| Index: chrome/browser/history/scored_history_match.cc
|
| ===================================================================
|
| --- chrome/browser/history/scored_history_match.cc (revision 0)
|
| +++ chrome/browser/history/scored_history_match.cc (revision 0)
|
| @@ -0,0 +1,472 @@
|
| +// Copyright (c) 2012 The Chromium Authors. All rights reserved.
|
| +// Use of this source code is governed by a BSD-style license that can be
|
| +// found in the LICENSE file.
|
| +
|
| +#include "chrome/browser/history/scored_history_match.h"
|
| +
|
| +#include <algorithm>
|
| +#include <functional>
|
| +#include <iterator>
|
| +#include <numeric>
|
| +#include <set>
|
| +
|
| +#include <math.h>
|
| +
|
| +#include "base/command_line.h"
|
| +#include "base/i18n/case_conversion.h"
|
| +#include "base/string_util.h"
|
| +#include "base/utf_string_conversions.h"
|
| +#include "chrome/browser/autocomplete/url_prefix.h"
|
| +#include "chrome/common/chrome_switches.h"
|
| +#include "content/public/browser/browser_thread.h"
|
| +
|
| +namespace history {
|
| +
|
| +// The maximum score any candidate result can achieve.
|
| +const int kMaxTotalScore = 1425;
|
| +
|
| +// Score ranges used to get a 'base' score for each of the scoring factors
|
| +// (such as recency of last visit, times visited, times the URL was typed,
|
| +// and the quality of the string match). There is a matching value range for
|
| +// each of these scores for each factor. Note that the top score is greater
|
| +// than |kMaxTotalScore|. The score for each candidate will be capped in the
|
| +// final calculation.
|
| +const int kScoreRank[] = { 1450, 1200, 900, 400 };
|
| +
|
| +// ScoredHistoryMatch ----------------------------------------------------------
|
| +
|
| +bool ScoredHistoryMatch::initialized = false;
|
| +bool ScoredHistoryMatch::use_new_scoring = false;
|
| +
|
| +ScoredHistoryMatch::ScoredHistoryMatch()
|
| + : raw_score(0),
|
| + can_inline(false) {
|
| + if (!initialized) {
|
| + const std::string switch_value = CommandLine::ForCurrentProcess()->
|
| + GetSwitchValueASCII(switches::kOmniboxHistoryQuickProviderNewScoring);
|
| + if (switch_value == switches::kOmniboxHistoryQuickProviderNewScoringEnabled)
|
| + use_new_scoring = true;
|
| + initialized = true;
|
| + }
|
| +}
|
| +
|
| +ScoredHistoryMatch::ScoredHistoryMatch(const URLRow& row,
|
| + const string16& lower_string,
|
| + const String16Vector& terms,
|
| + const RowWordStarts& word_starts,
|
| + const base::Time now)
|
| + : HistoryMatch(row, 0, false, false),
|
| + raw_score(0),
|
| + can_inline(false) {
|
| + if (!initialized) {
|
| + const std::string switch_value = CommandLine::ForCurrentProcess()->
|
| + GetSwitchValueASCII(switches::kOmniboxHistoryQuickProviderNewScoring);
|
| + if (switch_value == switches::kOmniboxHistoryQuickProviderNewScoringEnabled)
|
| + use_new_scoring = true;
|
| + initialized = true;
|
| + }
|
| +
|
| + GURL gurl = row.url();
|
| + if (!gurl.is_valid())
|
| + return;
|
| +
|
| + // Figure out where each search term appears in the URL and/or page title
|
| + // so that we can score as well as provide autocomplete highlighting.
|
| + string16 url = base::i18n::ToLower(UTF8ToUTF16(gurl.spec()));
|
| + string16 title = base::i18n::ToLower(row.title());
|
| + int term_num = 0;
|
| + for (String16Vector::const_iterator iter = terms.begin(); iter != terms.end();
|
| + ++iter, ++term_num) {
|
| + string16 term = *iter;
|
| + TermMatches url_term_matches = MatchTermInString(term, url, term_num);
|
| + TermMatches title_term_matches = MatchTermInString(term, title, term_num);
|
| + if (url_term_matches.empty() && title_term_matches.empty())
|
| + return; // A term was not found in either URL or title - reject.
