helix-mirror/helix-core/src/selection.rs

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//! Selections are the primary editing construct. Even a single cursor is
//! defined as a single empty or 1-wide selection range.
//!
//! All positioning is done via `char` offsets into the buffer.
use crate::{
graphemes::{
ensure_grapheme_boundary_next, ensure_grapheme_boundary_prev, next_grapheme_boundary,
prev_grapheme_boundary,
},
Assoc, ChangeSet, RopeSlice,
};
use smallvec::{smallvec, SmallVec};
use std::borrow::Cow;
/// A single selection range.
///
/// The range consists of an "anchor" and "head" position in
/// the text. The head is the part that the user moves when
/// directly extending the selection. The head and anchor
/// can be in any order: either can precede or follow the
/// other in the text, and they can share the same position
/// for a zero-width range.
///
/// Below are some example `Range` configurations to better
/// illustrate. The anchor and head indices are show as
/// "(anchor, head)", followed by example text with "[" and "]"
/// inserted to visually represent the anchor and head positions:
///
/// - (0, 3): [Som]e text.
/// - (3, 0): ]Som[e text.
/// - (2, 7): So[me te]xt.
/// - (1, 1): S[]ome text.
///
/// Ranges are considered to be inclusive on the left and
/// exclusive on the right, regardless of anchor-head ordering.
/// This means, for example, that non-zero-width ranges that
/// are directly adjecent, sharing an edge, do not overlap.
/// However, a zero-width range will overlap with the shared
/// left-edge of another range.
#[derive(Debug, Clone, Copy, PartialEq, Eq)]
pub struct Range {
/// The anchor of the range: the side that doesn't move when extending.
pub anchor: usize,
/// The head of the range, moved when extending.
pub head: usize,
pub horiz: Option<u32>,
}
impl Range {
pub fn new(anchor: usize, head: usize) -> Self {
Self {
anchor,
head,
horiz: None,
}
}
pub fn point(head: usize) -> Self {
Self::new(head, head)
}
/// Start of the range.
#[inline]
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#[must_use]
pub fn from(&self) -> usize {
std::cmp::min(self.anchor, self.head)
}
/// End of the range.
#[inline]
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#[must_use]
pub fn to(&self) -> usize {
std::cmp::max(self.anchor, self.head)
}
/// `true` when head and anchor are at the same position.
#[inline]
pub fn is_empty(&self) -> bool {
self.anchor == self.head
}
/// Check two ranges for overlap.
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#[must_use]
pub fn overlaps(&self, other: &Self) -> bool {
// To my eye, it's non-obvious why this works, but I arrived
// at it after transforming the slower version that explicitly
// enumerated more cases. The unit tests are thorough.
self.from() == other.from() || (self.to() > other.from() && other.to() > self.from())
}
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pub fn contains(&self, pos: usize) -> bool {
self.from() <= pos && pos < self.to()
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}
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/// Map a range through a set of changes. Returns a new range representing the same position
/// after the changes are applied.
pub fn map(self, changes: &ChangeSet) -> Self {
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let anchor = changes.map_pos(self.anchor, Assoc::After);
let head = changes.map_pos(self.head, Assoc::After);
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// We want to return a new `Range` with `horiz == None` every time,
// even if the anchor and head haven't changed, because we don't
// know if the *visual* position hasn't changed due to
// character-width or grapheme changes earlier in the text.
Self {
anchor,
head,
horiz: None,
}
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}
/// Extend the range to cover at least `from` `to`.
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#[must_use]
pub fn extend(&self, from: usize, to: usize) -> Self {
debug_assert!(from <= to);
if self.anchor <= self.head {
Self {
anchor: self.anchor.min(from),
head: self.head.max(to),
horiz: None,
}
} else {
Self {
anchor: self.anchor.max(to),
head: self.head.min(from),
horiz: None,
}
}
}
/// Returns a range that encompasses both input ranges.
///
/// This is like `extend()`, but tries to negotiate the
/// anchor/head ordering between the two input ranges.
