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actix-extras/static.files/search-39ee4160c7dc16c9.js

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/* global addClass, getNakedUrl, getSettingValue */
/* global onEachLazy, removeClass, searchState, browserSupportsHistoryApi, exports */
"use strict";
(function() {
// This mapping table should match the discriminants of
// `rustdoc::formats::item_type::ItemType` type in Rust.
const itemTypes = [
"mod",
"externcrate",
"import",
"struct",
"enum",
"fn",
"type",
"static",
"trait",
"impl",
"tymethod",
"method",
"structfield",
"variant",
"macro",
"primitive",
"associatedtype",
"constant",
"associatedconstant",
"union",
"foreigntype",
"keyword",
"existential",
"attr",
"derive",
"traitalias",
];
// used for special search precedence
const TY_PRIMITIVE = itemTypes.indexOf("primitive");
const TY_KEYWORD = itemTypes.indexOf("keyword");
const ROOT_PATH = typeof window !== "undefined" ? window.rootPath : "../";
function hasOwnPropertyRustdoc(obj, property) {
return Object.prototype.hasOwnProperty.call(obj, property);
}
// In the search display, allows to switch between tabs.
function printTab(nb) {
let iter = 0;
let foundCurrentTab = false;
let foundCurrentResultSet = false;
onEachLazy(document.getElementById("titles").childNodes, elem => {
if (nb === iter) {
addClass(elem, "selected");
foundCurrentTab = true;
} else {
removeClass(elem, "selected");
}
iter += 1;
});
iter = 0;
onEachLazy(document.getElementById("results").childNodes, elem => {
if (nb === iter) {
addClass(elem, "active");
foundCurrentResultSet = true;
} else {
removeClass(elem, "active");
}
iter += 1;
});
if (foundCurrentTab && foundCurrentResultSet) {
searchState.currentTab = nb;
} else if (nb !== 0) {
printTab(0);
}
}
/**
* A function to compute the Levenshtein distance between two strings
* Licensed under the Creative Commons Attribution-ShareAlike 3.0 Unported
* Full License can be found at http://creativecommons.org/licenses/by-sa/3.0/legalcode
* This code is an unmodified version of the code written by Marco de Wit
* and was found at https://stackoverflow.com/a/18514751/745719
*/
const levenshtein_row2 = [];
function levenshtein(s1, s2) {
if (s1 === s2) {
return 0;
}
const s1_len = s1.length, s2_len = s2.length;
if (s1_len && s2_len) {
let i1 = 0, i2 = 0, a, b, c, c2;
const row = levenshtein_row2;
while (i1 < s1_len) {
row[i1] = ++i1;
}
while (i2 < s2_len) {
c2 = s2.charCodeAt(i2);
a = i2;
++i2;
b = i2;
for (i1 = 0; i1 < s1_len; ++i1) {
c = a + (s1.charCodeAt(i1) !== c2 ? 1 : 0);
a = row[i1];
b = b < a ? (b < c ? b + 1 : c) : (a < c ? a + 1 : c);
row[i1] = b;
}
}
return b;
}
return s1_len + s2_len;
}
function initSearch(rawSearchIndex) {
const MAX_LEV_DISTANCE = 3;
const MAX_RESULTS = 200;
const NO_TYPE_FILTER = -1;
/**
* @type {Array<Row>}
*/
let searchIndex;
let currentResults;
const ALIASES = Object.create(null);
function isWhitespace(c) {
return " \t\n\r".indexOf(c) !== -1;
}
function isSpecialStartCharacter(c) {
return "<\"".indexOf(c) !== -1;
}
function isEndCharacter(c) {
return ",>-".indexOf(c) !== -1;
}
function isStopCharacter(c) {
return isWhitespace(c) || isEndCharacter(c);
}
function isErrorCharacter(c) {
return "()".indexOf(c) !== -1;
}
function itemTypeFromName(typename) {
for (let i = 0, len = itemTypes.length; i < len; ++i) {
if (itemTypes[i] === typename) {
return i;
}
}
throw new Error("Unknown type filter `" + typename + "`");
}
/**
* If we encounter a `"`, then we try to extract the string from it until we find another `"`.
*
* This function will throw an error in the following cases:
* * There is already another string element.
* * We are parsing a generic argument.
* * There is more than one element.
* * There is no closing `"`.
*
* @param {ParsedQuery} query
* @param {ParserState} parserState
* @param {boolean} isInGenerics
*/
function getStringElem(query, parserState, isInGenerics) {
if (isInGenerics) {
throw new Error("`\"` cannot be used in generics");
} else if (query.literalSearch) {
throw new Error("Cannot have more than one literal search element");
} else if (parserState.totalElems - parserState.genericsElems > 0) {
throw new Error("Cannot use literal search when there is more than one element");
}
parserState.pos += 1;
const start = parserState.pos;
const end = getIdentEndPosition(parserState);
if (parserState.pos >= parserState.length) {
throw new Error("Unclosed `\"`");
} else if (parserState.userQuery[end] !== "\"") {
throw new Error(`Unexpected \`${parserState.userQuery[end]}\` in a string element`);
} else if (start === end) {
throw new Error("Cannot have empty string element");
}
// To skip the quote at the end.
parserState.pos += 1;
query.literalSearch = true;
}
/**
* Returns `true` if the current parser position is starting with "::".
*
* @param {ParserState} parserState
*
* @return {boolean}
*/
function isPathStart(parserState) {
return parserState.userQuery.slice(parserState.pos, parserState.pos + 2) === "::";
}
/**
* Returns `true` if the current parser position is starting with "->".
*
* @param {ParserState} parserState
*
* @return {boolean}
*/
function isReturnArrow(parserState) {
return parserState.userQuery.slice(parserState.pos, parserState.pos + 2) === "->";
}
/**
* Returns `true` if the given `c` character is valid for an ident.
*
* @param {string} c
*
* @return {boolean}
*/
function isIdentCharacter(c) {
return (
c === "_" ||
(c >= "0" && c <= "9") ||
(c >= "a" && c <= "z") ||
(c >= "A" && c <= "Z"));
}
/**
* Returns `true` if the given `c` character is a separator.
*
* @param {string} c
*
* @return {boolean}
*/
function isSeparatorCharacter(c) {
return c === "," || isWhitespaceCharacter(c);
}
/**
* Returns `true` if the given `c` character is a whitespace.
*
* @param {string} c
*
* @return {boolean}
*/
function isWhitespaceCharacter(c) {
return c === " " || c === "\t";
}
/**
* @param {ParsedQuery} query
* @param {ParserState} parserState
* @param {string} name - Name of the query element.
* @param {Array<QueryElement>} generics - List of generics of this query element.
*
* @return {QueryElement} - The newly created `QueryElement`.
*/
function createQueryElement(query, parserState, name, generics, isInGenerics) {
if (name === "*" || (name.length === 0 && generics.length === 0)) {
return;
}
if (query.literalSearch && parserState.totalElems - parserState.genericsElems > 0) {
throw new Error("You cannot have more than one element if you use quotes");
}
const pathSegments = name.split("::");
if (pathSegments.length > 1) {
for (let i = 0, len = pathSegments.length; i < len; ++i) {
const pathSegment = pathSegments[i];
if (pathSegment.length === 0) {
if (i === 0) {
throw new Error("Paths cannot start with `::`");
} else if (i + 1 === len) {
throw new Error("Paths cannot end with `::`");
}
throw new Error("Unexpected `::::`");
}
}
}
// In case we only have something like `<p>`, there is no name.
if (pathSegments.length === 0 || (pathSegments.length === 1 && pathSegments[0] === "")) {
throw new Error("Found generics without a path");
}
parserState.totalElems += 1;
if (isInGenerics) {
parserState.genericsElems += 1;
}
return {
name: name,
fullPath: pathSegments,
pathWithoutLast: pathSegments.slice(0, pathSegments.length - 1),
pathLast: pathSegments[pathSegments.length - 1],
generics: generics,
};
}
/**
* This function goes through all characters until it reaches an invalid ident character or the
* end of the query. It returns the position of the last character of the ident.
