patch 8.2.1665: cannot do fuzzy string matching

Problem: Cannot do fuzzy string matching. Solution: Add matchfuzzy(). (Yegappan Lakshmanan, closes #6932)
2020-09-11 22:25:15 +02:00
parent c2c8205634
commit 635414dd2f
7 changed files with 393 additions and 0 deletions
--- a/runtime/doc/eval.txt
+++ b/runtime/doc/eval.txt
@@ -2641,6 +2641,7 @@ matcharg({nr})			List	arguments of |:match|
 matchdelete({id} [, {win}])	Number	delete match identified by {id}
 matchend({expr}, {pat} [, {start} [, {count}]])
 				Number	position where {pat} ends in {expr}
 matchfuzzy({list}, {str})	List	fuzzy match {str} in {list}
 matchlist({expr}, {pat} [, {start} [, {count}]])
 				List	match and submatches of {pat} in {expr}
 matchstr({expr}, {pat} [, {start} [, {count}]])
@@ -7307,6 +7308,29 @@ matchend({expr}, {pat} [, {start} [, {count}]])			*matchend()*
 		Can also be used as a |method|: >
 			GetText()->matchend('word')
 matchfuzzy({list}, {str})			*matchfuzzy()*
 		Returns a list with all the strings in {list} that fuzzy
 		match {str}. The strings in the returned list are sorted
 		based on the matching score. {str} is treated as a literal
 		string and regular expression matching is NOT supported.
 		The maximum supported {str} length is 256.
 		If there are no matching strings or there is an error, then an
 		empty list is returned. If length of {str} is greater than
 		256, then returns an empty list.
 		Example: >
 		   :echo matchfuzzy(["clay", "crow"], "cay")
 <		results in ["clay"]. >
 		   :echo getbufinfo()->map({_, v -> v.name})->matchfuzzy("ndl")
 <		results in a list of buffer names fuzzy matching "ndl". >
 		   :echo v:oldfiles->matchfuzzy("test")
 <		results in a list of file names fuzzy matching "test". >
 		   :let l = readfile("buffer.c")->matchfuzzy("str")
 <		results in a list of lines in "buffer.c" fuzzy matching "str".
 matchlist({expr}, {pat} [, {start} [, {count}]])		*matchlist()*
 		Same as |match()|, but return a |List|.  The first item in the
 		list is the matched string, same as what matchstr() would
--- a/runtime/doc/usr_41.txt
+++ b/runtime/doc/usr_41.txt
@@ -603,6 +603,7 @@ String manipulation:					*string-functions*
 	charclass()		class of a character
 	match()			position where a pattern matches in a string
 	matchend()		position where a pattern match ends in a string
 	matchfuzzy()		fuzzy matches a string in a list of strings
 	matchstr()		match of a pattern in a string
 	matchstrpos()		match and positions of a pattern in a string
 	matchlist()		like matchstr() and also return submatches
--- a/src/evalfunc.c
+++ b/src/evalfunc.c
@@ -750,6 +750,7 @@ static funcentry_T global_functions[] =
    {"matcharg",	1, 1, FEARG_1,	  ret_list_string, f_matcharg},
    {"matchdelete",	1, 2, FEARG_1,	  ret_number,	f_matchdelete},
    {"matchend",	2, 4, FEARG_1,	  ret_number,	f_matchend},
    {"matchfuzzy",	2, 2, FEARG_1,	  ret_list_string,	f_matchfuzzy},
    {"matchlist",	2, 4, FEARG_1,	  ret_list_string, f_matchlist},
    {"matchstr",	2, 4, FEARG_1,	  ret_string,	f_matchstr},
    {"matchstrpos",	2, 4, FEARG_1,	  ret_list_any,	f_matchstrpos},
--- a/src/proto/search.pro
+++ b/src/proto/search.pro
@@ -36,4 +36,5 @@ void find_pattern_in_path(char_u *ptr, int dir, int len, int whole, int skip_com
 spat_T *get_spat(int idx);
 int get_spat_last_idx(void);
 void f_searchcount(typval_T *argvars, typval_T *rettv);
 void f_matchfuzzy(typval_T *argvars, typval_T *rettv);
 /* vim: set ft=c : */
--- a/src/search.c
+++ b/src/search.c
@@ -4165,4 +4165,344 @@ f_searchcount(typval_T *argvars, typval_T *rettv)
 the_end:
    restore_last_search_pattern();
 }
 /*
 * Fuzzy string matching
 *
 * Ported from the lib_fts library authored by Forrest Smith.
