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//! The implementation for Version 7 UUIDs.
//!
//! Note that you need to enable the `v7` Cargo feature
//! in order to use this module.
use crate::{rng, std::convert::TryInto, timestamp::Timestamp, Builder, Uuid};
impl Uuid {
/// Create a new version 7 UUID using the current time value.
///
/// This method is a convenient alternative to [`Uuid::new_v7`] that uses the current system time
/// as the source timestamp. All UUIDs generated through this method by the same process are
/// guaranteed to be ordered by their creation.
#[cfg(feature = "std")]
pub fn now_v7() -> Self {
Self::new_v7(Timestamp::now(
crate::timestamp::context::shared_context_v7(),
))
}
/// Create a new version 7 UUID using a time value and random bytes.
///
/// When the `std` feature is enabled, you can also use [`Uuid::now_v7`].
///
/// Note that usage of this method requires the `v7` feature of this crate
/// to be enabled.
///
/// Also see [`Uuid::now_v7`] for a convenient way to generate version 7
/// UUIDs using the current system time.
///
/// # Examples
///
/// A v7 UUID can be created from a unix [`Timestamp`] plus a 128 bit
/// random number. When supplied as such, the data will be combined
/// to ensure uniqueness and sortability at millisecond granularity.
///
/// ```rust
/// # use uuid::{Uuid, Timestamp, NoContext};
/// let ts = Timestamp::from_unix(NoContext, 1497624119, 1234);
///
/// let uuid = Uuid::new_v7(ts);
///
/// assert!(
/// uuid.hyphenated().to_string().starts_with("015cb15a-86d8-7")
/// );
/// ```
///
/// A v7 UUID can also be created with a counter to ensure batches of
/// UUIDs created together remain sortable:
///
/// ```rust
/// # use uuid::{Uuid, Timestamp, ContextV7};
/// let context = ContextV7::new();
/// let uuid1 = Uuid::new_v7(Timestamp::from_unix(&context, 1497624119, 1234));
/// let uuid2 = Uuid::new_v7(Timestamp::from_unix(&context, 1497624119, 1234));
///
/// assert!(uuid1 < uuid2);
/// ```
///
/// # References
///
/// * [UUID Version 7 in RFC 9562](https://www.ietf.org/rfc/rfc9562.html#section-5.7)
pub fn new_v7(ts: Timestamp) -> Self {
let (secs, nanos) = ts.to_unix();
let millis = (secs * 1000).saturating_add(nanos as u64 / 1_000_000);
let mut counter_and_random = rng::u128();
let (mut counter, counter_bits) = ts.counter();
debug_assert!(counter_bits <= 128);
let mut counter_bits = counter_bits as u32;
// If the counter intersects the variant field then shift around it.
// This ensures that any bits set in the counter that would intersect
// the variant are still preserved
if counter_bits > 12 {
let mask = u128::MAX << (counter_bits - 12);
counter = (counter & !mask) | ((counter & mask) << 2);
counter_bits += 2;
}
counter_and_random &= u128::MAX.overflowing_shr(counter_bits).0;
counter_and_random |= counter
.overflowing_shl(128u32.saturating_sub(counter_bits))
.0;
Builder::from_unix_timestamp_millis(
millis,
&counter_and_random.to_be_bytes()[..10].try_into().unwrap(),
)
.into_uuid()
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate::{std::string::ToString, ClockSequence, NoContext, Variant, Version};
#[cfg(all(target_arch = "wasm32", any(target_os = "unknown", target_os = "none")))]
use wasm_bindgen_test::*;
#[test]
#[cfg_attr(
all(target_arch = "wasm32", any(target_os = "unknown", target_os = "none")),
wasm_bindgen_test
)]
fn test_new() {
let ts: u64 = 1645557742000;
let seconds = ts / 1000;
let nanos = ((ts % 1000) * 1_000_000) as u32;
let uuid = Uuid::new_v7(Timestamp::from_unix(NoContext, seconds, nanos));
let uustr = uuid.hyphenated().to_string();
assert_eq!(uuid.get_version(), Some(Version::SortRand));
assert_eq!(uuid.get_variant(), Variant::RFC4122);
assert!(uuid.hyphenated().to_string().starts_with("017f22e2-79b0-7"));
// Ensure parsing the same UUID produces the same timestamp
let parsed = Uuid::parse_str(uustr.as_str()).unwrap();
assert_eq!(uuid, parsed);
}
#[test]
#[cfg_attr(
all(target_arch = "wasm32", any(target_os = "unknown", target_os = "none")),
wasm_bindgen_test
)]
#[cfg(feature = "std")]
fn test_now() {
let uuid = Uuid::now_v7();
assert_eq!(uuid.get_version(), Some(Version::SortRand));
assert_eq!(uuid.get_variant(), Variant::RFC4122);
}
#[test]
#[cfg_attr(
all(target_arch = "wasm32", any(target_os = "unknown", target_os = "none")),
wasm_bindgen_test
)]
fn test_sorting() {
let time1: u64 = 1_496_854_535;
let time_fraction1: u32 = 812_000_000;
let time2 = time1 + 4000;
let time_fraction2 = time_fraction1;
let uuid1 = Uuid::new_v7(Timestamp::from_unix(NoContext, time1, time_fraction1));
let uuid2 = Uuid::new_v7(Timestamp::from_unix(NoContext, time2, time_fraction2));
assert!(uuid1.as_bytes() < uuid2.as_bytes());
assert!(uuid1.to_string() < uuid2.to_string());
}
#[test]
#[cfg_attr(
all(target_arch = "wasm32", any(target_os = "unknown", target_os = "none")),
wasm_bindgen_test
)]
fn test_new_timestamp_roundtrip() {
let time: u64 = 1_496_854_535;
let time_fraction: u32 = 812_000_000;
let ts = Timestamp::from_unix(NoContext, time, time_fraction);
let uuid = Uuid::new_v7(ts);
let decoded_ts = uuid.get_timestamp().unwrap();
assert_eq!(ts.to_unix(), decoded_ts.to_unix());
}
#[test]
#[cfg_attr(
all(target_arch = "wasm32", any(target_os = "unknown", target_os = "none")),
wasm_bindgen_test
)]
fn test_new_max_context() {
struct MaxContext;
#[cfg(test)]
impl ClockSequence for MaxContext {
type Output = u128;
fn generate_sequence(&self, _seconds: u64, _nanos: u32) -> Self::Output {
u128::MAX
}
fn usable_bits(&self) -> usize {
128
}
}
let time: u64 = 1_496_854_535;
let time_fraction: u32 = 812_000_000;
// Ensure we don't overflow here
let ts = Timestamp::from_unix(MaxContext, time, time_fraction);
let uuid = Uuid::new_v7(ts);
assert_eq!(uuid.get_version(), Some(Version::SortRand));
assert_eq!(uuid.get_variant(), Variant::RFC4122);
let decoded_ts = uuid.get_timestamp().unwrap();
assert_eq!(ts.to_unix(), decoded_ts.to_unix());
}
}