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// Take a look at the license at the top of the repository in the LICENSE file.
// rustdoc-stripper-ignore-next
//! This module gathers GStreamer's formatted value concepts together.
//!
//! GStreamer uses formatted values to differentiate value units in some APIs.
//! In C this is done by qualifying an integer value by a companion enum
//! [`GstFormat`]. In Rust, most APIs can use a specific type for each format.
//! Each format type embeds the actual value using the new type pattern.
//!
//! # Specific Formatted Values
//!
//! Examples of specific formatted values include [`ClockTime`], [`Buffers`], etc.
//! These types represent both the quantity and the unit making it possible for Rust
//! to perform runtime and, to a certain extent, compile time invariants enforcement.
//!
//! Specific formatted values are also guaranteed to always represent a valid value.
//! For instance:
//!
//! - [`Percent`] only allows values in the integer range [0, 1_000_000] or
//! float range [0.0, 1.0].
//! - [`ClockTime`] can use all `u64` values except `u64::MAX` which is reserved by
//! the C constant `GST_CLOCK_TIME_NONE`.
//!
//! ## Examples
//!
//! ### Querying the pipeline for a time position
//!
//! ```
//! # use gstreamer as gst;
//! # use gst::prelude::ElementExtManual;
//! # gst::init();
//! # let pipeline = gst::Pipeline::new();
//! let res = pipeline.query_position::<gst::ClockTime>();
//! ```
//!
//! ## Seeking to a specific time position
//!
//! ```
//! # use gstreamer as gst;
//! # use gst::{format::prelude::*, prelude::ElementExtManual};
//! # gst::init();
//! # let pipeline = gst::Pipeline::new();
//! # let seek_flags = gst::SeekFlags::FLUSH | gst::SeekFlags::KEY_UNIT;
//! let seek_pos = gst::ClockTime::from_seconds(10);
//! let res = pipeline.seek_simple(seek_flags, seek_pos);
//! ```
//!
//! ### Downcasting a `Segment` for specific formatted value use
//!
//! ```
//! # use gstreamer as gst;
//! # use gst::format::FormattedValue;
//! # gst::init();
//! # let segment = gst::FormattedSegment::<gst::ClockTime>::new().upcast();
//! // Downcasting the generic `segment` for `gst::ClockTime` use.
//! let time_segment = segment.downcast_ref::<gst::ClockTime>().expect("time segment");
//! // Setters and getters conform to `gst::ClockTime`.
//! // This is enforced at compilation time.
//! let start = time_segment.start();
//! assert_eq!(start.format(), gst::Format::Time);
//! ```
//!
//! ### Building a specific formatted value
//!
//! ```
//! # use gstreamer as gst;
//! use gst::prelude::*;
//! use gst::format::{Buffers, Bytes, ClockTime, Default, Percent};
//!
//! // Specific formatted values implement the faillible `try_from` constructor:
//! let default = Default::try_from(42).unwrap();
//! assert_eq!(*default, 42);
//! assert_eq!(Default::try_from(42), Ok(default));
//! assert_eq!(Default::try_from(42).ok(), Some(default));
//!
//! // `ClockTime` provides specific `const` constructors,
//! // which can panic if the requested value is out of range.
//! let time = ClockTime::from_nseconds(45_834_908_569_837);
//! let time = ClockTime::from_seconds(20);
//!
//! // Other formatted values also come with (panicking) `const` constructors:
//! let buffers_nb = Buffers::from_u64(512);
//! let received = Bytes::from_u64(64);
//! let quantity = Default::from_u64(42);
//!
//! // `Bytes` can be built from an `usize` too (not `const`):
//! let sample_size = Bytes::from_usize([0u8; 4].len());
//!
//! // This can be convenient (not `const`):
//! assert_eq!(
//! 7.seconds() + 250.mseconds(),
//! ClockTime::from_nseconds(7_250_000_000),
//! );
//!
//! // Those too (not `const`):
//! assert_eq!(512.buffers(), Buffers::from_u64(512));
//! assert_eq!(64.bytes(), Bytes::from_u64(64));
//! assert_eq!(42.default_format(), Default::from_u64(42));
//!
//! // The `ZERO` and `NONE` constants can come in handy sometimes:
//! assert_eq!(*Buffers::ZERO, 0);
//! assert!(ClockTime::NONE.is_none());
//!
//! // Specific formatted values provide the constant `ONE` value:
//! assert_eq!(*Buffers::ONE, 1);
//!
//! // `Bytes` also comes with usual multipliers (not `const`):
//! assert_eq!(*(512.kibibytes()), 512 * 1024);
//! assert_eq!(*(8.mebibytes()), 8 * 1024 * 1024);
//! assert_eq!(*(4.gibibytes()), 4 * 1024 * 1024 * 1024);
//!
//! // ... and the matching constants:
//! assert_eq!(512 * Bytes::KiB, 512.kibibytes());
//!