 * https://github.com/forrestthewoods/lib_fts/tree/master/code
 *
 * Blog describing the algorithm:
 * https://www.forrestthewoods.com/blog/reverse_engineering_sublime_texts_fuzzy_match/
 *
 * Each matching string is assigned a score. The following factors are checked:
 *   Matched letter
 *   Unmatched letter
 *   Consecutively matched letters
 *   Proximity to start
 *   Letter following a separator (space, underscore)
 *   Uppercase letter following lowercase (aka CamelCase)
 *
 * Matched letters are good. Unmatched letters are bad. Matching near the start
 * is good. Matching the first letter in the middle of a phrase is good.
 * Matching the uppercase letters in camel case entries is good.
 *
 * The score assigned for each factor is explained below.
 * File paths are different from file names. File extensions may be ignorable.
 * Single words care about consecutive matches but not separators or camel
 * case.
 *   Score starts at 0
 *   Matched letter: +0 points
 *   Unmatched letter: -1 point
 *   Consecutive match bonus: +5 points
 *   Separator bonus: +10 points
 *   Camel case bonus: +10 points
 *   Unmatched leading letter: -3 points (max: -9)
 *
 * There is some nuance to this. Scores don’t have an intrinsic meaning. The
 * score range isn’t 0 to 100. It’s roughly [-50, 50]. Longer words have a
 * lower minimum score due to unmatched letter penalty. Longer search patterns
 * have a higher maximum score due to match bonuses.
 *
 * Separator and camel case bonus is worth a LOT. Consecutive matches are worth
 * quite a bit.
 *
 * There is a penalty if you DON’T match the first three letters. Which
 * effectively rewards matching near the start. However there’s no difference
 * in matching between the middle and end.
 *
 * There is not an explicit bonus for an exact match. Unmatched letters receive
 * a penalty. So shorter strings and closer matches are worth more.
 */
 typedef struct
 {
    listitem_T *item;
    int		score;
 } fuzzyItem_T;
    static int
 fuzzy_match_recursive(
 	char_u	*fuzpat,
 	char_u	*str,
 	int	*outScore,
 	char_u	*strBegin,
 	char_u	*srcMatches,
 	char_u	*matches,
 	int	maxMatches,
 	int	nextMatch,
 	int	*recursionCount,
 	int	recursionLimit)
 {
    // Recursion params
    int		recursiveMatch = FALSE;
    char_u	bestRecursiveMatches[256];
    int		bestRecursiveScore = 0;
    int		first_match;
    int		matched;
    // Count recursions
    ++*recursionCount;
    if (*recursionCount >= recursionLimit)
 	return FALSE;
    // Detect end of strings
    if (*fuzpat == '\0' || *str == '\0')
 	return FALSE;
    // Loop through fuzpat and str looking for a match
    first_match = TRUE;
    while (*fuzpat != '\0' && *str != '\0')
    {
 	// Found match
 	if (vim_tolower(*fuzpat) == vim_tolower(*str))
 	{
 	    char_u	recursiveMatches[256];
 	    int		recursiveScore = 0;
 	    // Supplied matches buffer was too short
 	    if (nextMatch >= maxMatches)
 		return FALSE;
 	    // "Copy-on-Write" srcMatches into matches
 	    if (first_match && srcMatches)
 	    {
 		memcpy(matches, srcMatches, nextMatch);
 		first_match = FALSE;
 	    }
 	    // Recursive call that "skips" this match
 	    if (fuzzy_match_recursive(fuzpat, str + 1, &recursiveScore,
 			strBegin, matches, recursiveMatches,
 			sizeof(recursiveMatches), nextMatch, recursionCount,
 			recursionLimit))
 	    {
 		// Pick best recursive score
 		if (!recursiveMatch || recursiveScore > bestRecursiveScore)
 		{
 		    memcpy(bestRecursiveMatches, recursiveMatches, 256);
 		    bestRecursiveScore = recursiveScore;
 		}
 		recursiveMatch = TRUE;
 	    }
 	    // Advance
