mirror of
https://github.com/fish-shell/fish-shell.git
synced 2024-12-26 04:03:52 +08:00
622 lines
21 KiB
Rust
622 lines
21 KiB
Rust
//! Helper functions for working with wcstring.
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use crate::common::{get_ellipsis_char, get_ellipsis_str};
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use crate::compat::MB_CUR_MAX;
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use crate::expand::INTERNAL_SEPARATOR;
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use crate::fallback::{fish_wcwidth, wcscasecmp};
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use crate::flog::FLOGF;
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use crate::wchar::{decode_byte_from_char, wstr, WString, L};
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use crate::wchar_ext::WExt;
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use crate::wutil::encoding::{wcrtomb, zero_mbstate, AT_LEAST_MB_LEN_MAX};
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/// Test if a string prefixes another without regard to case. Returns true if a is a prefix of b.
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pub fn string_prefixes_string_case_insensitive(proposed_prefix: &wstr, value: &wstr) -> bool {
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let prefix_size = proposed_prefix.len();
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prefix_size <= value.len() && wcscasecmp(&value[..prefix_size], proposed_prefix).is_eq()
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}
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/// Test if a string is a suffix of another.
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pub fn string_suffixes_string_case_insensitive(proposed_suffix: &wstr, value: &wstr) -> bool {
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let suffix_size = proposed_suffix.len();
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suffix_size <= value.len()
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&& wcscasecmp(&value[value.len() - suffix_size..], proposed_suffix).is_eq()
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}
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/// Test if a string matches a subsequence of another.
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/// Note subsequence is not substring: "foo" is a subsequence of "follow" for example.
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pub fn subsequence_in_string(needle: &wstr, haystack: &wstr) -> bool {
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// Impossible if needle is larger than haystack.
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if needle.len() > haystack.len() {
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return false;
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}
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if needle.is_empty() {
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// Empty strings are considered to be subsequences of everything.
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return true;
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}
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let mut ni = needle.chars();
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let mut nc = ni.next();
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for hc in haystack.chars() {
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if nc == Some(hc) {
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nc = ni.next();
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}
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}
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// We succeeded if we exhausted our sequence.
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nc.is_none()
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}
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/// Case-insensitive string search, modeled after std::string::find().
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/// \param fuzzy indicates this is being used for fuzzy matching and case insensitivity is
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/// expanded to include symbolic characters (#3584).
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/// \return the offset of the first case-insensitive matching instance of `needle` within
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/// `haystack`, or `string::npos()` if no results were found.
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pub fn ifind(haystack: &wstr, needle: &wstr, fuzzy: bool) -> Option<usize> {
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haystack
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.as_char_slice()
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.windows(needle.len())
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.position(|window| {
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for (l, r) in window.iter().zip(needle.chars()) {
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// In fuzzy matching treat treat `-` and `_` as equal (#3584).
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if fuzzy && ['-', '_'].contains(l) && ['-', '_'].contains(&r) {
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continue;
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}
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// TODO Decide what to do for different lengths.
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let l = l.to_lowercase();
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let r = r.to_lowercase();
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for (l, r) in l.zip(r) {
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if l != r {
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return false;
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}
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}
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}
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true
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})
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}
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// The ways one string can contain another.
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#[derive(Copy, Clone, Debug, Eq, PartialEq)]
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pub enum ContainType {
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/// exact match: foobar matches foo
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exact,
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/// prefix match: foo matches foobar
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prefix,
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/// substring match: ooba matches foobar
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substr,
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/// subsequence match: fbr matches foobar
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subseq,
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}
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// The case-folding required for the match.
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#[derive(Copy, Clone, Debug, Eq, PartialEq)]
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pub enum CaseFold {
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/// exact match: foobar matches foobar
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samecase,
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/// case insensitive match with lowercase input. foobar matches FoBar.
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smartcase,
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/// case insensitive: FoBaR matches foobAr
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icase,
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}
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/// A lightweight value-type describing how closely a string fuzzy-matches another string.
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#[derive(Debug, Eq, PartialEq)]
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pub struct StringFuzzyMatch {
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typ: ContainType,
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case_fold: CaseFold,
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}
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impl StringFuzzyMatch {
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pub fn new(typ: ContainType, case_fold: CaseFold) -> Self {
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Self { typ, case_fold }
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}
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// Helper to return an exact match.
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pub fn exact_match() -> Self {
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Self::new(ContainType::exact, CaseFold::samecase)
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}
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/// \return whether this is a samecase exact match.
