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/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
/**
* This module exports a component used to sort results in a UrlbarQueryContext.
*/
import {
UrlbarMuxer,
UrlbarUtils,
} from "resource:///modules/UrlbarUtils.sys.mjs";
const lazy = {};
ChromeUtils.defineESModuleGetters(lazy, {
QuickSuggest: "resource:///modules/QuickSuggest.sys.mjs",
UrlbarPrefs: "resource:///modules/UrlbarPrefs.sys.mjs",
UrlbarProviderOpenTabs: "resource:///modules/UrlbarProviderOpenTabs.sys.mjs",
UrlbarProviderQuickSuggest:
"resource:///modules/UrlbarProviderQuickSuggest.sys.mjs",
UrlbarProviderTabToSearch:
"resource:///modules/UrlbarProviderTabToSearch.sys.mjs",
UrlbarSearchUtils: "resource:///modules/UrlbarSearchUtils.sys.mjs",
});
ChromeUtils.defineLazyGetter(lazy, "logger", () =>
UrlbarUtils.getLogger({ prefix: "MuxerUnifiedComplete" })
);
const MS_PER_DAY = 1000 * 60 * 60 * 24;
/**
* Constructs the map key by joining the url with the userContextId if
* 'browser.urlbar.switchTabs.searchAllContainers' is set to true.
* Otherwise, just the url is used.
*
* @param {UrlbarResult} result The result object.
* @returns {string} map key
*/
function makeMapKeyForTabResult(result) {
return UrlbarUtils.tupleString(
result.payload.url,
lazy.UrlbarPrefs.get("switchTabs.searchAllContainers") &&
result.type == UrlbarUtils.RESULT_TYPE.TAB_SWITCH &&
lazy.UrlbarProviderOpenTabs.isNonPrivateUserContextId(
result.payload.userContextId
)
? result.payload.userContextId
: undefined
);
}
/**
* Class used to create a muxer.
* The muxer receives and sorts results in a UrlbarQueryContext.
*/
class MuxerUnifiedComplete extends UrlbarMuxer {
constructor() {
super();
}
get name() {
return "UnifiedComplete";
}
/**
* Sorts results in the given UrlbarQueryContext.
*
* @param {UrlbarQueryContext} context
* The query context.
* @param {Array} unsortedResults
* The array of UrlbarResult that is not sorted yet.
*/
sort(context, unsortedResults) {
// This method is called multiple times per keystroke, so it should be as
// fast and efficient as possible. We do two passes through the results:
// one to collect state for the second pass, and then a second to build the
// sorted list of results. If you find yourself writing something like
// context.results.find(), filter(), sort(), etc., modify one or both passes
// instead.
// Global state we'll use to make decisions during this sort.
let state = {
context,
// RESULT_GROUP => array of results belonging to the group, excluding
// group-relative suggestedIndex results
resultsByGroup: new Map(),
// RESULT_GROUP => array of group-relative suggestedIndex results
// belonging to the group
suggestedIndexResultsByGroup: new Map(),
// This is analogous to `maxResults` except it's the total available
// result span instead of the total available result count. We'll add
// results until `usedResultSpan` would exceed `availableResultSpan`.
availableResultSpan: context.maxResults,
// The total result span taken up by all global (non-group-relative)
// suggestedIndex results.
globalSuggestedIndexResultSpan: 0,
// The total span of results that have been added so far.
usedResultSpan: 0,
strippedUrlToTopPrefixAndTitle: new Map(),
baseAndTitleToTopRef: new Map(),
urlToTabResultType: new Map(),
addedRemoteTabUrls: new Set(),
addedSwitchTabUrls: new Set(),
addedResultUrls: new Set(),
canShowPrivateSearch: unsortedResults.length > 1,
canShowTailSuggestions: true,
// Form history and remote suggestions added so far. Used for deduping
// suggestions. Also includes the heuristic query string if the heuristic
// is a search result. All strings in the set are lowercased.
suggestions: new Set(),
canAddTabToSearch: true,
hasUnitConversionResult: false,
maxHeuristicResultSpan: 0,
maxTabToSearchResultSpan: 0,
// When you add state, update _copyState() as necessary.
};
// Do the first pass over all results to build some state.
for (let result of unsortedResults) {
// Add each result to the appropriate `resultsByGroup` map.
let group = UrlbarUtils.getResultGroup(result);
let resultsByGroup =
result.hasSuggestedIndex && result.isSuggestedIndexRelativeToGroup
? state.suggestedIndexResultsByGroup
: state.resultsByGroup;
let results = resultsByGroup.get(group);
if (!results) {
results = [];
resultsByGroup.set(group, results);
}
results.push(result);
// Update pre-add state.
this._updateStatePreAdd(result, state);
}
// Now that the first pass is done, adjust the available result span. More
// than one tab-to-search result may be present but only one will be shown;
// add the max TTS span to the total span of global suggestedIndex results.
state.globalSuggestedIndexResultSpan += state.maxTabToSearchResultSpan;
// Leave room for global suggestedIndex results at the end of the sort, by
// subtracting their total span from the total available span. For very
// small values of `maxRichResults`, their total span may be larger than
// `state.availableResultSpan`.
let globalSuggestedIndexAvailableSpan = Math.min(
state.availableResultSpan,
state.globalSuggestedIndexResultSpan
);
state.availableResultSpan -= globalSuggestedIndexAvailableSpan;
if (state.maxHeuristicResultSpan) {
if (lazy.UrlbarPrefs.get("experimental.hideHeuristic")) {
// The heuristic is hidden. The muxer will include it but the view will
// hide it. Increase the available span to compensate so that the total
// visible span accurately reflects `context.maxResults`.
state.availableResultSpan += state.maxHeuristicResultSpan;
} else if (context.maxResults > 0) {
// `context.maxResults` is positive. Make sure there's room for the
// heuristic even if it means exceeding `context.maxResults`.
state.availableResultSpan = Math.max(
state.availableResultSpan,
state.maxHeuristicResultSpan
);
}
}
// Show Top Sites above trending results.