|
| + url_matches.insert(url_matches.end(), url_term_matches.begin(),
|
| + url_term_matches.end());
|
| + title_matches.insert(title_matches.end(), title_term_matches.begin(),
|
| + title_term_matches.end());
|
| + }
|
| +
|
| + // Sort matches by offset and eliminate any which overlap.
|
| + // TODO(mpearson): Investigate whether this has any meaningful
|
| + // effect on scoring. (It's necessary at some point: removing
|
| + // overlaps and sorting is needed to decide what to highlight in the
|
| + // suggestion string. But this sort and de-overlap doesn't have to
|
| + // be done before scoring.)
|
| + url_matches = SortAndDeoverlapMatches(url_matches);
|
| + title_matches = SortAndDeoverlapMatches(title_matches);
|
| +
|
| + // We can inline autocomplete a result if:
|
| + // 1) there is only one search term
|
| + // 2) AND EITHER:
|
| + // 2a) the first match starts at the beginning of the candidate URL, OR
|
| + // 2b) the candidate URL starts with one of the standard URL prefixes with
|
| + // the URL match immediately following that prefix.
|
| + // 3) AND the search string does not end in whitespace (making it look to
|
| + // the IMUI as though there is a single search term when actually there
|
| + // is a second, empty term).
|
| + can_inline = !url_matches.empty() &&
|
| + terms.size() == 1 &&
|
| + (url_matches[0].offset == 0 ||
|
| + URLPrefix::IsURLPrefix(url.substr(0, url_matches[0].offset))) &&
|
| + !IsWhitespace(*(lower_string.rbegin()));
|
| + match_in_scheme = can_inline && url_matches[0].offset == 0;
|
| +
|
| + if (use_new_scoring) {
|
| + const float topicality_score = GetTopicalityScore(
|
| + terms.size(), url, url_matches, title_matches, word_starts);
|
| + const float recency_score = GetRecencyScore(
|
| + (now - row.last_visit()).InDays());
|
| + const float popularity_score = GetPopularityScore(
|
| + row.typed_count(), row.visit_count());
|
| +
|
| + // Combine recency, popularity, and topicality scores into one.
|
| + // Example of how this functions: Suppose the omnibox has one
|
| + // input term. Suppose we have a URL that has 4 typed visits with
|
| + // the most recent being within a day and the omnibox input term
|
| + // has a single URL hostname hit at a word boundary. Then this
|
| + // URL will score 1400 ( = 4 * 350), which is exactly the value of
|
| + // search what you type. That is, it's the boundary of what might
|
| + // end up being inlined.
|
| + raw_score = 350 * topicality_score * recency_score * popularity_score;
|
| + raw_score =
|
| + (raw_score <= kint32max) ? static_cast<int>(raw_score) : kint32max;
|
| + } else { // "old" scoring
|
| + // Get partial scores based on term matching. Note that the score for
|
| + // each of the URL and title are adjusted by the fraction of the
|
| + // terms appearing in each.
|
| + int url_score = ScoreComponentForMatches(url_matches, url.length()) *
|
| + std::min(url_matches.size(), terms.size()) / terms.size();
|
| + int title_score =
|
| + ScoreComponentForMatches(title_matches, title.length()) *
|
| + std::min(title_matches.size(), terms.size()) / terms.size();
|
| + // Arbitrarily pick the best.
|
| + // TODO(mrossetti): It might make sense that a term which appears in both
|
| + // the URL and the Title should boost the score a bit.
|
| + int term_score = std::max(url_score, title_score);
|
| + if (term_score == 0)
|
| + return;
|
| +
|
| + // Determine scoring factors for the recency of visit, visit count and typed
|
| + // count attributes of the URLRow.
|
| + const int kDaysAgoLevel[] = { 1, 10, 20, 30 };
|
| + int days_ago_value = ScoreForValue((base::Time::Now() -
|
| + row.last_visit()).InDays(), kDaysAgoLevel);
|
| + const int kVisitCountLevel[] = { 50, 30, 10, 5 };
|
| + int visit_count_value = ScoreForValue(row.visit_count(), kVisitCountLevel);
|
| + const int kTypedCountLevel[] = { 50, 30, 10, 5 };
|
| + int typed_count_value = ScoreForValue(row.typed_count(), kTypedCountLevel);
|
| +
|
| + // The final raw score is calculated by:
|
| + // - multiplying each factor by a 'relevance'
|
| + // - calculating the average.
