// Copyright (c) 2010 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 "app/l10n_util.h" #if defined(TOOLKIT_USES_GTK) #include #endif #include #include #include #include "app/app_paths.h" #include "app/l10n_util_collator.h" #include "app/resource_bundle.h" #include "base/command_line.h" #include "base/file_util.h" #include "base/i18n/file_util_icu.h" #include "base/i18n/rtl.h" #include "base/path_service.h" #include "base/scoped_ptr.h" #include "base/string16.h" #include "base/string_number_conversions.h" #include "base/string_split.h" #include "base/sys_string_conversions.h" #include "base/utf_string_conversions.h" #include "build/build_config.h" #include "gfx/canvas.h" #include "unicode/rbbi.h" #include "unicode/uloc.h" #if defined(OS_MACOSX) #include "app/l10n_util_mac.h" #elif defined(OS_WIN) #include "app/l10n_util_win.h" #endif namespace { #if defined(OS_WIN) static const FilePath::CharType kLocaleFileExtension[] = L".dll"; #elif defined(OS_POSIX) static const FilePath::CharType kLocaleFileExtension[] = ".pak"; #endif static const char* const kAcceptLanguageList[] = { "af", // Afrikaans "am", // Amharic "ar", // Arabic "az", // Azerbaijani "be", // Belarusian "bg", // Bulgarian "bh", // Bihari "bn", // Bengali "br", // Breton "bs", // Bosnian "ca", // Catalan "co", // Corsican "cs", // Czech "cy", // Welsh "da", // Danish "de", // German "de-AT", // German (Austria) "de-CH", // German (Switzerland) "de-DE", // German (Germany) "el", // Greek "en", // English "en-AU", // English (Austrailia) "en-CA", // English (Canada) "en-GB", // English (UK) "en-NZ", // English (New Zealand) "en-US", // English (US) "en-ZA", // English (South Africa) "eo", // Esperanto // TODO(jungshik) : Do we want to list all es-Foo for Latin-American // Spanish speaking countries? "es", // Spanish "et", // Estonian "eu", // Basque "fa", // Persian "fi", // Finnish "fil", // Filipino "fo", // Faroese "fr", // French "fr-CA", // French (Canada) "fr-CH", // French (Switzerland) "fr-FR", // French (France) "fy", // Frisian "ga", // Irish "gd", // Scots Gaelic "gl", // Galician "gn", // Guarani "gu", // Gujarati "ha", // Hausa "haw", // Hawaiian "he", // Hebrew "hi", // Hindi "hr", // Croatian "hu", // Hungarian "hy", // Armenian "ia", // Interlingua "id", // Indonesian "is", // Icelandic "it", // Italian "it-CH", // Italian (Switzerland) "it-IT", // Italian (Italy) "ja", // Japanese "jw", // Javanese "ka", // Georgian "kk", // Kazakh "km", // Cambodian "kn", // Kannada "ko", // Korean "ku", // Kurdish "ky", // Kyrgyz "la", // Latin "ln", // Lingala "lo", // Laothian "lt", // Lithuanian "lv", // Latvian "mk", // Macedonian "ml", // Malayalam "mn", // Mongolian "mo", // Moldavian "mr", // Marathi "ms", // Malay "mt", // Maltese "nb", // Norwegian (Bokmal) "ne", // Nepali "nl", // Dutch "nn", // Norwegian (Nynorsk) "no", // Norwegian "oc", // Occitan "om", // Oromo "or", // Oriya "pa", // Punjabi "pl", // Polish "ps", // Pashto "pt", // Portuguese "pt-BR", // Portuguese (Brazil) "pt-PT", // Portuguese (Portugal) "qu", // Quechua "rm", // Romansh "ro", // Romanian "ru", // Russian "sd", // Sindhi "sh", // Serbo-Croatian "si", // Sinhalese "sk", // Slovak "sl", // Slovenian "sn", // Shona "so", // Somali "sq", // Albanian "sr", // Serbian "st", // Sesotho "su", // Sundanese "sv", // Swedish "sw", // Swahili "ta", // Tamil "te", // Telugu "tg", // Tajik "th", // Thai "ti", // Tigrinya "tk", // Turkmen "to", // Tonga "tr", // Turkish "tt", // Tatar "tw", // Twi "ug", // Uighur "uk", // Ukrainian "ur", // Urdu "uz", // Uzbek "vi", // Vietnamese "xh", // Xhosa "yi", // Yiddish "yo", // Yoruba "zh", // Chinese "zh-CN", // Chinese (Simplified) "zh-TW", // Chinese (Traditional) "zu", // Zulu }; // Returns true if |locale_name| has an alias in the ICU data file. bool IsDuplicateName(const std::string& locale_name) { static const char* const kDuplicateNames[] = { "en", "pt", "zh", "zh_hans_cn", "zh_hant_tw" }; // Skip all 'es_RR'. Currently, we use 'es' for es-ES (Spanish