// Take a look at the license at the top of the repository in the LICENSE file. use glib::translate::*; use std::cmp; use std::convert; use std::fmt; use crate::DateTime; // Validate that the given values result in a valid DateTime fn validate( tzoffset: Option, year: i32, month: Option, day: Option, hour: Option, minute: Option, seconds: Option, ) -> Result<(), glib::BoolError> { skip_assert_initialized!(); // Check for valid ranges if year <= 0 || year > 9999 { return Err(glib::bool_error!( "Can't create DateTime: Year out of range" )); } if let Some(month) = month { if month <= 0 || month > 12 { return Err(glib::bool_error!( "Can't create DateTime: Month out of range" )); } } if let Some(day) = day { if day <= 0 || day > 31 { return Err(glib::bool_error!("Can't create DateTime: Day out of range")); } } if let Some(hour) = hour { if hour < 0 || hour >= 24 { return Err(glib::bool_error!( "Can't create DateTime: Hour out of range" )); } } if let Some(minute) = minute { if minute < 0 || minute >= 60 { return Err(glib::bool_error!( "Can't create DateTime: Minute out of range" )); } } if let Some(seconds) = seconds { if seconds < 0.0 || seconds >= 60.0 { return Err(glib::bool_error!( "Can't create DateTime: Seconds out of range" )); } } if let Some(tzoffset) = tzoffset { if tzoffset < -12.0 || tzoffset > 12.0 { return Err(glib::bool_error!( "Can't create DateTime: Timezone offset out of range" )); } } // If day is provided, month also has to be provided if day.is_some() && month.is_none() { return Err(glib::bool_error!( "Can't create DateTime: Need to provide month if providing day" )); } // If hour is provided, day also has to be provided if hour.is_some() && day.is_none() { return Err(glib::bool_error!( "Can't create DateTime: Need to provide day if providing hour" )); } // If minutes are provided, hours also need to be provided and the other way around if hour.is_none() && minute.is_some() { return Err(glib::bool_error!( "Can't create DateTime: Need to provide both hour and minute or neither" )); } if minute.is_some() && hour.is_none() { return Err(glib::bool_error!( "Can't create DateTime: Need to provide both hour and minute or neither" )); } // If seconds or tzoffset are provided then also hours and minutes must be provided if (seconds.is_some() || tzoffset.is_some()) && (hour.is_none() || minute.is_none()) { return Err(glib::bool_error!("Can't create DateTime: Need to provide hour and minute if providing seconds or timezone offset")); } Ok(()) } impl DateTime { #[doc(alias = "gst_date_time_new")] pub fn new< TZ: Into>, Y: Into, MO: Into>, D: Into>, H: Into>, MI: Into>, S: Into>, >( tzoffset: TZ, year: Y, month: MO, day: D, hour: H, minute: MI, seconds: S, ) -> Result { assert_initialized_main_thread!(); let tzoffset = tzoffset.into(); let year = year.into(); let month = month.into(); let day = day.into(); let hour = hour.into(); let minute = minute.into(); let seconds = seconds.into(); validate(tzoffset, year, month, day, hour, minute, seconds)?; unsafe { Option::<_>::from_glib_full(ffi::gst_date_time_new( tzoffset.unwrap_or(0.0), year, month.unwrap_or(-1), day.unwrap_or(-1), hour.unwrap_or(-1), minute.unwrap_or(-1), seconds.unwrap_or(-1.0), )) .ok_or_else(|| glib::bool_error!("Can't create DateTime")) } } #[doc(alias = "gst_date_time_new_local_time")] pub fn new_local_time< Y: Into, MO: Into>, D: Into>, H: Into>, MI: Into>, S: Into>, >( year: Y, month: MO, day: D, hour: H, minute: MI, seconds: S, ) -> Result { assert_initialized_main_thread!(); let year = year.into(); let month = month.into(); let day = day.into(); let hour = hour.into(); let minute = minute.into(); let seconds = seconds.into(); validate(None, year, month, day, hour, minute, seconds)?; unsafe { Option::<_>::from_glib_full(ffi::gst_date_time_new_local_time( year, month.unwrap_or(-1), day.unwrap_or(-1), hour.unwrap_or(-1), minute.unwrap_or(-1), seconds.unwrap_or(-1.0), )) .ok_or_else(|| glib::bool_error!