//! // `Percent` can be built from a percent integer value:
//! let a_quarter = 25.percent();
//! // ... from a floating point ratio:
//! let a_quarter_from_ratio = 0.25.percent_ratio();
//! assert_eq!(a_quarter, a_quarter_from_ratio);
//! // ... from a part per million integer value:
//! let a_quarter_from_ppm = (25 * 10_000).ppm();
//! assert_eq!(a_quarter, a_quarter_from_ppm);
//! // ... `MAX` which represents 100%:
//! assert_eq!(Percent::MAX / 4, a_quarter);
//! // ... `ONE` which is 1%:
//! assert_eq!(25 * Percent::ONE, a_quarter);
//! // ... and `SCALE` which is 1% in ppm:
//! assert_eq!(Percent::SCALE, 10_000.ppm());
//! ```
//!
//! ### Displaying a formatted value
//!
//! Formatted values implement the [`Display`] trait which allows getting
//! human readable representations.
//!
//! ```
//! # use gstreamer as gst;
//! # use gst::prelude::*;
//! let time = 45_834_908_569_837.nseconds();
//!
//! assert_eq!(format!("{time}"), "12:43:54.908569837");
//! assert_eq!(format!("{time:.0}"), "12:43:54");
//!
//! let percent = 0.1234.percent_ratio();
//! assert_eq!(format!("{percent}"), "12.34 %");
//! assert_eq!(format!("{percent:5.1}"), " 12.3 %");
//! ```
//!
//! ## Some operations available on specific formatted values
//!
//! ```
//! # use gstreamer as gst;
//! # use gst::prelude::*;
//! let cur_pos = gst::ClockTime::ZERO;
//!
//! // All four arithmetic operations can be used:
//! let fwd = cur_pos + 2.seconds() / 3 - 5.mseconds();
//!
//! // Examples of operations which make sure not to overflow:
//! let bwd = cur_pos.saturating_sub(2.seconds());
//! let further = cur_pos.checked_mul(2).expect("Overflowed");
//!
//! // Specific formatted values can be compared:
//! assert!(fwd > bwd);
//! assert_ne!(fwd, cur_pos);
//!
//! # fn next() -> gst::ClockTime { gst::ClockTime::ZERO };
//! // Use `gst::ClockTime::MAX` for the maximum valid value:
//! let mut min_pos = gst::ClockTime::MAX;
//! for _ in 0..4 {
//! min_pos = min_pos.min(next());
//! }
//!
//! // And `gst::ClockTime::ZERO` for the minimum value:
//! let mut max_pos = gst::ClockTime::ZERO;
//! for _ in 0..4 {
//! max_pos = max_pos.max(next());
//! }
//!
//! // Specific formatted values implement the `MulDiv` trait:
//! # use gst::prelude::MulDiv;
//! # let (samples, rate) = (1024u64, 48_000u64);
//! let duration = samples
//! .mul_div_round(*gst::ClockTime::SECOND, rate)
//! .map(gst::ClockTime::from_nseconds);
//! ```
//!
//! ## Types in operations
//!
//! Additions and substractions are available with the specific formatted value type
//! as both left and right hand side operands.
//!
//! On the other hand, multiplications are only available with plain integers.
//! This is because multiplying a `ClockTime` by a `ClockTime` would result in
//! `ClockTime²`, whereas a `u64 * ClockTime` (or `ClockTime * u64`) still
//! results in `ClockTime`.
//!
//! Divisions are available with both the specific formatted value and plain
//! integers as right hand side operands. The difference is that
//! `ClockTime / ClockTime` results in `u64` and `ClockTime / u64` results in
//! `ClockTime`.
//!
//! # Optional specific formatted values
//!
//! Optional specific formatted values are represented as a standard Rust
//! `Option<F>`. This departs from the C APIs which use a sentinel that must
//! be checked in order to figure out whether the value is defined.
//!
//! Besides giving access to the usual `Option` features, this ensures the APIs
//! enforce mandatory or optional variants whenever possible.
//!
//! Note: for each specific formatted value `F`, the constant `F::NONE` is defined
//! as a shortcut for `Option::<F>::None`. For `gst::ClockTime`, this constant is
//! equivalent to the C constant `GST_CLOCK_TIME_NONE`.
//!
//! ## Examples
//!
//! ### Building a seek `Event` with undefined `stop` time
//!
//! ```
//! # use gstreamer as gst;
//! # use gst::format::prelude::*;
//! # gst::init();
//! # let seek_flags = gst::SeekFlags::FLUSH | gst::SeekFlags::KEY_UNIT;
//! let seek_evt = gst::event::Seek::new(
//! 1.0f64,
//! seek_flags,
//! gst::SeekType::Set,
//! 10.seconds(), // start at 10s
//! gst::SeekType::Set,
//! gst::ClockTime::NONE, // stop is undefined
//! );
//! ```
//!
//! ### Displaying an optional formatted value
//!