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pub fn is_samecase_exact(&self) -> bool {
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self.typ == ContainType::exact && self.case_fold == CaseFold::samecase
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}
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/// \return if we are exact or prefix match.
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pub fn is_exact_or_prefix(&self) -> bool {
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matches!(self.typ, ContainType::exact | ContainType::prefix)
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}
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// \return if our match requires a full replacement, i.e. is not a strict extension of our
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// existing string. This is false only if our case matches, and our type is prefix or exact.
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pub fn requires_full_replacement(&self) -> bool {
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if self.case_fold != CaseFold::samecase {
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return true;
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}
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matches!(self.typ, ContainType::substr | ContainType::subseq)
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}
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/// Try creating a fuzzy match for \p string against \p match_against.
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/// \p string is something like "foo" and \p match_against is like "FooBar".
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/// If \p anchor_start is set, then only exact and prefix matches are permitted.
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pub fn try_create(
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string: &wstr,
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match_against: &wstr,
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anchor_start: bool,
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) -> Option<StringFuzzyMatch> {
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// Helper to lazily compute if case insensitive matches should use icase or smartcase.
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// Use icase if the input contains any uppercase characters, smartcase otherwise.
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let get_case_fold = || {
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for c in string.chars() {
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if c.to_lowercase().next().unwrap() != c {
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return CaseFold::icase;
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}
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}
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CaseFold::smartcase
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};
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// A string cannot fuzzy match against a shorter string.
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if string.len() > match_against.len() {
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return None;
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}
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// exact samecase
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if string == match_against {
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return Some(StringFuzzyMatch::new(
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ContainType::exact,
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CaseFold::samecase,
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));
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}
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// prefix samecase
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if match_against.starts_with(string) {
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return Some(StringFuzzyMatch::new(
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ContainType::prefix,
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CaseFold::samecase,
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));
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}
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// exact icase
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if wcscasecmp(string, match_against).is_eq() {
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return Some(StringFuzzyMatch::new(ContainType::exact, get_case_fold()));
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}
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// prefix icase
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if string_prefixes_string_case_insensitive(string, match_against) {
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return Some(StringFuzzyMatch::new(ContainType::prefix, get_case_fold()));
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}
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// If anchor_start is set, this is as far as we go.
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if anchor_start {
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return None;
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}
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// substr samecase
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if match_against
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.as_char_slice()
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.windows(string.len())
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.any(|window| wstr::from_char_slice(window) == string)
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{
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return Some(StringFuzzyMatch::new(
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ContainType::substr,
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CaseFold::samecase,
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));
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}
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// substr icase
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if ifind(match_against, string, true /* fuzzy */).is_some() {
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return Some(StringFuzzyMatch::new(ContainType::substr, get_case_fold()));
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}
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// subseq samecase
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if subsequence_in_string(string, match_against) {
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return Some(StringFuzzyMatch::new(
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ContainType::subseq,
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CaseFold::samecase,
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));
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}
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// We do not currently test subseq icase.
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None
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}
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pub fn rank(&self) -> u32 {
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// Combine our type and our case fold into a single number, such that better matches are
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// smaller. Treat 'exact' types the same as 'prefix' types; this is because we do not
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// prefer exact matches to prefix matches when presenting completions to the user.
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// Treat smartcase the same as samecase; see #3978.
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let effective_type = if self.typ == ContainType::exact {
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ContainType::prefix
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} else {
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self.typ
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};
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let effective_case = if self.case_fold == CaseFold::smartcase {
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CaseFold::samecase
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} else {
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self.case_fold
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};
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// Type dominates fold.
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effective_type as u32 * 8 + effective_case as u32
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}
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}
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/// Cover over string_fuzzy_match_t::try_create().
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pub fn string_fuzzy_match_string(
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string: &wstr,
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match_against: &wstr,
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anchor_start: bool,
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) -> Option<StringFuzzyMatch> {
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StringFuzzyMatch::try_create(string, match_against, anchor_start)
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}
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/// Implementation of wcs2string that accepts a callback.
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/// This invokes \p func with (const char*, size_t) pairs.
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/// If \p func returns false, it stops; otherwise it continues.
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/// \return false if the callback returned false, otherwise true.
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pub fn wcs2string_callback(input: &wstr, mut func: impl FnMut(&[u8]) -> bool) -> bool {
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let mut state = zero_mbstate();
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let mut converted = [0_u8; AT_LEAST_MB_LEN_MAX];
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for c in input.chars() {
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// TODO: this doesn't seem sound.