let showSearchSuggestionsFirst =
context.searchString ||
(!lazy.UrlbarPrefs.get("suggest.trending") &&
!lazy.UrlbarPrefs.get("suggest.recentsearches"));
// Determine the result groups to use for this sort. In search mode with
// an engine, show search suggestions first.
let rootGroup =
context.searchMode?.engineName || !showSearchSuggestionsFirst
? lazy.UrlbarPrefs.makeResultGroups({ showSearchSuggestionsFirst })
: lazy.UrlbarPrefs.resultGroups;
lazy.logger.debug("Root groups", rootGroup);
// Fill the root group.
let [sortedResults] = this._fillGroup(
rootGroup,
{ availableSpan: state.availableResultSpan, maxResultCount: Infinity },
state
);
// Add global suggestedIndex results.
let globalSuggestedIndexResults = state.resultsByGroup.get(
UrlbarUtils.RESULT_GROUP.SUGGESTED_INDEX
);
if (globalSuggestedIndexResults) {
this._addSuggestedIndexResults(
globalSuggestedIndexResults,
sortedResults,
{
availableSpan: globalSuggestedIndexAvailableSpan,
maxResultCount: Infinity,
},
state
);
}
context.results = sortedResults;
}
/**
* Returns a *deep* copy of state (except for `state.context`, which is
* shallow copied). i.e., any Maps, Sets, and arrays in the state should be
* recursively copied so that the original state is not modified when the copy
* is modified.
*
* @param {object} state
* The muxer state to copy.
* @returns {object}
* A deep copy of the state.
*/
_copyState(state) {
let copy = Object.assign({}, state, {
resultsByGroup: new Map(),
suggestedIndexResultsByGroup: new Map(),
strippedUrlToTopPrefixAndTitle: new Map(
state.strippedUrlToTopPrefixAndTitle
),
baseAndTitleToTopRef: new Map(state.baseAndTitleToTopRef),
urlToTabResultType: new Map(state.urlToTabResultType),
addedRemoteTabUrls: new Set(state.addedRemoteTabUrls),
addedSwitchTabUrls: new Set(state.addedSwitchTabUrls),
suggestions: new Set(state.suggestions),
addedResultUrls: new Set(state.addedResultUrls),
});
// Deep copy the `resultsByGroup` maps.
for (let key of ["resultsByGroup", "suggestedIndexResultsByGroup"]) {
for (let [group, results] of state[key]) {
copy[key].set(group, [...results]);
}
}
return copy;
}
/**
* Recursively fills a result group and its children.
*
* There are two ways to limit the number of results in a group:
*
* (1) By max total result span using the `availableSpan` property. The group
* will be filled so that the total span of its results does not exceed this
* value.
*
* (2) By max total result count using the `maxResultCount` property. The
* group will be filled so that the total number of its results does not
* exceed this value.
*
* Both `availableSpan` and `maxResultCount` may be defined, and the group's
* results will be capped to whichever limit is reached first. If either is
* not defined, then the group inherits that limit from its parent group.
*
* In addition to limiting their total number of results, groups can also
* control the composition of their child groups by using flex ratios. A group
* can define a `flexChildren: true` property, and in that case each of its
* children should have a `flex` property. Each child will be filled according
* to the ratio of its flex value and the sum of the flex values of all the
* children, similar to HTML flexbox. If some children do not fill up but
* others do, the filled-up children will be allowed to grow to use up the
* unfilled space.
*
* @param {object} group
* The result group to fill.
* @param {object} limits
* An object with optional `availableSpan` and `maxResultCount` properties
* as described above. They will be used as the limits for the group.
* @param {object} state
* The muxer state.
* @returns {Array}
* `[results, usedLimits, hasMoreResults]` -- see `_addResults`.
*/
_fillGroup(group, limits, state) {
// Get the group's suggestedIndex results. Reminder: `group.group` is a
// `RESULT_GROUP` constant.
let suggestedIndexResults;
let suggestedIndexAvailableSpan = 0;
let suggestedIndexAvailableCount = 0;
if ("group" in group) {
let results = state.suggestedIndexResultsByGroup.get(group.group);
if (results) {
// Subtract them from the group's limits so there will be room for them
// later. Discard results that can't be added.
let span = 0;
let resultCount = 0;
for (let result of results) {
if (this._canAddResult(result, state)) {
suggestedIndexResults ??= [];
suggestedIndexResults.push(result);
const spanSize = UrlbarUtils.getSpanForResult(result);
span += spanSize;
if (spanSize) {
resultCount++;
}
}
}
suggestedIndexAvailableSpan = Math.min(limits.availableSpan, span);
suggestedIndexAvailableCount = Math.min(
limits.maxResultCount,
resultCount
);
// Create a new `limits` object so we don't modify the caller's.
limits = { ...limits };
limits.availableSpan -= suggestedIndexAvailableSpan;
limits.maxResultCount -= suggestedIndexAvailableCount;
}
}
// Fill the group. If it has children, fill them recursively. Otherwise fill
// the group directly.
let [results, usedLimits, hasMoreResults] = group.children
? this._fillGroupChildren(group, limits, state)
: this._addResults(group.group, limits, state);
// Add the group's suggestedIndex results.
if (suggestedIndexResults) {
let suggestedIndexUsedLimits = this._addSuggestedIndexResults(
suggestedIndexResults,
results,
{
availableSpan: suggestedIndexAvailableSpan,
maxResultCount: suggestedIndexAvailableCount,
},
state
);
for (let [key, value] of Object.entries(suggestedIndexUsedLimits)) {
usedLimits[key] += value;
}
}
return [results, usedLimits, hasMoreResults];
}
/**
* Helper for `_fillGroup` that fills a group's children.
*
* @param {object} group
* The result group to fill. It's assumed to have a `children` property.
* @param {object} limits
* An object with optional `availableSpan` and `maxResultCount` properties
* as described in `_fillGroup`.