in Spain). // 'es-419' (Spanish in Latin America) is not available in ICU so that it // has to be added manually in GetAvailableLocales(). if (LowerCaseEqualsASCII(locale_name.substr(0, 3), "es_")) return true; for (size_t i = 0; i < arraysize(kDuplicateNames); ++i) { if (base::strcasecmp(kDuplicateNames[i], locale_name.c_str()) == 0) return true; } return false; } bool IsLocaleNameTranslated(const char* locale, const std::string& display_locale) { string16 display_name = l10n_util::GetDisplayNameForLocale(locale, display_locale, false); // Because ICU sets the error code to U_USING_DEFAULT_WARNING whether or not // uloc_getDisplayName returns the actual translation or the default // value (locale code), we have to rely on this hack to tell whether // the translation is available or not. If ICU doesn't have a translated // name for this locale, GetDisplayNameForLocale will just return the // locale code. return !IsStringASCII(display_name) || UTF16ToASCII(display_name) != locale; } // We added 30+ minimally populated locales with only a few entries // (exemplar character set, script, writing direction and its own // lanaguage name). These locales have to be distinguished from the // fully populated locales to which Chrome is localized. bool IsLocalePartiallyPopulated(const std::string& locale_name) { // For partially populated locales, even the translation for "English" // is not available. A more robust/elegant way to check is to add a special // field (say, 'isPartial' to our version of ICU locale files) and // check its value, but this hack seems to work well. return !IsLocaleNameTranslated("en", locale_name); } #if !defined(OS_MACOSX) bool IsLocaleAvailable(const std::string& locale, const FilePath& locale_path) { // If locale has any illegal characters in it, we don't want to try to // load it because it may be pointing outside the locale data file directory. if (!file_util::IsFilenameLegal(ASCIIToUTF16(locale))) return false; // IsLocalePartiallyPopulated() can be called here for an early return w/o // checking the resource availability below. It'd help when Chrome is run // under a system locale Chrome is not localized to (e.g.Farsi on Linux), // but it'd slow down the start up time a little bit for locales Chrome is // localized to. So, we don't call it here. if (!l10n_util::IsLocaleSupportedByOS(locale)) return false; FilePath test_path = locale_path; test_path = test_path.AppendASCII(locale).ReplaceExtension(kLocaleFileExtension); return file_util::PathExists(test_path); } bool CheckAndResolveLocale(const std::string& locale, const FilePath& locale_path, std::string* resolved_locale) { if (IsLocaleAvailable(locale, locale_path)) { *resolved_locale = locale; return true; } // If the locale matches language but not country, use that instead. // TODO(jungshik) : Nothing is done about languages that Chrome // does not support but available on Windows. We fall // back to en-US in GetApplicationLocale so that it's a not critical, // but we can do better. std::string::size_type hyphen_pos = locale.find('-'); if (hyphen_pos != std::string::npos && hyphen_pos > 0) { std::string lang(locale, 0, hyphen_pos); std::string region(locale, hyphen_pos + 1); std::string tmp_locale(lang); // Map es-RR other than es-ES to es-419 (Chrome's Latin American // Spanish locale). if (LowerCaseEqualsASCII(lang, "es") && !LowerCaseEqualsASCII(region, "es")) tmp_locale.append("-419"); else if (LowerCaseEqualsASCII(lang, "zh")) { // Map zh-HK and zh-MK to zh-TW. Otherwise, zh-FOO is mapped to zh-CN. if (LowerCaseEqualsASCII(region, "hk") || LowerCaseEqualsASCII(region, "mk")) { tmp_locale.append("-TW"); } else { tmp_locale.append("-CN"); } } if (IsLocaleAvailable(tmp_locale, locale_path)) { resolved_locale->swap(tmp_locale); return true; } } // Google updater uses no, iw and en for our nb, he, and en-US. // We need to map them to our codes. struct { const char* source; const char* dest; } alias_map[] = { {"no", "nb"}, {"tl", "fil"}, {"iw", "he"}, {"en", "en-US"}, }; for (size_t i = 0; i < ARRAYSIZE_UNSAFE(alias_map); ++i) { if (LowerCaseEqualsASCII(locale, alias_map[i].source)) { std::string tmp_locale(alias_map[i].dest); if (IsLocaleAvailable(tmp_locale, locale_path)) { resolved_locale->swap(tmp_locale); return true; } } } return false; } #endif // On Linux, the text layout engine Pango determines paragraph directionality // by looking at the first strongly-directional character in the text. This // means text such as "Google Chrome foo bar..." will be layed out LTR even // if "foo bar" is RTL. So this function prepends the necessary RLM in such // cases. void AdjustParagraphDirectionality(string16* paragraph) { #if defined(OS_LINUX) if (base::i18n::IsRTL() && base::i18n::StringContainsStrongRTLChars(*paragraph)) { paragraph->insert(0, 1, static_cast(base::i18n::kRightToLeftMark)); } #endif } #if defined(OS_WIN) std::string GetCanonicalLocale(const std::string& locale) { return base::i18n::GetCanonicalLocale(locale.c_str()); } #endif } // namespace namespace l10n_util { std::string GetApplicationLocale(const std::string& pref_locale) { #if defined(OS_MACOSX) // Use any override (Cocoa for the browser), otherwise use the preference // passed to the function. std::string app_locale = l10n_util::GetLocaleOverride(); if (app_locale.empty()) app_locale = pref_locale; // The above should handle all of the cases Chrome normally hits, but for some // unit tests, we need something to fall back too. if (app_locale.empty()) app_locale = "en-US"; // Windows/Linux call SetICUDefaultLocale after determining the actual locale // with CheckAndResolveLocal to make ICU APIs work in that locale. // Mac doesn't use a locale directory tree of resources (it uses Mac style // resources), so mirror the Windows/Linux behavior of calling // SetICUDefaultLocale. base::i18n::SetICUDefaultLocale(app_locale); return app_locale; #else FilePath locale_path; PathService::Get(app::DIR_LOCALES, &locale_path); std::string resolved_locale; std::vector candidates; // We only use --lang and the app pref on Windows. On Linux, we only // look at the LC_*/LANG environment variables. We do, however, pass --lang // to renderer and plugin processes so they know what language the parent // process decided to use. #if defined(OS_WIN) // First, try the preference value. if (!pref_locale.empty()) candidates.push_back(pref_locale); // Next, try the overridden locale. const std::vector& languages = l10n_util::GetLocaleOverrides(); if (!languages.empty()) { candidates.reserve(candidates.size() + languages.size()); std::transform(languages.begin(), languages.end(), std::back_inserter(candidates), &GetCanonicalLocale); } else { // If no override was set, defer to ICU candidates.push_back(base::i18n::GetConfiguredLocale()); } #elif defined(OS_CHROMEOS) // On ChromeOS, use the application locale preference. if (!pref_locale.empty()) candidates.push_back(pref_locale); #elif defined(OS_POSIX) && defined(TOOLKIT_USES_GTK) // GLib implements correct environment variable parsing with // the precedence order: LANGUAGE, LC_ALL, LC_MESSAGES and LANG. // We used to use our custom parsing code along with ICU for this purpose. // If we have a port that does not depend on GTK, we have to // restore our custom code for that port. const char* const* languages = g_get_language_names(); DCHECK(languages); // A valid pointer is guaranteed. DCHECK(*languages); // At least one entry, "C", is guaranteed. for (; *languages != NULL; ++languages) { candidates.push_back(base::i18n::GetCanonicalLocale(*languages)); } #else #error Unsupported platform, see build/build_config.h #endif std::vector::const_iterator i = candidates.begin(); for (; i != candidates.end(); ++i) { if (CheckAndResolveLocale(*i, locale_path, &resolved_locale)) { base::i18n::SetICUDefaultLocale(resolved_locale); return resolved_locale; } } // Fallback on en-US. const std::string fallback_locale("en-US"); if (IsLocaleAvailable(fallback_locale, locale_path)) { base::i18n::SetICUDefaultLocale(fallback_locale); return