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if c == INTERNAL_SEPARATOR {
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// do nothing
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} else if let Some(byte) = decode_byte_from_char(c) {
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converted[0] = byte;
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if !func(&converted[..1]) {
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return false;
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}
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} else if MB_CUR_MAX() == 1 {
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// single-byte locale (C/POSIX/ISO-8859)
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// If `c` contains a wide character we emit a question-mark.
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converted[0] = u8::try_from(u32::from(c)).unwrap_or(b'?');
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if !func(&converted[..1]) {
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return false;
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}
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} else {
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converted = [0; AT_LEAST_MB_LEN_MAX];
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let len = unsafe {
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wcrtomb(
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std::ptr::addr_of_mut!(converted[0]).cast(),
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c as libc::wchar_t,
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&mut state,
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)
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};
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if len == 0_usize.wrapping_sub(1) {
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wcs2string_bad_char(c);
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state = zero_mbstate();
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} else if !func(&converted[..len]) {
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return false;
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}
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}
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}
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true
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}
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fn wcs2string_bad_char(c: char) {
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FLOGF!(
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char_encoding,
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L!("Wide character U+%4X has no narrow representation"),
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c
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);
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}
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/// Split a string by a separator character.
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pub fn split_string(val: &wstr, sep: char) -> Vec<WString> {
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val.as_char_slice()
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.split(|c| *c == sep)
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.map(WString::from_chars)
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.collect()
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}
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/// Split a string by runs of any of the separator characters provided in \p seps.
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/// Note the delimiters are the characters in \p seps, not \p seps itself.
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/// \p seps may contain the NUL character.
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/// Do not output more than \p max_results results. If we are to output exactly that much,
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/// the last output is the the remainder of the input, including leading delimiters,
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/// except for the first. This is historical behavior.
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/// Example: split_string_tok(" a b c ", " ", 3) -> {"a", "b", " c "}
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pub fn split_string_tok<'val>(
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val: &'val wstr,
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seps: &wstr,
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max_results: Option<usize>,
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) -> Vec<&'val wstr> {
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let mut out = vec![];
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let val = val.as_char_slice();
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let end = val.len();
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let mut pos = 0;
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let max_results = max_results.unwrap_or(usize::MAX);
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while pos < end && out.len() + 1 < max_results {
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// Skip leading seps.
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pos += match val[pos..].iter().position(|c| !seps.contains(*c)) {
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Some(p) => p,
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None => break,
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};
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// Find next sep.
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let next_sep = val[pos..]
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.iter()
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.position(|c| seps.contains(*c))
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.map(|p| pos + p)
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.unwrap_or(end);
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out.push(wstr::from_char_slice(&val[pos..next_sep]));
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// Note we skip exactly one sep here. This is because on the last iteration we retain all
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// but the first leading separators. This is historical.
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pos = next_sep + 1;
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}
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if pos < end && max_results > 0 {
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assert!(out.len() + 1 == max_results, "Should have split the max");
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out.push(wstr::from_char_slice(&val[pos..]));
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}
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assert!(out.len() <= max_results, "Got too many results");
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out
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}
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/// Joins strings with a separator.
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pub fn join_strings<S: AsRef<wstr>>(strs: &[S], sep: char) -> WString {
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if strs.is_empty() {
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return WString::new();
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}
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let capacity = strs.iter().fold(0, |acc, s| acc + s.as_ref().len()) + strs.len() - 1;
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let mut result = WString::with_capacity(capacity);
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for (i, s) in strs.iter().enumerate() {
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if i > 0 {
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result.push(sep);
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}
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result.push_utfstr(&s);
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}
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result
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}
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pub fn bool_from_string(x: &wstr) -> bool {
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if x.is_empty() {
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return false;
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}
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matches!(x.chars().next().unwrap(), 'Y' | 'T' | 'y' | 't' | '1')
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}
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/// Given iterators into a string (forward or reverse), splits the haystack iterators
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/// about the needle sequence, up to max times. Inserts splits into the output array.
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/// If the iterators are forward, this does the normal thing.
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/// If the iterators are backward, this returns reversed strings, in reversed order!
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/// If the needle is empty, split on individual elements (characters).
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/// Max output entries will be max + 1 (after max splits)
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pub fn split_about<'haystack>(
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haystack: &'haystack wstr,
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needle: &wstr,
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max: Option<i64>,
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no_empty: bool,
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) -> Vec<&'haystack wstr> {
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let mut output = vec![];
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let mut remaining = max.unwrap_or(i64::MAX);
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let mut haystack = haystack.as_char_slice();
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while remaining > 0 && !haystack.is_empty() {
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let split_point = if needle.is_empty() {
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// empty needle, we split on individual elements
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1
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} else {
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match haystack
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.windows(needle.len())
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.position(|window| window == needle.as_char_slice())
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{
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Some(pos) => pos,
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None => break, // not found
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}
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};
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if !no_empty || split_point != 0 {
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output.push(wstr::from_char_slice(&haystack[..split_point]));
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}
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remaining -= 1;
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// Need to skip over the needle for the next search note that the needle may be empty.