("Can't create DateTime")) } } #[doc(alias = "gst_date_time_new_y")] pub fn new_y(year: i32) -> Result { assert_initialized_main_thread!(); validate(None, year, None, None, None, None, None)?; unsafe { Option::<_>::from_glib_full(ffi::gst_date_time_new_y(year)) .ok_or_else(|| glib::bool_error!("Can't create DateTime")) } } #[doc(alias = "gst_date_time_new_ym")] pub fn new_ym(year: i32, month: i32) -> Result { assert_initialized_main_thread!(); validate(None, year, Some(month), None, None, None, None)?; unsafe { Option::<_>::from_glib_full(ffi::gst_date_time_new_ym(year, month)) .ok_or_else(|| glib::bool_error!("Can't create DateTime")) } } #[doc(alias = "gst_date_time_new_ymd")] pub fn new_ymd(year: i32, month: i32, day: i32) -> Result { assert_initialized_main_thread!(); validate(None, year, Some(month), Some(day), None, None, None)?; unsafe { Option::<_>::from_glib_full(ffi::gst_date_time_new_ymd(year, month, day)) .ok_or_else(|| glib::bool_error!("Can't create DateTime")) } } #[doc(alias = "get_day")] #[doc(alias = "gst_date_time_get_day")] pub fn day(&self) -> Option { if !self.has_day() { return None; } unsafe { Some(ffi::gst_date_time_get_day(self.to_glib_none().0)) } } #[doc(alias = "get_hour")] #[doc(alias = "gst_date_time_get_hour")] pub fn hour(&self) -> Option { if !self.has_time() { return None; } unsafe { Some(ffi::gst_date_time_get_hour(self.to_glib_none().0)) } } #[doc(alias = "get_microsecond")] #[doc(alias = "gst_date_time_get_microsecond")] pub fn microsecond(&self) -> Option { if !self.has_second() { return None; } unsafe { Some(ffi::gst_date_time_get_microsecond(self.to_glib_none().0)) } } #[doc(alias = "get_minute")] #[doc(alias = "gst_date_time_get_minute")] pub fn minute(&self) -> Option { if !self.has_time() { return None; } unsafe { Some(ffi::gst_date_time_get_minute(self.to_glib_none().0)) } } #[doc(alias = "get_month")] #[doc(alias = "gst_date_time_get_month")] pub fn month(&self) -> Option { if !self.has_month() { return None; } unsafe { Some(ffi::gst_date_time_get_month(self.to_glib_none().0)) } } #[doc(alias = "get_second")] #[doc(alias = "gst_date_time_get_second")] pub fn second(&self) -> Option { if !self.has_second() { return None; } unsafe { Some(ffi::gst_date_time_get_second(self.to_glib_none().0)) } } #[doc(alias = "get_time_zone_offset")] #[doc(alias = "gst_date_time_get_time_zone_offset")] pub fn time_zone_offset(&self) -> Option { if !self.has_time() { return None; } unsafe { Some(ffi::gst_date_time_get_time_zone_offset( self.to_glib_none().0, )) } } pub fn to_utc(&self) -> Result { if !self.has_time() { // No time => no TZ offset return Ok(self.clone()); } assert!(self.has_year() && self.has_month() && self.has_day() && self.has_time()); // Can instantiate `gst::DateTime` without seconds using `gst::DateTime::new` // with `-1f64` for the `second` argument // however, the resulting instance can't be translated to `glib::DateTime` if self.has_second() { self.to_g_date_time() .and_then(|d| d.to_utc()) .map(|d| d.into()) } else { // It would be cheaper to build a `glib::DateTime` direcly, unfortunetaly // this would require using `glib::TimeZone::new_offset` which is feature-gated // to `glib/v2_58`. So we need to build a new `gst::DateTime` with `0f64` // and then discard seconds again DateTime::new( self.time_zone_offset(), self.year(), self.month(), self.day(), self.hour(), self.minute(), Some(0.0), ) .and_then(|d| d.to_g_date_time()) .and_then(|d| d.to_utc()) .and_then(|d| { DateTime::new( None, // UTC TZ offset