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windows.rs
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// Copyright 2012-2014 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
use std::cmp::Ordering;
use std::mem::MaybeUninit;
use std::ptr;
use super::win_bindings::{GetTimeZoneInformationForYear, SYSTEMTIME, TIME_ZONE_INFORMATION};
use crate::offset::local::{lookup_with_dst_transitions, Transition};
use crate::{Datelike, FixedOffset, MappedLocalTime, NaiveDate, NaiveDateTime, NaiveTime, Weekday};
// We don't use `SystemTimeToTzSpecificLocalTime` because it doesn't support the same range of dates
// as Chrono. Also it really isn't that difficult to work out the correct offset from the provided
// DST rules.
//
// This method uses `overflowing_sub_offset` because it is no problem if the transition time in UTC
// falls a couple of hours inside the buffer space around the `NaiveDateTime` range (although it is
// very theoretical to have a transition at midnight around `NaiveDate::(MIN|MAX)`.
pub(super) fn offset_from_utc_datetime(utc: &NaiveDateTime) -> MappedLocalTime<FixedOffset> {
// Using a `TzInfo` based on the year of an UTC datetime is technically wrong, we should be
// using the rules for the year of the corresponding local time. But this matches what
// `SystemTimeToTzSpecificLocalTime` is documented to do.
let tz_info = match TzInfo::for_year(utc.year()) {
Some(tz_info) => tz_info,
None => return MappedLocalTime::None,
};
let offset = match (tz_info.std_transition, tz_info.dst_transition) {
(Some(std_transition), Some(dst_transition)) => {
let std_transition_utc = std_transition.overflowing_sub_offset(tz_info.dst_offset);
let dst_transition_utc = dst_transition.overflowing_sub_offset(tz_info.std_offset);
if dst_transition_utc < std_transition_utc {
match utc >= &dst_transition_utc && utc < &std_transition_utc {
true => tz_info.dst_offset,
false => tz_info.std_offset,
}
} else {
match utc >= &std_transition_utc && utc < &dst_transition_utc {
true => tz_info.std_offset,
false => tz_info.dst_offset,
}
}
}
(Some(std_transition), None) => {
let std_transition_utc = std_transition.overflowing_sub_offset(tz_info.dst_offset);
match utc < &std_transition_utc {
true => tz_info.dst_offset,
false => tz_info.std_offset,
}
}
(None, Some(dst_transition)) => {
let dst_transition_utc = dst_transition.overflowing_sub_offset(tz_info.std_offset);
match utc < &dst_transition_utc {
true => tz_info.std_offset,
false => tz_info.dst_offset,
}
}
(None, None) => tz_info.std_offset,
};
MappedLocalTime::Single(offset)
}
// We don't use `TzSpecificLocalTimeToSystemTime` because it doesn't let us choose how to handle
// ambiguous cases (during a DST transition). Instead we get the timezone information for the
// current year and compute it ourselves, like we do on Unix.
pub(super) fn offset_from_local_datetime(local: &NaiveDateTime) -> MappedLocalTime<FixedOffset> {
let tz_info = match TzInfo::for_year(local.year()) {
Some(tz_info) => tz_info,
None => return MappedLocalTime::None,
};
// Create a sorted slice of transitions and use `lookup_with_dst_transitions`.
match (tz_info.std_transition, tz_info.dst_transition) {
(Some(std_transition), Some(dst_transition)) => {
let std_transition =
Transition::new(std_transition, tz_info.dst_offset, tz_info.std_offset);
let dst_transition =
Transition::new(dst_transition, tz_info.std_offset, tz_info.dst_offset);
let transitions = match std_transition.cmp(&dst_transition) {
Ordering::Less => [std_transition, dst_transition],
Ordering::Greater => [dst_transition, std_transition],
Ordering::Equal => {
// This doesn't make sense. Let's just return the standard offset.
return MappedLocalTime::Single(tz_info.std_offset);
}
};
lookup_with_dst_transitions(&transitions, *local)
}
(Some(std_transition), None) => {
let transitions =
[Transition::new(std_transition, tz_info.dst_offset, tz_info.std_offset)];
lookup_with_dst_transitions(&transitions, *local)
}
(None, Some(dst_transition)) => {
let transitions =
[Transition::new(dst_transition, tz_info.std_offset, tz_info.dst_offset)];
lookup_with_dst_transitions(&transitions, *local)
}
(None, None) => MappedLocalTime::Single(tz_info.std_offset),
}
}
// The basis for Windows timezone and DST support has been in place since Windows 2000. It does not
// allow for complex rules like the IANA timezone database:
// - A timezone has the same base offset the whole year.