fallback_locale; } // No locale data file was found; we shouldn't get here. NOTREACHED(); return std::string(); #endif } string16 GetDisplayNameForLocale(const std::string& locale, const std::string& display_locale, bool is_for_ui) { std::string locale_code = locale; // Internally, we use the language code of zh-CN and zh-TW, but we want the // display names to be Chinese (Simplified) and Chinese (Traditional) instead // of Chinese (China) and Chinese (Taiwan). To do that, we pass zh-Hans // and zh-Hant to ICU. Even with this mapping, we'd get // 'Chinese (Simplified Han)' and 'Chinese (Traditional Han)' in English and // even longer results in other languages. Arguably, they're better than // the current results : Chinese (China) / Chinese (Taiwan). // TODO(jungshik): Do one of the following: // 1. Special-case Chinese by getting the custom-translation for them // 2. Recycle IDS_ENCODING_{SIMP,TRAD}_CHINESE. // 3. Get translations for two directly from the ICU resouce bundle // because they're not accessible with other any API. // 4. Patch ICU to special-case zh-Hans/zh-Hant for us. // #1 and #2 wouldn't work if display_locale != current UI locale although // we can think of additional hack to work around the problem. // #3 can be potentially expensive. if (locale_code == "zh-CN") locale_code = "zh-Hans"; else if (locale_code == "zh-TW") locale_code = "zh-Hant"; UErrorCode error = U_ZERO_ERROR; const int buffer_size = 1024; string16 display_name; int actual_size = uloc_getDisplayName(locale_code.c_str(), display_locale.c_str(), WriteInto(&display_name, buffer_size + 1), buffer_size, &error); DCHECK(U_SUCCESS(error)); display_name.resize(actual_size); // Add an RTL mark so parentheses are properly placed. if (is_for_ui && base::i18n::IsRTL()) display_name.push_back(static_cast(base::i18n::kRightToLeftMark)); return display_name; } std::string NormalizeLocale(const std::string& locale) { std::string normalized_locale(locale); std::replace(normalized_locale.begin(), normalized_locale.end(), '-', '_'); return normalized_locale; } void GetParentLocales(const std::string& current_locale, std::vector* parent_locales) { std::string locale(NormalizeLocale(current_locale)); const int kNameCapacity = 256; char parent[kNameCapacity]; base::strlcpy(parent, locale.c_str(), kNameCapacity); parent_locales->push_back(parent); UErrorCode err = U_ZERO_ERROR; while (uloc_getParent(parent, parent, kNameCapacity, &err) > 0) { if (U_FAILURE(err)) break; parent_locales->push_back(parent); } } bool IsValidLocaleSyntax(const std::string& locale) { // Check that the length is plausible. if (locale.size() < 2 || locale.size() >= ULOC_FULLNAME_CAPACITY) return false; // Strip off the part after an '@' sign, which might contain keywords, // as in en_IE@currency=IEP or fr@collation=phonebook;calendar=islamic-civil. // We don't validate that part much, just check that there's at least one // equals sign in a plausible place. Normalize the prefix so that hyphens // are changed to underscores. std::string prefix = NormalizeLocale(locale); size_t split_point = locale.find("@"); if (split_point != std::string::npos) { std::string keywords = locale.substr(split_point + 1); prefix = locale.substr(0, split_point); size_t equals_loc = keywords.find("="); if (equals_loc == std::string::npos || equals_loc < 1 || equals_loc > keywords.size() - 2) return false; } // Check that all characters before the at-sign are alphanumeric or // underscore. for (size_t i = 0; i < prefix.size(); i++) { char ch = prefix[i]; if (!IsAsciiAlpha(ch) && !IsAsciiDigit(ch) && ch != '_') return false; } // Check that the initial token (before the first hyphen/underscore) // is 1 - 3 alphabetical characters (a language tag). for (size_t i = 0; i < prefix.size(); i++) { char ch = prefix[i]; if (ch == '_') { if (i < 1 || i > 3) return false; break; } if (!IsAsciiAlpha(ch)) return false; } // Check that the all tokens after the initial token are 1 - 8 characters. // (Tokenize/StringTokenizer