d.year(), Some(d.month()), Some(d.day_of_month()), Some(d.hour()), Some(d.minute()), None, // No second ) }) } } } impl cmp::PartialOrd for DateTime { // *NOTE 1:* When comparing a partially defined [`DateTime`](struct.DateTime.html) `d1` // such as *"2019/8/20"* with a [`DateTime`](struct.DateTime.html) with a time part `d2` // such as *"2019/8/20 21:10"*: // // - `d1` includes `d2`, // - neither `d1` < `d2` nor `d1` > `d2`, // - and `d1` != `d2`, // // so we can only return `None`. // // This is the reason why [`DateTime`](struct.DateTime.html) neither implements // [`Ord`](https://doc.rust-lang.org/nightly/std/cmp/trait.Ord.html) // nor [`Eq`](https://doc.rust-lang.org/nightly/std/cmp/trait.Eq.html). // // *NOTE 2:* When comparing a [`DateTime`](struct.DateTime.html) `d1` without a TZ offset // such as *"2019/8/20"* with a [`DateTime`](struct.DateTime.html) `d2` with a TZ offset // such as *"2019/8/20 21:10 +02:00"*, we can't tell in which TZ `d1` is expressed and which // time should be considered for an offset, therefore the two [`DateTime`s](struct.DateTime.html) // are compared in the same TZ. fn partial_cmp(&self, other: &Self) -> Option { #[inline] #[allow(clippy::unnecessary_wraps)] #[doc(alias = "get_cmp")] fn cmp(delta: i32) -> Option { skip_assert_initialized!(); Some(delta.cmp(&0)) } if !(self.has_year() && other.has_year()) { // Can't compare anything return None; } // Normalize to UTC only if both members have time (see note 2). let (self_norm, other_norm) = if self.has_time() && other.has_time() { (self.to_utc().ok()?, other.to_utc().ok()?) } else { (self.clone(), other.clone()) }; let year_delta = self_norm.year() - other_norm.year(); if year_delta != 0 { return cmp(year_delta); } // Same year if !self.has_month() && !other.has_month() { // Nothing left to compare return cmp(year_delta); } if !(self.has_month() && other.has_month()) { // One has month, the other doesn't => can't compare (note 1) return None; } let month_delta = self_norm.month().unwrap() - other_norm.month().unwrap(); if month_delta != 0 { return cmp(month_delta); } // Same year, same month if !self.has_day() && !other.has_day() { // Nothing left to compare return Some(cmp::Ordering::Equal); } if !(self.has_day() && other.has_day()) { // One has day, the other doesn't => can't compare (note 1) return None; } let day_delta = self_norm.day().unwrap() - other_norm.day().unwrap(); if day_delta != 0 { return cmp(day_delta); } // Same year, same month, same day if !self.has_time() && !other.has_time() { // Nothing left to compare return Some(cmp::Ordering::Equal); } if !(self.has_time() && other.has_time()) { // One has time, the other doesn't => can't compare (note 1) return None; } let hour_delta = self_norm.hour().unwrap() - other_norm.hour().unwrap(); if hour_delta != 0 { return cmp(hour_delta); } let minute_delta = self_norm.minute().unwrap() - other_norm.minute().unwrap(); if minute_delta != 0 { return cmp(minute_delta); } // Same year, same month, same day, same time if !self.has_second() && !other.has_second() { // Nothing left to compare return Some(cmp::Ordering::Equal); } if !(self.has_second() && other.has_second()) { // One has second, the other doesn't => can't compare (note 1) return None; } let second_delta = self_norm.second().unwrap() - other_norm.second().unwrap(); if second_delta != 0 { return cmp(second_delta); } cmp(self_norm.microsecond().unwrap() - other_norm.microsecond().unwrap()) } } impl cmp::PartialEq for DateTime { fn eq(&self, other: &Self) -> bool { self.partial_cmp(other) .map_or_else(|| false, |cmp| cmp == cmp::Ordering::Equal) } } impl fmt::Debug for DateTime { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { let mut debug_struct = f.debug_struct("DateTime"); if