*
* @param {ParserState} parserState
*
* @return {integer}
*/
function getIdentEndPosition(parserState) {
let end = parserState.pos;
let foundExclamation = false;
while (parserState.pos < parserState.length) {
const c = parserState.userQuery[parserState.pos];
if (!isIdentCharacter(c)) {
if (c === "!") {
if (foundExclamation) {
throw new Error("Cannot have more than one `!` in an ident");
} else if (parserState.pos + 1 < parserState.length &&
isIdentCharacter(parserState.userQuery[parserState.pos + 1])
) {
throw new Error("`!` can only be at the end of an ident");
}
foundExclamation = true;
} else if (isErrorCharacter(c)) {
throw new Error(`Unexpected \`${c}\``);
} else if (
isStopCharacter(c) ||
isSpecialStartCharacter(c) ||
isSeparatorCharacter(c)
) {
break;
} else if (c === ":") { // If we allow paths ("str::string" for example).
if (!isPathStart(parserState)) {
break;
}
// Skip current ":".
parserState.pos += 1;
foundExclamation = false;
} else {
throw new Error(`Unexpected \`${c}\``);
}
}
parserState.pos += 1;
end = parserState.pos;
}
return end;
}
/**
* @param {ParsedQuery} query
* @param {ParserState} parserState
* @param {Array<QueryElement>} elems - This is where the new {QueryElement} will be added.
* @param {boolean} isInGenerics
*/
function getNextElem(query, parserState, elems, isInGenerics) {
const generics = [];
let start = parserState.pos;
let end;
// We handle the strings on their own mostly to make code easier to follow.
if (parserState.userQuery[parserState.pos] === "\"") {
start += 1;
getStringElem(query, parserState, isInGenerics);
end = parserState.pos - 1;
} else {
end = getIdentEndPosition(parserState);
}
if (parserState.pos < parserState.length &&
parserState.userQuery[parserState.pos] === "<"
) {
if (isInGenerics) {
throw new Error("Unexpected `<` after `<`");
} else if (start >= end) {
throw new Error("Found generics without a path");
}
parserState.pos += 1;
getItemsBefore(query, parserState, generics, ">");
}
if (start >= end && generics.length === 0) {
return;
}
elems.push(
createQueryElement(
query,
parserState,
parserState.userQuery.slice(start, end),
generics,
isInGenerics
)
);
}
/**
* This function parses the next query element until it finds `endChar`, calling `getNextElem`
* to collect each element.
*
* If there is no `endChar`, this function will implicitly stop at the end without raising an
* error.
*
* @param {ParsedQuery} query
* @param {ParserState} parserState
* @param {Array<QueryElement>} elems - This is where the new {QueryElement} will be added.
* @param {string} endChar - This function will stop when it'll encounter this
* character.
*/
function getItemsBefore(query, parserState, elems, endChar) {
let foundStopChar = true;
while (parserState.pos < parserState.length) {
const c = parserState.userQuery[parserState.pos];
if (c === endChar) {
break;
} else if (isSeparatorCharacter(c)) {
parserState.pos += 1;
foundStopChar = true;
continue;
} else if (c === ":" && isPathStart(parserState)) {
throw new Error("Unexpected `::`: paths cannot start with `::`");
} else if (c === ":" || isEndCharacter(c)) {
let extra = "";
if (endChar === ">") {
extra = "`<`";
} else if (endChar === "") {
extra = "`->`";
}
throw new Error("Unexpected `" + c + "` after " + extra);
}
if (!foundStopChar) {
if (endChar !== "") {
throw new Error(`Expected \`,\`, \` \` or \`${endChar}\`, found \`${c}\``);
}
throw new Error(`Expected \`,\` or \` \`, found \`${c}\``);
}
const posBefore = parserState.pos;
getNextElem(query, parserState, elems, endChar === ">");
// This case can be encountered if `getNextElem` encountered a "stop character" right
// from the start. For example if you have `,,` or `<>`. In this case, we simply move up
// the current position to continue the parsing.
if (posBefore === parserState.pos) {
parserState.pos += 1;
}
foundStopChar = false;
}
// We are either at the end of the string or on the `endChar`` character, let's move forward
// in any case.
parserState.pos += 1;
}
/**
* Checks that the type filter doesn't have unwanted characters like `<>` (which are ignored
* if empty).
*
* @param {ParserState} parserState
*/
function checkExtraTypeFilterCharacters(parserState) {
const query = parserState.userQuery;
for (let pos = 0; pos < parserState.pos; ++pos) {
if (!isIdentCharacter(query[pos]) && !isWhitespaceCharacter(query[pos])) {
throw new Error(`Unexpected \`${query[pos]}\` in type filter`);
}
}
}
/**
* Parses the provided `query` input to fill `parserState`. If it encounters an error while
* parsing `query`, it'll throw an error.
*
* @param {ParsedQuery} query
* @param {ParserState} parserState
*/
function parseInput(query, parserState) {
let c, before;
let foundStopChar = true;
while (parserState.pos < parserState.length) {
c = parserState.userQuery[parserState.pos];
if (isStopCharacter(c)) {
foundStopChar = true;
if (isSeparatorCharacter(c)) {
parserState.pos += 1;
continue;
} else if (c === "-" || c === ">") {
if (isReturnArrow(parserState)) {
break;
}
throw new Error(`Unexpected \`${c}\` (did you mean \`->\`?)`);
}
throw new Error(`Unexpected \`${c}\``);
} else if (c === ":" && !isPathStart(parserState)) {
if (parserState.typeFilter !== null) {
throw new Error("Unexpected `:`");
}
if (query.elems.length === 0) {
throw new Error("Expected type filter before `:`");
} else if (query.elems.length !== 1 || parserState.totalElems !== 1) {
throw new Error("Unexpected `:`");
} else if (query.literalSearch) {
throw new Error("You cannot use quotes on type filter");
}
checkExtraTypeFilterCharacters(parserState);
// The type filter doesn't count as an element since it's a modifier.
parserState.typeFilter = query.elems.pop().name;
parserState.pos += 1;
parserState.totalElems = 0;
query.literalSearch = false;
foundStopChar = true;
continue;
}
if (!foundStopChar) {
if (parserState.typeFilter !== null) {
throw new Error(`Expected \`,\`, \` \` or \`->\`, found \`${c}\``);
}
throw new Error(`Expected \`,\`, \` \`, \`:\` or \`->\`, found \`${c}\``);
}
before = query.elems.length;
getNextElem(query, parserState, query.elems, false);
if (query.elems.length === before) {
// Nothing was added, weird... Let's increase the position to not remain stuck.
parserState.pos += 1;
}
foundStopChar = false;
}
while (parserState.pos < parserState.length) {
c = parserState.userQuery[parserState.pos];
if (isReturnArrow(parserState)) {
parserState.pos += 2;
// Get returned elements.
getItemsBefore(query, parserState, query.returned, "");
// Nothing can come afterward!
if (query.returned.length === 0) {
throw new Error("Expected at least one item after `->`");
}
break;
} else {
parserState.pos += 1;
}
}
}
/**
* Takes the user search input and returns an empty `ParsedQuery`.
*
* @param {string} userQuery
*
* @return {ParsedQuery}
*/
function newParsedQuery(userQuery) {
return {
original: userQuery,
userQuery: userQuery.toLowerCase(),
typeFilter: NO_TYPE_FILTER,
elems: [],
returned: [],
// Total number of "top" elements (does not include generics).
foundElems: 0,
literalSearch: false,
error: null,
};
}
/**
* Build an URL with search parameters.
*
* @param {string} search - The current search being performed.
* @param {string|null} filterCrates - The current filtering crate (if any).
*
* @return {string}
*/
function buildUrl(search, filterCrates) {
let extra = "?search=" + encodeURIComponent(search);
if (filterCrates !== null) {
extra += "&filter-crate=" + encodeURIComponent(filterCrates);
}
return getNakedUrl() + extra + window.location.hash;
}
/**
* Return the filtering crate or `null` if there is none.
*
* @return {string|null}
*/
function getFilterCrates() {
const elem = document.getElementById("crate-search");
if (elem &&
elem.value !== "all crates" &&
hasOwnPropertyRustdoc(rawSearchIndex, elem.value)
) {
return elem.value;
}
return null;
}
/**
* Parses the query.
*
* The supported syntax by this parser is as follow:
*
* ident = *(ALPHA / DIGIT / "_") [!]
