Crate sort_by_derive
source · [−]Expand description
sort_by_derive
This crate provides 3 derive macros SortBy
, EnumAccessor
and EnumSequence
.
SortBy
derives the traitsOrd
,PartialOrd
,Eq
,PartialEq
andHash
on structs that can’t automatically derive those traits because they contain unorderable fields such asf32
.- On enums and structs,
SortBy
can also implement aOrd
trait that calls arbitrary methods - this is particularly useful in combination with enum variant accessor methods derived byEnumAccessor
anEnumSequence
EnumAccessor
derives accessor methods to common fields in variants - so you don’t need to write yourselfmatch
statements to access a field with the same name and type on different variants.EnumSequence
provides aenum_sequence
method where the first variant returns0
, the second1
, etc. This is useful is you want to implement a custom sorting, while the order of declaration of variant is still relevant as a secondary ordering criteria.
Usage
SortBy
Fields that should be used for sorting are marked with the attribute #[sort_by]
. Other fields will be ignored.
Alternatively, or in combination with, a struct-level or enum-level #[sort_by(method1(),method2(),attr1,nested.attr)]
can be declared. This top-level declaration takes precedence,
fields comparison will be considered if top-level comparisons are all eq
. The top-level sort_by
attribute takes a list of attributes or method calls; items will be prepended with self.
.
Example
#[derive(SortBy)]
#[sort_by(somemethod())]
struct Something {
#[sort_by]
a: u16,
#[sort_by]
c: u32,
b: f32
}
will expand to:
impl std::hash::Hash for Something {
fn hash<H: std::hash::Hasher>(&self, state: &mut H) {
self.somemethod().hash(state);
self.a.hash(state);
self.c.hash(state);
}
}
impl core::cmp::Eq for Something {}
impl core::cmp::PartialEq<Self> for Something {
fn eq(&self, other: &Self) -> bool {
self.cmp(other).is_eq()
}
}
impl core::cmp::PartialOrd<Self> for Something {
fn partial_cmp(
&self,
other: &Self,
) -> core::option::Option<core::cmp::Ordering> {
std::option::Option::Some(self.cmp(other))
}
}
impl core::cmp::Ord for Something {
fn cmp(&self, other: &Self) -> core::cmp::Ordering {
core::cmp::Ord::cmp(&self.somemethod(), &other.somemethod())
.then_with(|| self.a.cmp(&other.a))
.then_with(|| self.c.cmp(&other.c))
}
}
EnumAccessor
Attributes are declared at top-level.
#[accessor(name: type)]
will derive the accessor methodsfn name(&self) -> &type;
andfn name_mut(&mut self) -> &mut type;
, and return a reference to the field of the same name on any variant.#[accessor(name: type, (Exception1,Exception2))]
derive the same accessor methods, but the return type will beOption<&type>
andOption<&mut type>
. The provided comma-separated list of variants are exceptions and will returnNone
.
Methods without arguments ( i.e. only &self
are also supported ). It takes the form: #[accessor(method_name(): type)]
.
Example
Say we have a series of midi events, they are very similar but with slight variations - they always have some timing information but they may not always have a pitch or channel.
Using #[accessor(global_time: usize)]
, a global_time(&self)
method is derived, along with a global_time_mut(&mut self)
, so without any boilerplate you can access the timing.
By declaring #[accessor(channel: u8, (CC))]
, channel(&self)
and channel_mut(&mut self)
are derived, but they return Some
for NoteOn
and NoteOff
, and None
for CC
and Unsupported
.