 	    matches[nextMatch++] = (char_u)(str - strBegin);
 	    ++fuzpat;
 	}
 	++str;
    }
    // Determine if full fuzpat was matched
    matched = *fuzpat == '\0' ? TRUE : FALSE;
    // Calculate score
    if (matched)
    {
 	// bonus for adjacent matches
 	int	sequential_bonus = 15;
 	// bonus if match occurs after a separator
 	int	separator_bonus = 30;
 	// bonus if match is uppercase and prev is lower
 	int	camel_bonus = 30;
 	// bonus if the first letter is matched
 	int	first_letter_bonus = 15;
 	// penalty applied for every letter in str before the first match
 	int	leading_letter_penalty = -5;
 	// maximum penalty for leading letters
 	int	max_leading_letter_penalty = -15;
 	// penalty for every letter that doesn't matter
 	int	unmatched_letter_penalty = -1;
 	int	penalty;
 	int	unmatched;
 	int	i;
 	// Iterate str to end
 	while (*str != '\0')
 	    ++str;
 	// Initialize score
 	*outScore = 100;
 	// Apply leading letter penalty
 	penalty = leading_letter_penalty * matches[0];
 	if (penalty < max_leading_letter_penalty)
 	    penalty = max_leading_letter_penalty;
 	*outScore += penalty;
 	// Apply unmatched penalty
 	unmatched = (int)(str - strBegin) - nextMatch;
 	*outScore += unmatched_letter_penalty * unmatched;
 	// Apply ordering bonuses
 	for (i = 0; i < nextMatch; ++i)
 	{
 	    char_u	currIdx = matches[i];
 	    if (i > 0)
 	    {
 		char_u	prevIdx = matches[i - 1];
 		// Sequential
 		if (currIdx == (prevIdx + 1))
 		    *outScore += sequential_bonus;
 	    }
 	    // Check for bonuses based on neighbor character value
 	    if (currIdx > 0)
 	    {
 		// Camel case
 		char_u	neighbor = strBegin[currIdx - 1];
 		char_u	curr = strBegin[currIdx];
 		int	neighborSeparator;
 		if (islower(neighbor) && isupper(curr))
 		    *outScore += camel_bonus;
 		// Separator
 		neighborSeparator = neighbor == '_' || neighbor == ' ';
 		if (neighborSeparator)
 		    *outScore += separator_bonus;
 	    }
 	    else
 	    {
 		// First letter
 		*outScore += first_letter_bonus;
 	    }
 	}
    }
    // Return best result
    if (recursiveMatch && (!matched || bestRecursiveScore > *outScore))
    {
 	// Recursive score is better than "this"
 	memcpy(matches, bestRecursiveMatches, maxMatches);
 	*outScore = bestRecursiveScore;
 	return TRUE;
    }
    else if (matched)
 	return TRUE;		// "this" score is better than recursive
    return FALSE;		// no match
 }
 /*
 * fuzzy_match()
 *
 * Performs exhaustive search via recursion to find all possible matches and
 * match with highest score.
 * Scores values have no intrinsic meaning.  Possible score range is not
 * normalized and varies with pattern.
 * Recursion is limited internally (default=10) to prevent degenerate cases
 * (fuzpat="aaaaaa" str="aaaaaaaaaaaaaaaaaaaaaaaaaaaaaa").
 * Uses char_u for match indices. Therefore patterns are limited to 256
 * characters.
 *
 * Returns TRUE if fuzpat is found AND calculates a score.
 */
    static int
 fuzzy_match(char_u *str, char_u *fuzpat, int *outScore)
 {
    char_u	matches[256];
    int		recursionCount = 0;
    int		recursionLimit = 10;
    *outScore = 0;
    return fuzzy_match_recursive(fuzpat, str, outScore, str, NULL, matches,
 	    sizeof(matches), 0, &recursionCount, recursionLimit);
 }
 /*
 * Sort the fuzzy matches in the descending order of the match score.
 */
    static int
 fuzzy_item_compare(const void *s1, const void *s2)
 {
    int		v1 = ((fuzzyItem_T *)s1)->score;
    int		v2 = ((fuzzyItem_T *)s2)->score;
    return v1 == v2 ? 0 : v1 > v2 ? -1 : 1;
 }
 /*
 * Fuzzy search the string 'str' in 'strlist' and return the matching strings
 * in 'fmatchlist'.