* path = ident *(DOUBLE-COLON ident)
* arg = path [generics]
* arg-without-generic = path
* type-sep = COMMA/WS *(COMMA/WS)
* nonempty-arg-list = *(type-sep) arg *(type-sep arg) *(type-sep)
* nonempty-arg-list-without-generics = *(type-sep) arg-without-generic
* *(type-sep arg-without-generic) *(type-sep)
* generics = OPEN-ANGLE-BRACKET [ nonempty-arg-list-without-generics ] *(type-sep)
* CLOSE-ANGLE-BRACKET/EOF
* return-args = RETURN-ARROW *(type-sep) nonempty-arg-list
*
* exact-search = [type-filter *WS COLON] [ RETURN-ARROW ] *WS QUOTE ident QUOTE [ generics ]
* type-search = [type-filter *WS COLON] [ nonempty-arg-list ] [ return-args ]
*
* query = *WS (exact-search / type-search) *WS
*
* type-filter = (
* "mod" /
* "externcrate" /
* "import" /
* "struct" /
* "enum" /
* "fn" /
* "type" /
* "static" /
* "trait" /
* "impl" /
* "tymethod" /
* "method" /
* "structfield" /
* "variant" /
* "macro" /
* "primitive" /
* "associatedtype" /
* "constant" /
* "associatedconstant" /
* "union" /
* "foreigntype" /
* "keyword" /
* "existential" /
* "attr" /
* "derive" /
* "traitalias")
*
* OPEN-ANGLE-BRACKET = "<"
* CLOSE-ANGLE-BRACKET = ">"
* COLON = ":"
* DOUBLE-COLON = "::"
* QUOTE = %x22
* COMMA = ","
* RETURN-ARROW = "->"
*
* ALPHA = %x41-5A / %x61-7A ; A-Z / a-z
* DIGIT = %x30-39
* WS = %x09 / " "
*
* @param {string} val - The user query
*
* @return {ParsedQuery} - The parsed query
*/
function parseQuery(userQuery) {
userQuery = userQuery.trim();
const parserState = {
length: userQuery.length,
pos: 0,
// Total number of elements (includes generics).
totalElems: 0,
genericsElems: 0,
typeFilter: null,
userQuery: userQuery.toLowerCase(),
};
let query = newParsedQuery(userQuery);
try {
parseInput(query, parserState);
if (parserState.typeFilter !== null) {
let typeFilter = parserState.typeFilter;
if (typeFilter === "const") {
typeFilter = "constant";
}
query.typeFilter = itemTypeFromName(typeFilter);
}
} catch (err) {
query = newParsedQuery(userQuery);
query.error = err.message;
query.typeFilter = -1;
return query;
}
if (!query.literalSearch) {
// If there is more than one element in the query, we switch to literalSearch in any
// case.
query.literalSearch = parserState.totalElems > 1;
}
query.foundElems = query.elems.length + query.returned.length;
return query;
}
/**
* Creates the query results.
*
* @param {Array<Result>} results_in_args
* @param {Array<Result>} results_returned
* @param {Array<Result>} results_in_args
* @param {ParsedQuery} parsedQuery
*
* @return {ResultsTable}
*/
function createQueryResults(results_in_args, results_returned, results_others, parsedQuery) {
return {
"in_args": results_in_args,
"returned": results_returned,
"others": results_others,
"query": parsedQuery,
};
}
/**
* Executes the parsed query and builds a {ResultsTable}.
*
* @param {ParsedQuery} parsedQuery - The parsed user query
* @param {Object} searchWords - The list of search words to query against
* @param {Object} [filterCrates] - Crate to search in if defined
* @param {Object} [currentCrate] - Current crate, to rank results from this crate higher
*
* @return {ResultsTable}
*/
function execQuery(parsedQuery, searchWords, filterCrates, currentCrate) {
const results_others = {}, results_in_args = {}, results_returned = {};
function transformResults(results) {
const duplicates = {};
const out = [];
for (const result of results) {
if (result.id > -1) {
const obj = searchIndex[result.id];
obj.lev = result.lev;
const res = buildHrefAndPath(obj);
obj.displayPath = pathSplitter(res[0]);
obj.fullPath = obj.displayPath + obj.name;
// To be sure than it some items aren't considered as duplicate.
obj.fullPath += "|" + obj.ty;
if (duplicates[obj.fullPath]) {
continue;
}
duplicates[obj.fullPath] = true;
obj.href = res[1];
out.push(obj);
if (out.length >= MAX_RESULTS) {
break;
}
}
}
return out;
}
function sortResults(results, isType, preferredCrate) {
const userQuery = parsedQuery.userQuery;
const ar = [];
for (const entry in results) {
if (hasOwnPropertyRustdoc(results, entry)) {
const result = results[entry];
result.word = searchWords[result.id];
result.item = searchIndex[result.id] || {};
ar.push(result);
}
}
results = ar;
// if there are no results then return to default and fail
if (results.length === 0) {
return [];
}
results.sort((aaa, bbb) => {
let a, b;
// sort by exact match with regard to the last word (mismatch goes later)
a = (aaa.word !== userQuery);
b = (bbb.word !== userQuery);
if (a !== b) {
return a - b;
}
// Sort by non levenshtein results and then levenshtein results by the distance
// (less changes required to match means higher rankings)
a = (aaa.lev);
b = (bbb.lev);
if (a !== b) {
return a - b;
}
// sort by crate (current crate comes first)
a = (aaa.item.crate !== preferredCrate);
b = (bbb.item.crate !== preferredCrate);
if (a !== b) {
return a - b;
}
// sort by item name length (longer goes later)
a = aaa.word.length;
b = bbb.word.length;
if (a !== b) {
return a - b;
}
// sort by item name (lexicographically larger goes later)
a = aaa.word;
b = bbb.word;
if (a !== b) {
return (a > b ? +1 : -1);
}
// sort by index of keyword in item name (no literal occurrence goes later)
a = (aaa.index < 0);
b = (bbb.index < 0);
if (a !== b) {
return a - b;
}
// (later literal occurrence, if any, goes later)
a = aaa.index;
b = bbb.index;
if (a !== b) {
return a - b;
}
// special precedence for primitive and keyword pages
if ((aaa.item.ty === TY_PRIMITIVE && bbb.item.ty !== TY_KEYWORD) ||
(aaa.item.ty === TY_KEYWORD && bbb.item.ty !== TY_PRIMITIVE)) {
return -1;
}
if ((bbb.item.ty === TY_PRIMITIVE && aaa.item.ty !== TY_PRIMITIVE) ||
(bbb.item.ty === TY_KEYWORD && aaa.item.ty !== TY_KEYWORD)) {
return 1;
}
// sort by description (no description goes later)
a = (aaa.item.desc === "");
b = (bbb.item.desc === "");
if (a !== b) {
return a - b;
}
// sort by type (later occurrence in `itemTypes` goes later)
a = aaa.item.ty;
b = bbb.item.ty;
if (a !== b) {
return a - b;
}
// sort by path (lexicographically larger goes later)
a = aaa.item.path;
b = bbb.item.path;
if (a !== b) {
return (a > b ? +1 : -1);
}
// que sera, sera
return 0;
});
let nameSplit = null;
if (parsedQuery.elems.length === 1) {
const hasPath = typeof parsedQuery.elems[0].path === "undefined";
nameSplit = hasPath ? null : parsedQuery.elems[0].path;
}
for (const result of results) {
// this validation does not make sense when searching by types
if (result.dontValidate) {
continue;
}
const name = result.item.name.toLowerCase(),
path = result.item.path.toLowerCase(),
parent = result.item.parent;
if (!isType && !validateResult(name, path, nameSplit, parent)) {
result.id = -1;
}
}
return transformResults(results);
}
/**
* This function checks if the object (`row`) generics match the given type (`elem`)
* generics. If there are no generics on `row`, `defaultLev` is returned.
*
* @param {Row} row - The object to check.
* @param {QueryElement} elem - The element from the parsed query.
* @param {integer} defaultLev - This is the value to return in case there are no generics.
*
* @return {integer} - Returns the best match (if any) or `MAX_LEV_DISTANCE + 1`.
