}
#if defined(WITH_SEASTAR)
explicit utime_t(const seastar::lowres_system_clock::time_point& t) {
tv.tv_sec = std::chrono::duration_cast<std::chrono::seconds>(
t.time_since_epoch()).count();
tv.tv_nsec = std::chrono::duration_cast<std::chrono::nanoseconds>(
t.time_since_epoch() % std::chrono::seconds(1)).count();
}
explicit operator seastar::lowres_system_clock::time_point() const noexcept {
using clock_t = seastar::lowres_system_clock;
return clock_t::time_point{std::chrono::duration_cast<clock_t::duration>(
std::chrono::seconds{tv.tv_sec} + std::chrono::nanoseconds{tv.tv_nsec})};
}
#endif
utime_t(const struct timeval &v) {
set_from_timeval(&v);
}
utime_t(const struct timeval *v) {
set_from_timeval(v);
}
void to_timespec(struct timespec *ts) const {
ts->tv_sec = tv.tv_sec;
ts->tv_nsec = tv.tv_nsec;
}
void set_from_double(double d) {
tv.tv_sec = (__u32)trunc(d);
tv.tv_nsec = (__u32)((d - (double)tv.tv_sec) * 1000000000.0);
}
ceph::real_time to_real_time() const {
ceph_timespec ts;
encode_timeval(&ts);
return ceph::real_clock::from_ceph_timespec(ts);
}
// accessors
time_t sec() const { return tv.tv_sec; }
long usec() const { return tv.tv_nsec/1000; }
int nsec() const { return tv.tv_nsec; }
// ref accessors/modifiers
__u32& sec_ref() { return tv.tv_sec; }
__u32& nsec_ref() { return tv.tv_nsec; }
uint64_t to_nsec() const {
return (uint64_t)tv.tv_nsec + (uint64_t)tv.tv_sec * 1000000000ull;
}
uint64_t to_msec() const {
return (uint64_t)tv.tv_nsec / 1000000ull + (uint64_t)tv.tv_sec * 1000ull;
}
void copy_to_timeval(struct timeval *v) const {
v->tv_sec = tv.tv_sec;
v->tv_usec = tv.tv_nsec/1000;
}
void set_from_timeval(const struct timeval *v) {
tv.tv_sec = v->tv_sec;
tv.tv_nsec = v->tv_usec*1000;
}
void padding_check() {
static_assert(
sizeof(utime_t) ==
sizeof(tv.tv_sec) +
sizeof(tv.tv_nsec)
,
"utime_t have padding");
}
void encode(ceph::buffer::list &bl) const {
#if defined(CEPH_LITTLE_ENDIAN)
bl.append((char *)(this), sizeof(__u32) + sizeof(__u32));
#else
using ceph::encode;
encode(tv.tv_sec, bl);
encode(tv.tv_nsec, bl);
#endif
}
void decode(ceph::buffer::list::const_iterator &p) {
#if defined(CEPH_LITTLE_ENDIAN)
p.copy(sizeof(__u32) + sizeof(__u32), (char *)(this));
#else
using ceph::decode;
decode(tv.tv_sec, p);
decode(tv.tv_nsec, p);
#endif
}
DENC(utime_t, v, p) {
denc(v.tv.tv_sec, p);
denc(v.tv.tv_nsec, p);
}
void dump(ceph::Formatter *f) const;
static void generate_test_instances(std::list<utime_t*>& o);
void encode_timeval(struct ceph_timespec *t) const {
t->tv_sec = tv.tv_sec;
t->tv_nsec = tv.tv_nsec;
}
void decode_timeval(const struct ceph_timespec *t) {
tv.tv_sec = t->tv_sec;
tv.tv_nsec = t->tv_nsec;
}
utime_t round_to_minute() {
struct tm bdt;
time_t tt = sec();
localtime_r(&tt, &bdt);
bdt.tm_sec = 0;
tt = mktime(&bdt);
return utime_t(tt, 0);
}
utime_t round_to_hour() {
struct tm bdt;
time_t tt = sec();
localtime_r(&tt, &bdt);
bdt.tm_sec = 0;
bdt.tm_min = 0;
tt = mktime(&bdt);
return utime_t(tt, 0);
}
utime_t round_to_day() {
struct tm bdt;
time_t tt = sec();
localtime_r(&tt, &bdt);
bdt.tm_sec = 0;
bdt.tm_min = 0;
bdt.tm_hour = 0;
tt = mktime(&bdt);
return utime_t(tt, 0);
}
// cast to double
operator double() const {
return (double)sec() + ((double)nsec() / 1000000000.0f);
}
operator ceph_timespec() const {
ceph_timespec ts;
ts.tv_sec = sec();
ts.tv_nsec = nsec();
return ts;
}
void sleep() const {
struct timespec ts;
to_timespec(&ts);
nanosleep(&ts, NULL);
}
// output
std::ostream& gmtime(std::ostream& out, bool legacy_form=false) const {
out.setf(std::ios::right);
char oldfill = out.fill();
out.fill('0');
if (sec() < ((time_t)(60*60*24*365*10))) {
// raw seconds. this looks like a relative time.