//! Optional formatted values can take advantage of the [`Display`] implementation
//! of the base specific formatted value. We have to workaround the [orphan rule]
//! that forbids the implementation of [`Display`] for `Option<FormattedValue>`
//! though. This is why displaying an optional formatted value necessitates calling
//! [`display()`].
//!
//! ```
//! # use gstreamer as gst;
//! # use gst::prelude::*;
//! let opt_time = Some(45_834_908_569_837.nseconds());
//!
//! assert_eq!(format!("{}", opt_time.display()), "12:43:54.908569837");
//! assert_eq!(format!("{:.0}", opt_time.display()), "12:43:54");
//! assert_eq!(format!("{:.0}", gst::ClockTime::NONE.display()), "--:--:--");
//! ```
//!
//! ### Some operations available on optional formatted values
//!
//! ```
//! # use gstreamer as gst;
//! # use gst::prelude::*;
//! let pts = Some(gst::ClockTime::ZERO);
//! assert!(pts.is_some());
//!
//! // All four arithmetic operations can be used. Ex.:
//! let fwd = pts.opt_add(2.seconds());
//! // `pts` is defined, so `fwd` will contain the addition result in `Some`,
//! assert!(fwd.is_some());
//! // otherwise `fwd` would be `None`.
//!
//! // Examples of operations which make sure not to overflow:
//! let bwd = pts.opt_saturating_sub(2.seconds());
//! let further = pts.opt_checked_mul(2).expect("Overflowed");
//!
//! // Optional specific formatted values can be compared:
//! assert_eq!(fwd.opt_gt(bwd), Some(true));
//! assert_ne!(fwd, pts);
//! assert_eq!(fwd.opt_min(bwd), bwd);
//!
//! // Optional specific formatted values operations also apply to non-optional values:
//! assert_eq!(fwd.opt_lt(gst::ClockTime::SECOND), Some(false));
//! assert_eq!(gst::ClockTime::SECOND.opt_lt(fwd), Some(true));
//!
//! // Comparing a defined values to an undefined value results in `None`:
//! assert_eq!(bwd.opt_gt(gst::ClockTime::NONE), None);
//! assert_eq!(gst::ClockTime::ZERO.opt_lt(gst::ClockTime::NONE), None);
//! ```
//!
//! # Signed formatted values
//!
//! Some APIs can return a signed formatted value. See [`Segment::to_running_time_full`]
//! for an example. In Rust, we use the [`Signed`] enum wrapper around the actual
//! formatted value.
//!
//! For each signed specific formatted value `F`, the constants `F::MIN_SIGNED` and
//! `F::MAX_SIGNED` represent the minimum and maximum signed values for `F`.
//!
//! ## Examples
//!
//! ### Handling a signed formatted value
//!
//! ```
//! # use gstreamer as gst;
//! # use gst::prelude::*;
//! # gst::init();
//! # let segment = gst::FormattedSegment::<gst::ClockTime>::new();
//! use gst::Signed::*;
//! match segment.to_running_time_full(2.seconds()) {
//! Some(Positive(pos_rtime)) => println!("positive rtime {pos_rtime}"),
//! Some(Negative(neg_rtime)) => println!("negative rtime {neg_rtime}"),
//! None => println!("undefined rtime"),
//! }
//! ```
//!
//! ### Converting a formatted value into a signed formatted value
//!
//! ```
//! # use gstreamer as gst;
//! # use gst::prelude::*;
//! let step = 10.mseconds();
//!
//! let positive_step = step.into_positive();
//! assert!(positive_step.is_positive());
//!
//! let negative_step = step.into_negative();
//! assert!(negative_step.is_negative());
//! ```
//!
//! ### Handling one sign only
//!
//! ```
//! # use gstreamer as gst;
//! # use gst::prelude::*;
//! # struct NegativeError;
//! let pos_step = 10.mseconds().into_positive();
//! assert!(pos_step.is_positive());
//!
//! let abs_step_or_panic = pos_step.positive().expect("positive");
//! let abs_step_or_zero = pos_step.positive().unwrap_or(gst::ClockTime::ZERO);
//!
//! let abs_step_or_err = pos_step.positive_or(NegativeError);
//! let abs_step_or_else_err = pos_step.positive_or_else(|step| {
//! println!("{step} is negative");
//! NegativeError
//! });
//! ```
//!
//! ### Displaying a signed formatted value
//!
//! ```
//! # use gstreamer as gst;
//! # use gst::prelude::*;
//! # gst::init();
//! # let mut segment = gst::FormattedSegment::<gst::ClockTime>::new();
//! # segment.set_start(10.seconds());
//! let start = segment.start().unwrap();
//! assert_eq!(format!("{start:.0}"), "0:00:10");
//!
//! let p_rtime = segment.to_running_time_full(20.seconds());
//! // Use `display()` with optional signed values.
//! assert_eq!(format!("{:.0}", p_rtime.display()), "+0:00:10");
//!
//! let p_rtime = segment.to_running_time_full(gst::ClockTime::ZERO);
//! assert_eq!(format!("{:.0}", p_rtime.display()), "-0:00:10");
//!