don't work here, they collapse multiple // delimiters into one.) int token_len = 0; int token_index = 0; for (size_t i = 0; i < prefix.size(); i++) { if (prefix[i] != '_') { token_len++; continue; } if (token_index > 0 && (token_len < 1 || token_len > 8)) { return false; } token_index++; token_len = 0; } if (token_index == 0 && (token_len < 1 || token_len > 3)) { return false; } else if (token_len < 1 || token_len > 8) { return false; } return true; } std::wstring GetString(int message_id) { return UTF16ToWide(GetStringUTF16(message_id)); } std::string GetStringUTF8(int message_id) { return UTF16ToUTF8(GetStringUTF16(message_id)); } string16 GetStringUTF16(int message_id) { ResourceBundle& rb = ResourceBundle::GetSharedInstance(); string16 str = rb.GetLocalizedString(message_id); AdjustParagraphDirectionality(&str); return str; } static string16 GetStringF(int message_id, const std::vector& replacements, std::vector* offsets) { // TODO(tc): We could save a string copy if we got the raw string as // a StringPiece and were able to call ReplaceStringPlaceholders with // a StringPiece format string and string16 substitution strings. In // practice, the strings should be relatively short. ResourceBundle& rb = ResourceBundle::GetSharedInstance(); const string16& format_string = rb.GetLocalizedString(message_id); #ifndef NDEBUG // Make sure every replacement string is being used, so we don't just // silently fail to insert one. If |offsets| is non-NULL, then don't do this // check as the code may simply want to find the placeholders rather than // actually replacing them. if (!offsets) { std::string utf8_string = UTF16ToUTF8(format_string); // $9 is the highest allowed placeholder. for (size_t i = 0; i < 9; ++i) { bool placeholder_should_exist = replacements.size() > i; std::string placeholder = StringPrintf("$%d", static_cast(i + 1)); size_t pos = utf8_string.find(placeholder.c_str()); if (placeholder_should_exist) { DCHECK_NE(std::string::npos, pos) << " Didn't find a " << placeholder << " placeholder in " << utf8_string; } else { DCHECK_EQ(std::string::npos, pos) << " Unexpectedly found a " << placeholder << " placeholder in " << utf8_string; } } } #endif string16 formatted = ReplaceStringPlaceholders(format_string, replacements, offsets); AdjustParagraphDirectionality(&formatted); return formatted; } #if !defined(WCHAR_T_IS_UTF16) std::wstring GetStringF(int message_id, const std::wstring& a) { return UTF16ToWide(GetStringFUTF16(message_id, WideToUTF16(a))); } std::wstring GetStringF(int message_id, const std::wstring& a, const std::wstring& b) { return UTF16ToWide(GetStringFUTF16(message_id, WideToUTF16(a), WideToUTF16(b))); } std::wstring GetStringF(int message_id, const std::wstring& a, const std::wstring& b, const std::wstring& c) { return UTF16ToWide(GetStringFUTF16(message_id, WideToUTF16(a), WideToUTF16(b), WideToUTF16(c))); } std::wstring GetStringF(int message_id, const std::wstring& a, const std::wstring& b, const std::wstring& c, const std::wstring& d) { return UTF16ToWide(GetStringFUTF16(message_id, WideToUTF16(a), WideToUTF16(b), WideToUTF16(c), WideToUTF16(d))); } #endif std::string GetStringFUTF8(int message_id, const string16& a) { return UTF16ToUTF8(GetStringFUTF16(message_id, a)); } std::string GetStringFUTF8(int message_id, const string16& a, const string16& b) { return UTF16ToUTF8(GetStringFUTF16(message_id, a, b)); } std::string GetStringFUTF8(int message_id, const string16& a, const string16& b, const string16& c) { return UTF16ToUTF8(GetStringFUTF16(message_id, a, b, c)); } std::string GetStringFUTF8(int message_id, const string16& a, const string16& b, const string16& c, const string16& d) { return UTF16ToUTF8(GetStringFUTF16(message_id, a, b, c, d)); } string16 GetStringFUTF16(int message_id, const string16& a) { std::vector replacements; replacements.push_back(a); return GetStringF(message_id, replacements, NULL); } string16 GetStringFUTF16(int message_id, const string16& a, const string16& b) { return