out << (long)sec() << "." << std::setw(6) << usec();
} else {
// this looks like an absolute time.
// conform to http://en.wikipedia.org/wiki/ISO_8601
struct tm bdt;
time_t tt = sec();
gmtime_r(&tt, &bdt);
out << std::setw(4) << (bdt.tm_year+1900) // 2007 -> '07'
<< '-' << std::setw(2) << (bdt.tm_mon+1)
<< '-' << std::setw(2) << bdt.tm_mday;
if (legacy_form) {
out << ' ';
} else {
out << 'T';
}
out << std::setw(2) << bdt.tm_hour
<< ':' << std::setw(2) << bdt.tm_min
<< ':' << std::setw(2) << bdt.tm_sec;
out << "." << std::setw(6) << usec();
out << "Z";
}
out.fill(oldfill);
out.unsetf(std::ios::right);
return out;
}
// output
std::ostream& gmtime_nsec(std::ostream& out) const {
out.setf(std::ios::right);
char oldfill = out.fill();
out.fill('0');
if (sec() < ((time_t)(60*60*24*365*10))) {
// raw seconds. this looks like a relative time.
out << (long)sec() << "." << std::setw(6) << usec();
} else {
// this looks like an absolute time.
// conform to http://en.wikipedia.org/wiki/ISO_8601
struct tm bdt;
time_t tt = sec();
gmtime_r(&tt, &bdt);
out << std::setw(4) << (bdt.tm_year+1900) // 2007 -> '07'
<< '-' << std::setw(2) << (bdt.tm_mon+1)
<< '-' << std::setw(2) << bdt.tm_mday
<< 'T'
<< std::setw(2) << bdt.tm_hour
<< ':' << std::setw(2) << bdt.tm_min
<< ':' << std::setw(2) << bdt.tm_sec;
out << "." << std::setw(9) << nsec();
out << "Z";
}
out.fill(oldfill);
out.unsetf(std::ios::right);
return out;
}
// output
std::ostream& asctime(std::ostream& out) const {
out.setf(std::ios::right);
char oldfill = out.fill();
out.fill('0');
if (sec() < ((time_t)(60*60*24*365*10))) {
// raw seconds. this looks like a relative time.
out << (long)sec() << "." << std::setw(6) << usec();
} else {
// this looks like an absolute time.
struct tm bdt;
time_t tt = sec();
gmtime_r(&tt, &bdt);
char buf[128];
asctime_r(&bdt, buf);
int len = strlen(buf);
if (buf[len - 1] == '\n')
buf[len - 1] = '\0';
out << buf;
}
out.fill(oldfill);
out.unsetf(std::ios::right);
return out;
}
std::ostream& localtime(std::ostream& out, bool legacy_form=false) const {
out.setf(std::ios::right);
char oldfill = out.fill();
out.fill('0');
if (sec() < ((time_t)(60*60*24*365*10))) {
// raw seconds. this looks like a relative time.
out << (long)sec() << "." << std::setw(6) << usec();
} else {
// this looks like an absolute time.