#[must_use]
pub fn merge(&self, other: Self) -> Self {
if self.anchor > self.head && other.anchor > other.head {
Range {
anchor: self.anchor.max(other.anchor),
head: self.head.min(other.head),
horiz: None,
}
} else {
Range {
anchor: self.from().min(other.from()),
head: self.to().max(other.to()),
horiz: None,
}
}
}
/// Compute a possibly new range from this range, attempting to ensure
/// a minimum range width of 1 char by shifting the head in the forward
/// direction as needed.
///
/// This method will never shift the anchor, and will only shift the
/// head in the forward direction. Therefore, this method can fail
/// at ensuring the minimum width if and only if the passed range is
/// both zero-width and at the end of the `RopeSlice`.
///
/// If the input range is grapheme-boundary aligned, the returned range
/// will also be. Specifically, if the head needs to shift to achieve
/// the minimum width, it will shift to the next grapheme boundary.
#[must_use]
#[inline]
pub fn min_width_1(&self, slice: RopeSlice) -> Self {
if self.anchor == self.head {
Range {
anchor: self.anchor,
head: next_grapheme_boundary(slice, self.head),
horiz: self.horiz,
}
} else {
*self
}
}
/// Compute a possibly new range from this range, with its ends
/// shifted as needed to align with grapheme boundaries.
///
/// Zero-width ranges will always stay zero-width, and non-zero-width
/// ranges will never collapse to zero-width.
#[must_use]
pub fn grapheme_aligned(&self, slice: RopeSlice) -> Self {
use std::cmp::Ordering;
let (new_anchor, new_head) = match self.anchor.cmp(&self.head) {
Ordering::Equal => {
let pos = ensure_grapheme_boundary_prev(slice, self.anchor);
(pos, pos)
}
Ordering::Less => (
ensure_grapheme_boundary_prev(slice, self.anchor),
ensure_grapheme_boundary_next(slice, self.head),
),
Ordering::Greater => (
ensure_grapheme_boundary_next(slice, self.anchor),
ensure_grapheme_boundary_prev(slice, self.head),
),
};
Range {
anchor: new_anchor,
head: new_head,
horiz: if new_anchor == self.anchor {
self.horiz
} else {
None
},
}
}
/// Moves the `Range` to `char_idx`. If `extend == true`, then only the head
/// is moved to `char_idx`, and the anchor is adjusted only as needed to
/// preserve 1-width range semantics.
///
/// This method assumes that the range and `char_idx` are already properly
/// grapheme-aligned.
#[must_use]
#[inline]
pub fn put(self, text: RopeSlice, char_idx: usize, extend: bool) -> Range {
let anchor = if !extend {
char_idx
} else if self.head >= self.anchor && char_idx < self.anchor {
next_grapheme_boundary(text, self.anchor)
} else if self.head < self.anchor && char_idx >= self.anchor {
prev_grapheme_boundary(text, self.anchor)
} else {
self.anchor
};
Range::new(anchor, char_idx)
}
// groupAt
#[inline]
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pub fn fragment<'a, 'b: 'a>(&'a self, text: RopeSlice<'b>) -> Cow<'b, str> {
text.slice(self.from()..self.to()).into()
}
}
impl From<(usize, usize)> for Range {
fn from(tuple: (usize, usize)) -> Self {
Self {
anchor: tuple.0,
head: tuple.1,
horiz: None,
}
}
}
/// 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)]
pub struct Selection {
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ranges: SmallVec<[Range; 1]>,
primary_index: usize,
}
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#[allow(clippy::len_without_is_empty)] // a Selection is never empty
impl Selection {
// eq
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#[must_use]
pub fn primary(&self) -> Range {
self.ranges[self.primary_index]
}
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#[must_use]
pub fn cursor(&self, text: RopeSlice) -> usize {
let range = self.primary();
// For 1-width cursor semantics.
if range.anchor < range.head {
prev_grapheme_boundary(text, range.head)
} else {
range.head
}
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}
/// Ensure selection containing only the primary selection.