* @param {object} state
* The muxer state.
* @param {Array} flexDataArray
* See `_updateFlexData`.
* @returns {Array}
* `[results, usedLimits, hasMoreResults]` -- see `_addResults`.
*/
_fillGroupChildren(group, limits, state, flexDataArray = null) {
// If the group has flexed children, update the data we use during flex
// calculations.
//
// Handling flex is complicated so we discuss it briefly. We may do multiple
// passes for a group with flexed children in order to try to optimally fill
// them. If after one pass some children do not fill up but others do, we'll
// do another pass that tries to overfill the filled-up children while still
// respecting their flex ratios. We'll continue to do passes until all
// children stop filling up or we reach the parent's limits. The way we
// overfill children is by increasing their individual limits to make up for
// the unused space in their underfilled siblings. Before starting a new
// pass, we discard the results from the current pass so the new pass starts
// with a clean slate. That means we need to copy the global sort state
// (`state`) before modifying it in the current pass so we can use its
// original value in the next pass [1].
//
// [1] Instead of starting each pass with a clean slate in this way, we
// could accumulate results with each pass since we only ever add results to
// flexed children and never remove them. However, that would subvert muxer
// logic related to the global state (deduping, `_canAddResult`) since we
// generally assume the muxer adds results in the order they appear.
let stateCopy;
if (group.flexChildren) {
stateCopy = this._copyState(state);
flexDataArray = this._updateFlexData(group, limits, flexDataArray);
}
// Fill each child group, collecting all results in the `results` array.
let results = [];
let usedLimits = {};
for (let key of Object.keys(limits)) {
usedLimits[key] = 0;
}
let anyChildUnderfilled = false;
let anyChildHasMoreResults = false;
for (let i = 0; i < group.children.length; i++) {
let child = group.children[i];
let flexData = flexDataArray?.[i];
// Compute the child's limits.
let childLimits = {};
for (let key of Object.keys(limits)) {
childLimits[key] = flexData
? flexData.limits[key]
: Math.min(
typeof child[key] == "number" ? child[key] : Infinity,
limits[key] - usedLimits[key]
);
}
// Recurse and fill the child.
let [childResults, childUsedLimits, childHasMoreResults] =
this._fillGroup(child, childLimits, state);
results = results.concat(childResults);
for (let key of Object.keys(usedLimits)) {
usedLimits[key] += childUsedLimits[key];
}
anyChildHasMoreResults = anyChildHasMoreResults || childHasMoreResults;
if (flexData?.hasMoreResults) {
// The child is flexed and we possibly added more results to it.
flexData.usedLimits = childUsedLimits;
flexData.hasMoreResults = childHasMoreResults;
anyChildUnderfilled =
anyChildUnderfilled ||
(!childHasMoreResults &&
[...Object.entries(childLimits)].every(
([key, limit]) => flexData.usedLimits[key] < limit
));
}
}
// If the children are flexed and some underfilled but others still have
// more results, do another pass.
if (anyChildUnderfilled && anyChildHasMoreResults) {
[results, usedLimits, anyChildHasMoreResults] = this._fillGroupChildren(
group,
limits,
stateCopy,
flexDataArray
);
// Update `state` in place so that it's also updated in the caller.
for (let [key, value] of Object.entries(stateCopy)) {
state[key] = value;
}
}
return [results, usedLimits, anyChildHasMoreResults];
}
/**
* Updates flex-related state used while filling a group.
*
* @param {object} group
* The result group being filled.
* @param {object} limits
* An object defining the group's limits as described in `_fillGroup`.
* @param {Array} flexDataArray
* An array parallel to `group.children`. The object at index i corresponds
* to the child in `group.children` at index i. Each object maintains some
* flex-related state for its child and is updated during each pass in
* `_fillGroup` for `group`. When this method is called in the first pass,
* this argument should be null, and the method will create and return a new
* `flexDataArray` array that should be used in the remainder of the first
* pass and all subsequent passes.
* @returns {Array}
* A new `flexDataArray` when called in the first pass, and `flexDataArray`
* itself when called in subsequent passes.
*/
_updateFlexData(group, limits, flexDataArray) {
flexDataArray =
flexDataArray ||
group.children.map((child, index) => {
let data = {
// The index of the corresponding child in `group.children`.
index,
// The child's limits.
limits: {},
// The fractional parts of the child's unrounded limits; see below.
limitFractions: {},
// The used-up portions of the child's limits.
usedLimits: {},
// True if `state.resultsByGroup` has more results of the child's
// `RESULT_GROUP`. This is not related to the child's limits.
hasMoreResults: true,
// The child's flex value.
flex: typeof child.flex == "number" ? child.flex : 0,
};
for (let key of Object.keys(limits)) {
data.limits[key] = 0;
data.limitFractions[key] = 0;
data.usedLimits[key] = 0;
}
return data;
});
// The data objects for children with more results (i.e., that are still
// fillable).
let fillableDataArray = [];
// The sum of the flex values of children with more results.
let fillableFlexSum = 0;
for (let data of flexDataArray) {
if (data.hasMoreResults) {
fillableFlexSum += data.flex;
fillableDataArray.push(data);
}
}
// Update each limit.
for (let [key, limit] of Object.entries(limits)) {
// Calculate the group's limit only including children with more results.
let fillableLimit = limit;
for (let data of flexDataArray) {
if (!data.hasMoreResults) {
fillableLimit -= data.usedLimits[key];
}
}
// Allow for the possibility that some children may have gone over limit.
// `fillableLimit` will be negative in that case.
fillableLimit = Math.max(fillableLimit, 0);
// Next we'll compute the limits of children with more results. This value
// is the sum of those limits. It may differ from `fillableLimit` due to
// the fact that each individual child limit must be an integer.
let summedFillableLimit = 0;
// Compute the limits of children with more results. If there are also
// children that don't have more results, then these new limits will be
// larger than they were in the previous pass.
for (let data of fillableDataArray) {
let unroundedLimit = fillableLimit * (data.flex / fillableFlexSum);
// `limitFraction` is the fractional part of the unrounded ideal limit.