//! let p_rtime = segment.to_running_time_full(gst::ClockTime::NONE);
//! assert_eq!(format!("{:.0}", p_rtime.display()), "--:--:--");
//! ```
//!
//! ## Some operations available for signed formatted values
//!
//! All the operations available for formatted values can be used with
//! signed formatted values.
//!
//! ```
//! # use gstreamer as gst;
//! # use gst::prelude::*;
//! let p_one_sec = gst::ClockTime::SECOND.into_positive();
//! let p_two_sec = 2.seconds().into_positive();
//! let n_one_sec = gst::ClockTime::SECOND.into_negative();
//!
//! assert_eq!(p_one_sec + p_one_sec, p_two_sec);
//! assert_eq!(p_two_sec - p_one_sec, p_one_sec);
//! assert_eq!(gst::ClockTime::ZERO - p_one_sec, n_one_sec);
//! assert_eq!(p_one_sec * 2u64, p_two_sec);
//! assert_eq!(n_one_sec * -1i64, p_one_sec);
//! assert_eq!(p_two_sec / 2u64, p_one_sec);
//! assert_eq!(p_two_sec / p_one_sec, 2);
//!
//! // Examples of operations which make sure not to overflow:
//! assert_eq!(p_one_sec.saturating_sub(p_two_sec), n_one_sec);
//! assert_eq!(p_one_sec.checked_mul(2), Some(p_two_sec));
//!
//! // Signed formatted values can be compared:
//! assert!(p_one_sec > n_one_sec);
//!
//! # fn next() -> gst::Signed<gst::ClockTime> { gst::ClockTime::ZERO.into_positive() };
//! // Use `gst::ClockTime::MAX_SIGNED` for the maximum valid signed value:
//! let mut min_signed_pos = gst::ClockTime::MAX_SIGNED;
//! for _ in 0..4 {
//! min_signed_pos = min_signed_pos.min(next());
//! }
//!
//! // And `gst::ClockTime::MIN_SIGNED` for the minimum valid signed value:
//! let mut max_signed_pos = gst::ClockTime::MIN_SIGNED;
//! for _ in 0..4 {
//! max_signed_pos = max_signed_pos.max(next());
//! }
//!
//! // Signed formatted values implement the `MulDiv` trait:
//! # use gst::prelude::*;
//! # let rate = 48_000u64;
//! let samples = 1024.default_format().into_negative();
//! let duration = samples
//! .mul_div_round(*gst::ClockTime::SECOND, rate)
//! .map(|signed_default| {
//! let signed_u64 = signed_default.into_inner_signed();
//! gst::Signed::<gst::ClockTime>::from_nseconds(signed_u64)
//! })
//! .unwrap();
//! assert!(duration.is_negative());
//! ```
//!
//! ### Some operations available for optional signed formatted values
//!
//! All the operations available for optional formatted values can be used
//! with signed formatted values.
//!
//! ```
//! # use gstreamer as gst;
//! # use gst::prelude::*;
//! let p_one_sec = 1.seconds().into_positive();
//! let p_two_sec = 2.seconds().into_positive();
//! let n_one_sec = 1.seconds().into_negative();
//!
//! // Signed `ClockTime` addition with optional and non-optional operands.
//! assert_eq!(Some(p_one_sec).opt_add(p_one_sec), Some(p_two_sec));
//! assert_eq!(p_two_sec.opt_add(Some(n_one_sec)), Some(p_one_sec));
//!
//! // This can also be used with unsigned formatted values.
//! assert_eq!(Some(p_one_sec).opt_add(gst::ClockTime::SECOND), Some(p_two_sec));
//!
//! // Etc...
//! ```
//!
//! # Generic Formatted Values
//!
//! Sometimes, generic code can't assume a specific format will be used. For such
//! use cases, the [`GenericFormattedValue`] enum makes it possible to select
//! the appropriate behaviour at runtime.
//!
//! Most variants embed an optional specific formatted value.
//!
//! ## Example
//!
//! ### Generic handling of the position from a `SegmentDone` event
//!
//! ```
//! # use gstreamer as gst;
//! # use gst::prelude::*;
//! # gst::init();
//! # let event = gst::event::SegmentDone::new(512.buffers());
//! if let gst::EventView::SegmentDone(seg_done_evt) = event.view() {
//! use gst::GenericFormattedValue::*;
//! match seg_done_evt.get() {
//! Buffers(buffers) => println!("Segment done @ {}", buffers.display()),
//! Bytes(bytes) => println!("Segment done @ {}", bytes.display()),
//! Time(time) => println!("Segment done @ {}", time.display()),
//! other => println!("Unexpected format for Segment done position {other:?}"),
//! }
//! }
//! ```
//!
