//! The implementation for Version 1 UUIDs. //! //! Note that you need feature `v1` in order to use these features. use crate::prelude::*; use core::sync::atomic; /// The number of 100 ns ticks between the UUID epoch /// `1582-10-15 00:00:00` and the Unix epoch `1970-01-01 00:00:00`. const UUID_TICKS_BETWEEN_EPOCHS: u64 = 0x01B2_1DD2_1381_4000; /// A thread-safe, stateful context for the v1 generator to help ensure /// process-wide uniqueness. #[derive(Debug)] pub struct Context { count: atomic::AtomicUsize, } /// Stores the number of nanoseconds from an epoch and a counter for ensuring /// V1 ids generated on the same host are unique. #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct Timestamp { ticks: u64, counter: u16, } impl Timestamp { /// Construct a `Timestamp` from its raw component values: an RFC4122 /// timestamp and counter. /// /// RFC4122, which defines the V1 UUID, specifies a 60-byte timestamp format /// as the number of 100-nanosecond intervals elapsed since 00:00:00.00, /// 15 Oct 1582, "the date of the Gregorian reform of the Christian /// calendar." /// /// The counter value is used to differentiate between ids generated by /// the same host computer in rapid succession (i.e. with the same observed /// time). See the [`ClockSequence`] trait for a generic interface to any /// counter generators that might be used. /// /// Internally, the timestamp is stored as a `u64`. For this reason, dates /// prior to October 1582 are not supported. /// /// [`ClockSequence`]: trait.ClockSequence.html pub const fn from_rfc4122(ticks: u64, counter: u16) -> Self { Timestamp { ticks, counter } } /// Construct a `Timestamp` from a unix timestamp and sequence-generating /// `context`. /// /// A unix timestamp represents the elapsed time since Jan 1 1970. Libc's /// `clock_gettime` and other popular implementations traditionally /// represent this duration as a `timespec`: a struct with `u64` and /// `u32` fields representing the seconds, and "subsecond" or fractional /// nanoseconds elapsed since the timestamp's second began, /// respectively. /// /// This constructs a `Timestamp` from the seconds and fractional /// nanoseconds of a unix timestamp, converting the duration since 1970 /// into the number of 100-nanosecond intervals since 00:00:00.00, 15 /// Oct 1582 specified by RFC4122 and used internally by `Timestamp`. /// /// The function is not guaranteed to produce monotonically increasing /// values however. There is a slight possibility that two successive /// equal time values could be supplied and the sequence counter wraps back /// over to 0. /// /// If uniqueness and monotonicity is required, the user is responsible for /// ensuring that the time value always increases between calls (including /// between restarts of the process and device). pub fn from_unix( context: impl ClockSequence, seconds: u64, subsec_nanos: u32, ) -> Self { let counter = context.generate_sequence(seconds, subsec_nanos); let ticks = UUID_TICKS_BETWEEN_EPOCHS + seconds * 10_000_000 + u64::from(subsec_nanos) / 100; Timestamp { ticks, counter } } /// Returns the raw RFC4122 timestamp and counter values stored by the /// `Timestamp`. /// /// The timestamp (the first, `u64` element in the tuple) represents the /// number of 100-nanosecond intervals since 00:00:00.00, 15 Oct 1582. /// The counter is used to differentiate between ids generated on the /// same host computer with the same observed time. pub const fn to_rfc4122(&self) -> (u64, u16) { (self.ticks, self.counter) } /// Returns the timestamp converted to the seconds and fractional /// nanoseconds since Jan 1 1970. /// /// Internally, the time is stored in 100-nanosecond intervals, /// thus the maximum precision represented by the fractional nanoseconds /// value is less than its unit size (100 ns vs. 1 ns). pub const fn to_unix(&self) -> (u64, u32) { ( (self.ticks - UUID_TICKS_BETWEEN_EPOCHS) / 10_000_000, ((self.ticks - UUID_TICKS_BETWEEN_EPOCHS) % 10_000_000) as u32 * 100, ) } /// Returns the timestamp converted into nanoseconds elapsed since Jan 1 /// 1970. Internally, the time is stored in 100-nanosecond intervals, /// thus the maximum precision represented is less than the units it is /// measured in (100 ns vs. 1 ns). The value returned represents the /// same duration as [`Timestamp::to_unix`]; this provides it in nanosecond /// units for convenience. pub const fn to_unix_nanos(&self) -> u64 { (self.ticks - UUID_TICKS_BETWEEN_EPOCHS) * 100 } } /// A trait that abstracts over generation of UUID v1 "Clock Sequence" values. pub trait ClockSequence { /// Return a 16-bit number that will be used as the "clock sequence" in /// the UUID. The number must be different if the time has changed since /// the last time a clock sequence was requested. fn generate_sequence(&self, seconds: u64, subsec_nanos: u32) -> u16; } impl<'a, T: ClockSequence + ?Sized> ClockSequence for &'a T { fn generate_sequence(&self, seconds: u64, subsec_nanos: u32) -> u16 { (**self).generate_sequence(seconds, subsec_nanos) } } impl Uuid { /// Create a new UUID (version 1) using a