*/
function checkGenerics(row, elem, defaultLev) {
if (row.generics.length === 0) {
return elem.generics.length === 0 ? defaultLev : MAX_LEV_DISTANCE + 1;
} else if (row.generics.length > 0 && row.generics[0].name === null) {
return checkGenerics(row.generics[0], elem, defaultLev);
}
// The names match, but we need to be sure that all generics kinda
// match as well.
let elem_name;
if (elem.generics.length > 0 && row.generics.length >= elem.generics.length) {
const elems = Object.create(null);
for (const entry of row.generics) {
elem_name = entry.name;
if (elem_name === "") {
// Pure generic, needs to check into it.
if (checkGenerics(entry, elem, MAX_LEV_DISTANCE + 1) !== 0) {
return MAX_LEV_DISTANCE + 1;
}
continue;
}
if (elems[elem_name] === undefined) {
elems[elem_name] = 0;
}
elems[elem_name] += 1;
}
// We need to find the type that matches the most to remove it in order
// to move forward.
for (const generic of elem.generics) {
let match = null;
if (elems[generic.name]) {
match = generic.name;
} else {
for (elem_name in elems) {
if (!hasOwnPropertyRustdoc(elems, elem_name)) {
continue;
}
if (elem_name === generic) {
match = elem_name;
break;
}
}
}
if (match === null) {
return MAX_LEV_DISTANCE + 1;
}
elems[match] -= 1;
if (elems[match] === 0) {
delete elems[match];
}
}
return 0;
}
return MAX_LEV_DISTANCE + 1;
}
/**
* This function checks if the object (`row`) matches the given type (`elem`) and its
* generics (if any).
*
* @param {Row} row
* @param {QueryElement} elem - The element from the parsed query.
*
* @return {integer} - Returns a Levenshtein distance to the best match.
*/
function checkIfInGenerics(row, elem) {
let lev = MAX_LEV_DISTANCE + 1;
for (const entry of row.generics) {
lev = Math.min(checkType(entry, elem, true), lev);
if (lev === 0) {
break;
}
}
return lev;
}
/**
* This function checks if the object (`row`) matches the given type (`elem`) and its
* generics (if any).
*
* @param {Row} row
* @param {QueryElement} elem - The element from the parsed query.
* @param {boolean} literalSearch
*
* @return {integer} - Returns a Levenshtein distance to the best match. If there is
* no match, returns `MAX_LEV_DISTANCE + 1`.
*/
function checkType(row, elem, literalSearch) {
if (row.name === null) {
// This is a pure "generic" search, no need to run other checks.
if (row.generics.length > 0) {
return checkIfInGenerics(row, elem);
}
return MAX_LEV_DISTANCE + 1;
}
let lev = levenshtein(row.name, elem.name);
if (literalSearch) {
if (lev !== 0) {
// The name didn't match, let's try to check if the generics do.
if (elem.generics.length === 0) {
const checkGeneric = row.generics.length > 0;
if (checkGeneric && row.generics
.findIndex(tmp_elem => tmp_elem.name === elem.name) !== -1) {
return 0;
}
}
return MAX_LEV_DISTANCE + 1;
} else if (elem.generics.length > 0) {
return checkGenerics(row, elem, MAX_LEV_DISTANCE + 1);
}
return 0;
} else if (row.generics.length > 0) {
if (elem.generics.length === 0) {
if (lev === 0) {
return 0;
}
// The name didn't match so we now check if the type we're looking for is inside
// the generics!
lev = checkIfInGenerics(row, elem);
// Now whatever happens, the returned distance is "less good" so we should mark
// it as such, and so we add 0.5 to the distance to make it "less good".
return lev + 0.5;
} else if (lev > MAX_LEV_DISTANCE) {
// So our item's name doesn't match at all and has generics.
//
// Maybe it's present in a sub generic? For example "f<A<B<C>>>()", if we're
// looking for "B<C>", we'll need to go down.
return checkIfInGenerics(row, elem);
} else {
// At this point, the name kinda match and we have generics to check, so
// let's go!
const tmp_lev = checkGenerics(row, elem, lev);
if (tmp_lev > MAX_LEV_DISTANCE) {
return MAX_LEV_DISTANCE + 1;
}
// We compute the median value of both checks and return it.
return (tmp_lev + lev) / 2;
}
} else if (elem.generics.length > 0) {
// In this case, we were expecting generics but there isn't so we simply reject this
// one.
return MAX_LEV_DISTANCE + 1;
}
// No generics on our query or on the target type so we can return without doing
// anything else.
return lev;
}
/**
* This function checks if the object (`row`) has an argument with the given type (`elem`).
*
* @param {Row} row
* @param {QueryElement} elem - The element from the parsed query.
* @param {integer} typeFilter
*
* @return {integer} - Returns a Levenshtein distance to the best match. If there is no
* match, returns `MAX_LEV_DISTANCE + 1`.
*/
function findArg(row, elem, typeFilter) {
let lev = MAX_LEV_DISTANCE + 1;
if (row && row.type && row.type.inputs && row.type.inputs.length > 0) {
for (const input of row.type.inputs) {
if (!typePassesFilter(typeFilter, input.ty)) {
continue;
}
lev = Math.min(lev, checkType(input, elem, parsedQuery.literalSearch));
if (lev === 0) {
return 0;
}
}
}
return parsedQuery.literalSearch ? MAX_LEV_DISTANCE + 1 : lev;
}
/**
* This function checks if the object (`row`) returns the given type (`elem`).
*
* @param {Row} row
* @param {QueryElement} elem - The element from the parsed query.
* @param {integer} typeFilter
*
* @return {integer} - Returns a Levenshtein distance to the best match. If there is no
* match, returns `MAX_LEV_DISTANCE + 1`.
*/
function checkReturned(row, elem, typeFilter) {
let lev = MAX_LEV_DISTANCE + 1;
if (row && row.type && row.type.output.length > 0) {
const ret = row.type.output;
for (const ret_ty of ret) {
if (!typePassesFilter(typeFilter, ret_ty.ty)) {
continue;
}
lev = Math.min(lev, checkType(ret_ty, elem, parsedQuery.literalSearch));
if (lev === 0) {
return 0;
}
}
}
return parsedQuery.literalSearch ? MAX_LEV_DISTANCE + 1 : lev;
}
function checkPath(contains, ty) {
if (contains.length === 0) {
return 0;
}
let ret_lev = MAX_LEV_DISTANCE + 1;
const path = ty.path.split("::");
if (ty.parent && ty.parent.name) {
path.push(ty.parent.name.toLowerCase());
}
const length = path.length;
const clength = contains.length;
if (clength > length) {
return MAX_LEV_DISTANCE + 1;
}
for (let i = 0; i < length; ++i) {
if (i + clength > length) {
break;
}
let lev_total = 0;
let aborted = false;
for (let x = 0; x < clength; ++x) {
const lev = levenshtein(path[i + x], contains[x]);
if (lev > MAX_LEV_DISTANCE) {
aborted = true;
break;
}
lev_total += lev;
}
if (!aborted) {
ret_lev = Math.min(ret_lev, Math.round(lev_total / clength));
}
}
return ret_lev;
}
function typePassesFilter(filter, type) {
// No filter or Exact mach
if (filter <= NO_TYPE_FILTER || filter === type) return true;
// Match related items
const name = itemTypes[type];
switch (itemTypes[filter]) {
case "constant":
return name === "associatedconstant";
case "fn":
return name === "method" || name === "tymethod";
case "type":
return name === "primitive" || name === "associatedtype";
case "trait":
return name === "traitalias";
}
// No match
return false;
}
function createAliasFromItem(item) {
return {
crate: item.crate,
name: item.name,
path: item.path,
desc: item.desc,
ty: item.ty,
parent: item.parent,
type: item.type,
is_alias: true,
};
}
function handleAliases(ret, query, filterCrates, currentCrate) {
const lowerQuery = query.toLowerCase();
// We separate aliases and crate aliases because we want to have current crate
// aliases to be before the others in the displayed results.
const aliases = [];
const crateAliases = [];
if (filterCrates !== null) {
if (ALIASES[filterCrates] && ALIASES[filterCrates][lowerQuery]) {
const query_aliases = ALIASES[filterCrates][lowerQuery];
for (const alias of query_aliases) {
aliases.push(createAliasFromItem(searchIndex[alias]));
}
}
} else {
Object.keys(ALIASES).forEach(crate => {
if (ALIASES[crate][lowerQuery]) {
const pushTo = crate === currentCrate ? crateAliases : aliases;
const query_aliases = ALIASES[crate][lowerQuery];
for (const alias of query_aliases) {
pushTo.push(createAliasFromItem(searchIndex[alias]));
}
}
});
}
const sortFunc = (aaa, bbb) => {
if (aaa.path < bbb.path) {
return 1;
} else if (aaa.path === bbb.path) {
return 0;
}
return -1;
};
crateAliases.sort(sortFunc);
aliases.sort(sortFunc);
const pushFunc = alias => {
alias.alias = query;
const res = buildHrefAndPath(alias);
alias.displayPath = pathSplitter(res[0]);
alias.fullPath = alias.displayPath + alias.name;
alias.href = res[1];
ret.others.unshift(alias);
if (ret.others.length > MAX_RESULTS) {
ret.others.pop();
}
};
aliases.forEach(pushFunc);
crateAliases.forEach(pushFunc);
}
/**
* This function adds the given result into the provided `results` map if it matches the
* following condition:
*
* * If it is a "literal search" (`parsedQuery.literalSearch`), then `lev` must be 0.