// e.g., for 5.234 it will be 0.234. We use this to minimize the
// mathematical error when tweaking limits below.
data.limitFractions[key] = unroundedLimit - Math.floor(unroundedLimit);
data.limits[key] = Math.round(unroundedLimit);
summedFillableLimit += data.limits[key];
}
// As mentioned above, the sum of the individual child limits may not
// equal the group's fillable limit. If the sum is smaller, the group will
// end up with too few results. If it's larger, the group will have the
// correct number of results (since we stop adding results once limits are
// reached) but it may end up with a composition that does not reflect the
// child flex ratios as accurately as possible.
//
// In either case, tweak the individual limits so that (1) their sum
// equals the group's fillable limit, and (2) the composition respects the
// flex ratios with as little mathematical error as possible.
if (summedFillableLimit != fillableLimit) {
// Collect the flex datas with a non-zero limit fractions. We'll round
// them up or down depending on whether the sum is larger or smaller
// than the group's fillable limit.
let fractionalDataArray = fillableDataArray.filter(
data => data.limitFractions[key]
);
let diff;
if (summedFillableLimit < fillableLimit) {
// The sum is smaller. We'll increment individual limits until the sum
// is equal, starting with the child whose limit fraction is closest
// to 1 in order to minimize error.
diff = 1;
fractionalDataArray.sort((a, b) => {
// Sort by fraction descending so larger fractions are first.
let cmp = b.limitFractions[key] - a.limitFractions[key];
// Secondarily sort by index ascending so that children with the
// same fraction are incremented in the order they appear, allowing
// earlier children to have larger spans.
return cmp || a.index - b.index;
});
} else if (fillableLimit < summedFillableLimit) {
// The sum is larger. We'll decrement individual limits until the sum
// is equal, starting with the child whose limit fraction is closest
// to 0 in order to minimize error.
diff = -1;
fractionalDataArray.sort((a, b) => {
// Sort by fraction ascending so smaller fractions are first.
let cmp = a.limitFractions[key] - b.limitFractions[key];
// Secondarily sort by index descending so that children with the
// same fraction are decremented in reverse order, allowing earlier
// children to retain larger spans.
return cmp || b.index - a.index;
});
}
// Now increment or decrement individual limits until their sum is equal
// to the group's fillable limit.
while (summedFillableLimit != fillableLimit) {
if (!fractionalDataArray.length) {
// This shouldn't happen, but don't let it break us.
lazy.logger.error("fractionalDataArray is empty!");
break;
}
let data = flexDataArray[fractionalDataArray.shift().index];
data.limits[key] += diff;
summedFillableLimit += diff;
}
}
}
return flexDataArray;
}
/**
* Adds results to a group using the results from its `RESULT_GROUP` in
* `state.resultsByGroup`.
*
* @param {UrlbarUtils.RESULT_GROUP} groupConst
* The group's `RESULT_GROUP`.
* @param {object} limits
* An object defining the group's limits as described in `_fillGroup`.
* @param {object} state
* Global state that we use to make decisions during this sort.
* @returns {Array}
* `[results, usedLimits, hasMoreResults]` where:
* results: A flat array of results in the group, empty if no results
* were added.
* usedLimits: An object defining the amount of each limit that the
* results use. For each possible limit property (see `_fillGroup`),
* there will be a corresponding property in this object. For example,
* if 3 results are added with a total span of 4, then this object will
* be: { maxResultCount: 3, availableSpan: 4 }
* hasMoreResults: True if `state.resultsByGroup` has more results of
* the same `RESULT_GROUP`. This is not related to the group's limits.
*/
_addResults(groupConst, limits, state) {
let usedLimits = {};
for (let key of Object.keys(limits)) {
usedLimits[key] = 0;
}
// For form history, maxHistoricalSearchSuggestions == 0 implies the user
// has opted out of form history completely, so we override the max result
// count here in that case. Other values of maxHistoricalSearchSuggestions
// are ignored and we use the flex defined on the form history group.
if (
groupConst == UrlbarUtils.RESULT_GROUP.FORM_HISTORY &&
!lazy.UrlbarPrefs.get("maxHistoricalSearchSuggestions")
) {
// Create a new `limits` object so we don't modify the caller's.
limits = { ...limits };
limits.maxResultCount = 0;
}
let addedResults = [];
let groupResults = state.resultsByGroup.get(groupConst);
while (
groupResults?.length &&
state.usedResultSpan < state.availableResultSpan &&
[...Object.entries(limits)].every(([k, limit]) => usedLimits[k] < limit)
) {
let result = groupResults[0];
if (this._canAddResult(result, state)) {
if (!this.#updateUsedLimits(result, limits, usedLimits, state)) {
// Adding the result would exceed the group's available span, so stop
// adding results to it. Skip the shift() below so the result can be
// added to later groups.
break;
}
addedResults.push(result);
}
// We either add or discard results in the order they appear in
// `groupResults`, so shift() them off. That way later groups with the
// same `RESULT_GROUP` won't include results that earlier groups have
// added or discarded.
groupResults.shift();
}
return [addedResults, usedLimits, !!groupResults?.length];
}
/**
* Returns whether a result can be added to its group given the current sort
* state.
*
* @param {UrlbarResult} result
* The result.
* @param {object} state
* Global state that we use to make decisions during this sort.
* @returns {boolean}
* True if the result can be added and false if it should be discarded.
*/
// error or increase the complexity threshold.