time value + sequence + /// *NodeId*. /// /// When generating [`Timestamp`]s using a [`ClockSequence`], this function /// is only guaranteed to produce unique values if the following conditions /// hold: /// /// 1. The *NodeId* is unique for this process, /// 2. The *Context* is shared across all threads which are generating v1 /// UUIDs, /// 3. The [`ClockSequence`] implementation reliably returns unique /// clock sequences (this crate provides [`Context`] for this /// purpose. However you can create your own [`ClockSequence`] /// implementation, if [`Context`] does not meet your needs). /// /// The NodeID must be exactly 6 bytes long. /// /// Note that usage of this method requires the `v1` feature of this crate /// to be enabled. /// /// # Examples /// /// A UUID can be created from a unix [`Timestamp`] with a /// [`ClockSequence`]: /// /// ```rust /// use uuid::v1::{Timestamp, Context}; /// use uuid::Uuid; /// /// let context = Context::new(42); /// let ts = Timestamp::from_unix(&context, 1497624119, 1234); /// let uuid = Uuid::new_v1(ts, &[1, 2, 3, 4, 5, 6]).expect("failed to generate UUID"); /// /// assert_eq!( /// uuid.to_hyphenated().to_string(), /// "f3b4958c-52a1-11e7-802a-010203040506" /// ); /// ``` /// /// The timestamp can also be created manually as per RFC4122: /// /// ``` /// use uuid::v1::{Timestamp, Context}; /// use uuid::Uuid; /// /// let context = Context::new(42); /// let ts = Timestamp::from_rfc4122(1497624119, 0); /// let uuid = Uuid::new_v1(ts, &[1, 2, 3, 4, 5, 6]).expect("failed to generate UUID"); /// /// assert_eq!( /// uuid.to_hyphenated().to_string(), /// "5943ee37-0000-1000-8000-010203040506" /// ); /// ``` /// /// [`Timestamp`]: v1/struct.Timestamp.html /// [`ClockSequence`]: v1/struct.ClockSequence.html /// [`Context`]: v1/struct.Context.html pub fn new_v1(ts: Timestamp, node_id: &[u8]) -> Result { const NODE_ID_LEN: usize = 6; let len = node_id.len(); if len != NODE_ID_LEN { Err(crate::builder::Error::new(NODE_ID_LEN, len))?; } let time_low = (ts.ticks & 0xFFFF_FFFF) as u32; let time_mid = ((ts.ticks >> 32) & 0xFFFF) as u16; let time_high_and_version = (((ts.ticks >> 48) & 0x0FFF) as u16) | (1 << 12); let mut d4 = [0; 8]; { d4[0] = (((ts.counter & 0x3F00) >> 8) as u8) | 0x80; d4[1] = (ts.counter & 0xFF) as u8; } d4[2..].copy_from_slice(node_id); Uuid::from_fields(time_low, time_mid, time_high_and_version, &d4) } /// Returns an optional [`Timestamp`] storing the timestamp and /// counter portion parsed from a V1 UUID. /// /// Returns `None` if the supplied UUID is not V1. /// /// The V1 timestamp format defined in RFC4122 specifies a 60-bit /// integer representing the number of 100-nanosecond intervals /// since 00:00:00.00, 15 Oct 1582. /// /// [`Timestamp`] offers several options for converting the raw RFC4122 /// value into more commonly-used formats, such as a unix timestamp. /// /// [`Timestamp`]: v1/struct.Timestamp.html pub fn to_timestamp(&self) -> Option { if self .get_version() .map(|v| v != Version::Mac) .unwrap_or(true) { return None; } let ticks: u64 = u64::from(self.as_bytes()[6] & 0x0F) << 56 | u64::from(self.as_bytes()[7]) << 48 | u64::from(self.as_bytes()[4]) << 40 | u64::from(self.as_bytes()[5]) << 32 | u64::from(self.as_bytes()[0]) << 24 | u64::from(self.as_bytes()[1]) << 16 | u64::from(self.as_bytes()[2]) << 8 | u64::from(self.as_bytes()[3]); let counter: u16 = u16::from(self.as_bytes()[8] & 0x3F) << 8 | u16::from(self.as_bytes()[9]); Some(Timestamp::from_rfc4122(ticks, counter)) } } impl Context { /// Creates a thread-safe, internally mutable context to help ensure /// uniqueness. /// /// This is a context which can be shared across threads. It maintains an /// internal counter that is incremented at every request, the value ends /// up in the clock_seq portion of the UUID (the fourth group). This /// will improve the probability that the UUID is unique across the /// process. pub const fn new(count: u16) -> Self { Self { count: atomic::AtomicUsize::new(count as usize), } } } impl ClockSequence for Context { fn generate_sequence(&self, _: u64, _: u32) -> u16 { (self.count.fetch_add(1, atomic::Ordering::SeqCst) & 0xffff) as u16 } } #[cfg(test)] mod tests { use super::*; use crate::std::string::ToString; #[test] fn test_new_v1() { let time: u64 = 1_496_854_535; let time_fraction: u32 = 812_946_000; let node = [1, 2, 3, 4, 5, 6]; let context = Context::new(0); { let uuid = Uuid::new_v1( Timestamp::from_unix(&context, time, time_fraction), &node, ) .unwrap(); assert_eq!(uuid.get_version(), Some(Version::Mac)); assert_eq!(uuid.get_variant(), Some(Variant::RFC4122)); assert_eq!( uuid.to_hyphenated().to_string(), "20616934-4ba2-11e7-8000-010203040506" ); let ts = uuid.to_timestamp().unwrap().to_rfc4122(); assert_eq!(ts.0 - 0x01B2_1DD2_1381_4000, 14_968_545_358_129_460); assert_eq!(ts.1, 0); }; { let uuid2 = Uuid::new_v1( Timestamp::from_unix(&context, time, time_fraction), &node, ) .unwrap(); assert_eq!( uuid2.to_hyphenated().to_string(), "20616934-4ba2-11e7-8001-010203040506" ); assert_eq!(uuid2.to_timestamp().unwrap().to_rfc4122().1, 1) }; } }