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haystack = &haystack[split_point + needle.len()..];
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}
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// Trailing component, possibly empty.
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if !no_empty || !haystack.is_empty() {
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output.push(wstr::from_char_slice(haystack));
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}
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output
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}
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#[derive(Eq, PartialEq)]
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pub enum EllipsisType {
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None,
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// Prefer niceness over minimalness
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Prettiest,
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// Make every character count ($ instead of ...)
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Shortest,
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}
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pub fn truncate(input: &wstr, max_len: usize, etype: Option<EllipsisType>) -> WString {
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let etype = etype.unwrap_or(EllipsisType::Prettiest);
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if input.len() <= max_len {
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return input.to_owned();
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}
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if etype == EllipsisType::None {
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return input[..max_len].to_owned();
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}
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if etype == EllipsisType::Prettiest {
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let ellipsis_str = get_ellipsis_str();
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let mut output = input[..max_len - ellipsis_str.len()].to_owned();
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output += ellipsis_str;
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return output;
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}
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let mut output = input[..max_len - 1].to_owned();
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output.push(get_ellipsis_char());
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output
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}
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pub fn trim(input: WString, any_of: Option<&wstr>) -> WString {
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let any_of = any_of.unwrap_or(L!("\t\x0B \r\n"));
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let mut result = input;
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let Some(suffix) = result.chars().rposition(|c| !any_of.contains(c)) else {
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return WString::new();
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};
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result.truncate(suffix + 1);
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let prefix = result
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.chars()
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.position(|c| !any_of.contains(c))
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.expect("Should have one non-trimmed character");
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result.split_off(prefix)
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}
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/// \return the number of escaping backslashes before a character.
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/// \p idx may be "one past the end."
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pub fn count_preceding_backslashes(text: &wstr, idx: usize) -> usize {
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assert!(idx <= text.len(), "Out of bounds");
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let mut backslashes = 0;
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while backslashes < idx && text.char_at(idx - backslashes - 1) == '\\' {
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backslashes += 1;
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}
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backslashes
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}
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/// Support for iterating over a newline-separated string.
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pub struct LineIterator<'a> {
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// The string we're iterating.
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coll: &'a str,
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// The current location in the iteration.
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current: usize,
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}
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impl<'a> LineIterator<'a> {
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pub fn new(coll: &'a str) -> Self {
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Self { coll, current: 0 }
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}
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}
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impl<'a> Iterator for LineIterator<'a> {
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type Item = &'a str;
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fn next(&mut self) -> Option<Self::Item> {
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if self.current == self.coll.len() {
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return None;
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}
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let newline_or_end = self.coll[self.current..]
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.bytes()
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.position(|b| b == b'\n')
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.map(|pos| self.current + pos)
|
|
.unwrap_or(self.coll.len());
|
|
let result = &self.coll[self.current..newline_or_end];
|
|
self.current = newline_or_end;
|
|
|
|
// Skip the newline.
|
|
if self.current != self.coll.len() {
|
|
self.current += 1;
|
|
}
|
|
Some(result)
|
|
}
|
|
}
|
|
|
|
/// Like fish_wcwidth, but returns 0 for characters with no real width instead of -1.
|
|
pub fn fish_wcwidth_visible(c: char) -> i32 {
|
|
if c == '\x08' {
|
|
return -1;
|
|
}
|
|
fish_wcwidth(c).max(0)
|
|
}
|
|
|
|
#[test]
|
|
fn test_ifind() {
|
|
macro_rules! validate {
|
|
($haystack:expr, $needle:expr, $expected:expr) => {
|
|
assert_eq!(ifind(L!($haystack), L!($needle), false), $expected);
|
|
};
|
|
}
|
|
validate!("alpha", "alpha", Some(0));
|
|
validate!("alphab", "alpha", Some(0));
|
|
validate!("alpha", "balpha", None);
|
|
validate!("balpha", "alpha", Some(1));
|
|
validate!("alphab", "balpha", None);
|
|
validate!("balpha", "lPh", Some(2));
|
|
validate!("balpha", "Plh", None);
|
|
validate!("echo Ö", "ö", Some(5));
|
|
}
|
|
|
|
#[test]
|
|
fn test_ifind_fuzzy() {
|
|
macro_rules! validate {
|
|
($haystack:expr, $needle:expr, $expected:expr) => {
|
|
assert_eq!(ifind(L!($haystack), L!($needle), true), $expected);
|
|
};
|
|
}
|
|
validate!("alpha", "alpha", Some(0));
|
|
validate!("alphab", "alpha", Some(0));
|
|
validate!("alpha-b", "alpha_b", Some(0));
|
|
validate!("alpha-_", "alpha_-", Some(0));
|
|
validate!("alpha-b", "alpha b", None);
|
|
}
|
|
|
|
#[test]
|
|
fn test_fuzzy_match() {
|
|
// Check that a string fuzzy match has the expected type and case folding.