* * If it is not a "literal search", `lev` must be <= `MAX_LEV_DISTANCE`.
*
* The `results` map contains information which will be used to sort the search results:
*
* * `fullId` is a `string`` used as the key of the object we use for the `results` map.
* * `id` is the index in both `searchWords` and `searchIndex` arrays for this element.
* * `index` is an `integer`` used to sort by the position of the word in the item's name.
* * `lev` is the main metric used to sort the search results.
*
* @param {Results} results
* @param {string} fullId
* @param {integer} id
* @param {integer} index
* @param {integer} lev
*/
function addIntoResults(results, fullId, id, index, lev) {
if (lev === 0 || (!parsedQuery.literalSearch && lev <= MAX_LEV_DISTANCE)) {
if (results[fullId] !== undefined) {
const result = results[fullId];
if (result.dontValidate || result.lev <= lev) {
return;
}
}
results[fullId] = {
id: id,
index: index,
dontValidate: parsedQuery.literalSearch,
lev: lev,
};
}
}
/**
* This function is called in case the query is only one element (with or without generics).
* This element will be compared to arguments' and returned values' items and also to items.
*
* Other important thing to note: since there is only one element, we use levenshtein
* distance for name comparisons.
*
* @param {Row} row
* @param {integer} pos - Position in the `searchIndex`.
* @param {QueryElement} elem - The element from the parsed query.
* @param {Results} results_others - Unqualified results (not in arguments nor in
* returned values).
* @param {Results} results_in_args - Matching arguments results.
* @param {Results} results_returned - Matching returned arguments results.
*/
function handleSingleArg(
row,
pos,
elem,
results_others,
results_in_args,
results_returned
) {
if (!row || (filterCrates !== null && row.crate !== filterCrates)) {
return;
}
let lev, lev_add = 0, index = -1;
const fullId = row.id;
const in_args = findArg(row, elem, parsedQuery.typeFilter);
const returned = checkReturned(row, elem, parsedQuery.typeFilter);
addIntoResults(results_in_args, fullId, pos, index, in_args);
addIntoResults(results_returned, fullId, pos, index, returned);
if (!typePassesFilter(parsedQuery.typeFilter, row.ty)) {
return;
}
const searchWord = searchWords[pos];
if (parsedQuery.literalSearch) {
if (searchWord === elem.name) {
addIntoResults(results_others, fullId, pos, -1, 0);
}
return;
}
// No need to check anything else if it's a "pure" generics search.
if (elem.name.length === 0) {
if (row.type !== null) {
lev = checkGenerics(row.type, elem, MAX_LEV_DISTANCE + 1);
addIntoResults(results_others, fullId, pos, index, lev);
}
return;
}
if (elem.fullPath.length > 1) {
lev = checkPath(elem.pathWithoutLast, row);
if (lev > MAX_LEV_DISTANCE || (parsedQuery.literalSearch && lev !== 0)) {
return;
} else if (lev > 0) {
lev_add = lev / 10;
}
}
if (searchWord.indexOf(elem.pathLast) > -1 ||
row.normalizedName.indexOf(elem.pathLast) > -1
) {
index = row.normalizedName.indexOf(elem.pathLast);
}
lev = levenshtein(searchWord, elem.pathLast);
if (lev > 0 && elem.pathLast.length > 2 && searchWord.indexOf(elem.pathLast) > -1) {
if (elem.pathLast.length < 6) {
lev = 1;
} else {
lev = 0;
}
}
lev += lev_add;
if (lev > MAX_LEV_DISTANCE) {
return;
} else if (index !== -1 && elem.fullPath.length < 2) {
lev -= 1;
}
if (lev < 0) {
lev = 0;
}
addIntoResults(results_others, fullId, pos, index, lev);
}
/**
* This function is called in case the query has more than one element. In this case, it'll
* try to match the items which validates all the elements. For `aa -> bb` will look for
* functions which have a parameter `aa` and has `bb` in its returned values.
*
* @param {Row} row
* @param {integer} pos - Position in the `searchIndex`.
* @param {Object} results
*/
function handleArgs(row, pos, results) {
if (!row || (filterCrates !== null && row.crate !== filterCrates)) {
return;
}
let totalLev = 0;
let nbLev = 0;
// If the result is too "bad", we return false and it ends this search.
function checkArgs(elems, callback) {
for (const elem of elems) {
// There is more than one parameter to the query so all checks should be "exact"
const lev = callback(row, elem, NO_TYPE_FILTER);
if (lev <= 1) {
nbLev += 1;
totalLev += lev;
} else {
return false;
}
}
return true;
}
if (!checkArgs(parsedQuery.elems, findArg)) {
return;
}
if (!checkArgs(parsedQuery.returned, checkReturned)) {
return;
}
if (nbLev === 0) {
return;
}
const lev = Math.round(totalLev / nbLev);
addIntoResults(results, row.id, pos, 0, lev);
}
function innerRunQuery() {
let elem, i, nSearchWords, in_returned, row;
if (parsedQuery.foundElems === 1) {
if (parsedQuery.elems.length === 1) {
elem = parsedQuery.elems[0];
for (i = 0, nSearchWords = searchWords.length; i < nSearchWords; ++i) {
// It means we want to check for this element everywhere (in names, args and
// returned).
handleSingleArg(
searchIndex[i],
i,
elem,
results_others,
results_in_args,
results_returned
);
}
} else if (parsedQuery.returned.length === 1) {
// We received one returned argument to check, so looking into returned values.
elem = parsedQuery.returned[0];
for (i = 0, nSearchWords = searchWords.length; i < nSearchWords; ++i) {
row = searchIndex[i];
in_returned = checkReturned(row, elem, parsedQuery.typeFilter);
addIntoResults(results_others, row.id, i, -1, in_returned);
}
}
} else if (parsedQuery.foundElems > 0) {
for (i = 0, nSearchWords = searchWords.length; i < nSearchWords; ++i) {
handleArgs(searchIndex[i], i, results_others);
}
}
}
if (parsedQuery.error === null) {
innerRunQuery();
}
const ret = createQueryResults(
sortResults(results_in_args, true, currentCrate),
sortResults(results_returned, true, currentCrate),
sortResults(results_others, false, currentCrate),
parsedQuery);
handleAliases(ret, parsedQuery.original.replace(/"/g, ""), filterCrates, currentCrate);
if (parsedQuery.error !== null && ret.others.length !== 0) {
// It means some doc aliases were found so let's "remove" the error!
ret.query.error = null;
}
return ret;
}
/**
* Validate performs the following boolean logic. For example:
* "File::open" will give IF A PARENT EXISTS => ("file" && "open")
* exists in (name || path || parent) OR => ("file" && "open") exists in
* (name || path )
*
* This could be written functionally, but I wanted to minimise
* functions on stack.