// - There seem to be either zero or two DST transitions (but we support having just one).
// - As of Vista(?) only years from 2004 until a few years into the future are supported.
// - All other years get the base settings, which seem to be that of the current year.
//
// These details don't matter much, we just work with the offsets and transition dates Windows
// returns through `GetTimeZoneInformationForYear` for a particular year.
struct TzInfo {
// Offset from UTC during standard time.
std_offset: FixedOffset,
// Offset from UTC during daylight saving time.
dst_offset: FixedOffset,
// Transition from standard time to daylight saving time, given in local standard time.
std_transition: Option<NaiveDateTime>,
// Transition from daylight saving time to standard time, given in local daylight saving time.
dst_transition: Option<NaiveDateTime>,
}
impl TzInfo {
fn for_year(year: i32) -> Option<TzInfo> {
// The API limits years to 1601..=30827.
// Working with timezones and daylight saving time this far into the past or future makes
// little sense. But whatever is extrapolated for 1601 or 30827 is what can be extrapolated
// for years beyond.
let ref_year = year.clamp(1601, 30827) as u16;
let tz_info = unsafe {
let mut tz_info = MaybeUninit::<TIME_ZONE_INFORMATION>::uninit();
if GetTimeZoneInformationForYear(ref_year, ptr::null_mut(), tz_info.as_mut_ptr()) == 0 {
return None;
}
tz_info.assume_init()
};
let std_offset = (tz_info.Bias)
.checked_add(tz_info.StandardBias)
.and_then(|o| o.checked_mul(60))
.and_then(FixedOffset::west_opt)?;
let dst_offset = (tz_info.Bias)
.checked_add(tz_info.DaylightBias)
.and_then(|o| o.checked_mul(60))
.and_then(FixedOffset::west_opt)?;
Some(TzInfo {
std_offset,
dst_offset,
std_transition: naive_date_time_from_system_time(tz_info.StandardDate, year).ok()?,
dst_transition: naive_date_time_from_system_time(tz_info.DaylightDate, year).ok()?,
})
}
}
/// Resolve a `SYSTEMTIME` object to an `Option<NaiveDateTime>`.
///
/// A `SYSTEMTIME` within a `TIME_ZONE_INFORMATION` struct can be zero to indicate there is no
/// transition.
/// If it has year, month and day values it is a concrete date.
/// If the year is missing the `SYSTEMTIME` is a rule, which this method resolves for the provided
/// year. A rule has a month, weekday, and nth weekday of the month as components.
///
/// Returns `Err` if any of the values is invalid, which should never happen.
fn naive_date_time_from_system_time(
st: SYSTEMTIME,
year: i32,
) -> Result<Option<NaiveDateTime>, ()> {
if st.wYear == 0 && st.wMonth == 0 {
return Ok(None);
}
let time = NaiveTime::from_hms_milli_opt(
st.wHour as u32,
st.wMinute as u32,
st.wSecond as u32,
st.wMilliseconds as u32,
)
.ok_or(())?;
if st.wYear != 0 {
// We have a concrete date.
let date =
NaiveDate::from_ymd_opt(st.wYear as i32, st.wMonth as u32, st.wDay as u32).ok_or(())?;
return Ok(Some(date.and_time(time)));
}
// Resolve a rule with month, weekday, and nth weekday of the month to a date in the current
// year.