// eslint-disable-next-line complexity
_canAddResult(result, state) {
// Typically the first visible Suggest result is always added.
if (result.providerName == lazy.UrlbarProviderQuickSuggest.name) {
if (result.isHiddenExposure) {
// Always allow hidden exposure Suggest results.
return true;
}
if (state.quickSuggestResult && state.quickSuggestResult != result) {
// A Suggest result was already added.
return false;
}
// Don't add navigational suggestions that dupe the heuristic.
let heuristicUrl = state.context.heuristicResult?.payload.url;
if (
heuristicUrl &&
result.payload.telemetryType == "top_picks" &&
!lazy.UrlbarPrefs.get("experimental.hideHeuristic")
) {
let opts = {
stripHttp: true,
stripHttps: true,
stripWww: true,
trimSlash: true,
};
result.payload.dupedHeuristic =
UrlbarUtils.stripPrefixAndTrim(heuristicUrl, opts)[0] ==
UrlbarUtils.stripPrefixAndTrim(result.payload.url, opts)[0];
return !result.payload.dupedHeuristic;
}
return true;
}
// We expect UrlbarProviderPlaces sent us the highest-ranked www. and non-www
// origins, if any. Now, compare them to each other and to the heuristic
// result.
//
// 1. If the heuristic result is lower ranked than both, discard the www
// origin, unless it has a different page title than the non-www
// origin. This is a guard against deduping when www.site.com and
// site.com have different content.
// 2. If the heuristic result is higher than either the www origin or
// non-www origin:
// 2a. If the heuristic is a www origin, discard the non-www origin.
// 2b. If the heuristic is a non-www origin, discard the www origin.
if (
!result.heuristic &&
result.type == UrlbarUtils.RESULT_TYPE.URL &&
result.payload.url
) {
let [strippedUrl, prefix] = UrlbarUtils.stripPrefixAndTrim(
result.payload.url,
{
stripHttp: true,
stripHttps: true,
stripWww: true,
trimEmptyQuery: true,
}
);
let topPrefixData = state.strippedUrlToTopPrefixAndTitle.get(strippedUrl);
// If the condition below is not met, we are deduping a result against
// itself.
if (
topPrefixData &&
(prefix != topPrefixData.prefix ||
result.providerName != topPrefixData.providerName)
) {
let prefixRank = UrlbarUtils.getPrefixRank(prefix);
if (
(prefixRank < topPrefixData.rank &&
(prefix.endsWith("www.") == topPrefixData.prefix.endsWith("www.") ||
result.payload?.title == topPrefixData.title)) ||
(prefix == topPrefixData.prefix &&
result.providerName != topPrefixData.providerName)
) {
return false;
}
}
}
// Discard results that dupe autofill.
if (
state.context.heuristicResult &&
state.context.heuristicResult.autofill &&
!result.autofill &&
state.context.heuristicResult.payload?.url == result.payload.url &&
state.context.heuristicResult.type == result.type &&
!lazy.UrlbarPrefs.get("experimental.hideHeuristic")
) {
return false;
}
// HeuristicFallback may add non-heuristic results in some cases, but those
// should be retained only if the heuristic result comes from it.
if (
!result.heuristic &&
result.providerName == "HeuristicFallback" &&
state.context.heuristicResult?.providerName != "HeuristicFallback"
) {
return false;
}
if (result.providerName == lazy.UrlbarProviderTabToSearch.name) {
// Discard the result if a tab-to-search result was added already.
if (!state.canAddTabToSearch) {
return false;
}
// In cases where the heuristic result is not a URL and we have a
// tab-to-search result, the tab-to-search provider determined that the
// typed string is similar to an engine domain. We can let the
// tab-to-search result through.
if (state.context.heuristicResult?.type == UrlbarUtils.RESULT_TYPE.URL) {
// Discard the result if the heuristic result is not autofill and we are
// not making an exception for a fuzzy match.
if (
!state.context.heuristicResult.autofill &&
!result.payload.satisfiesAutofillThreshold
) {
return false;
}
let autofillHostname = new URL(
state.context.heuristicResult.payload.url
).hostname;
let [autofillDomain] = UrlbarUtils.stripPrefixAndTrim(
autofillHostname,
{
stripWww: true,
}
);
// Strip the public suffix because we want to allow matching "domain.it"
// with "domain.com".
autofillDomain = UrlbarUtils.stripPublicSuffixFromHost(autofillDomain);
if (!autofillDomain) {
return false;
}
// `searchUrlDomainWithoutSuffix` is the engine's domain with the public
// suffix already stripped, for example "www.mozilla.".
let [engineDomain] = UrlbarUtils.stripPrefixAndTrim(
result.payload.searchUrlDomainWithoutSuffix,
{
stripWww: true,
}
);
// Discard if the engine domain does not end with the autofilled one.
if (!engineDomain.endsWith(autofillDomain)) {
return false;
}
}
}
// Discard "Search in a Private Window" if appropriate.
if (
result.type == UrlbarUtils.RESULT_TYPE.SEARCH &&
result.payload.inPrivateWindow &&
!state.canShowPrivateSearch
) {
return false;
}
// Discard form history and remote suggestions that dupe previously added
// suggestions or the heuristic. We do not deduplicate rich suggestions so
// they do not visually disapear as the suggestion is completed and
// becomes the same url as the heuristic result.
if (
result.type == UrlbarUtils.RESULT_TYPE.SEARCH &&
result.payload.lowerCaseSuggestion &&
!result.isRichSuggestion
) {
let suggestion = result.payload.lowerCaseSuggestion.trim();
if (!suggestion || state.suggestions.has(suggestion)) {
return false;
}
}
// Discard tail suggestions if appropriate.
if (
result.type == UrlbarUtils.RESULT_TYPE.SEARCH &&
result.payload.tail &&
!result.isRichSuggestion &&
!state.canShowTailSuggestions
) {
return false;
}
// Discard remote tab results that dupes another remote tab or a
// switch-to-tab result.
if (result.type == UrlbarUtils.RESULT_TYPE.REMOTE_TAB) {
if (state.addedRemoteTabUrls.has(result.payload.url)) {
return false;
}
let maybeDupeType = state.urlToTabResultType.get(result.payload.url);
if (maybeDupeType == UrlbarUtils.RESULT_TYPE.TAB_SWITCH) {
return false;
}
}
// Discard switch-to-tab results that dupes another switch-to-tab result.