*
* @param {string} name - The name of the result
* @param {string} path - The path of the result
* @param {string} keys - The keys to be used (["file", "open"])
* @param {Object} parent - The parent of the result
*
* @return {boolean} - Whether the result is valid or not
*/
function validateResult(name, path, keys, parent) {
if (!keys || !keys.length) {
return true;
}
for (const key of keys) {
// each check is for validation so we negate the conditions and invalidate
if (!(
// check for an exact name match
name.indexOf(key) > -1 ||
// then an exact path match
path.indexOf(key) > -1 ||
// next if there is a parent, check for exact parent match
(parent !== undefined && parent.name !== undefined &&
parent.name.toLowerCase().indexOf(key) > -1) ||
// lastly check to see if the name was a levenshtein match
levenshtein(name, key) <= MAX_LEV_DISTANCE)) {
return false;
}
}
return true;
}
function nextTab(direction) {
const next = (searchState.currentTab + direction + 3) % searchState.focusedByTab.length;
searchState.focusedByTab[searchState.currentTab] = document.activeElement;
printTab(next);
focusSearchResult();
}
// Focus the first search result on the active tab, or the result that
// was focused last time this tab was active.
function focusSearchResult() {
const target = searchState.focusedByTab[searchState.currentTab] ||
document.querySelectorAll(".search-results.active a").item(0) ||
document.querySelectorAll("#titles > button").item(searchState.currentTab);
if (target) {
target.focus();
}
}
function buildHrefAndPath(item) {
let displayPath;
let href;
const type = itemTypes[item.ty];
const name = item.name;
let path = item.path;
if (type === "mod") {
displayPath = path + "::";
href = ROOT_PATH + path.replace(/::/g, "/") + "/" +
name + "/index.html";
} else if (type === "import") {
displayPath = item.path + "::";
href = ROOT_PATH + item.path.replace(/::/g, "/") + "/index.html#reexport." + name;
} else if (type === "primitive" || type === "keyword") {
displayPath = "";
href = ROOT_PATH + path.replace(/::/g, "/") +
"/" + type + "." + name + ".html";
} else if (type === "externcrate") {
displayPath = "";
href = ROOT_PATH + name + "/index.html";
} else if (item.parent !== undefined) {
const myparent = item.parent;
let anchor = "#" + type + "." + name;
const parentType = itemTypes[myparent.ty];
let pageType = parentType;
let pageName = myparent.name;
if (parentType === "primitive") {
displayPath = myparent.name + "::";
} else if (type === "structfield" && parentType === "variant") {
// Structfields belonging to variants are special: the
// final path element is the enum name.
const enumNameIdx = item.path.lastIndexOf("::");
const enumName = item.path.substr(enumNameIdx + 2);
path = item.path.substr(0, enumNameIdx);
displayPath = path + "::" + enumName + "::" + myparent.name + "::";
anchor = "#variant." + myparent.name + ".field." + name;
pageType = "enum";
pageName = enumName;
} else {
displayPath = path + "::" + myparent.name + "::";
}
href = ROOT_PATH + path.replace(/::/g, "/") +
"/" + pageType +
"." + pageName +
".html" + anchor;
} else {
displayPath = item.path + "::";
href = ROOT_PATH + item.path.replace(/::/g, "/") +
"/" + type + "." + name + ".html";
}
return [displayPath, href];
}
function pathSplitter(path) {
const tmp = "<span>" + path.replace(/::/g, "::</span><span>");
if (tmp.endsWith("<span>")) {
return tmp.slice(0, tmp.length - 6);
}
return tmp;
}
/**
* Render a set of search results for a single tab.
* @param {Array<?>} array - The search results for this tab
* @param {ParsedQuery} query
* @param {boolean} display - True if this is the active tab
*/
function addTab(array, query, display) {
let extraClass = "";
if (display === true) {
extraClass = " active";
}
const output = document.createElement("div");
let length = 0;
if (array.length > 0) {
output.className = "search-results " + extraClass;
array.forEach(item => {
const name = item.name;
const type = itemTypes[item.ty];
length += 1;
let extra = "";
if (type === "primitive") {
extra = " <i>(primitive type)</i>";
} else if (type === "keyword") {
extra = " <i>(keyword)</i>";
}
const link = document.createElement("a");
link.className = "result-" + type;
link.href = item.href;
const resultName = document.createElement("div");
resultName.className = "result-name";
if (item.is_alias) {
const alias = document.createElement("span");
alias.className = "alias";
const bold = document.createElement("b");
bold.innerText = item.alias;
alias.appendChild(bold);
alias.insertAdjacentHTML(
"beforeend",
"<span class=\"grey\"><i>&nbsp;- see&nbsp;</i></span>");
resultName.appendChild(alias);
}
resultName.insertAdjacentHTML(
"beforeend",
item.displayPath + "<span class=\"" + type + "\">" + name + extra + "</span>");
link.appendChild(resultName);
const description = document.createElement("div");
description.className = "desc";
description.insertAdjacentHTML("beforeend", item.desc);
link.appendChild(description);
output.appendChild(link);
});
} else if (query.error === null) {
output.className = "search-failed" + extraClass;
output.innerHTML = "No results :(<br/>" +
"Try on <a href=\"https://duckduckgo.com/?q=" +
encodeURIComponent("rust " + query.userQuery) +
"\">DuckDuckGo</a>?<br/><br/>" +
"Or try looking in one of these:<ul><li>The <a " +
"href=\"https://doc.rust-lang.org/reference/index.html\">Rust Reference</a> " +
" for technical details about the language.</li><li><a " +
"href=\"https://doc.rust-lang.org/rust-by-example/index.html\">Rust By " +
"Example</a> for expository code examples.</a></li><li>The <a " +
"href=\"https://doc.rust-lang.org/book/index.html\">Rust Book</a> for " +
"introductions to language features and the language itself.</li><li><a " +
"href=\"https://docs.rs\">Docs.rs</a> for documentation of crates released on" +
" <a href=\"https://crates.io/\">crates.io</a>.</li></ul>";
}
return [output, length];
}
function makeTabHeader(tabNb, text, nbElems) {
if (searchState.currentTab === tabNb) {
return "<button class=\"selected\">" + text +
" <div class=\"count\">(" + nbElems + ")</div></button>";
}
return "<button>" + text + " <div class=\"count\">(" + nbElems + ")</div></button>";
}
/**
* @param {ResultsTable} results
* @param {boolean} go_to_first
* @param {string} filterCrates
*/
function showResults(results, go_to_first, filterCrates) {
const search = searchState.outputElement();
if (go_to_first || (results.others.length === 1
&& getSettingValue("go-to-only-result") === "true"
// By default, the search DOM element is "empty" (meaning it has no children not
// text content). Once a search has been run, it won't be empty, even if you press
// ESC or empty the search input (which also "cancels" the search).
&& (!search.firstChild || search.firstChild.innerText !== searchState.loadingText))
) {
const elem = document.createElement("a");
elem.href = results.others[0].href;
removeClass(elem, "active");
// For firefox, we need the element to be in the DOM so it can be clicked.
document.body.appendChild(elem);
elem.click();
return;
}
if (results.query === undefined) {
results.query = parseQuery(searchState.input.value);
}
currentResults = results.query.userQuery;
const ret_others = addTab(results.others, results.query, true);
const ret_in_args = addTab(results.in_args, results.query, false);
const ret_returned = addTab(results.returned, results.query, false);
// Navigate to the relevant tab if the current tab is empty, like in case users search
// for "-> String". If they had selected another tab previously, they have to click on
// it again.
let currentTab = searchState.currentTab;
if ((currentTab === 0 && ret_others[1] === 0) ||
(currentTab === 1 && ret_in_args[1] === 0) ||
(currentTab === 2 && ret_returned[1] === 0)) {
if (ret_others[1] !== 0) {
currentTab = 0;
} else if (ret_in_args[1] !== 0) {
currentTab = 1;
} else if (ret_returned[1] !== 0) {
currentTab = 2;
}
}
let crates = "";
const crates_list = Object.keys(rawSearchIndex);
if (crates_list.length > 1) {
crates = " in&nbsp;<div id=\"crate-search-div\"><select id=\"crate-search\">" +
"<option value=\"all crates\">all crates</option>";
for (const c of crates_list) {
crates += `<option value="${c}" ${c === filterCrates && "selected"}>${c}</option>`;
}
crates += "</select></div>";
}
let output = `<h1 class="search-results-title">Results${crates}</h1>`;
if (results.query.error !== null) {
output += `<h3>Query parser error: "${results.query.error}".</h3>`;
output += "<div id=\"titles\">" +
makeTabHeader(0, "In Names", ret_others[1]) +
"</div>";
currentTab = 0;
} else if (results.query.foundElems <= 1 && results.query.returned.length === 0) {
output += "<div id=\"titles\">" +
makeTabHeader(0, "In Names", ret_others[1]) +
makeTabHeader(1, "In Parameters", ret_in_args[1]) +
makeTabHeader(2, "In Return Types", ret_returned[1]) +
"</div>";
} else {
const signatureTabTitle =
results.query.elems.length === 0 ? "In Function Return Types" :
results.query.returned.length === 0 ? "In Function Parameters" :
"In Function Signatures";
output += "<div id=\"titles\">" +
makeTabHeader(0, signatureTabTitle, ret_others[1]) +
"</div>";
currentTab = 0;
}
const resultsElem = document.createElement("div");
resultsElem.id = "results";
resultsElem.appendChild(ret_others[0]);
resultsElem.appendChild(ret_in_args[0]);
resultsElem.appendChild(ret_returned[0]);
search.innerHTML = output;
const crateSearch = document.getElementById("crate-search");
if (crateSearch) {
crateSearch.addEventListener("input", updateCrate);
}
search.appendChild(resultsElem);
// Reset focused elements.
searchState.showResults(search);
const elems = document.getElementById("titles").childNodes;
searchState.focusedByTab = [];
let i = 0;
for (const elem of elems) {
const j = i;
elem.onclick = () => printTab(j);
searchState.focusedByTab.push(null);
i += 1;
}
printTab(currentTab);
}
/**
* Perform a search based on the current state of the search input element
* and display the results.