|
| + // Note that visit_count is reduced by typed_count because both are bumped
|
| + // when a typed URL is recorded thus giving visit_count too much weight.
|
| + const int kTermScoreRelevance = 4;
|
| + const int kDaysAgoRelevance = 2;
|
| + const int kVisitCountRelevance = 2;
|
| + const int kTypedCountRelevance = 5;
|
| + int effective_visit_count_value =
|
| + std::max(0, visit_count_value - typed_count_value);
|
| + raw_score = term_score * kTermScoreRelevance +
|
| + days_ago_value * kDaysAgoRelevance +
|
| + effective_visit_count_value * kVisitCountRelevance +
|
| + typed_count_value * kTypedCountRelevance;
|
| + raw_score /= (kTermScoreRelevance + kDaysAgoRelevance +
|
| + kVisitCountRelevance + kTypedCountRelevance);
|
| + raw_score = std::min(kMaxTotalScore, raw_score);
|
| + }
|
| +}
|
| +
|
| +ScoredHistoryMatch::~ScoredHistoryMatch() {}
|
| +
|
| +// std::accumulate helper function to add up TermMatches' lengths as used in
|
| +// ScoreComponentForMatches
|
| +int AccumulateMatchLength(int total, const TermMatch& match) {
|
| + return total + match.length;
|
| +}
|
| +
|
| +// static
|
| +int ScoredHistoryMatch::ScoreComponentForMatches(const TermMatches& matches,
|
| + size_t max_length) {
|
| + if (matches.empty())
|
| + return 0;
|
| +
|
| + // Score component for whether the input terms (if more than one) were found
|
| + // in the same order in the match. Start with kOrderMaxValue points divided
|
| + // equally among (number of terms - 1); then discount each of those terms that
|
| + // is out-of-order in the match.
|
| + const int kOrderMaxValue = 1000;
|
| + int order_value = kOrderMaxValue;
|
| + if (matches.size() > 1) {
|
| + int max_possible_out_of_order = matches.size() - 1;
|
| + int out_of_order = 0;
|
| + for (size_t i = 1; i < matches.size(); ++i) {
|
| + if (matches[i - 1].term_num > matches[i].term_num)
|
| + ++out_of_order;
|
| + }
|
| + order_value = (max_possible_out_of_order - out_of_order) * kOrderMaxValue /
|
| + max_possible_out_of_order;
|
| + }
|
| +
|
| + // Score component for how early in the match string the first search term
|
| + // appears. Start with kStartMaxValue points and discount by
|
| + // kStartMaxValue/kMaxSignificantChars points for each character later than
|
| + // the first at which the term begins. No points are earned if the start of
|
| + // the match occurs at or after kMaxSignificantChars.
|
| + const int kStartMaxValue = 1000;
|
| + int start_value = (kMaxSignificantChars -
|
| + std::min(kMaxSignificantChars, matches[0].offset)) * kStartMaxValue /
|
| + kMaxSignificantChars;
|
| +
|
| + // Score component for how much of the matched string the input terms cover.
|
| + // kCompleteMaxValue points times the fraction of the URL/page title string
|
| + // that was matched.
|
| + size_t term_length_total = std::accumulate(matches.begin(), matches.end(),
|
| + 0, AccumulateMatchLength);
|
| + const size_t kMaxSignificantLength = 50;
|
| + size_t max_significant_length =
|
| + std::min(max_length, std::max(term_length_total, kMaxSignificantLength));
|
| + const int kCompleteMaxValue = 1000;
|
| + int complete_value =
|
| + term_length_total * kCompleteMaxValue / max_significant_length;
|
| +
|
| + const int kOrderRelevance = 1;
|
| + const int kStartRelevance = 6;
|
| + const int kCompleteRelevance = 3;
|
| + int raw_score = order_value * kOrderRelevance +
|
| + start_value * kStartRelevance +
|
| + complete_value * kCompleteRelevance;
|
| + raw_score /= (kOrderRelevance + kStartRelevance + kCompleteRelevance);
|
| +
|
| + // Scale the raw score into a single score component in the same manner as
|
| + // used in ScoredMatchForURL().