|
|
macro_rules! validate {
|
|
($needle:expr, $haystack:expr, $contain_type:expr, $case_fold:expr) => {
|
|
let m = string_fuzzy_match_string(L!($needle), L!($haystack), false).unwrap();
|
|
assert_eq!(m.typ, $contain_type);
|
|
assert_eq!(m.case_fold, $case_fold);
|
|
};
|
|
($needle:expr, $haystack:expr, None) => {
|
|
assert_eq!(
|
|
string_fuzzy_match_string(L!($needle), L!($haystack), false),
|
|
None,
|
|
);
|
|
};
|
|
}
|
|
validate!("", "", ContainType::exact, CaseFold::samecase);
|
|
validate!("alpha", "alpha", ContainType::exact, CaseFold::samecase);
|
|
validate!("alp", "alpha", ContainType::prefix, CaseFold::samecase);
|
|
validate!("alpha", "AlPhA", ContainType::exact, CaseFold::smartcase);
|
|
validate!("alpha", "AlPhA!", ContainType::prefix, CaseFold::smartcase);
|
|
validate!("ALPHA", "alpha!", ContainType::prefix, CaseFold::icase);
|
|
validate!("ALPHA!", "alPhA!", ContainType::exact, CaseFold::icase);
|
|
validate!("alPh", "ALPHA!", ContainType::prefix, CaseFold::icase);
|
|
validate!("LPH", "ALPHA!", ContainType::substr, CaseFold::samecase);
|
|
validate!("lph", "AlPhA!", ContainType::substr, CaseFold::smartcase);
|
|
validate!("lPh", "ALPHA!", ContainType::substr, CaseFold::icase);
|
|
validate!("AA", "ALPHA!", ContainType::subseq, CaseFold::samecase);
|
|
// no subseq icase
|
|
validate!("lh", "ALPHA!", None);
|
|
validate!("BB", "ALPHA!", None);
|
|
}
|
|
|
|
#[test]
|
|
fn test_split_string_tok() {
|
|
macro_rules! validate {
|
|
($val:expr, $seps:expr, $max_len:expr, $expected:expr) => {
|
|
assert_eq!(split_string_tok(L!($val), L!($seps), $max_len), $expected,);
|
|
};
|
|
}
|
|
validate!(" hello \t world", " \t\n", None, vec!["hello", "world"]);
|
|
validate!(" stuff ", " ", Some(0), vec![] as Vec<&wstr>);
|
|
validate!(" stuff ", " ", Some(1), vec![" stuff "]);
|
|
validate!(
|
|
" hello \t world andstuff ",
|
|
" \t\n",
|
|
Some(3),
|
|
vec!["hello", "world", " andstuff "]
|
|
);
|
|
// NUL chars are OK.
|
|
validate!("hello \x00 world", " \0", None, vec!["hello", "world"]);
|
|
}
|
|
|
|
#[test]
|
|
fn test_join_strings() {
|
|
use crate::wchar::L;
|
|
let empty: &[&wstr] = &[];
|
|
assert_eq!(join_strings(empty, '/'), "");
|
|
assert_eq!(join_strings(&[L!("foo")], '/'), "foo");
|
|
assert_eq!(
|
|
join_strings(&[L!("foo"), L!("bar"), L!("baz")], '/'),
|
|
"foo/bar/baz"
|
|
);
|
|
}
|
|
|
|
#[test]
|
|
fn test_line_iterator() {
|
|
let text = "Alpha\nBeta\nGamma\n\nDelta\n";
|
|
let mut lines = vec![];
|
|
let iter = LineIterator::new(text);
|
|
for line in iter {
|
|
lines.push(line);
|
|
}
|
|
assert_eq!(lines, vec!["Alpha", "Beta", "Gamma", "", "Delta"]);
|
|
}
|