//! [`GstFormat`]: https://gstreamer.freedesktop.org/documentation/gstreamer/gstformat.html?gi-language=c
//! [`ClockTime`]: struct.ClockTime.html
//! [`Buffers`]: struct.Buffers.html
//! [`Percent`]: struct.Percent.html
//! [`Display`]: https://doc.rust-lang.org/std/fmt/trait.Display.html
//! [`display()`]: ../prelude/trait.Displayable.html
//! [orphan rule]: https://doc.rust-lang.org/book/ch10-02-traits.html?highlight=orphan#implementing-a-trait-on-a-type
//! [`Segment::to_running_time_full`]: ../struct.FormattedSegment.html#method.to_running_time_full
//! [`Signed`]: enum.Signed.html
//! [`GenericFormattedValue`]: generic/enum.GenericFormattedValue.html
use thiserror::Error;
#[macro_use]
mod macros;
mod clock_time;
pub use clock_time::*;
#[cfg(feature = "serde")]
mod clock_time_serde;
mod compatible;
pub use compatible::*;
#[cfg(feature = "serde")]
mod format_serde;
mod generic;
pub use generic::*;
mod signed;
pub use signed::*;
mod specific;
pub use specific::*;
mod undefined;
pub use undefined::*;
pub mod prelude {
pub use super::{
BuffersFormatConstructor, BytesFormatConstructor, DefaultFormatConstructor, FormattedValue,
FormattedValueNoneBuilder, NoneSignedBuilder, OtherFormatConstructor,
PercentFormatFloatConstructor, PercentFormatIntegerConstructor, TimeFormatConstructor,
UndefinedFormatConstructor, UnsignedIntoSigned,
};
}
use crate::Format;
#[derive(Clone, Copy, Debug, PartialEq, Eq, Error)]
#[error("invalid formatted value format {:?}", .0)]
pub struct FormattedValueError(Format);
pub trait FormattedValue: Copy + Clone + Sized + Into<GenericFormattedValue> + 'static {
// rustdoc-stripper-ignore-next
/// Type which allows building a `FormattedValue` of this format from any raw value.
type FullRange: FormattedValueFullRange + From<Self>;
#[doc(alias = "get_default_format")]
fn default_format() -> Format;
#[doc(alias = "get_format")]
fn format(&self) -> Format;
// rustdoc-stripper-ignore-next
/// Returns `true` if this `FormattedValue` represents a defined value.
fn is_some(&self) -> bool;
// rustdoc-stripper-ignore-next
/// Returns `true` if this `FormattedValue` represents an undefined value.
fn is_none(&self) -> bool {
!self.is_some()
}
unsafe fn into_raw_value(self) -> i64;
}
// rustdoc-stripper-ignore-next
/// A [`FormattedValue`] which can be built from any raw value.
///
/// # Examples:
///
/// - `GenericFormattedValue` is the `FormattedValueFullRange` type for `GenericFormattedValue`.
/// - `Undefined` is the `FormattedValueFullRange` type for `Undefined`.
/// - `Option<Percent>` is the `FormattedValueFullRange` type for `Percent`.
pub trait FormattedValueFullRange: FormattedValue + TryFrom<GenericFormattedValue> {
unsafe fn from_raw(format: Format, value: i64) -> Self;
}
// rustdoc-stripper-ignore-next
/// A trait implemented on the intrinsic type of a `FormattedValue`.
///
/// # Examples
///
/// - `GenericFormattedValue` is the intrinsic type for `GenericFormattedValue`.
/// - `Undefined` is the intrinsic type for `Undefined`.
/// - `Bytes` is the intrinsic type for `Option<Bytes>`.
pub trait FormattedValueIntrinsic: FormattedValue {}
pub trait FormattedValueNoneBuilder: FormattedValueFullRange {
// rustdoc-stripper-ignore-next
/// Returns the `None` value for `Self` as a `FullRange` if such a value can be represented.
///
/// - For `SpecificFormattedValue`s, this results in `Option::<FormattedValueIntrinsic>::None`.
/// - For `GenericFormattedValue`, this can only be obtained using [`Self::none_for_format`]
/// because the `None` is an inner value of some of the variants.
///
/// # Panics
///
/// Panics if `Self` is `GenericFormattedValue` in which case, the `Format` must be known.
fn none() -> Self;
// rustdoc-stripper-ignore-next
/// Returns the `None` value for `Self` if such a value can be represented.
///
/// - For `SpecificFormattedValue`s, this is the same as `Self::none()`
/// if the `format` matches the `SpecificFormattedValue`'s format.
/// - For `GenericFormattedValue` this is the variant for the specified `format`,
/// initialized with `None` as a value, if the `format` can represent that value.
///
/// # Panics
///
/// Panics if `None` can't be represented by `Self` for `format` or by the requested
/// `GenericFormattedValue` variant.