|
| + const int kTermScoreLevel[] = { 1000, 750, 500, 200 };
|
| + return ScoreForValue(raw_score, kTermScoreLevel);
|
| +}
|
| +
|
| +// static
|
| +int ScoredHistoryMatch::ScoreForValue(int value, const int* value_ranks) {
|
| + int i = 0;
|
| + int rank_count = arraysize(kScoreRank);
|
| + while ((i < rank_count) && ((value_ranks[0] < value_ranks[1]) ?
|
| + (value > value_ranks[i]) : (value < value_ranks[i])))
|
| + ++i;
|
| + if (i >= rank_count)
|
| + return 0;
|
| + int score = kScoreRank[i];
|
| + if (i > 0) {
|
| + score += (value - value_ranks[i]) *
|
| + (kScoreRank[i - 1] - kScoreRank[i]) /
|
| + (value_ranks[i - 1] - value_ranks[i]);
|
| + }
|
| + return score;
|
| +}
|
| +
|
| +// Comparison function for sorting ScoredMatches by their scores.
|
| +bool ScoredHistoryMatch::MatchScoreGreater(const ScoredHistoryMatch& m1,
|
| + const ScoredHistoryMatch& m2) {
|
| + return m1.raw_score > m2.raw_score;
|
| +}
|
| +
|
| +// static
|
| +float ScoredHistoryMatch::GetTopicalityScore(
|
| + const int num_terms,
|
| + const string16& url,
|
| + const TermMatches& url_matches,
|
| + const TermMatches& title_matches,
|
| + const RowWordStarts& word_starts) {
|
| + // Because the below thread is not thread safe, we check that we're
|
| + // only calling it from one thread: the UI thread. Specifically,
|
| + // we check "if we've heard of the UI thread then we'd better
|
| + // be on it." The first part is necessary so unit tests pass. (Many
|
| + // unit tests don't set up the threading naming system; hence
|
| + // CurrentlyOn(UI thread) will fail.)
|
| + DCHECK(
|
| + !content::BrowserThread::IsWellKnownThread(content::BrowserThread::UI) ||
|
| + content::BrowserThread::CurrentlyOn(content::BrowserThread::UI));
|
| + if (raw_term_score_to_topicality_score == NULL) {
|
| + raw_term_score_to_topicality_score = new float[kMaxRawTermScore];
|
| + FillInTermScoreToTopicalityScoreArray();
|
| + }
|
| + // A vector that accumulates per-term scores. The strongest match--a
|
| + // match in the hostname at a word boundary--is worth 10 points.
|
| + // Everything else is less. In general, a match that's not at a word
|
| + // boundary is worth about 1/4th or 1/5th of a match at the word boundary
|
| + // in the same part of the URL/title.
|
| + std::vector<int> term_scores(num_terms, 0);
|
| + std::vector<size_t>::const_iterator next_word_starts =
|
| + word_starts.url_word_starts_.begin();
|
| + std::vector<size_t>::const_iterator end_word_starts =
|
| + word_starts.url_word_starts_.end();
|
| + const size_t question_mark_pos = url.find('?');
|
| + const size_t colon_pos = url.find(':');
|
| + // The + 3 skips the // that probably appears in the protocol
|
| + // after the colon. If the protocol doesn't have two slashes after
|
| + // the colon, that's okay--all this ends up doing is starting our
|
| + // search for the next / a few characters into the hostname. The
|
| + // only times this can cause problems is if we have a protocol without
|
| + // a // after the colon and the hostname is only one or two characters.
|
| + // This isn't worth worrying about.
|
| + const size_t end_of_hostname_pos = (colon_pos != std::string::npos) ?
|
| + url.find('/', colon_pos + 3) : url.find('/');
|
| + // Loop through all URL matches and score them appropriately.
|
| + for (TermMatches::const_iterator iter = url_matches.begin();
|
| + iter != url_matches.end(); ++iter) {
|
| + // Advance next_word_starts until it's >= the position of the term
|
| + // we're considering.