* @param {Event} [e] - The event that triggered this search, if any
* @param {boolean} [forced]
*/
function search(e, forced) {
const params = searchState.getQueryStringParams();
const query = parseQuery(searchState.input.value.trim());
if (e) {
e.preventDefault();
}
if (!forced && query.userQuery === currentResults) {
if (query.userQuery.length > 0) {
putBackSearch();
}
return;
}
let filterCrates = getFilterCrates();
// In case we have no information about the saved crate and there is a URL query parameter,
// we override it with the URL query parameter.
if (filterCrates === null && params["filter-crate"] !== undefined) {
filterCrates = params["filter-crate"];
}
// Update document title to maintain a meaningful browser history
searchState.title = "Results for " + query.original + " - Rust";
// Because searching is incremental by character, only the most
// recent search query is added to the browser history.
if (browserSupportsHistoryApi()) {
const newURL = buildUrl(query.original, filterCrates);
if (!history.state && !params.search) {
history.pushState(null, "", newURL);
} else {
history.replaceState(null, "", newURL);
}
}
showResults(
execQuery(query, searchWords, filterCrates, window.currentCrate),
params.go_to_first,
filterCrates);
}
/**
* Convert a list of RawFunctionType / ID to object-based FunctionType.
*
* Crates often have lots of functions in them, and it's common to have a large number of
* functions that operate on a small set of data types, so the search index compresses them
* by encoding function parameter and return types as indexes into an array of names.
*
* Even when a general-purpose compression algorithm is used, this is still a win. I checked.
* https://github.com/rust-lang/rust/pull/98475#issue-1284395985
*
* The format for individual function types is encoded in
* librustdoc/html/render/mod.rs: impl Serialize for RenderType
*
* @param {null|Array<RawFunctionType>} types
* @param {Array<{name: string, ty: number}>} lowercasePaths
*
* @return {Array<FunctionSearchType>}
*/
function buildItemSearchTypeAll(types, lowercasePaths) {
const PATH_INDEX_DATA = 0;
const GENERICS_DATA = 1;
return types.map(type => {
let pathIndex, generics;
if (typeof type === "number") {
pathIndex = type;
generics = [];
} else {
pathIndex = type[PATH_INDEX_DATA];
generics = buildItemSearchTypeAll(type[GENERICS_DATA], lowercasePaths);
}
return {
// `0` is used as a sentinel because it's fewer bytes than `null`
name: pathIndex === 0 ? null : lowercasePaths[pathIndex - 1].name,
ty: pathIndex === 0 ? null : lowercasePaths[pathIndex - 1].ty,
generics: generics,
};
});
}
/**
* Convert from RawFunctionSearchType to FunctionSearchType.
*
* Crates often have lots of functions in them, and function signatures are sometimes complex,
* so rustdoc uses a pretty tight encoding for them. This function converts it to a simpler,
* object-based encoding so that the actual search code is more readable and easier to debug.
*
* The raw function search type format is generated using serde in
* librustdoc/html/render/mod.rs: impl Serialize for IndexItemFunctionType
*
* @param {RawFunctionSearchType} functionSearchType
* @param {Array<{name: string, ty: number}>} lowercasePaths
*
* @return {null|FunctionSearchType}
*/
function buildFunctionSearchType(functionSearchType, lowercasePaths) {
const INPUTS_DATA = 0;
const OUTPUT_DATA = 1;
// `0` is used as a sentinel because it's fewer bytes than `null`
if (functionSearchType === 0) {
return null;
}
let inputs, output;
if (typeof functionSearchType[INPUTS_DATA] === "number") {
const pathIndex = functionSearchType[INPUTS_DATA];
inputs = [{
name: pathIndex === 0 ? null : lowercasePaths[pathIndex - 1].name,
ty: pathIndex === 0 ? null : lowercasePaths[pathIndex - 1].ty,
generics: [],
}];
} else {
inputs = buildItemSearchTypeAll(functionSearchType[INPUTS_DATA], lowercasePaths);
}
if (functionSearchType.length > 1) {
if (typeof functionSearchType[OUTPUT_DATA] === "number") {
const pathIndex = functionSearchType[OUTPUT_DATA];
output = [{
name: pathIndex === 0 ? null : lowercasePaths[pathIndex - 1].name,
ty: pathIndex === 0 ? null : lowercasePaths[pathIndex - 1].ty,
generics: [],
}];
} else {
output = buildItemSearchTypeAll(functionSearchType[OUTPUT_DATA], lowercasePaths);
}
} else {
output = [];
}
return {
inputs, output,
};
}
function buildIndex(rawSearchIndex) {
searchIndex = [];
/**
* @type {Array<string>}
*/
const searchWords = [];
let i, word;
let currentIndex = 0;
let id = 0;
for (const crate in rawSearchIndex) {
if (!hasOwnPropertyRustdoc(rawSearchIndex, crate)) {
continue;
}
let crateSize = 0;
/**
* The raw search data for a given crate. `n`, `t`, `d`, and `q`, `i`, and `f`
* are arrays with the same length. n[i] contains the name of an item.
* t[i] contains the type of that item (as a small integer that represents an
* offset in `itemTypes`). d[i] contains the description of that item.
*
* q[i] contains the full path of the item, or an empty string indicating
* "same as q[i-1]".
*
* i[i] contains an item's parent, usually a module. For compactness,
* it is a set of indexes into the `p` array.
*
* f[i] contains function signatures, or `0` if the item isn't a function.
* Functions are themselves encoded as arrays. The first item is a list of
* types representing the function's inputs, and the second list item is a list
* of types representing the function's output. Tuples are flattened.
* Types are also represented as arrays; the first item is an index into the `p`
* array, while the second is a list of types representing any generic parameters.
*
* `a` defines aliases with an Array of pairs: [name, offset], where `offset`
* points into the n/t/d/q/i/f arrays.
*
* `doc` contains the description of the crate.
*
* `p` is a list of path/type pairs. It is used for parents and function parameters.
*
* @type {{
* doc: string,
* a: Object,
* n: Array<string>,
* t: Array<Number>,
* d: Array<string>,
* q: Array<string>,
* i: Array<Number>,
* f: Array<RawFunctionSearchType>,
* p: Array<Object>,
* }}
*/
const crateCorpus = rawSearchIndex[crate];
searchWords.push(crate);
// This object should have exactly the same set of fields as the "row"
// object defined below. Your JavaScript runtime will thank you.
// https://mathiasbynens.be/notes/shapes-ics
const crateRow = {
crate: crate,
ty: 1, // == ExternCrate
name: crate,
path: "",
desc: crateCorpus.doc,
parent: undefined,
type: null,
id: id,
normalizedName: crate.indexOf("_") === -1 ? crate : crate.replace(/_/g, ""),
};
id += 1;
searchIndex.push(crateRow);
currentIndex += 1;
// an array of (Number) item types
const itemTypes = crateCorpus.t;
// an array of (String) item names
const itemNames = crateCorpus.n;
// an array of (String) full paths (or empty string for previous path)
const itemPaths = crateCorpus.q;
// an array of (String) descriptions
const itemDescs = crateCorpus.d;
// an array of (Number) the parent path index + 1 to `paths`, or 0 if none
const itemParentIdxs = crateCorpus.i;
// an array of (Object | null) the type of the function, if any
const itemFunctionSearchTypes = crateCorpus.f;
// an array of [(Number) item type,
// (String) name]
const paths = crateCorpus.p;
// an array of [(String) alias name
// [Number] index to items]
const aliases = crateCorpus.a;
// an array of [{name: String, ty: Number}]
const lowercasePaths = [];
// convert `rawPaths` entries into object form
// generate normalizedPaths for function search mode
let len = paths.length;
for (i = 0; i < len; ++i) {
lowercasePaths.push({ty: paths[i][0], name: paths[i][1].toLowerCase()});
paths[i] = {ty: paths[i][0], name: paths[i][1]};
}
// convert `item*` into an object form, and construct word indices.