GetStringFUTF16(message_id, a, b, NULL); } string16 GetStringFUTF16(int message_id, const string16& a, const string16& b, const string16& c) { std::vector replacements; replacements.push_back(a); replacements.push_back(b); replacements.push_back(c); return GetStringF(message_id, replacements, NULL); } string16 GetStringFUTF16(int message_id, const string16& a, const string16& b, const string16& c, const string16& d) { std::vector replacements; replacements.push_back(a); replacements.push_back(b); replacements.push_back(c); replacements.push_back(d); return GetStringF(message_id, replacements, NULL); } std::wstring GetStringF(int message_id, const std::wstring& a, size_t* offset) { DCHECK(offset); std::vector offsets; std::vector replacements; replacements.push_back(WideToUTF16(a)); string16 result = GetStringF(message_id, replacements, &offsets); DCHECK(offsets.size() == 1); *offset = offsets[0]; return UTF16ToWide(result); } std::wstring GetStringF(int message_id, const std::wstring& a, const std::wstring& b, std::vector* offsets) { std::vector replacements; replacements.push_back(WideToUTF16(a)); replacements.push_back(WideToUTF16(b)); return UTF16ToWide(GetStringF(message_id, replacements, offsets)); } string16 GetStringFUTF16(int message_id, const string16& a, size_t* offset) { DCHECK(offset); std::vector offsets; std::vector replacements; replacements.push_back(a); string16 result = GetStringF(message_id, replacements, &offsets); DCHECK(offsets.size() == 1); *offset = offsets[0]; return result; } string16 GetStringFUTF16(int message_id, const string16& a, const string16& b, std::vector* offsets) { std::vector replacements; replacements.push_back(a); replacements.push_back(b); return GetStringF(message_id, replacements, offsets); } std::wstring GetStringF(int message_id, int a) { return GetStringF(message_id, UTF8ToWide(base::IntToString(a))); } std::wstring GetStringF(int message_id, int64 a) { return GetStringF(message_id, UTF8ToWide(base::Int64ToString(a))); } string16 TruncateString(const string16& string, size_t length) { if (string.size() <= length) // String fits, return it. return string; if (length == 0) { // No room for the elide string, return an empty string. return string16(); } size_t max = length - 1; // Added to the end of strings that are too big. static const char16 kElideString[] = { 0x2026, 0 }; if (max == 0) { // Just enough room for the elide string. return kElideString; } // Use a line iterator to find the first boundary. UErrorCode status = U_ZERO_ERROR; scoped_ptr bi( static_cast( icu::RuleBasedBreakIterator::createLineInstance( icu::Locale::getDefault(), status))); if (U_FAILURE(status)) return string.substr(0, max) + kElideString; bi->setText(string.c_str()); int32_t index = bi->preceding(static_cast(max)); if (index == icu::BreakIterator::DONE) { index = static_cast(max); } else { // Found a valid break (may be the beginning of the string). Now use // a character iterator to find the previous non-whitespace character. icu::StringCharacterIterator char_iterator(string.c_str()); if (index == 0) { // No valid line breaks. Start at the end again. This ensures we break // on a valid character boundary. index = static_cast(max); } char_iterator.setIndex(index); while (char_iterator.hasPrevious()) { char_iterator.previous(); if (!(u_isspace(char_iterator.current()) || u_charType(char_iterator.current()) == U_CONTROL_CHAR || u_charType(char_iterator.current()) == U_NON_SPACING_MARK)) { // Not a whitespace character. Advance the iterator so that we // include the current character in the truncated string. char_iterator.next(); break; } } if (char_iterator.hasPrevious()) { // Found a valid break point. index = char_iterator.getIndex(); } else { // String has leading whitespace, return the elide string. return kElideString; } } return string.substr(0, index) + kElideString; } string16 ToLower(const string16& string) { icu::UnicodeString lower_u_str( icu::UnicodeString(string.c_str()).toLower(icu::Locale::getDefault())); string16 