|
| + while ((next_word_starts != end_word_starts) &&
|
| + (*next_word_starts < iter->offset)) {
|
| + ++next_word_starts;
|
| + }
|
| + const bool at_word_boundary = (next_word_starts != end_word_starts) &&
|
| + (*next_word_starts == iter->offset);
|
| + if ((question_mark_pos != std::string::npos) &&
|
| + (iter->offset > question_mark_pos)) {
|
| + // match in CGI ?... fragment
|
| + term_scores[iter->term_num] += at_word_boundary ? 5 : 0;
|
| + } else if ((end_of_hostname_pos != std::string::npos) &&
|
| + (iter->offset > end_of_hostname_pos)) {
|
| + // match in path
|
| + term_scores[iter->term_num] += at_word_boundary ? 8 : 1;
|
| + } else if ((colon_pos == std::string::npos) ||
|
| + (iter->offset > colon_pos)) {
|
| + // match in hostname
|
| + term_scores[iter->term_num] += at_word_boundary ? 10 : 2;
|
| + } // else: match in protocol. Do not count this match for scoring.
|
| + }
|
| + // Now do the analogous loop over all matches in the title.
|
| + next_word_starts = word_starts.title_word_starts_.begin();
|
| + end_word_starts = word_starts.title_word_starts_.end();
|
| + int word_num = 0;
|
| + for (TermMatches::const_iterator iter = title_matches.begin();
|
| + iter != title_matches.end(); ++iter) {
|
| + // Advance next_word_starts until it's >= the position of the term
|
| + // we're considering.
|
| + while ((next_word_starts != end_word_starts) &&
|
| + (*next_word_starts < iter->offset)) {
|
| + ++next_word_starts;
|
| + ++word_num;
|
| + }
|
| + if (word_num >= 10) break; // only count the first ten words
|
| + const bool at_word_boundary = (next_word_starts != end_word_starts) &&
|
| + (*next_word_starts == iter->offset);
|
| + term_scores[iter->term_num] += at_word_boundary ? 8 : 2;
|
| + }
|
| + // TODO(mpearson): Restore logic for penalizing out-of-order matches.
|
| + // (Perhaps discount them by 0.8?)
|
| + // TODO(mpearson): Consider: if the earliest match occurs late in the string,
|
| + // should we discount it?
|
| + // TODO(mpearson): Consider: do we want to score based on how much of the
|
| + // input string the input covers? (I'm leaning toward no.)
|
| +
|
| + // Compute the topicality_score as the sum of transformed term_scores.
|
| + float topicality_score = 0;
|
| + for (size_t i = 0; i < term_scores.size(); ++i) {
|
| + topicality_score += raw_term_score_to_topicality_score[
|
| + (term_scores[i] >= kMaxRawTermScore)? kMaxRawTermScore - 1:
|
| + term_scores[i]];
|
| + }
|
| + // TODO(mpearson): If there are multiple terms, consider taking the
|
| + // geometric mean of per-term scores rather than sum as we're doing now
|
| + // (which is equivalent to the arthimatic mean).
|
| +
|
| + return topicality_score;
|
| +}
|
| +
|
| +// static
|
| +float* ScoredHistoryMatch::raw_term_score_to_topicality_score = NULL;
|
| +
|
| +// static
|
| +void ScoredHistoryMatch::FillInTermScoreToTopicalityScoreArray() {
|
| + for (int term_score = 0; term_score < kMaxRawTermScore; ++term_score) {
|
| + float topicality_score;
|
| + if (term_score < 10) {
|
| + // If the term scores less than 10 points (no full-credit hit, or
|
| + // no combination of hits that score that well), then the topicality
|
| + // score is linear in the term score.
|
| + topicality_score = 0.1 * term_score;
|
| + } else {
|
| + // For term scores of at least ten points, pass them through a log
|
| + // function so a score of 10 points gets a 1.0 (to meet up exactly
|
| + // with the linear component) and increases logarithmically until
|
| + // maxing out at 30 points, with computes to a score around 2.1.