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pub fn into_single(self) -> Self {
if self.ranges.len() == 1 {
self
} else {
Self {
ranges: smallvec![self.ranges[self.primary_index]],
primary_index: 0,
}
}
}
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pub fn push(mut self, range: Range) -> Self {
self.ranges.push(range);
self.normalize()
}
// replace_range
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/// Map selections over a set of changes. Useful for adjusting the selection position after
/// applying changes to a document.
pub fn map(self, changes: &ChangeSet) -> Self {
if changes.is_empty() {
return self;
}
Self::new(
self.ranges
.into_iter()
.map(|range| range.map(changes))
.collect(),
self.primary_index,
)
}
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pub fn ranges(&self) -> &[Range] {
&self.ranges
}
pub fn primary_index(&self) -> usize {
self.primary_index
}
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#[must_use]
/// Constructs a selection holding a single range.
pub fn single(anchor: usize, head: usize) -> Self {
Self {
ranges: smallvec![Range {
anchor,
head,
horiz: None
}],
primary_index: 0,
}
}
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/// Constructs a selection holding a single cursor.
pub fn point(pos: usize) -> Self {
Self::single(pos, pos)
}
/// Normalizes a `Selection`.
fn normalize(mut self) -> Self {
let primary = self.ranges[self.primary_index];
self.ranges.sort_unstable_by_key(Range::from);
self.primary_index = self
.ranges
.iter()
.position(|&range| range == primary)
.unwrap();
let mut prev_i = 0;
for i in 1..self.ranges.len() {
if self.ranges[prev_i].overlaps(&self.ranges[i]) {
if i == self.primary_index {
self.primary_index = prev_i;
}
self.ranges[prev_i] = self.ranges[prev_i].merge(self.ranges[i]);
} else {
prev_i += 1;
self.ranges[prev_i] = self.ranges[i];
}
}
self.ranges.truncate(prev_i + 1);
self
}
// TODO: consume an iterator or a vec to reduce allocations?
#[must_use]
pub fn new(ranges: SmallVec<[Range; 1]>, primary_index: usize) -> Self {
assert!(!ranges.is_empty());
debug_assert!(primary_index < ranges.len());
let mut selection = Self {
ranges,
primary_index,
};
if selection.ranges.len() > 1 {
// TODO: only normalize if needed (any ranges out of order)
selection = selection.normalize();
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}
selection
}
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/// Takes a closure and maps each `Range` over the closure.
pub fn transform<F>(mut self, f: F) -> Self
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where
F: Fn(Range) -> Range,
{
for range in self.ranges.iter_mut() {
*range = f(*range)
}
self.normalize()
}
/// A convenience short-cut for `transform(|r| r.min_width_1(text))`.
pub fn min_width_1(self, text: RopeSlice) -> Self {
self.transform(|r| r.min_width_1(text))
}
pub fn fragments<'a>(&'a self, text: RopeSlice<'a>) -> impl Iterator<Item = Cow<str>> + 'a {
self.ranges.iter().map(move |range| range.fragment(text))
}
#[inline(always)]
pub fn iter(&self) -> std::slice::Iter<'_, Range> {
self.ranges.iter()
}
#[inline(always)]
pub fn len(&self) -> usize {
self.ranges.len()
}
}
impl<'a> IntoIterator for &'a Selection {
type Item = &'a Range;
type IntoIter = std::slice::Iter<'a, Range>;
fn into_iter(self) -> std::slice::Iter<'a, Range> {
self.ranges().iter()
}
}
// TODO: checkSelection -> check if valid for doc length && sorted
pub fn keep_matches(
text: RopeSlice,
selection: &Selection,
regex: &crate::regex::Regex,
) -> Option<Selection> {
let result: SmallVec<_> = selection
.iter()
.filter(|range| regex.is_match(&range.fragment(text)))
.copied()
.collect();
// TODO: figure out a new primary index
if !result.is_empty() {
return Some(Selection::new(result, 0));
}
None
}
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pub fn select_on_matches(
text: RopeSlice,
selection: &Selection,
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regex: &crate::regex::Regex,
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) -> Option<Selection> {
let mut result = SmallVec::with_capacity(selection.len());
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for sel in selection {
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// TODO: can't avoid occasional allocations since Regex can't operate on chunks yet
let fragment = sel.fragment(text);
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let sel_start = sel.from();
let start_byte = text.char_to_byte(sel_start);
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for mat in regex.find_iter(&fragment) {
// TODO: retain range direction
let start = text.byte_to_char(start_byte + mat.start());
let end = text.byte_to_char(start_byte + mat.end());
result.push(Range::new(start, end));
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}
}
// TODO: figure out a new primary index
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if !result.is_empty() {
return Some(Selection::new(result, 0));
}
None
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}
// TODO: support to split on capture #N instead of whole match
pub fn split_on_matches(
text: RopeSlice,
selection: &Selection,
regex: &crate::regex::Regex,
) -> Selection {
let mut result = SmallVec::with_capacity(selection.len());
for sel in selection {
// Special case: zero-width selection.