#[track_caller]
#[inline]
fn none_for_format(format: Format) -> Self {
skip_assert_initialized!();
// This is the default impl. `GenericFormattedValue` must override.
if Self::default_format() != format {
panic!(
"Expected: {:?}, requested {format:?}",
Self::default_format()
);
}
Self::none()
}
}
use std::fmt;
impl fmt::Display for Format {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
match self {
Self::Undefined => f.write_str("undefined"),
Self::Default => f.write_str("default"),
Self::Bytes => f.write_str("bytes"),
Self::Time => f.write_str("time"),
Self::Buffers => f.write_str("buffers"),
Self::Percent => f.write_str("%"),
Self::__Unknown(format) => write!(f, "(format: {format})"),
}
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate::utils::Displayable;
fn with_compatible_formats<V1, V2>(
arg1: V1,
arg2: V2,
) -> Result<V2::Original, FormattedValueError>
where
V1: FormattedValue,
V2: CompatibleFormattedValue<V1>,
{
skip_assert_initialized!();
arg2.try_into_checked(arg1)
}
#[test]
fn compatible() {
assert_eq!(
with_compatible_formats(ClockTime::ZERO, ClockTime::ZERO),
Ok(ClockTime::ZERO),
);
assert_eq!(
with_compatible_formats(ClockTime::ZERO, ClockTime::NONE),
Ok(ClockTime::NONE),
);
assert_eq!(
with_compatible_formats(ClockTime::NONE, ClockTime::ZERO),
Ok(ClockTime::ZERO),
);
assert_eq!(
with_compatible_formats(
ClockTime::ZERO,
GenericFormattedValue::Time(Some(ClockTime::ZERO)),
),
Ok(GenericFormattedValue::Time(Some(ClockTime::ZERO))),
);
assert_eq!(
with_compatible_formats(
GenericFormattedValue::Time(Some(ClockTime::ZERO)),
ClockTime::NONE,
),
Ok(ClockTime::NONE),
);
}
#[test]
fn incompatible() {
with_compatible_formats(
ClockTime::ZERO,
GenericFormattedValue::Buffers(Some(42.buffers())),
)
.unwrap_err();
with_compatible_formats(
GenericFormattedValue::Buffers(Some(42.buffers())),
ClockTime::NONE,
)
.unwrap_err();
}
fn with_compatible_explicit<T, V>(arg: V, f: Format) -> Result<V::Original, FormattedValueError>
where
T: FormattedValue,
V: CompatibleFormattedValue<T>,
{
skip_assert_initialized!();
arg.try_into_checked_explicit(f)
}
#[test]
fn compatible_explicit() {
assert_eq!(
with_compatible_explicit::<ClockTime, _>(ClockTime::ZERO, Format::Time),
Ok(ClockTime::ZERO),
);
assert_eq!(
with_compatible_explicit::<ClockTime, _>(ClockTime::NONE, Format::Time),
Ok(ClockTime::NONE),
);
assert_eq!(
with_compatible_explicit::<ClockTime, _>(ClockTime::ZERO, Format::Time),
Ok(ClockTime::ZERO),
);
assert_eq!(
with_compatible_explicit::<ClockTime, _>(
GenericFormattedValue::Time(None),
Format::Time
),
Ok(GenericFormattedValue::Time(None)),
);
assert_eq!(
with_compatible_explicit::<GenericFormattedValue, _>(ClockTime::NONE, Format::Time),
Ok(ClockTime::NONE),
);
}
#[test]
fn incompatible_explicit() {
with_compatible_explicit::<Buffers, _>(GenericFormattedValue::Time(None), Format::Buffers)
.unwrap_err();
with_compatible_explicit::<GenericFormattedValue, _>(Buffers::ZERO, Format::Time)
.unwrap_err();
with_compatible_explicit::<GenericFormattedValue, _>(
GenericFormattedValue::Time(None),
Format::Buffers,
)
.unwrap_err();
}
#[test]
fn none_builder() {
let ct_none: Option<ClockTime> = Option::<ClockTime>::none();
assert!(ct_none.is_none());
let ct_none: Option<ClockTime> = Option::<ClockTime>::none_for_format(Format::Time);
assert!(ct_none.is_none());
let gen_ct_none: GenericFormattedValue =
GenericFormattedValue::none_for_format(Format::Time);
assert!(gen_ct_none.is_none());
assert!(ClockTime::ZERO.is_some());
assert!(!ClockTime::ZERO.is_none());
}
#[test]
#[should_panic]
fn none_for_inconsistent_format() {
let _ = Option::<ClockTime>::none_for_format(Format::Percent);
}
#[test]
#[should_panic]
fn none_for_unsupported_format() {
let _ = GenericFormattedValue::none_for_format(Format::Undefined);
}
#[test]
fn none_signed_builder() {
let ct_none: Option<Signed<ClockTime>> = Option::<ClockTime>::none_signed();
assert!(ct_none.is_none());
let ct_none: Option<Signed<ClockTime>> =