let weekday = match st.wDayOfWeek {
0 => Weekday::Sun,
1 => Weekday::Mon,
2 => Weekday::Tue,
3 => Weekday::Wed,
4 => Weekday::Thu,
5 => Weekday::Fri,
6 => Weekday::Sat,
_ => return Err(()),
};
let nth_day = match st.wDay {
1..=5 => st.wDay as u8,
_ => return Err(()),
};
let date = NaiveDate::from_weekday_of_month_opt(year, st.wMonth as u32, weekday, nth_day)
.or_else(|| NaiveDate::from_weekday_of_month_opt(year, st.wMonth as u32, weekday, 4))
.ok_or(())?; // `st.wMonth` must be invalid
Ok(Some(date.and_time(time)))
}
#[cfg(test)]
mod tests {
use crate::offset::local::win_bindings::{
SystemTimeToFileTime, TzSpecificLocalTimeToSystemTime, FILETIME, SYSTEMTIME,
};
use crate::{DateTime, FixedOffset, Local, NaiveDate, NaiveDateTime, TimeDelta};
use crate::{Datelike, TimeZone, Timelike};
use std::mem::MaybeUninit;
use std::ptr;
#[test]
fn verify_against_tz_specific_local_time_to_system_time() {
// The implementation in Windows itself is the source of truth on how to work with the OS
// timezone information. This test compares for every hour over a period of 125 years our
// implementation to `TzSpecificLocalTimeToSystemTime`.
//
// This uses parts of a previous Windows `Local` implementation in chrono.
fn from_local_time(dt: &NaiveDateTime) -> DateTime<Local> {
let st = system_time_from_naive_date_time(dt);
let utc_time = local_to_utc_time(&st);
let utc_secs = system_time_as_unix_seconds(&utc_time);
let local_secs = system_time_as_unix_seconds(&st);
let offset = (local_secs - utc_secs) as i32;
let offset = FixedOffset::east_opt(offset).unwrap();
DateTime::from_naive_utc_and_offset(*dt - offset, offset)
}
fn system_time_from_naive_date_time(dt: &NaiveDateTime) -> SYSTEMTIME {
SYSTEMTIME {
// Valid values: 1601-30827
wYear: dt.year() as u16,
// Valid values:1-12
wMonth: dt.month() as u16,
// Valid values: 0-6, starting Sunday.
// NOTE: enum returns 1-7, starting Monday, so we are
// off here, but this is not currently used in local.
wDayOfWeek: dt.weekday() as u16,
// Valid values: 1-31
wDay: dt.day() as u16,
// Valid values: 0-23
wHour: dt.hour() as u16,
// Valid values: 0-59
wMinute: dt.minute() as u16,
// Valid values: 0-59
wSecond: dt.second() as u16,
// Valid values: 0-999
wMilliseconds: 0,
}
}
fn local_to_utc_time(local: &SYSTEMTIME) -> SYSTEMTIME {
let mut sys_time = MaybeUninit::<SYSTEMTIME>::uninit();
unsafe { TzSpecificLocalTimeToSystemTime(ptr::null(), local, sys_time.as_mut_ptr()) };
// SAFETY: TzSpecificLocalTimeToSystemTime must have succeeded at this point, so we can
// assume the value is initialized.
unsafe { sys_time.assume_init() }
}
const HECTONANOSECS_IN_SEC: i64 = 10_000_000;
const HECTONANOSEC_TO_UNIX_EPOCH: i64 = 11_644_473_600 * HECTONANOSECS_IN_SEC;
fn system_time_as_unix_seconds(st: &SYSTEMTIME) -> i64 {
let mut init = MaybeUninit::<FILETIME>::uninit();
unsafe {
SystemTimeToFileTime(st, init.as_mut_ptr());
}
// SystemTimeToFileTime must have succeeded at this point, so we can assume the value is
// initialized.
let filetime = unsafe { init.assume_init() };
let bit_shift =
((filetime.dwHighDateTime as u64) << 32) | (filetime.dwLowDateTime as u64);
(bit_shift as i64 - HECTONANOSEC_TO_UNIX_EPOCH) / HECTONANOSECS_IN_SEC
}
let mut date = NaiveDate::from_ymd_opt(1975, 1, 1).unwrap().and_hms_opt(0, 30, 0).unwrap();
while date.year() < 2078 {
// Windows doesn't handle non-existing dates, it just treats it as valid.
if let Some(our_result) = Local.from_local_datetime(&date).earliest() {
assert_eq!(from_local_time(&date), our_result);
}
date += TimeDelta::try_hours(1).unwrap();
}
}
}