self.has_year() { debug_struct.field("year", &self.year()); } if self.has_month() { debug_struct.field("month", &self.month()); } if self.has_day() { debug_struct.field("day", &self.day()); } if self.has_time() { debug_struct.field("hour", &self.hour()); debug_struct.field("minute", &self.minute()); if self.has_second() { debug_struct.field("second", &self.second()); debug_struct.field("microsecond", &self.microsecond()); } debug_struct.field("tz_offset", &self.time_zone_offset()); } debug_struct.finish() } } impl fmt::Display for DateTime { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { f.write_str( self.to_iso8601_string() .unwrap_or_else(|_| "None".into()) .as_str(), ) } } impl<'a> From<&'a glib::DateTime> for DateTime { fn from(v: &'a glib::DateTime) -> DateTime { skip_assert_initialized!(); DateTime::from_g_date_time(v) } } impl From for DateTime { fn from(v: glib::DateTime) -> DateTime { skip_assert_initialized!(); DateTime::from_g_date_time(&v) } } impl<'a> convert::TryFrom<&'a DateTime> for glib::DateTime { type Error = glib::BoolError; fn try_from(v: &'a DateTime) -> Result { skip_assert_initialized!(); v.to_g_date_time() } } impl convert::TryFrom for glib::DateTime { type Error = glib::BoolError; fn try_from(v: DateTime) -> Result { skip_assert_initialized!(); v.to_g_date_time() } } #[cfg(test)] mod tests { use super::*; #[allow(clippy::cognitive_complexity)] #[test] fn test_to_utc() { crate::init().unwrap(); // Hour offset let utc_date_time = DateTime::new(2f32, 2019, 8, 20, 20, 9, 42.123_456f64) .unwrap() .to_utc() .unwrap(); assert_eq!(utc_date_time.year(), 2019); assert_eq!(utc_date_time.month().unwrap(), 8); assert_eq!(utc_date_time.day().unwrap(), 20); assert_eq!(utc_date_time.hour().unwrap(), 18); assert_eq!(utc_date_time.minute().unwrap(), 9); assert_eq!(utc_date_time.second().unwrap(), 42); assert_eq!(utc_date_time.microsecond().unwrap(), 123_456); // Year, month, day and hour offset let utc_date_time = DateTime::new(2f32, 2019, 1, 1, 0, 0, 42.123_456f64) .unwrap() .to_utc() .unwrap(); assert_eq!(utc_date_time.year(), 2018); assert_eq!(utc_date_time.month().unwrap(), 12); assert_eq!(utc_date_time.day().unwrap(), 31); assert_eq!(utc_date_time.hour().unwrap(), 22); assert_eq!(utc_date_time.minute().unwrap(), 0); assert_eq!(utc_date_time.second().unwrap(), 42); assert_eq!(utc_date_time.microsecond().unwrap(), 123_456); // Date without an hour (which implies no TZ) let utc_date_time = DateTime::new_ymd(2019, 1, 1).unwrap().to_utc().unwrap(); assert_eq!(utc_date_time.year(), 2019); assert_eq!(utc_date_time.month().unwrap(), 1); assert_eq!(utc_date_time.day().unwrap(), 1); assert!(!utc_date_time.has_time()); assert!(!utc_date_time.has_second()); // Date without seconds let utc_date_time = DateTime::new(2f32, 2018, 5, 28, 16, 6, None) .unwrap() .to_utc() .unwrap(); assert_eq!(utc_date_time.year(), 2018); assert_eq!(utc_date_time.month().unwrap(), 5); assert_eq!(utc_date_time.day().unwrap(), 28); assert_eq!(utc_date_time.hour().unwrap(), 14); assert_eq!(utc_date_time.minute().unwrap(), 6); assert!(!utc_date_time.has_second()); } #[test] fn test_partial_ord() { crate::init().unwrap(); // Different years assert!( DateTime::new(2f32, 2020, 8, 20, 19, 43, 42.123_456f64).unwrap() > DateTime::new(2f32, 2019, 8, 20, 19, 43, 42.123_456f64).unwrap() ); // Different months (order intentionally reversed) assert!( DateTime::new(2f32, 2019, 8, 20, 19, 43, 42.123_456f64).unwrap() < DateTime::new(2f32, 2019, 9, 19, 19, 43, 42.123_456f64).unwrap() ); // Different days assert!( DateTime::new(2f32, 2019, 8, 21, 19, 43, 42.123_456f64).unwrap() > DateTime::new(2f32, 2019, 8, 20, 19, 43, 42.123_456f64).unwrap() ); // Different hours assert!