if sel.from() == sel.to() {
result.push(*sel);
continue;
}
// TODO: can't avoid occasional allocations since Regex can't operate on chunks yet
let fragment = sel.fragment(text);
let sel_start = sel.from();
let sel_end = sel.to();
let start_byte = text.char_to_byte(sel_start);
let mut start = sel_start;
for mat in regex.find_iter(&fragment) {
// TODO: retain range direction
let end = text.byte_to_char(start_byte + mat.start());
result.push(Range::new(start, end));
start = text.byte_to_char(start_byte + mat.end());
}
if start < sel_end {
result.push(Range::new(start, sel_end));
}
}
// TODO: figure out a new primary index
Selection::new(result, 0)
}
#[cfg(test)]
mod test {
use super::*;
use crate::Rope;
#[test]
#[should_panic]
fn test_new_empty() {
let _ = Selection::new(smallvec![], 0);
}
#[test]
fn test_create_normalizes_and_merges() {
let sel = Selection::new(
smallvec![
Range::new(10, 12),
Range::new(6, 7),
Range::new(4, 5),
Range::new(3, 4),
Range::new(0, 6),
Range::new(7, 8),
Range::new(9, 13),
Range::new(13, 14),
],
0,
);
let res = sel
.ranges
.into_iter()
.map(|range| format!("{}/{}", range.anchor, range.head))
.collect::<Vec<String>>()
.join(",");
assert_eq!(res, "0/6,6/7,7/8,9/13,13/14");
// it correctly calculates a new primary index
let sel = Selection::new(
smallvec![Range::new(0, 2), Range::new(1, 5), Range::new(4, 7)],
2,
);
let res = sel
.ranges
.into_iter()
.map(|range| format!("{}/{}", range.anchor, range.head))
.collect::<Vec<String>>()
.join(",");
assert_eq!(res, "0/7");
assert_eq!(sel.primary_index, 0);
}
#[test]
fn test_create_merges_adjacent_points() {
let sel = Selection::new(
smallvec![
Range::new(10, 12),
Range::new(12, 12),
Range::new(12, 12),
Range::new(10, 10),
Range::new(8, 10),
],
0,
);
let res = sel
.ranges
.into_iter()
.map(|range| format!("{}/{}", range.anchor, range.head))
.collect::<Vec<String>>()
.join(",");
assert_eq!(res, "8/10,10/12,12/12");
}
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#[test]
fn test_contains() {
let range = Range::new(10, 12);
assert_eq!(range.contains(9), false);
assert_eq!(range.contains(10), true);
assert_eq!(range.contains(11), true);
assert_eq!(range.contains(12), false);
assert_eq!(range.contains(13), false);
let range = Range::new(9, 6);
assert_eq!(range.contains(9), false);
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assert_eq!(range.contains(7), true);
assert_eq!(range.contains(6), true);
}
#[test]
fn test_overlaps() {
fn overlaps(a: (usize, usize), b: (usize, usize)) -> bool {
Range::new(a.0, a.1).overlaps(&Range::new(b.0, b.1))
}
// Two non-zero-width ranges, no overlap.