 */
    static void
 match_fuzzy(list_T *strlist, char_u *str, list_T *fmatchlist)
 {
    long	len;
    fuzzyItem_T	*ptrs;
    listitem_T	*li;
    long	i = 0;
    int		found_match = FALSE;
    len = list_len(strlist);
    if (len == 0)
 	return;
    ptrs = ALLOC_MULT(fuzzyItem_T, len);
    if (ptrs == NULL)
 	return;
    // For all the string items in strlist, get the fuzzy matching score
    FOR_ALL_LIST_ITEMS(strlist, li)
    {
 	int	score;
 	ptrs[i].item = li;
 	ptrs[i].score = -9999;
 	// ignore non-string items in the list
 	if (li->li_tv.v_type == VAR_STRING && li->li_tv.vval.v_string != NULL)
 	    if (fuzzy_match(li->li_tv.vval.v_string, str, &score))
 	    {
 		ptrs[i].score = score;
 		found_match = TRUE;
 	    }
 	++i;
    }
    if (found_match)
    {
 	// Sort the list by the descending order of the match score
 	qsort((void *)ptrs, (size_t)len, sizeof(fuzzyItem_T),
 		fuzzy_item_compare);
 	// Copy the matching strings with 'score != -9999' to the return list
 	for (i = 0; i < len; i++)
 	{
 	    if (ptrs[i].score == -9999)
 		break;
 	    list_append_string(fmatchlist, ptrs[i].item->li_tv.vval.v_string,
 		    -1);
 	}
    }
    vim_free(ptrs);
 }
 /*
 * "matchfuzzy()" function
 */
    void
 f_matchfuzzy(typval_T *argvars, typval_T *rettv)
 {
    if (argvars[0].v_type != VAR_LIST)
    {
 	emsg(_(e_listreq));
 	return;
    }
    if (argvars[0].vval.v_list == NULL)
 	return;
    if (argvars[1].v_type != VAR_STRING
 	    || argvars[1].vval.v_string == NULL)
    {
 	semsg(_(e_invarg2), tv_get_string(&argvars[1]));
 	return;
    }
    if (rettv_list_alloc(rettv) == OK)
 	match_fuzzy(argvars[0].vval.v_list, tv_get_string(&argvars[1]),
 		rettv->vval.v_list);
 }
 #endif
--- a/src/testdir/test_functions.vim
+++ b/src/testdir/test_functions.vim
@@ -2554,4 +2554,28 @@ func Test_browsedir()
  call assert_fails('call browsedir("open", [])', 'E730:')
 endfunc
 " Test for matchfuzzy()
 func Test_matchfuzzy()
  call assert_fails('call matchfuzzy(10, "abc")', 'E714:')
  call assert_fails('call matchfuzzy(["abc"], [])', 'E730:')
  call assert_equal([], matchfuzzy([], 'abc'))
  call assert_equal([], matchfuzzy(['abc'], ''))
  call assert_equal(['abc'], matchfuzzy(['abc', 10], 'ac'))
  call assert_equal([], matchfuzzy([10, 20], 'ac'))
  call assert_equal(['abc'], matchfuzzy(['abc'], 'abc'))
  call assert_equal(['crayon', 'camera'], matchfuzzy(['camera', 'crayon'], 'cra'))
  call assert_equal(['aabbaa', 'aaabbbaaa', 'aaaabbbbaaaa', 'aba'], matchfuzzy(['aba', 'aabbaa', 'aaabbbaaa', 'aaaabbbbaaaa'], 'aa'))
  call assert_equal(['one'], matchfuzzy(['one', 'two'], 'one'))
  call assert_equal(['oneTwo', 'onetwo'], matchfuzzy(['onetwo', 'oneTwo'], 'oneTwo'))
  call assert_equal(['one_two', 'onetwo'], matchfuzzy(['onetwo', 'one_two'], 'oneTwo'))
  call assert_equal(['aaaaaaaaaaaaaaaaaaaaaaaaaaaaaa'], matchfuzzy(['aaaaaaaaaaaaaaaaaaaaaaaaaaaaaa'], 'aa'))
  call assert_equal([], matchfuzzy([repeat('a', 300)], repeat('a', 257)))
  %bw!
  eval ['somebuf', 'anotherone', 'needle', 'yetanotherone']->map({_, v -> bufadd(v) + bufload(v)})
  let l = getbufinfo()->map({_, v -> v.name})->matchfuzzy('ndl')
  call assert_equal(1, len(l))
  call assert_match('needle', l[0])
 endfunc
 " vim: shiftwidth=2 sts=2 expandtab
--- a/src/version.c
+++ b/src/version.c
@@ -750,6 +750,8 @@ static char *(features[]) =
 static int included_patches[] =
 {   /* Add new patch number below this line */
 /**/
    1665,
 /**/
    1664,
 /**/