Add range type to helix stdx

This commit is contained in:
Pascal Kuthe 2024-02-22 21:47:12 +01:00
parent a1e20a3426
commit 97a35d2812
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GPG Key ID: D715E8655AE166A6
4 changed files with 123 additions and 38 deletions

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@ -1,6 +1,7 @@
//! LSP diagnostic utility types.
use std::fmt;
pub use helix_stdx::range::Range;
use serde::{Deserialize, Serialize};
/// Describes the severity level of a [`Diagnostic`].
@ -19,19 +20,6 @@ fn default() -> Self {
}
}
/// A range of `char`s within the text.
#[derive(Debug, Clone, Copy, PartialOrd, Ord, PartialEq, Eq)]
pub struct Range {
pub start: usize,
pub end: usize,
}
impl Range {
pub fn contains(self, pos: usize) -> bool {
(self.start..self.end).contains(&pos)
}
}
#[derive(Debug, Eq, Hash, PartialEq, Clone, Deserialize, Serialize)]
pub enum NumberOrString {
Number(i32),

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@ -11,6 +11,7 @@
movement::Direction,
Assoc, ChangeSet, RopeGraphemes, RopeSlice,
};
use helix_stdx::range::is_subset;
use helix_stdx::rope::{self, RopeSliceExt};
use smallvec::{smallvec, SmallVec};
use std::{borrow::Cow, iter, slice};
@ -401,6 +402,15 @@ fn from((anchor, head): (usize, usize)) -> Self {
}
}
impl From<Range> for helix_stdx::Range {
fn from(range: Range) -> Self {
Self {
start: range.from(),
end: range.to(),
}
}
}
/// A selection consists of one or more selection ranges.
/// invariant: A selection can never be empty (always contains at least primary range).
#[derive(Debug, Clone, PartialEq, Eq)]
@ -513,6 +523,10 @@ pub fn line_ranges<'a>(&'a self, text: RopeSlice<'a>) -> LineRangeIter<'a> {
}
}
pub fn range_bounds(&self) -> impl Iterator<Item = helix_stdx::Range> + '_ {
self.ranges.iter().map(|&range| range.into())
}
pub fn primary_index(&self) -> usize {
self.primary_index
}
@ -683,32 +697,9 @@ pub fn len(&self) -> usize {
self.ranges.len()
}
// returns true if self ⊇ other
/// returns true if self ⊇ other
pub fn contains(&self, other: &Selection) -> bool {
let (mut iter_self, mut iter_other) = (self.iter(), other.iter());
let (mut ele_self, mut ele_other) = (iter_self.next(), iter_other.next());
loop {
match (ele_self, ele_other) {
(Some(ra), Some(rb)) => {
if !ra.contains_range(rb) {
// `self` doesn't contain next element from `other`, advance `self`, we need to match all from `other`
ele_self = iter_self.next();
} else {
// matched element from `other`, advance `other`
ele_other = iter_other.next();
};
}
(None, Some(_)) => {
// exhausted `self`, we can't match the reminder of `other`
return false;
}
(_, None) => {
// no elements from `other` left to match, `self` contains `other`
return true;
}
}
}
is_subset::<true>(self.range_bounds(), other.range_bounds())
}
}

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@ -1,4 +1,7 @@
pub mod env;
pub mod faccess;
pub mod path;
pub mod range;
pub mod rope;
pub use range::Range;

103
helix-stdx/src/range.rs Normal file
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@ -0,0 +1,103 @@
use std::ops::{self, RangeBounds};
/// A range of `char`s within the text.
#[derive(Debug, Clone, Copy, PartialOrd, Ord, PartialEq, Eq)]
pub struct Range<T = usize> {
pub start: T,
pub end: T,
}
impl<T: PartialOrd> Range<T> {
pub fn contains(&self, other: Self) -> bool {
self.start <= other.start && other.end <= self.end
}
pub fn is_empty(&self) -> bool {
self.end <= self.start
}
}
impl<T> RangeBounds<T> for Range<T> {
fn start_bound(&self) -> ops::Bound<&T> {
ops::Bound::Included(&self.start)
}
fn end_bound(&self) -> ops::Bound<&T> {
ops::Bound::Excluded(&self.end)
}
}
/// Returns true if all ranges yielded by `sub_set` are contained by
/// `super_set`. This is essentially an optimized implementation of
/// `sub_set.all(|rb| super_set.any(|ra| ra.contains(rb)))` that runs in O(m+n)
/// instead of O(mn) (and in many cases faster).
///
/// Both iterators must uphold a the follwong invariants:
/// * ranges must not overlap (but they can be adjecent)
/// * ranges must be sorted
pub fn is_subset<const ALLOW_EMPTY: bool>(
mut super_set: impl Iterator<Item = Range>,
mut sub_set: impl Iterator<Item = Range>,
) -> bool {
let (mut super_range, mut sub_range) = (super_set.next(), sub_set.next());
loop {
match (super_range, sub_range) {
// skip over irrelevant ranges
(Some(ra), Some(rb))
if ra.end <= rb.start && (ra.start != rb.start || !ALLOW_EMPTY) =>
{
super_range = super_set.next();
}
(Some(ra), Some(rb)) => {
if ra.contains(rb) {
sub_range = sub_set.next();
} else {
return false;
}
}
(None, Some(_)) => {
// exhausted `super_set`, we can't match the reminder of `sub_set`
return false;
}
(_, None) => {
// no elements from `sub_sut` left to match, `super_set` contains `sub_set`
return true;
}
}
}
}
pub fn is_exact_subset(
mut super_set: impl Iterator<Item = Range>,
mut sub_set: impl Iterator<Item = Range>,
) -> bool {
let (mut super_range, mut sub_range) = (super_set.next(), sub_set.next());
let mut super_range_matched = true;
loop {
match (super_range, sub_range) {
// skip over irrelevant ranges
(Some(ra), Some(rb)) if ra.end <= rb.start && ra.start < rb.start => {
if !super_range_matched {
return false;
}
super_range_matched = false;
super_range = super_set.next();
}
(Some(ra), Some(rb)) => {
if ra.contains(rb) {
super_range_matched = true;
sub_range = sub_set.next();
} else {
return false;
}
}
(None, Some(_)) => {
// exhausted `super_set`, we can't match the reminder of `sub_set`
return false;
}
(_, None) => {
// no elements from `sub_sut` left to match, `super_set` contains `sub_set`
return super_set.next().is_none();
}
}
}
}