if (
result.type == UrlbarUtils.RESULT_TYPE.TAB_SWITCH &&
state.addedSwitchTabUrls.has(makeMapKeyForTabResult(result))
) {
return false;
}
// Discard history results that dupe either remote or switch-to-tab results.
if (
!result.heuristic &&
result.type == UrlbarUtils.RESULT_TYPE.URL &&
result.payload.url &&
state.urlToTabResultType.has(result.payload.url)
) {
return false;
}
// Discard SERPs from browser history that dupe either the heuristic or
// previously added suggestions.
if (
result.source == UrlbarUtils.RESULT_SOURCE.HISTORY &&
result.type == UrlbarUtils.RESULT_TYPE.URL
) {
let submission = Services.search.parseSubmissionURL(result.payload.url);
if (submission) {
let resultQuery = submission.terms.trim().toLocaleLowerCase();
if (state.suggestions.has(resultQuery)) {
// If the result's URL is the same as a brand new SERP URL created
// from the query string modulo certain URL params, then treat the
// result as a dupe and discard it.
let [newSerpURL] = UrlbarUtils.getSearchQueryUrl(
submission.engine,
submission.terms
);
if (
lazy.UrlbarSearchUtils.serpsAreEquivalent(
result.payload.url,
newSerpURL
)
) {
return false;
}
}
}
}
// When in an engine search mode, discard URL results whose hostnames don't
// include the root domain of the search mode engine.
if (state.context.searchMode?.engineName && result.payload.url) {
let engine = Services.search.getEngineByName(
state.context.searchMode.engineName
);
if (engine) {
let searchModeRootDomain =
lazy.UrlbarSearchUtils.getRootDomainFromEngine(engine);
let resultUrl = new URL(result.payload.url);
// Add a trailing "." to increase the stringency of the check. This
// check covers most general cases. Some edge cases are not covered,
// like `resultUrl` being ebay.mydomain.com, which would escape this
// check if `searchModeRootDomain` was "ebay".
if (!resultUrl.hostname.includes(`${searchModeRootDomain}.`)) {
return false;
}
}
}
// Discard history results that dupe the quick suggest result.
if (
state.quickSuggestResult &&
!result.heuristic &&
result.type == UrlbarUtils.RESULT_TYPE.URL &&
lazy.QuickSuggest.isURLEquivalentToResultURL(
result.payload.url,
state.quickSuggestResult
)
) {
return false;
}
// Discard history results whose URLs were originally sponsored. We use the
// presence of a partner's URL search param to detect these. The param is
// defined in the pref below, which is also used for the newtab page.
if (
result.source == UrlbarUtils.RESULT_SOURCE.HISTORY &&
result.type == UrlbarUtils.RESULT_TYPE.URL
) {
let param = Services.prefs.getCharPref(
"browser.newtabpage.activity-stream.hideTopSitesWithSearchParam"
);
if (param) {
let [key, value] = param.split("=");
let searchParams;
try {
({ searchParams } = new URL(result.payload.url));
} catch (error) {}
if (
(value === undefined && searchParams?.has(key)) ||
(value !== undefined && searchParams?.getAll(key).includes(value))
) {
return false;
}
}
}
// Heuristic results must always be the first result. If this result is a
// heuristic but we've already added results, discard it. Normally this
// should never happen because the standard result groups are set up so
// that there's always at most one heuristic and it's always first, but
// since result groups are stored in a pref and can therefore be modified
// by the user, we perform this check.
if (result.heuristic && state.usedResultSpan) {
return false;
}
// Google search engine might suggest a result for unit conversion with
// format that starts with "= ". If our UnitConversion can provide the
// result, we discard the suggestion of Google in order to deduplicate.
if (
result.type == UrlbarUtils.RESULT_TYPE.SEARCH &&
result.payload.engine == "Google" &&
result.payload.suggestion?.startsWith("= ") &&
state.hasUnitConversionResult
) {
return false;
}
// Discard results that have an embedded "url" param with the same value
// as another result's url
if (result.payload.url) {
let urlParams = result.payload.url.split("?").pop();
let embeddedUrl = new URLSearchParams(urlParams).get("url");
if (state.addedResultUrls.has(embeddedUrl)) {
return false;
}
}
// Dedupe history results with different ref.
if (
lazy.UrlbarPrefs.get("deduplication.enabled") &&
result.source == UrlbarUtils.RESULT_SOURCE.HISTORY &&
result.type == UrlbarUtils.RESULT_TYPE.URL &&
!result.heuristic &&
result.payload.lastVisit
) {
let { base, ref } = UrlbarUtils.extractRefFromUrl(result.payload.url);
let baseAndTitle = `${base} ${result.payload.title}`;
let topRef = state.baseAndTitleToTopRef.get(baseAndTitle);
let msSinceLastVisit = Date.now() - result.payload.lastVisit;
let daysSinceLastVisit = msSinceLastVisit / MS_PER_DAY;
let thresholdDays = lazy.UrlbarPrefs.get("deduplication.thresholdDays");
if (daysSinceLastVisit >= thresholdDays && ref != topRef) {
return false;
}
}
// Include the result.
return true;
}
/**
* Updates the global state that we use to make decisions during sort. This
* should be called for results before we've decided whether to add or discard
* them.
*
* @param {UrlbarResult} result
* The result.
* @param {object} state
* Global state that we use to make decisions during this sort.
