#include "ranked_match.hh" #include "utf8_iterator.hh" #include "unit_tests.hh" namespace Kakoune { using Utf8It = utf8::iterator; static int count_word_boundaries_match(StringView candidate, StringView query) { int count = 0; Utf8It query_it{query.begin(), query}; Codepoint prev = 0; for (Utf8It it{candidate.begin(), candidate}; it != candidate.end(); ++it) { const Codepoint c = *it; const bool is_word_boundary = prev == 0 or (!iswalnum(prev) and iswalnum(c)) or (islower(prev) and isupper(c)); prev = c; if (not is_word_boundary) continue; const Codepoint lc = to_lower(c); for (auto qit = query_it; qit != query.end(); ++qit) { const Codepoint qc = *qit; if (qc == (islower(qc) ? lc : c)) { ++count; query_it = qit+1; break; } } if (query_it == query.end()) break; } return count; } static bool smartcase_eq(Codepoint query, Codepoint candidate) { return query == (islower(query) ? to_lower(candidate) : candidate); } static bool subsequence_match_smart_case(StringView str, StringView subseq, int& index_sum) { index_sum = 0; Utf8It it{str.begin(), str}; int index = 0; for (Utf8It subseq_it{subseq.begin(), subseq}; subseq_it != subseq.end(); ++subseq_it) { if (it == str.end()) return false; while (not smartcase_eq(*subseq_it, *it)) { ++index; if (++it == str.end()) return false; } index_sum += index++; ++it; } return true; } RankedMatch::RankedMatch(StringView candidate, StringView query) { if (candidate.empty() or query.length() > candidate.length()) return; if (query.empty()) { m_candidate = candidate; return; } if (not subsequence_match_smart_case(candidate, query, m_match_index_sum)) return; m_candidate = candidate; m_first_char_match = smartcase_eq(query[0], candidate[0]); m_word_boundary_match_count = count_word_boundaries_match(candidate, query); m_only_word_boundary = m_word_boundary_match_count == query.length(); m_prefix = std::equal(query.begin(), query.end(), candidate.begin(), smartcase_eq); } bool RankedMatch::operator<(const RankedMatch& other) const { if (m_first_char_match != other.m_first_char_match) return m_first_char_match; if (m_only_word_boundary and other.m_only_word_boundary) { if (m_word_boundary_match_count != other.m_word_boundary_match_count) return m_word_boundary_match_count > other.m_word_boundary_match_count; } else if (m_only_word_boundary or other.m_only_word_boundary) return m_only_word_boundary; if (m_prefix != other.m_prefix) return m_prefix; if (m_word_boundary_match_count != other.m_word_boundary_match_count) return m_word_boundary_match_count > other.m_word_boundary_match_count; if (m_match_index_sum != other.m_match_index_sum) return m_match_index_sum < other.m_match_index_sum; return std::lexicographical_compare( Utf8It{m_candidate.begin(), m_candidate}, Utf8It{m_candidate.end(), m_candidate}, Utf8It{other.m_candidate.begin(), other.m_candidate}, Utf8It{other.m_candidate.end(), other.m_candidate}, [](Codepoint a, Codepoint b) { const bool low_a = islower(a), low_b = islower(b); return low_a == low_b ? a < b : low_a; }); } UnitTest test_ranked_match{[] { kak_assert(count_word_boundaries_match("run_all_tests", "rat") == 3); kak_assert(count_word_boundaries_match("run_all_tests", "at") == 2); kak_assert(count_word_boundaries_match("countWordBoundariesMatch", "wm") == 2); kak_assert(count_word_boundaries_match("countWordBoundariesMatch", "cobm") == 3); kak_assert(count_word_boundaries_match("countWordBoundariesMatch", "cWBM") == 4); }}; }