Option::<ClockTime>::none_signed_for_format(Format::Time);
assert!(ct_none.is_none());
let gen_ct_none: GenericSignedFormattedValue =
GenericFormattedValue::none_signed_for_format(Format::Time);
assert!(gen_ct_none.abs().is_none());
}
#[test]
fn signed_optional() {
let ct_1 = Some(ClockTime::SECOND);
let signed = ct_1.into_positive().unwrap();
assert_eq!(signed, Signed::Positive(ClockTime::SECOND));
assert!(signed.is_positive());
assert_eq!(signed.positive_or(()).unwrap(), ClockTime::SECOND);
assert_eq!(signed.positive_or_else(|_| ()).unwrap(), ClockTime::SECOND);
signed.negative_or(()).unwrap_err();
assert_eq!(
signed.negative_or_else(|val| val).unwrap_err(),
ClockTime::SECOND
);
let signed = ct_1.into_negative().unwrap();
assert_eq!(signed, Signed::Negative(ClockTime::SECOND));
assert!(signed.is_negative());
assert_eq!(signed.negative_or(()).unwrap(), ClockTime::SECOND);
assert_eq!(signed.negative_or_else(|_| ()).unwrap(), ClockTime::SECOND);
signed.positive_or(()).unwrap_err();
assert_eq!(
signed.positive_or_else(|val| val).unwrap_err(),
ClockTime::SECOND
);
let ct_none = ClockTime::NONE;
assert!(ct_none.into_positive().is_none());
assert!(ct_none.into_negative().is_none());
}
#[test]
fn signed_mandatory() {
let ct_1 = ClockTime::SECOND;
let signed = ct_1.into_positive();
assert_eq!(signed, Signed::Positive(ct_1));
assert!(signed.is_positive());
assert_eq!(signed.positive(), Some(ct_1));
assert!(!signed.is_negative());
assert!(signed.negative().is_none());
assert_eq!(signed.signum(), 1);
let signed = ct_1.into_negative();
assert_eq!(signed, Signed::Negative(ct_1));
assert!(signed.is_negative());
assert_eq!(signed.negative(), Some(ct_1));
assert!(!signed.is_positive());
assert!(signed.positive().is_none());
assert_eq!(signed.signum(), -1);
let signed = Default::ONE.into_positive();
assert_eq!(signed, Signed::Positive(Default::ONE));
assert!(signed.is_positive());
assert_eq!(signed.positive(), Some(Default::ONE));
assert!(!signed.is_negative());
assert!(signed.negative().is_none());
assert_eq!(signed.signum(), 1);
let signed = Default::ONE.into_negative();
assert_eq!(signed, Signed::Negative(Default::ONE));
assert!(signed.is_negative());
assert_eq!(signed.negative(), Some(Default::ONE));
assert!(!signed.is_positive());
assert!(signed.positive().is_none());
assert_eq!(signed.signum(), -1);
let ct_zero = ClockTime::ZERO;
let p_ct_zero = ct_zero.into_positive();
assert!(p_ct_zero.is_positive());
assert!(!p_ct_zero.is_negative());
assert_eq!(p_ct_zero.signum(), 0);
let n_ct_zero = ct_zero.into_negative();
assert!(n_ct_zero.is_negative());
assert!(!n_ct_zero.is_positive());
assert_eq!(n_ct_zero.signum(), 0);
}
#[test]
fn signed_generic() {
let ct_1 = GenericFormattedValue::Time(Some(ClockTime::SECOND));
assert!(ct_1.is_some());
let signed = ct_1.into_positive();
assert_eq!(
signed,
GenericSignedFormattedValue::Time(Some(Signed::Positive(ClockTime::SECOND))),
);
assert_eq!(signed.is_positive(), Some(true));
assert_eq!(signed.is_negative(), Some(false));
assert_eq!(signed.signum(), Some(1));
let signed = ct_1.into_negative();
assert_eq!(
signed,
GenericSignedFormattedValue::Time(Some(Signed::Negative(ClockTime::SECOND))),
);
assert_eq!(signed.is_negative(), Some(true));
assert_eq!(signed.is_positive(), Some(false));
assert_eq!(signed.signum(), Some(-1));
let ct_none = GenericFormattedValue::Time(ClockTime::NONE);
assert!(ct_none.is_none());
let signed = ct_none.into_positive();
assert_eq!(signed, GenericSignedFormattedValue::Time(None),);
assert!(signed.is_positive().is_none());
assert!(signed.is_negative().is_none());
assert!(signed.signum().is_none());
let signed = ct_none.into_negative();
assert_eq!(signed, GenericSignedFormattedValue::Time(None),);
assert!(signed.is_negative().is_none());
assert!(signed.is_positive().is_none());
assert!(signed.signum().is_none());
let ct_zero = GenericFormattedValue::Time(Some(ClockTime::ZERO));
assert!(ct_zero.is_some());
let signed = ct_zero.into_positive();
assert_eq!(
signed,