// conform to http://en.wikipedia.org/wiki/ISO_8601
struct tm bdt;
time_t tt = sec();
localtime_r(&tt, &bdt);
out << std::setw(4) << (bdt.tm_year+1900) // 2007 -> '07'
<< '-' << std::setw(2) << (bdt.tm_mon+1)
<< '-' << std::setw(2) << bdt.tm_mday;
if (legacy_form) {
out << ' ';
} else {
out << 'T';
}
out << std::setw(2) << bdt.tm_hour
<< ':' << std::setw(2) << bdt.tm_min
<< ':' << std::setw(2) << bdt.tm_sec;
out << "." << std::setw(6) << usec();
if (!legacy_form) {
char buf[32] = { 0 };
strftime(buf, sizeof(buf), "%z", &bdt);
out << buf;
}
}
out.fill(oldfill);
out.unsetf(std::ios::right);
return out;
}
static int invoke_date(const std::string& date_str, utime_t *result) {
char buf[256];
SubProcess bin_date("/bin/date", SubProcess::CLOSE, SubProcess::PIPE,
SubProcess::KEEP);
bin_date.add_cmd_args("-d", date_str.c_str(), "+%s %N", NULL);
int r = bin_date.spawn();
if (r < 0) return r;
ssize_t n = safe_read(bin_date.get_stdout(), buf, sizeof(buf));
r = bin_date.join();
if (r || n <= 0) return -EINVAL;
uint64_t epoch, nsec;
std::istringstream iss(buf);
iss >> epoch;
iss >> nsec;
*result = utime_t(epoch, nsec);
return 0;
}
static int parse_date(const std::string& date, uint64_t *epoch, uint64_t *nsec,
std::string *out_date=nullptr,
std::string *out_time=nullptr) {
struct tm tm;
memset(&tm, 0, sizeof(tm));
if (nsec)
*nsec = 0;
const char *p = strptime(date.c_str(), "%Y-%m-%d", &tm);
if (p) {
if (*p == ' ' || *p == 'T') {
p++;
// strptime doesn't understand fractional/decimal seconds, and
// it also only takes format chars or literals, so we have to
// get creative.
char fmt[32] = {0};
strncpy(fmt, p, sizeof(fmt) - 1);
fmt[0] = '%';
fmt[1] = 'H';
fmt[2] = ':';
fmt[3] = '%';
fmt[4] = 'M';
fmt[6] = '%';
fmt[7] = 'S';
const char *subsec = 0;
char *q = fmt + 8;
if (*q == '.') {
++q;
subsec = p + 9;
q = fmt + 9;
while (*q && isdigit(*q)) {
++q;
}
}
// look for tz...