*/
_updateStatePreAdd(result, state) {
// Check whether the result should trigger exposure telemetry. If it will
// not be visible because it's a hidden exposure, it should not affect the
// muxer's state, so bail now.
this.#setExposureTelemetryProperty(result);
if (result.isHiddenExposure) {
return;
}
// Keep track of the largest heuristic result span.
if (result.heuristic && this._canAddResult(result, state)) {
state.maxHeuristicResultSpan = Math.max(
state.maxHeuristicResultSpan,
UrlbarUtils.getSpanForResult(result)
);
}
// Keep track of the total span of global suggestedIndex results so we can
// make room for them at the end of the sort. Tab-to-search results are an
// exception: There can be multiple TTS results but only one will be shown,
// so we track the max TTS span separately.
if (
result.hasSuggestedIndex &&
!result.isSuggestedIndexRelativeToGroup &&
this._canAddResult(result, state)
) {
let span = UrlbarUtils.getSpanForResult(result);
if (result.providerName == lazy.UrlbarProviderTabToSearch.name) {
state.maxTabToSearchResultSpan = Math.max(
state.maxTabToSearchResultSpan,
span
);
} else {
state.globalSuggestedIndexResultSpan += span;
}
}
// Save some state we'll use later to dedupe URL results.
if (
(result.type == UrlbarUtils.RESULT_TYPE.URL ||
result.type == UrlbarUtils.RESULT_TYPE.KEYWORD) &&
result.payload.url &&
(!result.heuristic || !lazy.UrlbarPrefs.get("experimental.hideHeuristic"))
) {
let [strippedUrl, prefix] = UrlbarUtils.stripPrefixAndTrim(
result.payload.url,
{
stripHttp: true,
stripHttps: true,
stripWww: true,
trimEmptyQuery: true,
}
);
let prefixRank = UrlbarUtils.getPrefixRank(prefix);
let topPrefixData = state.strippedUrlToTopPrefixAndTitle.get(strippedUrl);
let topPrefixRank = topPrefixData ? topPrefixData.rank : -1;
if (
topPrefixRank < prefixRank ||
// If a quick suggest result has the same stripped URL and prefix rank
// as another result, store the quick suggest as the top rank so we
// discard the other during deduping. That happens after the user picks
// the quick suggest: The URL is added to history and later both a
// history result and the quick suggest may match a query.
(topPrefixRank == prefixRank &&
result.providerName == lazy.UrlbarProviderQuickSuggest.name)
) {
// strippedUrl => { prefix, title, rank, providerName }
state.strippedUrlToTopPrefixAndTitle.set(strippedUrl, {
prefix,
title: result.payload.title,
rank: prefixRank,
providerName: result.providerName,
});
}
}
// Save some state to dedupe results that only differ by the ref of their URL.
// Even though we are considering tab results and URL results of all sources
// here to find the top ref, we will only dedupe URL results with history source.
if (
result.type == UrlbarUtils.RESULT_TYPE.URL ||
result.type == UrlbarUtils.RESULT_TYPE.TAB_SWITCH
) {
let { base, ref } = UrlbarUtils.extractRefFromUrl(result.payload.url);
// This is unique because all spaces in base will be url-encoded
// so the part before the space is always the base url.
let baseAndTitle = `${base} ${result.payload.title}`;
// The first result should have the highest frecency so we set it as the top
// ref for its base url. If a result is heuristic, always override an existing
// top ref for its base url in case the heuristic provider was slow and a non
// heuristic result was added first for the same base url.
if (!state.baseAndTitleToTopRef.has(baseAndTitle) || result.heuristic) {
state.baseAndTitleToTopRef.set(baseAndTitle, ref);
}
}
// Save some state we'll use later to dedupe results from open/remote tabs.
if (
result.payload.url &&
(result.type == UrlbarUtils.RESULT_TYPE.TAB_SWITCH ||
(result.type == UrlbarUtils.RESULT_TYPE.REMOTE_TAB &&
!state.urlToTabResultType.has(makeMapKeyForTabResult(result))))
) {
// url => result type
state.urlToTabResultType.set(makeMapKeyForTabResult(result), result.type);
}
// If we find results other than the heuristic, "Search in Private
// Window," or tail suggestions, then we should hide tail suggestions
// since they're a last resort.
if (
state.canShowTailSuggestions &&
!result.heuristic &&
(result.type != UrlbarUtils.RESULT_TYPE.SEARCH ||
(!result.payload.inPrivateWindow && !result.payload.tail))
) {
state.canShowTailSuggestions = false;
}
if (result.providerName == lazy.UrlbarProviderQuickSuggest.name) {
state.quickSuggestResult ??= result;
}
state.hasUnitConversionResult =
state.hasUnitConversionResult || result.providerName == "UnitConversion";
// Keep track of result urls to dedupe results with the same url embedded
// in its query string
if (result.payload.url) {
state.addedResultUrls.add(result.payload.url);
}
}
/**
* Updates the global state that we use to make decisions during sort. This
* should be called for results after they've been added. It should not be
* called for discarded results.
*
* @param {UrlbarResult} result
* The result.
* @param {object} state
* Global state that we use to make decisions during this sort.
*/
_updateStatePostAdd(result, state) {
// bail early if the result will be hidden from the final view.
if (result.isHiddenExposure) {
return;
}
// Update heuristic state.
if (result.heuristic) {
state.context.heuristicResult = result;
if (
result.type == UrlbarUtils.RESULT_TYPE.SEARCH &&
result.payload.query &&
!lazy.UrlbarPrefs.get("experimental.hideHeuristic")
) {
let query = result.payload.query.trim().toLocaleLowerCase();
if (query) {
state.suggestions.add(query);
}
}
}
// The "Search in a Private Window" result should only be shown when there
// are other results and all of them are searches. It should not be shown
// if the user typed an alias because that's an explicit engine choice.
if (
!Services.search.separatePrivateDefaultUrlbarResultEnabled ||
(state.canShowPrivateSearch &&
(result.type != UrlbarUtils.RESULT_TYPE.SEARCH ||
result.payload.providesSearchMode ||
(result.heuristic && result.payload.keyword)))
) {
state.canShowPrivateSearch = false;
}
// Update suggestions.
if (
result.type == UrlbarUtils.RESULT_TYPE.SEARCH &&
result.payload.lowerCaseSuggestion
) {
let suggestion = result.payload.lowerCaseSuggestion.trim();
if (suggestion) {
state.suggestions.add(suggestion);
}
}
// Avoid multiple tab-to-search results.
if (result.providerName == lazy.UrlbarProviderTabToSearch.name) {
state.canAddTabToSearch = false;
}
// Sync will send us duplicate remote tabs if multiple copies of a tab are
// open on a synced client. Keep track of which remote tabs we've added to
// dedupe these.
if (result.type == UrlbarUtils.RESULT_TYPE.REMOTE_TAB) {
state.addedRemoteTabUrls.add(result.payload.url);
}
// Keep track of which switch tabs we've added to dedupe switch tabs.
if (result.type == UrlbarUtils.RESULT_TYPE.TAB_SWITCH) {
state.addedSwitchTabUrls.add(makeMapKeyForTabResult(result));
}
}
/**
* Inserts results with suggested indexes. This can be called for either
* global or group-relative suggestedIndex results. It should be called after
* `sortedResults` has been filled in.