assert!(!overlaps((0, 3), (3, 6)));
assert!(!overlaps((0, 3), (6, 3)));
assert!(!overlaps((3, 0), (3, 6)));
assert!(!overlaps((3, 0), (6, 3)));
assert!(!overlaps((3, 6), (0, 3)));
assert!(!overlaps((3, 6), (3, 0)));
assert!(!overlaps((6, 3), (0, 3)));
assert!(!overlaps((6, 3), (3, 0)));
// Two non-zero-width ranges, overlap.
assert!(overlaps((0, 4), (3, 6)));
assert!(overlaps((0, 4), (6, 3)));
assert!(overlaps((4, 0), (3, 6)));
assert!(overlaps((4, 0), (6, 3)));
assert!(overlaps((3, 6), (0, 4)));
assert!(overlaps((3, 6), (4, 0)));
assert!(overlaps((6, 3), (0, 4)));
assert!(overlaps((6, 3), (4, 0)));
// Zero-width and non-zero-width range, no overlap.
assert!(!overlaps((0, 3), (3, 3)));
assert!(!overlaps((3, 0), (3, 3)));
assert!(!overlaps((3, 3), (0, 3)));
assert!(!overlaps((3, 3), (3, 0)));
// Zero-width and non-zero-width range, overlap.
assert!(overlaps((1, 4), (1, 1)));
assert!(overlaps((4, 1), (1, 1)));
assert!(overlaps((1, 1), (1, 4)));
assert!(overlaps((1, 1), (4, 1)));
assert!(overlaps((1, 4), (3, 3)));
assert!(overlaps((4, 1), (3, 3)));
assert!(overlaps((3, 3), (1, 4)));
assert!(overlaps((3, 3), (4, 1)));
// Two zero-width ranges, no overlap.
assert!(!overlaps((0, 0), (1, 1)));
assert!(!overlaps((1, 1), (0, 0)));
// Two zero-width ranges, overlap.
assert!(overlaps((1, 1), (1, 1)));
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}
#[test]
fn test_graphem_aligned() {
let r = Rope::from_str("\r\nHi\r\n");
let s = r.slice(..);
// Zero-width.
assert_eq!(Range::new(0, 0).grapheme_aligned(s), Range::new(0, 0));
assert_eq!(Range::new(1, 1).grapheme_aligned(s), Range::new(0, 0));
assert_eq!(Range::new(2, 2).grapheme_aligned(s), Range::new(2, 2));
assert_eq!(Range::new(3, 3).grapheme_aligned(s), Range::new(3, 3));
assert_eq!(Range::new(4, 4).grapheme_aligned(s), Range::new(4, 4));
assert_eq!(Range::new(5, 5).grapheme_aligned(s), Range::new(4, 4));
assert_eq!(Range::new(6, 6).grapheme_aligned(s), Range::new(6, 6));
// Forward.
assert_eq!(Range::new(0, 1).grapheme_aligned(s), Range::new(0, 2));
assert_eq!(Range::new(1, 2).grapheme_aligned(s), Range::new(0, 2));
assert_eq!(Range::new(2, 3).grapheme_aligned(s), Range::new(2, 3));
assert_eq!(Range::new(3, 4).grapheme_aligned(s), Range::new(3, 4));
assert_eq!(Range::new(4, 5).grapheme_aligned(s), Range::new(4, 6));
assert_eq!(Range::new(5, 6).grapheme_aligned(s), Range::new(4, 6));
assert_eq!(Range::new(0, 2).grapheme_aligned(s), Range::new(0, 2));
assert_eq!(Range::new(1, 3).grapheme_aligned(s), Range::new(0, 3));
assert_eq!(Range::new(2, 4).grapheme_aligned(s), Range::new(2, 4));
assert_eq!(Range::new(3, 5).grapheme_aligned(s), Range::new(3, 6));
assert_eq!(Range::new(4, 6).grapheme_aligned(s), Range::new(4, 6));
// Reverse.
