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0118eafee1
If we ever need any of these... they're in this commit: fish_wcswidth_visible() status_cmd_opts_t::feature_name completion_t::is_naturally_less_than() parser_t::set_empty_var_and_fire() parser_t::get_block_desc() parser_keywords_skip_arguments() parser_keywords_is_block() job_t::has_internal_proc() fish_wcswidth_visible()
301 lines
12 KiB
C++
301 lines
12 KiB
C++
// Helper functions for working with wcstring.
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#ifndef FISH_WCSTRINGUTIL_H
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#define FISH_WCSTRINGUTIL_H
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#include <algorithm>
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#include <cstring>
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#include <string>
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#include <utility>
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#include "common.h"
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#include "expand.h"
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/// Test if a string prefixes another. Returns true if a is a prefix of b.
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bool string_prefixes_string(const wcstring &proposed_prefix, const wcstring &value);
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bool string_prefixes_string(const wchar_t *proposed_prefix, const wcstring &value);
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bool string_prefixes_string(const wchar_t *proposed_prefix, const wchar_t *value);
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bool string_prefixes_string(const char *proposed_prefix, const std::string &value);
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bool string_prefixes_string(const char *proposed_prefix, const char *value);
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/// Test if a string is a suffix of another.
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bool string_suffixes_string(const wcstring &proposed_suffix, const wcstring &value);
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bool string_suffixes_string(const wchar_t *proposed_suffix, const wcstring &value);
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bool string_suffixes_string_case_insensitive(const wcstring &proposed_suffix,
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const wcstring &value);
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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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bool string_prefixes_string_case_insensitive(const wcstring &proposed_prefix,
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const wcstring &value);
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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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size_t ifind(const wcstring &haystack, const wcstring &needle, bool fuzzy = false);
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size_t ifind(const std::string &haystack, const std::string &needle, bool fuzzy = false);
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/// A lightweight value-type describing how closely a string fuzzy-matches another string.
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struct string_fuzzy_match_t {
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// The ways one string can contain another.
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enum class contain_type_t : uint8_t {
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exact, // exact match: foobar matches foo
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prefix, // prefix match: foo matches foobar
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substr, // substring match: ooba matches foobar
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subseq, // subsequence match: fbr matches foobar
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};
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contain_type_t type;
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// The case-folding required for the match.
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enum class case_fold_t : uint8_t {
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samecase, // exact match: foobar matches foobar
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smartcase, // case insensitive match with lowercase input. foobar matches FoBar.
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icase, // case insensitive: FoBaR matches foobAr
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};
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case_fold_t case_fold;
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// Constructor.
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constexpr string_fuzzy_match_t(contain_type_t type, case_fold_t case_fold)
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: type(type), case_fold(case_fold) {}
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// Helper to return an exact match.
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static constexpr string_fuzzy_match_t exact_match() {
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return string_fuzzy_match_t(contain_type_t::exact, case_fold_t::samecase);
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}
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/// \return whether this is a samecase exact match.
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bool is_samecase_exact() const {
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return type == contain_type_t::exact && case_fold == case_fold_t::samecase;
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}
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/// \return if we are exact or prefix match.
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bool is_exact_or_prefix() const {
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switch (type) {
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case contain_type_t::exact:
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case contain_type_t::prefix:
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return true;
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case contain_type_t::substr:
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case contain_type_t::subseq:
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return false;
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}
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DIE("Unreachable");
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return false;
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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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bool requires_full_replacement() const {
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if (case_fold != case_fold_t::samecase) return true;
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switch (type) {
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case contain_type_t::exact:
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case contain_type_t::prefix:
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return false;
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case contain_type_t::substr:
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case contain_type_t::subseq:
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return true;
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}
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DIE("Unreachable");
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return false;
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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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static maybe_t<string_fuzzy_match_t> try_create(const wcstring &string,
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const wcstring &match_against,
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bool anchor_start);
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/// \return a rank for filtering matches.
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/// Earlier (smaller) ranks are better matches.
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uint32_t rank() const;
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};
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/// Cover over string_fuzzy_match_t::try_create().
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inline maybe_t<string_fuzzy_match_t> string_fuzzy_match_string(const wcstring &string,
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const wcstring &match_against,
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bool anchor_start = false) {
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return string_fuzzy_match_t::try_create(string, match_against, anchor_start);
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}
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/// Split a string by a separator character.
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wcstring_list_t split_string(const wcstring &val, wchar_t sep);
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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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wcstring_list_t split_string_tok(const wcstring &val, const wcstring &seps,
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size_t max_results = std::numeric_limits<size_t>::max());
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/// Join a list of strings by a separator character.