result; lower_u_str.extract(0, lower_u_str.length(), WriteInto(&result, lower_u_str.length() + 1)); return result; } string16 ToUpper(const string16& string) { icu::UnicodeString upper_u_str( icu::UnicodeString(string.c_str()).toUpper(icu::Locale::getDefault())); string16 result; upper_u_str.extract(0, upper_u_str.length(), WriteInto(&result, upper_u_str.length() + 1)); return result; } // Compares the character data stored in two different string16 strings by // specified Collator instance. UCollationResult CompareString16WithCollator(const icu::Collator* collator, const string16& lhs, const string16& rhs) { DCHECK(collator); UErrorCode error = U_ZERO_ERROR; UCollationResult result = collator->compare( static_cast(lhs.c_str()), static_cast(lhs.length()), static_cast(rhs.c_str()), static_cast(rhs.length()), error); DCHECK(U_SUCCESS(error)); return result; } // Compares the character data stored in two different std:wstring strings by // specified Collator instance. UCollationResult CompareStringWithCollator(const icu::Collator* collator, const std::wstring& lhs, const std::wstring& rhs) { DCHECK(collator); UCollationResult result; #if defined(WCHAR_T_IS_UTF32) // Need to convert to UTF-16 to be compatible with UnicodeString's // constructor. string16 lhs_utf16 = WideToUTF16(lhs); string16 rhs_utf16 = WideToUTF16(rhs); result = CompareString16WithCollator(collator, lhs_utf16, rhs_utf16); #else result = CompareString16WithCollator(collator, lhs, rhs); #endif return result; } // Specialization of operator() method for std::wstring version. template <> bool StringComparator::operator()(const std::wstring& lhs, const std::wstring& rhs) { // If we can not get collator instance for specified locale, just do simple // string compare. if (!collator_) return lhs < rhs; return CompareStringWithCollator(collator_, lhs, rhs) == UCOL_LESS; }; #if !defined(WCHAR_T_IS_UTF16) // Specialization of operator() method for string16 version. template <> bool StringComparator::operator()(const string16& lhs, const string16& rhs) { // If we can not get collator instance for specified locale, just do simple // string compare. if (!collator_) return lhs < rhs; return CompareString16WithCollator(collator_, lhs, rhs) == UCOL_LESS; }; #endif // !defined(WCHAR_T_IS_UTF16) void SortStrings(const std::string& locale, std::vector* strings) { SortVectorWithStringKey(locale, strings, false); } void SortStrings16(const std::string& locale, std::vector* strings) { SortVectorWithStringKey(locale, strings, false); } const std::vector& GetAvailableLocales() { static std::vector locales; if (locales.empty()) { int num_locales = uloc_countAvailable(); for (int i = 0; i < num_locales; ++i) { std::string locale_name = uloc_getAvailable(i); // Filter out the names that have aliases. if (IsDuplicateName(locale_name)) continue; // Filter out locales for which we have only partially populated data // and to which Chrome is not localized. if (IsLocalePartiallyPopulated(locale_name)) continue; if (!IsLocaleSupportedByOS(locale_name)) continue; // Normalize underscores to hyphens because that's what our locale files // use. std::replace(locale_name.begin(), locale_name.end(), '_', '-'); // Map the Chinese locale names over to zh-CN and zh-TW. if (LowerCaseEqualsASCII(locale_name, "zh-hans")) { locale_name = "zh-CN"; } else if (LowerCaseEqualsASCII(locale_name, "zh-hant")) { locale_name = "zh-TW"; } locales.push_back(locale_name); } // Manually add 'es-419' to the list. See the comment in IsDuplicateName(). locales.push_back("es-419"); } return locales; } void GetAcceptLanguagesForLocale(const std::string& display_locale, std::vector* locale_codes) { for (size_t i = 0; i < arraysize(kAcceptLanguageList); ++i) { if (!IsLocaleNameTranslated(kAcceptLanguageList[i], display_locale)) // TODO(jungshik) : Put them at the of the list with language codes // enclosed by brackets instead of skipping. continue; locale_codes->push_back(kAcceptLanguageList[i]); } } } // namespace l10n_util