|
| + topicality_score = (1.0 + 2.25 * log10(0.1 *
|
| + ((term_score <= 30) ? term_score : 30)));
|
| + }
|
| + raw_term_score_to_topicality_score[term_score] = topicality_score;
|
| + }
|
| +}
|
| +
|
| +// static
|
| +float* ScoredHistoryMatch::days_ago_to_recency_score = NULL;
|
| +
|
| +// static
|
| +float ScoredHistoryMatch::GetRecencyScore(int last_visit_days_ago) {
|
| + // Because the below thread is not thread safe, we check that we're
|
| + // only calling it from one thread: the UI thread. Specifically,
|
| + // we check "if we've heard of the UI thread then we'd better
|
| + // be on it." The first part is necessary so unit tests pass. (Many
|
| + // unit tests don't set up the threading naming system; hence
|
| + // CurrentlyOn(UI thread) will fail.)
|
| + DCHECK(
|
| + !content::BrowserThread::IsWellKnownThread(content::BrowserThread::UI) ||
|
| + content::BrowserThread::CurrentlyOn(content::BrowserThread::UI));
|
| + if (days_ago_to_recency_score == NULL) {
|
| + days_ago_to_recency_score = new float[kDaysToPrecomputeRecencyScoresFor];
|
| + FillInDaysAgoToRecencyScoreArray();
|
| + }
|
| + // Lookup the score in days_ago_to_recency_score, treating
|
| + // everything older than what we've precomputed as the oldest thing
|
| + // we've precomputed. The std::max is to protect against corruption
|
| + // in the database (in case last_visit_days_ago is negative).
|
| + return days_ago_to_recency_score[
|
| + std::max(
|
| + std::min(last_visit_days_ago, kDaysToPrecomputeRecencyScoresFor - 1),
|
| + 0)];
|
| +}
|
| +
|
| +void ScoredHistoryMatch::FillInDaysAgoToRecencyScoreArray() {
|
| + for (int days_ago = 0; days_ago < kDaysToPrecomputeRecencyScoresFor;
|
| + days_ago++) {
|
| + int unnormalized_recency_score;
|
| + if (days_ago <= 1) {
|
| + unnormalized_recency_score = 100;
|
| + } else if (days_ago <= 7) {
|
| + // Linearly extrapolate between 1 and 7 days so 7 days has a score of 70.
|
| + unnormalized_recency_score = 70 + (7 - days_ago) * (100 - 70) / (7 - 1);
|
| + } else if (days_ago <= 30) {
|
| + // Linearly extrapolate between 7 and 30 days so 30 days has a score
|
| + // of 50.
|
| + unnormalized_recency_score = 50 + (30 - days_ago) * (70 - 50) / (30 - 7);
|
| + } else if (days_ago <= 90) {
|
| + // Linearly extrapolate between 30 and 90 days so 90 days has a score
|
| + // of 20.
|
| + unnormalized_recency_score = 20 + (90 - days_ago) * (50 - 20) / (90 - 30);
|
| + } else if (days_ago <= 365) {
|
| + // Linearly extrapolate between 90 and 365 days so 365 days has a score
|
| + // of 10.
|
| + unnormalized_recency_score =
|
| + 10 + (365 - days_ago) * (20 - 10) / (365 - 90);
|
| + } else {
|
| + // greater than a year.
|
| + unnormalized_recency_score = 10;
|
| + }
|
| + days_ago_to_recency_score[days_ago] = unnormalized_recency_score / 100.0;
|
| + if (days_ago > 0) {
|
| + DCHECK_LE(days_ago_to_recency_score[days_ago],
|
| + days_ago_to_recency_score[days_ago - 1]);
|
| + }
|
| + }
|
| +}
|
| +
|
| +// static
|
| +float ScoredHistoryMatch::GetPopularityScore(int typed_count,
|
| + int visit_count) {
|
| + // The max()s are to guard against database corruption.
|
| + return (std::max(typed_count, 0) * 5.0 + std::max(visit_count, 0) * 3.0) /
|
| + (5.0 + 3.0);
|
| +}
|
| +
|
| +} // namespace history
|
|
|
| Property changes on: chrome/browser/history/scored_history_match.cc
|
| ___________________________________________________________________
|
| Added: svn:eol-style
|
| + LF
|
|
|
|
|