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wcstring join_strings(const wcstring_list_t &vals, wchar_t sep);
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inline wcstring to_string(long x) {
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wchar_t buff[64];
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format_long_safe(buff, x);
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return wcstring(buff);
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}
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inline wcstring to_string(unsigned long long x) {
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wchar_t buff[64];
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format_ullong_safe(buff, x);
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return wcstring(buff);
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}
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inline wcstring to_string(int x) { return to_string(static_cast<long>(x)); }
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inline wcstring to_string(size_t x) { return to_string(static_cast<unsigned long long>(x)); }
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inline bool bool_from_string(const std::string &x) {
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if (x.empty()) return false;
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switch (x.front()) {
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case 'Y':
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case 'T':
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case 'y':
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case 't':
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case '1':
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return true;
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default:
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return false;
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}
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}
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inline bool bool_from_string(const wcstring &x) {
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return !x.empty() && std::wcschr(L"YTyt1", x.at(0));
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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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template <typename ITER>
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void split_about(ITER haystack_start, ITER haystack_end, ITER needle_start, ITER needle_end,
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wcstring_list_t *output, long max = LONG_MAX, bool no_empty = false) {
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long remaining = max;
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ITER haystack_cursor = haystack_start;
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while (remaining > 0 && haystack_cursor != haystack_end) {
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ITER split_point;
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if (needle_start == needle_end) { // empty needle, we split on individual elements
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split_point = haystack_cursor + 1;
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} else {
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split_point = std::search(haystack_cursor, haystack_end, needle_start, needle_end);
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}
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if (split_point == haystack_end) { // not found
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break;
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}
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if (!no_empty || haystack_cursor != split_point) {
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output->emplace_back(haystack_cursor, split_point);
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}
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remaining--;
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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_cursor = split_point + std::distance(needle_start, needle_end);
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}
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// Trailing component, possibly empty.
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if (!no_empty || haystack_cursor != haystack_end) {
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output->emplace_back(haystack_cursor, haystack_end);
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}
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}
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enum class ellipsis_type {
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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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wcstring truncate(const wcstring &input, int max_len,
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ellipsis_type etype = ellipsis_type::Prettiest);
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wcstring trim(wcstring input);
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wcstring trim(wcstring input, const wchar_t *any_of);
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/// Converts a string to lowercase.
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wcstring wcstolower(wcstring input);
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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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size_t count_preceding_backslashes(const wcstring &text, size_t idx);
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// Out-of-line helper for wcs2string_callback.
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void wcs2string_bad_char(wchar_t);
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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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template <typename Func>
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bool wcs2string_callback(const wchar_t *input, size_t len, const Func &func) {
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mbstate_t state = {};
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char converted[MB_LEN_MAX];
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for (size_t i = 0; i < len; i++) {
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wchar_t wc = input[i];
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// TODO: this doesn't seem sound.
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if (wc == INTERNAL_SEPARATOR) {
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// do nothing
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} else if (wc >= ENCODE_DIRECT_BASE && wc < ENCODE_DIRECT_BASE + 256) {
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converted[0] = wc - ENCODE_DIRECT_BASE;
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if (!func(converted, 1)) return false;
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} else if (MB_CUR_MAX == 1) { // single-byte locale (C/POSIX/ISO-8859)
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// If `wc` contains a wide character we emit a question-mark.
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if (wc & ~0xFF) {
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wc = '?';
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}
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converted[0] = wc;
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if (!func(converted, 1)) return false;
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} else {
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std::memset(converted, 0, sizeof converted);
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size_t len = std::wcrtomb(converted, wc, &state);
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if (len == static_cast<size_t>(-1)) {
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wcs2string_bad_char(wc);
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std::memset(&state, 0, sizeof(state));
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} else {
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if (!func(converted, len)) return false;
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}
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}
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}
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return true;
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}
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/// Support for iterating over a newline-separated string.
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template <typename Collection>
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class line_iterator_t {
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// Storage for each line.
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Collection storage;
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// The collection we're iterating. Note we hold this by reference.
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const Collection &coll;
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// The current location in the iteration.
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typename Collection::const_iterator current;
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public:
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/// Construct from a collection (presumably std::string or std::wcstring).
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line_iterator_t(const Collection &coll) : coll(coll), current(coll.cbegin()) {}
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/// Access the storage in which the last line was stored.
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const Collection &line() const { return storage; }
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/// Advances to the next line. \return true on success, false if we have exhausted the string.
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bool next() {
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if (current == coll.end()) return false;
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auto newline_or_end = std::find(current, coll.cend(), '\n');
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storage.assign(current, newline_or_end);
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current = newline_or_end;
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// Skip the newline.
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if (current != coll.cend()) ++current;
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return true;
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}
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};
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/// Like fish_wcwidth, but returns 0 for characters with no real width instead of -1.
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int fish_wcwidth_visible(wchar_t widechar);
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#endif
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