#[derive(EnumAccessor)]
#[accessor(global_time: usize)]
#[accessor(channel: u8, (CC))]
#[accessor(pitch: u8, (CC, Unsupported))]
enum Note {
NoteOn(NoteOn),
NoteOff(NoteOff),
CC(CC),
Unsupported {
global_time: usize,
rawdata: Vec<u8>
}
}
expands to:
pub trait NoteAccessor {
fn global_time(&self) -> &usize;
fn global_time_mut(&mut self) -> &mut usize;
fn channel(&self) -> std::option::Option<&u8>;
fn channel_mut(&mut self) -> std::option::Option<&mut u8>;
fn pitch(&self) -> std::option::Option<&u8>;
fn pitch_mut(&mut self) -> std::option::Option<&mut u8>;
}
impl NoteAccessor for Note {
fn global_time(&self) -> &usize {
match self {
Self::NoteOn(x) => &x.global_time,
Self::NoteOff(x) => &x.global_time,
Self::CC(x) => &x.global_time,
Self::Unsupported { global_time, .. } => global_time,
}
}
fn global_time_mut(&mut self) -> &mut usize {
match self {
Self::NoteOn(x) => &mut x.global_time,
Self::NoteOff(x) => &mut x.global_time,
Self::CC(x) => &mut x.global_time,
Self::Unsupported { global_time, .. } => global_time,
}
}
fn channel(&self) -> std::option::Option<&u8> {
match self {
Self::NoteOn(x) => std::option::Option::Some(&x.channel),
Self::NoteOff(x) => std::option::Option::Some(&x.channel),
Self::CC(x) => std::option::Option::Some(&x.channel),
Self::Unsupported { .. } => std::option::Option::None,
}
}
fn channel_mut(&mut self) -> std::option::Option<&mut u8> {
match self {
Self::NoteOn(x) => std::option::Option::Some(&mut x.channel),
Self::NoteOff(x) => std::option::Option::Some(&mut x.channel),
Self::CC(x) => std::option::Option::Some(&mut x.channel),
Self::Unsupported { .. } => std::option::Option::None,
}
}
fn pitch(&self) -> std::option::Option<&u8> {
match self {
Self::NoteOn(x) => std::option::Option::Some(&x.pitch),
Self::NoteOff(x) => std::option::Option::Some(&x.pitch),
Self::CC(_) => std::option::Option::None,
Self::Unsupported { .. } => std::option::Option::None,
}
}
fn pitch_mut(&mut self) -> std::option::Option<&mut u8> {
match self {
Self::NoteOn(x) => std::option::Option::Some(&mut x.pitch),
Self::NoteOff(x) => std::option::Option::Some(&mut x.pitch),
Self::CC(_) => std::option::Option::None,
Self::Unsupported { .. } => std::option::Option::None,
}
}
}
Example of method call
The General form is #[accessor(method():type)]
:
#[derive(EnumAccessor)]
#[accessor(method():type)]
enum E {
}
As for field access, declaring an exception will make the actual return type an Option<type>
.
Named fields is supported, it will consider that the named field is of type Fn() -> type
, and call it.
An intricate example:
struct A {
f1: u8,
f2: u8
}
impl A {
fn sum(&self) -> u8 {
self.f1 + self.f2
}
}
struct B {
values: Vec<u8>
}
impl B {
fn sum(&self) -> u8 {
self.values.iter().sum()
}
}
#[derive(EnumAccessor)]
#[accessor(sum():u8)]
enum E {
A(A),
B(B),
C{sum: Box<dyn Fn() -> u8>}
}
#[test]
fn test_sum() {
let a = E::A(A{ f1: 10, f2: 22 });
let b = E::B(B{ values: vec![9,4,3,2] });
let factor = Arc::new(AtomicU8::new(1));
let c = {
let factor = factor.clone();
E::C { sum: Box::new(move || 21 * factor.load(Ordering::Relaxed)) }
};
assert_eq!(32, a.sum());
assert_eq!(18, b.sum());
assert_eq!(21, c.sum());
factor.store(2, Ordering::Relaxed);
assert_eq!(42, c.sum());
}
EnumSequence
Simply derive EnumSequence
, and you get enum_sequence(&self)
which returns a usize
, starting from 0
and incrementing for each variant.
Example
#[derive(EnumSequence)]
enum ABC {
A(u8),
B(String),
C{f: String, g: usize}
}
expands to
pub trait ABCEnumSequence {
fn enum_sequence(&self) -> usize;
}
impl ABCEnumSequence for ABC {
fn enum_sequence(&self) -> usize {
match self {
Self::A(..) => 0usize,
Self::B(..) => 1usize,
Self::C { .. } => 2usize,
}
}
}
All together
Imagine the following :
#[derive(EnumSequence, EnumAccessor, SortBy, Debug)]
#[accessor(global_time: usize)]
#[accessor(channel: u8, (CC))]
#[accessor(pitch: u8, (CC,SomethingElse))]
#[sort_by(global_time(), channel(), pitch(), enum_sequence())]
enum Note {
NoteOn(NoteOn),
NoteOff(NoteOff),
CC(CC),
SomethingElse {
global_time: usize,
channel: u8,
}
}
Now I have a Note
enum that will sort by global_time
, channel
, pitch
, and lastly by variant order ( enum_sequence
). Note that None
is always less than Some
.
Conversely, separate structs such as NoteOn
may derive from SortBy
in order to ignore some fields ( ex: velocity
may be a f32
, so we can’t directly derive Ord
).
Limitations
- On unnamed variants,
EnumAccessor
only considers the first parameter. - struct-level
sort_by
attribute always come before field-level attributes.