GenericSignedFormattedValue::Time(Some(Signed::Positive(ClockTime::ZERO))),
);
assert_eq!(signed.is_positive(), Some(true));
assert_eq!(signed.is_negative(), Some(false));
assert_eq!(signed.signum(), Some(0));
}
#[test]
fn signed_roundtrip() {
let ct_1 = Some(ClockTime::SECOND);
let raw_ct_1 = unsafe { ct_1.into_raw_value() };
let signed = unsafe { Option::<ClockTime>::from_raw(Format::Time, raw_ct_1) }
.into_signed(1)
.unwrap();
assert_eq!(signed, Signed::Positive(ClockTime::SECOND));
assert!(signed.is_positive());
let signed = unsafe { Option::<ClockTime>::from_raw(Format::Time, raw_ct_1) }
.into_signed(-1)
.unwrap();
assert_eq!(signed, Signed::Negative(ClockTime::SECOND));
assert!(signed.is_negative());
let ct_none = ClockTime::NONE;
let raw_ct_none = unsafe { ct_none.into_raw_value() };
let signed =
unsafe { Option::<ClockTime>::from_raw(Format::Time, raw_ct_none) }.into_signed(1);
assert!(signed.is_none());
let signed =
unsafe { Option::<ClockTime>::from_raw(Format::Time, raw_ct_none) }.into_signed(-1);
assert!(signed.is_none());
}
#[test]
fn display_new_types() {
let bytes = 42.bytes();
assert_eq!(&format!("{bytes}"), "42 bytes");
assert_eq!(&format!("{}", bytes.display()), "42 bytes");
assert_eq!(&format!("{}", Some(bytes).display()), "42 bytes");
assert_eq!(&format!("{}", Bytes::NONE.display()), "undef. bytes");
let gv_1 = GenericFormattedValue::Percent(Some(42.percent()));
assert_eq!(&format!("{gv_1}"), "42 %");
assert_eq!(
&format!("{}", GenericFormattedValue::Percent(None)),
"undef. %"
);
let percent = Percent::try_from(0.1234).unwrap();
assert_eq!(&format!("{percent}"), "12.34 %");
assert_eq!(&format!("{percent:5.1}"), " 12.3 %");
let other: Other = 42.try_into().unwrap();
assert_eq!(&format!("{other}"), "42");
let g_other = GenericFormattedValue::new(Format::__Unknown(128), 42);
assert_eq!(&format!("{g_other}"), "42 (format: 128)");
assert_eq!(&format!("{}", g_other.display()), "42 (format: 128)");
let g_other_none = GenericFormattedValue::Other(Format::__Unknown(128), None);
assert_eq!(&format!("{g_other_none}"), "undef. (format: 128)");
assert_eq!(
&format!("{}", g_other_none.display()),
"undef. (format: 128)"
);
}
#[test]
fn display_signed() {
let bytes_42 = 42.bytes();
let p_bytes = bytes_42.into_positive();
assert_eq!(&format!("{p_bytes}"), "+42 bytes");
assert_eq!(&format!("{}", p_bytes.display()), "+42 bytes");
let some_p_bytes = Some(p_bytes);
assert_eq!(&format!("{}", some_p_bytes.display()), "+42 bytes");
let p_some_bytes = Signed::Positive(Some(bytes_42));
assert_eq!(&format!("{}", p_some_bytes.display()), "+42 bytes");
let n_bytes = bytes_42.into_negative();
assert_eq!(&format!("{n_bytes}"), "-42 bytes");
assert_eq!(&format!("{}", n_bytes.display()), "-42 bytes");
let some_n_bytes = Some(n_bytes);
assert_eq!(&format!("{}", some_n_bytes.display()), "-42 bytes");
let n_some_bytes = Signed::Negative(Some(bytes_42));
assert_eq!(&format!("{}", n_some_bytes.display()), "-42 bytes");
let p_none_bytes = Signed::Positive(Bytes::NONE);
assert_eq!(&format!("{}", p_none_bytes.display()), "undef. bytes");
let n_none_bytes = Signed::Negative(Bytes::NONE);
assert_eq!(&format!("{}", n_none_bytes.display()), "undef. bytes");
let none_s_bytes = Option::<Signed<Bytes>>::None;
assert_eq!(&format!("{}", none_s_bytes.display()), "undef. bytes");
let ct_1 = 45_834_908_569_837 * ClockTime::NSECOND;
assert_eq!(&format!("{ct_1}"), "12:43:54.908569837");
assert_eq!(&format!("{}", ct_1.display()), "12:43:54.908569837");
let g_ct_1 = GenericFormattedValue::Time(Some(ct_1));
assert_eq!(&format!("{g_ct_1}"), "12:43:54.908569837");
assert_eq!(&format!("{}", g_ct_1.display()), "12:43:54.908569837");
let p_g_ct1 = g_ct_1.into_positive();
assert_eq!(&format!("{p_g_ct1}"), "+12:43:54.908569837");
assert_eq!(&format!("{}", p_g_ct1.display()), "+12:43:54.908569837");
let n_g_ct1 = g_ct_1.into_negative();
assert_eq!(&format!("{n_g_ct1}"), "-12:43:54.908569837");
assert_eq!(&format!("{}", n_g_ct1.display()), "-12:43:54.908569837");
}
}