assert_eq!(Range::new(1, 0).grapheme_aligned(s), Range::new(2, 0));
assert_eq!(Range::new(2, 1).grapheme_aligned(s), Range::new(2, 0));
assert_eq!(Range::new(3, 2).grapheme_aligned(s), Range::new(3, 2));
assert_eq!(Range::new(4, 3).grapheme_aligned(s), Range::new(4, 3));
assert_eq!(Range::new(5, 4).grapheme_aligned(s), Range::new(6, 4));
assert_eq!(Range::new(6, 5).grapheme_aligned(s), Range::new(6, 4));
assert_eq!(Range::new(2, 0).grapheme_aligned(s), Range::new(2, 0));
assert_eq!(Range::new(3, 1).grapheme_aligned(s), Range::new(3, 0));
assert_eq!(Range::new(4, 2).grapheme_aligned(s), Range::new(4, 2));
assert_eq!(Range::new(5, 3).grapheme_aligned(s), Range::new(6, 3));
assert_eq!(Range::new(6, 4).grapheme_aligned(s), Range::new(6, 4));
}
#[test]
fn test_min_width_1() {
let r = Rope::from_str("\r\nHi\r\n");
let s = r.slice(..);
// Zero-width.
assert_eq!(Range::new(0, 0).min_width_1(s), Range::new(0, 2));
assert_eq!(Range::new(1, 1).min_width_1(s), Range::new(1, 2));
assert_eq!(Range::new(2, 2).min_width_1(s), Range::new(2, 3));
assert_eq!(Range::new(3, 3).min_width_1(s), Range::new(3, 4));
assert_eq!(Range::new(4, 4).min_width_1(s), Range::new(4, 6));
assert_eq!(Range::new(5, 5).min_width_1(s), Range::new(5, 6));
assert_eq!(Range::new(6, 6).min_width_1(s), Range::new(6, 6));
// Forward.
assert_eq!(Range::new(0, 1).min_width_1(s), Range::new(0, 1));
assert_eq!(Range::new(1, 2).min_width_1(s), Range::new(1, 2));
assert_eq!(Range::new(2, 3).min_width_1(s), Range::new(2, 3));
assert_eq!(Range::new(3, 4).min_width_1(s), Range::new(3, 4));
assert_eq!(Range::new(4, 5).min_width_1(s), Range::new(4, 5));
assert_eq!(Range::new(5, 6).min_width_1(s), Range::new(5, 6));
// Reverse.
assert_eq!(Range::new(1, 0).min_width_1(s), Range::new(1, 0));
assert_eq!(Range::new(2, 1).min_width_1(s), Range::new(2, 1));
assert_eq!(Range::new(3, 2).min_width_1(s), Range::new(3, 2));
assert_eq!(Range::new(4, 3).min_width_1(s), Range::new(4, 3));
assert_eq!(Range::new(5, 4).min_width_1(s), Range::new(5, 4));
assert_eq!(Range::new(6, 5).min_width_1(s), Range::new(6, 5));
}
#[test]
fn test_split_on_matches() {
use crate::regex::Regex;
let text = Rope::from(" abcd efg wrs xyz 123 456");
let selection = Selection::new(smallvec![Range::new(0, 9), Range::new(11, 20),], 0);
let result = split_on_matches(text.slice(..), &selection, &Regex::new(r"\s+").unwrap());
assert_eq!(
result.ranges(),
&[
// TODO: rather than this behavior, maybe we want it
// to be based on which side is the anchor?
//
// We get a leading zero-width range when there's
// a leading match because ranges are inclusive on
// the left. Imagine, for example, if the entire
// selection range were matched: you'd still want
// at least one range to remain after the split.
Range::new(0, 0),
Range::new(1, 5),
Range::new(6, 9),
Range::new(11, 13),
Range::new(16, 19),
// In contrast to the comment above, there is no
// _trailing_ zero-width range despite the trailing
// match, because ranges are exclusive on the right.
]
);
assert_eq!(
result.fragments(text.slice(..)).collect::<Vec<_>>(),
&["", "abcd", "efg", "rs", "xyz"]
);
}
}