*
* @param {Array} suggestedIndexResults
* Results with a `suggestedIndex` property.
* @param {Array} sortedResults
* The sorted results. For global suggestedIndex results, this should be the
* final list of all results before suggestedIndex results are inserted. For
* group-relative suggestedIndex results, this should be the final list of
* results in the group before group-relative suggestedIndex results are
* inserted.
* @param {object} limits
* An object defining span and count limits. See `_fillGroup()`.
* @param {object} state
* Global state that we use to make decisions during this sort.
* @returns {object}
* A `usedLimits` object that describes the total span and count of all the
* added results. See `_addResults`.
*/
_addSuggestedIndexResults(
suggestedIndexResults,
sortedResults,
limits,
state
) {
let usedLimits = {
availableSpan: 0,
maxResultCount: 0,
};
if (!suggestedIndexResults?.length) {
// This is just a slight optimization; no need to continue.
return usedLimits;
}
// Partition the results into positive- and negative-index arrays. Positive
// indexes are relative to the start of the list and negative indexes are
// relative to the end.
let positive = [];
let negative = [];
for (let result of suggestedIndexResults) {
let results = result.suggestedIndex < 0 ? negative : positive;
results.push(result);
}
// Sort the positive results ascending so that results at the end of the
// array don't end up offset by later insertions at the front.
positive.sort((a, b) => {
if (a.suggestedIndex !== b.suggestedIndex) {
return a.suggestedIndex - b.suggestedIndex;
}
if (a.providerName === b.providerName) {
return 0;
}
// If same suggestedIndex, change the displaying order along to following
// provider priority.
// TabToSearch > QuickSuggest > Other providers
if (a.providerName === lazy.UrlbarProviderTabToSearch.name) {
return 1;
}
if (b.providerName === lazy.UrlbarProviderTabToSearch.name) {
return -1;
}
if (a.providerName === lazy.UrlbarProviderQuickSuggest.name) {
return 1;
}
if (b.providerName === lazy.UrlbarProviderQuickSuggest.name) {
return -1;
}
return 0;
});
// Conversely, sort the negative results descending so that results at the
// front of the array don't end up offset by later insertions at the end.
negative.sort((a, b) => b.suggestedIndex - a.suggestedIndex);
// Insert the results. We start with the positive results because we have
// tests that assume they're inserted first. In practice it shouldn't matter
// because there's no good reason we would ever have a negative result come
// before a positive result in the same query. Even if we did, we have to
// insert one before the other, and there's no right or wrong order.
for (let results of [positive, negative]) {
let prevResult;
let prevIndex;
for (let result of results) {
if (this._canAddResult(result, state)) {
if (!this.#updateUsedLimits(result, limits, usedLimits, state)) {
return usedLimits;
}
let index;
if (
prevResult &&
prevResult.suggestedIndex == result.suggestedIndex
) {
index = prevIndex;
} else {
index =
result.suggestedIndex >= 0
? Math.min(result.suggestedIndex, sortedResults.length)
: Math.max(result.suggestedIndex + sortedResults.length + 1, 0);
}
prevResult = result;
prevIndex = index;
sortedResults.splice(index, 0, result);
}
}
}
return usedLimits;
}
/**
* Checks whether adding a result would exceed the given limits. If the limits
* would be exceeded, this returns false and does nothing else. If the limits
* would not be exceeded, the given used limits and state are updated to
* account for the result, true is returned, and the caller should then add
* the result to its list of sorted results.
*
* @param {UrlbarResult} result
* The result.
* @param {object} limits
* An object defining span and count limits. See `_fillGroup()`.
* @param {object} usedLimits
* An object with parallel properties to `limits` that describes how much of
* the limits have been used. See `_addResults()`.
* @param {object} state
* The muxer state.
* @returns {boolean}
* True if the limits were updated and the result can be added and false
* otherwise.
*/
#updateUsedLimits(result, limits, usedLimits, state) {
let span = UrlbarUtils.getSpanForResult(result);
let newUsedSpan = usedLimits.availableSpan + span;
if (limits.availableSpan < newUsedSpan) {
// Adding the result would exceed the available span.
return false;
}
usedLimits.availableSpan = newUsedSpan;
if (span) {
usedLimits.maxResultCount++;
}
state.usedResultSpan += span;
this._updateStatePostAdd(result, state);
return true;
}
/**
* Checks exposure eligibility and visibility for the given result.
* If the result passes the exposure check, we set `result.exposureTelemetry`
* to the appropriate `UrlbarUtils.EXPOSURE_TELEMETRY` value.
*
* @param {UrlbarResult} result
* The result.
*/
#setExposureTelemetryProperty(result) {
const exposureResults = lazy.UrlbarPrefs.get("exposureResults");
if (exposureResults.size) {
const telemetryType = UrlbarUtils.searchEngagementTelemetryType(result);
if (exposureResults.has(telemetryType)) {
result.exposureTelemetry = lazy.UrlbarPrefs.get("showExposureResults")
? UrlbarUtils.EXPOSURE_TELEMETRY.SHOWN
: UrlbarUtils.EXPOSURE_TELEMETRY.HIDDEN;
}
}
}
}
export var UrlbarMuxerUnifiedComplete = new MuxerUnifiedComplete();