if (*q == '-' || *q == '+') {
*q = '%';
*(q+1) = 'z';
*(q+2) = 0;
}
p = strptime(p, fmt, &tm);
if (!p) {
return -EINVAL;
}
if (nsec && subsec) {
unsigned i;
char buf[10]; /* 9 digit + null termination */
for (i = 0; (i < sizeof(buf) - 1) && isdigit(*subsec); ++i, ++subsec) {
buf[i] = *subsec;
}
for (; i < sizeof(buf) - 1; ++i) {
buf[i] = '0';
}
buf[i] = '\0';
std::string err;
*nsec = (uint64_t)strict_strtol(buf, 10, &err);
if (!err.empty()) {
return -EINVAL;
}
}
}
} else {
int sec, usec;
int r = sscanf(date.c_str(), "%d.%d", &sec, &usec);
if (r != 2) {
return -EINVAL;
}
time_t tt = sec;
gmtime_r(&tt, &tm);
if (nsec) {
*nsec = (uint64_t)usec * 1000;
}
}
#ifndef _WIN32
// apply the tm_gmtoff manually below, since none of mktime,
// gmtime, and localtime seem to do it. zero it out here just in
// case some other libc *does* apply it. :(
auto gmtoff = tm.tm_gmtoff;
tm.tm_gmtoff = 0;
#else
auto gmtoff = _timezone;
#endif /* _WIN32 */
time_t t = internal_timegm(&tm);
if (epoch)
*epoch = (uint64_t)t;
*epoch -= gmtoff;
if (out_date) {
char buf[32];
strftime(buf, sizeof(buf), "%Y-%m-%d", &tm);
*out_date = buf;
}
if (out_time) {
char buf[32];
strftime(buf, sizeof(buf), "%H:%M:%S", &tm);
*out_time = buf;
}
return 0;
}
bool parse(const std::string& s) {
uint64_t epoch, nsec;
int r = parse_date(s, &epoch, &nsec);
if (r < 0) {
return false;
}
*this = utime_t(epoch, nsec);
return true;
}
};
WRITE_CLASS_ENCODER(utime_t)
WRITE_CLASS_DENC(utime_t)
// arithmetic operators
inline utime_t operator+(const utime_t& l, const utime_t& r) {
__u64 sec = (__u64)l.sec() + r.sec();
return utime_t(cap_to_u32_max(sec), l.nsec() + r.nsec());
}
inline utime_t& operator+=(utime_t& l, const utime_t& r) {
l.sec_ref() = cap_to_u32_max((__u64)l.sec() + r.sec());
l.nsec_ref() += r.nsec();
l.normalize();
return l;
}
inline utime_t& operator+=(utime_t& l, double f) {
double fs = trunc(f);
double ns = (f - fs) * 1000000000.0;
l.sec_ref() = cap_to_u32_max(l.sec() + (__u64)fs);
l.nsec_ref() += (long)ns;
l.normalize();
return l;
}
inline utime_t operator-(const utime_t& l, const utime_t& r) {
return utime_t( l.sec() - r.sec() - (l.nsec()<r.nsec() ? 1:0),
l.nsec() - r.nsec() + (l.nsec()<r.nsec() ? 1000000000:0) );
}
inline utime_t& operator-=(utime_t& l, const utime_t& r) {
l.sec_ref() -= r.sec();
if (l.nsec() >= r.nsec())
l.nsec_ref() -= r.nsec();
else {
l.nsec_ref() += 1000000000L - r.nsec();
l.sec_ref()--;
}
return l;
}
inline utime_t& operator-=(utime_t& l, double f) {
double fs = trunc(f);
double ns = (f - fs) * 1000000000.0;
l.sec_ref() -= (long)fs;
long nsl = (long)ns;
if (nsl) {
l.sec_ref()--;
l.nsec_ref() = 1000000000L + l.nsec_ref() - nsl;
}
l.normalize();
return l;
}
// comparators
inline bool operator>(const utime_t& a, const utime_t& b)
{
return (a.sec() > b.sec()) || (a.sec() == b.sec() && a.nsec() > b.nsec());
}
inline bool operator<=(const utime_t& a, const utime_t& b)
{
return !(operator>(a, b));
}
inline bool operator<(const utime_t& a, const utime_t& b)
{
return (a.sec() < b.sec()) || (a.sec() == b.sec() && a.nsec() < b.nsec());
}
inline bool operator>=(const utime_t& a, const utime_t& b)
{
return !(operator<(a, b));
}
inline bool operator==(const utime_t& a, const utime_t& b)
{
return a.sec() == b.sec() && a.nsec() == b.nsec();
}
inline bool operator!=(const utime_t& a, const utime_t& b)
{
return a.sec() != b.sec() || a.nsec() != b.nsec();
}
// output
// ostream
inline std::ostream& operator<<(std::ostream& out, const utime_t& t)
{
return t.localtime(out);
}
inline std::string utimespan_str(const utime_t& age) {
auto age_ts = ceph::timespan(age.nsec()) + std::chrono::seconds(age.sec());
return ceph::timespan_str(age_ts);
}
#endif
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