( DateTime::new(2f32, 2019, 8, 20, 19, 44, 42.123_456f64).unwrap() > DateTime::new(2f32, 2019, 8, 20, 19, 43, 42.123_456f64).unwrap() ); // Different minutes assert!( DateTime::new(2f32, 2019, 8, 20, 19, 43, 44.123_456f64).unwrap() > DateTime::new(2f32, 2019, 8, 20, 19, 43, 42.123_456f64).unwrap() ); // Different seconds assert!( DateTime::new(2f32, 2019, 8, 20, 19, 43, 43.123_456f64).unwrap() > DateTime::new(2f32, 2019, 8, 20, 19, 43, 42.123_456f64).unwrap() ); // Different micro-seconds assert!( DateTime::new(2f32, 2019, 8, 20, 19, 43, 42.123_457f64).unwrap() > DateTime::new(2f32, 2019, 8, 20, 19, 43, 42.123_456f64).unwrap() ); // Different TZ offsets assert!( DateTime::new(1f32, 2019, 8, 20, 19, 43, 42.123_456f64).unwrap() > DateTime::new(2f32, 2019, 8, 20, 19, 43, 42.123_456f64).unwrap() ); // TZ offset leading to year, month, day, hour offset assert!( DateTime::new(2f32, 2019, 1, 1, 0, 0, 0f64).unwrap() < DateTime::new(1f32, 2018, 12, 31, 23, 59, 0f64).unwrap() ); // Partially defined `DateTime` assert!(DateTime::new_ymd(2020, 8, 20).unwrap() > DateTime::new_ymd(2019, 8, 20).unwrap()); assert!(DateTime::new_ymd(2019, 9, 20).unwrap() > DateTime::new_ymd(2019, 8, 20).unwrap()); assert!(DateTime::new_ymd(2019, 8, 21).unwrap() > DateTime::new_ymd(2019, 8, 20).unwrap()); assert!(DateTime::new_ym(2020, 8).unwrap() > DateTime::new_ym(2019, 8).unwrap()); assert!(DateTime::new_ym(2019, 9).unwrap() > DateTime::new_ym(2019, 8).unwrap()); assert!(DateTime::new_ym(2019, 9).unwrap() > DateTime::new_ymd(2019, 8, 20).unwrap()); assert!(DateTime::new_y(2020).unwrap() > DateTime::new_y(2019).unwrap()); assert!(DateTime::new_ym(2020, 1).unwrap() > DateTime::new_y(2019).unwrap()); assert!( DateTime::new(2f32, 2019, 8, 20, 19, 43, 44.123_456f64).unwrap() < DateTime::new_ymd(2020, 8, 20).unwrap() ); assert!( DateTime::new_ymd(2020, 8, 20).unwrap() > DateTime::new(2f32, 2019, 8, 20, 19, 43, 44.123_456f64).unwrap() ); // Comparison occurs on the same TZ when the `DateTime` doesn't have time (note 2) assert!( DateTime::new_ymd(2020, 1, 1).unwrap() > DateTime::new(-2f32, 2019, 12, 31, 23, 59, 0f64).unwrap() ); // In the following cases, the partially defined `DateTime` is a range WRT // the fully defined `DateTime` and this range includes the fully defined `DateTime`, // but we can't tell if it's before or after and they are not equal (note 1) assert!(DateTime::new(2f32, 2019, 8, 20, 19, 43, 44.123_456f64) .unwrap() .partial_cmp(&DateTime::new_ymd(2019, 8, 20).unwrap()) .is_none()); assert!(DateTime::new_ymd(2019, 8, 20) .unwrap() .partial_cmp(&DateTime::new(2f32, 2019, 8, 20, 19, 43, 44.123_456f64).unwrap()) .is_none()); assert!(DateTime::new_ym(2019, 1) .unwrap() .partial_cmp(&DateTime::new_y(2019).unwrap()) .is_none()); } #[test] fn test_eq() { crate::init().unwrap(); assert_eq!( DateTime::new(2f32, 2018, 5, 28, 16, 6, 42.123_456f64).unwrap(), DateTime::new(2f32, 2018, 5, 28, 16, 6, 42.123_456f64).unwrap() ); assert_eq!( DateTime::new(2f32, 2018, 5, 28, 16, 6, 0f64).unwrap(), DateTime::new(2f32, 2018, 5, 28, 16, 6, 0f64).unwrap() ); assert_eq!( DateTime::new(2f32, 2018, 5, 28, 16, 6, None).unwrap(), DateTime::new(2f32, 2018, 5, 28, 16, 6, None).unwrap() ); assert_eq!( DateTime::new_ymd(2018, 5, 28).unwrap(), DateTime::new_ymd(2018, 5, 28).unwrap() ); // In the following cases, the partially defined `DateTime` is a range WRT // the fully defined `DateTime` and this range includes the fully defined `DateTime`, // but they are not equal (note 1) assert_ne!( DateTime::new_ymd(2018, 5, 28).unwrap(), DateTime::new(2f32, 2018, 5, 28, 16, 6, None).unwrap() ); assert_ne!( DateTime::new(2f32, 2018, 5, 28, 16, 6, None).unwrap(), DateTime::new_ym(2018, 5).unwrap() ); assert_ne!( DateTime::new(2f32, 2018, 5, 28, 16, 6, None).unwrap(), DateTime::new_y(2018).unwrap() ); } }