//
// before any analysis is performed lets gather the search terms to
// search against apart from the rest of the data. This is a quick
// operation that is cached for the life of the page state so that
// all other search operations have access to this cached data for
// faster analysis operations
len = itemTypes.length;
let lastPath = "";
for (i = 0; i < len; ++i) {
// This object should have exactly the same set of fields as the "crateRow"
// object defined above.
if (typeof itemNames[i] === "string") {
word = itemNames[i].toLowerCase();
searchWords.push(word);
} else {
word = "";
searchWords.push("");
}
const row = {
crate: crate,
ty: itemTypes[i],
name: itemNames[i],
path: itemPaths[i] ? itemPaths[i] : lastPath,
desc: itemDescs[i],
parent: itemParentIdxs[i] > 0 ? paths[itemParentIdxs[i] - 1] : undefined,
type: buildFunctionSearchType(itemFunctionSearchTypes[i], lowercasePaths),
id: id,
normalizedName: word.indexOf("_") === -1 ? word : word.replace(/_/g, ""),
};
id += 1;
searchIndex.push(row);
lastPath = row.path;
crateSize += 1;
}
if (aliases) {
ALIASES[crate] = Object.create(null);
for (const alias_name in aliases) {
if (!hasOwnPropertyRustdoc(aliases, alias_name)) {
continue;
}
if (!hasOwnPropertyRustdoc(ALIASES[crate], alias_name)) {
ALIASES[crate][alias_name] = [];
}
for (const local_alias of aliases[alias_name]) {
ALIASES[crate][alias_name].push(local_alias + currentIndex);
}
}
}
currentIndex += crateSize;
}
return searchWords;
}
/**
* Callback for when the search form is submitted.
* @param {Event} [e] - The event that triggered this call, if any
*/
function onSearchSubmit(e) {
e.preventDefault();
searchState.clearInputTimeout();
search();
}
function putBackSearch() {
const search_input = searchState.input;
if (!searchState.input) {
return;
}
if (search_input.value !== "" && !searchState.isDisplayed()) {
searchState.showResults();
if (browserSupportsHistoryApi()) {
history.replaceState(null, "",
buildUrl(search_input.value, getFilterCrates()));
}
document.title = searchState.title;
}
}
function registerSearchEvents() {
const params = searchState.getQueryStringParams();
// Populate search bar with query string search term when provided,
// but only if the input bar is empty. This avoid the obnoxious issue
// where you start trying to do a search, and the index loads, and
// suddenly your search is gone!
if (searchState.input.value === "") {
searchState.input.value = params.search || "";
}
const searchAfter500ms = () => {
searchState.clearInputTimeout();
if (searchState.input.value.length === 0) {
if (browserSupportsHistoryApi()) {
history.replaceState(null, window.currentCrate + " - Rust",
getNakedUrl() + window.location.hash);
}
searchState.hideResults();
} else {
searchState.timeout = setTimeout(search, 500);
}
};
searchState.input.onkeyup = searchAfter500ms;
searchState.input.oninput = searchAfter500ms;
document.getElementsByClassName("search-form")[0].onsubmit = onSearchSubmit;
searchState.input.onchange = e => {
if (e.target !== document.activeElement) {
// To prevent doing anything when it's from a blur event.
return;
}
// Do NOT e.preventDefault() here. It will prevent pasting.
searchState.clearInputTimeout();
// zero-timeout necessary here because at the time of event handler execution the
// pasted content is not in the input field yet. Shouldnt make any difference for
// change, though.
setTimeout(search, 0);
};
searchState.input.onpaste = searchState.input.onchange;
searchState.outputElement().addEventListener("keydown", e => {
// We only handle unmodified keystrokes here. We don't want to interfere with,
// for instance, alt-left and alt-right for history navigation.
if (e.altKey || e.ctrlKey || e.shiftKey || e.metaKey) {
return;
}
// up and down arrow select next/previous search result, or the
// search box if we're already at the top.
if (e.which === 38) { // up
const previous = document.activeElement.previousElementSibling;
if (previous) {
previous.focus();
} else {
searchState.focus();
}
e.preventDefault();
} else if (e.which === 40) { // down
const next = document.activeElement.nextElementSibling;
if (next) {
next.focus();
}
const rect = document.activeElement.getBoundingClientRect();
if (window.innerHeight - rect.bottom < rect.height) {
window.scrollBy(0, rect.height);
}
e.preventDefault();
} else if (e.which === 37) { // left
nextTab(-1);
e.preventDefault();
} else if (e.which === 39) { // right
nextTab(1);
e.preventDefault();
}
});
searchState.input.addEventListener("keydown", e => {
if (e.which === 40) { // down
focusSearchResult();
e.preventDefault();
}
});
searchState.input.addEventListener("focus", () => {
putBackSearch();
});
searchState.input.addEventListener("blur", () => {
searchState.input.placeholder = searchState.input.origPlaceholder;
});
// Push and pop states are used to add search results to the browser
// history.
if (browserSupportsHistoryApi()) {
// Store the previous <title> so we can revert back to it later.
const previousTitle = document.title;
window.addEventListener("popstate", e => {
const params = searchState.getQueryStringParams();
// Revert to the previous title manually since the History
// API ignores the title parameter.
document.title = previousTitle;
// When browsing forward to search results the previous
// search will be repeated, so the currentResults are
// cleared to ensure the search is successful.
currentResults = null;
// Synchronize search bar with query string state and
// perform the search. This will empty the bar if there's
// nothing there, which lets you really go back to a
// previous state with nothing in the bar.
if (params.search && params.search.length > 0) {
searchState.input.value = params.search;
// Some browsers fire "onpopstate" for every page load
// (Chrome), while others fire the event only when actually
// popping a state (Firefox), which is why search() is
// called both here and at the end of the startSearch()
// function.
search(e);
} else {
searchState.input.value = "";
// When browsing back from search results the main page
// visibility must be reset.
searchState.hideResults();
}
});
}
// This is required in firefox to avoid this problem: Navigating to a search result
// with the keyboard, hitting enter, and then hitting back would take you back to
// the doc page, rather than the search that should overlay it.
// This was an interaction between the back-forward cache and our handlers
// that try to sync state between the URL and the search input. To work around it,
// do a small amount of re-init on page show.
window.onpageshow = () => {
const qSearch = searchState.getQueryStringParams().search;
if (searchState.input.value === "" && qSearch) {
searchState.input.value = qSearch;
}
search();
};
}
function updateCrate(ev) {
if (ev.target.value === "all crates") {
// If we don't remove it from the URL, it'll be picked up again by the search.
const params = searchState.getQueryStringParams();
const query = searchState.input.value.trim();
if (!history.state && !params.search) {
history.pushState(null, "", buildUrl(query, null));
} else {
history.replaceState(null, "", buildUrl(query, null));
}
}
// In case you "cut" the entry from the search input, then change the crate filter
// before paste back the previous search, you get the old search results without
// the filter. To prevent this, we need to remove the previous results.
currentResults = null;
search(undefined, true);
}
/**
* @type {Array<string>}
*/
const searchWords = buildIndex(rawSearchIndex);
if (typeof window !== "undefined") {
registerSearchEvents();
// If there's a search term in the URL, execute the search now.
if (window.searchState.getQueryStringParams().search) {
search();
}
}
if (typeof exports !== "undefined") {
exports.initSearch = initSearch;
exports.execQuery = execQuery;
exports.parseQuery = parseQuery;
}
return searchWords;
}
if (typeof window !== "undefined") {
window.initSearch = initSearch;
if (window.searchIndex !== undefined) {
initSearch(window.searchIndex);
}
} else {
// Running in Node, not a browser. Run initSearch just to produce the
// exports.
initSearch({});
}
})();