/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* 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 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "nsIDNService.h" #include "nsReadableUtils.h" #include "nsCRT.h" #include "nsUnicharUtils.h" #include "nsIServiceManager.h" #include "nsIPrefService.h" #include "nsIPrefBranch.h" #include "nsIObserverService.h" #include "nsISupportsPrimitives.h" #include "punycode.h" #include "mozilla/FunctionTimer.h" //----------------------------------------------------------------------------- // RFC 1034 - 3.1. Name space specifications and terminology static const uint32_t kMaxDNSNodeLen = 63; //----------------------------------------------------------------------------- #define NS_NET_PREF_IDNTESTBED "network.IDN_testbed" #define NS_NET_PREF_IDNPREFIX "network.IDN_prefix" #define NS_NET_PREF_IDNBLACKLIST "network.IDN.blacklist_chars" #define NS_NET_PREF_SHOWPUNYCODE "network.IDN_show_punycode" #define NS_NET_PREF_IDNWHITELIST "network.IDN.whitelist." inline bool isOnlySafeChars(const nsAFlatString& in, const nsAFlatString& blacklist) { return (blacklist.IsEmpty() || in.FindCharInSet(blacklist) == kNotFound); } //----------------------------------------------------------------------------- // nsIDNService //----------------------------------------------------------------------------- /* Implementation file */ NS_IMPL_THREADSAFE_ISUPPORTS3(nsIDNService, nsIIDNService, nsIObserver, nsISupportsWeakReference) nsresult nsIDNService::Init() { NS_TIME_FUNCTION; nsCOMPtr prefs(do_GetService(NS_PREFSERVICE_CONTRACTID)); if (prefs) prefs->GetBranch(NS_NET_PREF_IDNWHITELIST, getter_AddRefs(mIDNWhitelistPrefBranch)); nsCOMPtr prefInternal(do_QueryInterface(prefs)); if (prefInternal) { prefInternal->AddObserver(NS_NET_PREF_IDNTESTBED, this, true); prefInternal->AddObserver(NS_NET_PREF_IDNPREFIX, this, true); prefInternal->AddObserver(NS_NET_PREF_IDNBLACKLIST, this, true); prefInternal->AddObserver(NS_NET_PREF_SHOWPUNYCODE, this, true); prefsChanged(prefInternal, nullptr); } return NS_OK; } NS_IMETHODIMP nsIDNService::Observe(nsISupports *aSubject, const char *aTopic, const PRUnichar *aData) { if (!strcmp(aTopic, NS_PREFBRANCH_PREFCHANGE_TOPIC_ID)) { nsCOMPtr prefBranch( do_QueryInterface(aSubject) ); if (prefBranch) prefsChanged(prefBranch, aData); } return NS_OK; } void nsIDNService::prefsChanged(nsIPrefBranch *prefBranch, const PRUnichar *pref) { if (!pref || NS_LITERAL_STRING(NS_NET_PREF_IDNTESTBED).Equals(pref)) { bool val; if (NS_SUCCEEDED(prefBranch->GetBoolPref(NS_NET_PREF_IDNTESTBED, &val))) mMultilingualTestBed = val; } if (!pref || NS_LITERAL_STRING(NS_NET_PREF_IDNPREFIX).Equals(pref)) { nsXPIDLCString prefix; nsresult rv = prefBranch->GetCharPref(NS_NET_PREF_IDNPREFIX, getter_Copies(prefix)); if (NS_SUCCEEDED(rv) && prefix.Length() <= kACEPrefixLen) PL_strncpyz(nsIDNService::mACEPrefix, prefix.get(), kACEPrefixLen + 1); } if (!pref || NS_LITERAL_STRING(NS_NET_PREF_IDNBLACKLIST).Equals(pref)) { nsCOMPtr blacklist; nsresult rv = prefBranch->GetComplexValue(NS_NET_PREF_IDNBLACKLIST, NS_GET_IID(nsISupportsString), getter_AddRefs(blacklist)); if (NS_SUCCEEDED(rv)) blacklist->ToString(getter_Copies(mIDNBlacklist)); else mIDNBlacklist.Truncate(); } if (!pref || NS_LITERAL_STRING(NS_NET_PREF_SHOWPUNYCODE).Equals(pref)) { bool val; if (NS_SUCCEEDED(prefBranch->GetBoolPref(NS_NET_PREF_SHOWPUNYCODE, &val))) mShowPunycode = val; } } nsIDNService::nsIDNService() { // initialize to the official prefix (RFC 3490 "5. ACE prefix") const char kIDNSPrefix[] = "xn--"; strcpy(mACEPrefix, kIDNSPrefix); mMultilingualTestBed = false; if (idn_success != idn_nameprep_create(NULL, &mNamePrepHandle)) mNamePrepHandle = nullptr; mNormalizer = do_GetService(NS_UNICODE_NORMALIZER_CONTRACTID); /* member initializers and constructor code */ } nsIDNService::~nsIDNService() { idn_nameprep_destroy(mNamePrepHandle); } /* ACString ConvertUTF8toACE (in AUTF8String input); */ NS_IMETHODIMP nsIDNService::ConvertUTF8toACE(const nsACString & input, nsACString & ace) { return UTF8toACE(input, ace, true); } nsresult nsIDNService::UTF8toACE(const nsACString & input, nsACString & ace, bool allowUnassigned) { nsresult rv; NS_ConvertUTF8toUTF16 ustr(input); // map ideographic period to ASCII period etc. normalizeFullStops(ustr); uint32_t len, offset; len = 0; offset = 0; nsCAutoString encodedBuf; nsAString::const_iterator start, end; ustr.BeginReading(start); ustr.EndReading(end); ace.Truncate(); // encode nodes if non ASCII while (start != end) { len++; if (*start++ == (PRUnichar)'.') { rv = stringPrepAndACE(Substring(ustr, offset, len - 1), encodedBuf, allowUnassigned); NS_ENSURE_SUCCESS(rv, rv); ace.Append(encodedBuf); ace.Append('.'); offset += len; len = 0; } } // add extra node for multilingual test bed if (mMultilingualTestBed) ace.AppendLiteral("mltbd."); // encode the last node if non ASCII if (len) { rv = stringPrepAndACE(Substring(ustr, offset, len), encodedBuf, allowUnassigned); NS_ENSURE_SUCCESS(rv, rv); ace.Append(encodedBuf); } return NS_OK; } /* AUTF8String convertACEtoUTF8(in ACString input); */ NS_IMETHODIMP nsIDNService::ConvertACEtoUTF8(const nsACString & input, nsACString & _retval) { return ACEtoUTF8(input, _retval, true); } nsresult nsIDNService::ACEtoUTF8(const nsACString & input, nsACString & _retval, bool allowUnassigned) { // RFC 3490 - 4.2 ToUnicode // ToUnicode never fails. If any step fails, then the original input // sequence is returned immediately in that step. if (!IsASCII(input)) { _retval.Assign(input); return NS_OK; } uint32_t len = 0, offset = 0; nsCAutoString decodedBuf; nsACString::const_iterator start, end; input.BeginReading(start); input.EndReading(end); _retval.Truncate(); // loop and decode nodes while (start != end) { len++; if (*start++ == '.') { if (NS_FAILED(decodeACE(Substring(input, offset, len - 1), decodedBuf, allowUnassigned))) { _retval.Assign(input); return NS_OK; } _retval.Append(decodedBuf); _retval.Append('.'); offset += len; len = 0; } } // decode the last node if (len) { if (NS_FAILED(decodeACE(Substring(input, offset, len), decodedBuf, allowUnassigned))) _retval.Assign(input); else _retval.Append(decodedBuf); } return NS_OK; } /* boolean isACE(in ACString input); */ NS_IMETHODIMP nsIDNService::IsACE(const nsACString & input, bool *_retval) { nsACString::const_iterator begin; input.BeginReading(begin); const char *data = begin.get(); uint32_t dataLen = begin.size_forward(); // look for the ACE prefix in the input string. it may occur // at the beginning of any segment in the domain name. for // example: "www.xn--ENCODED.com" const char *p = PL_strncasestr(data, mACEPrefix, dataLen); *_retval = p && (p == data || *(p - 1) == '.'); return NS_OK; } /* AUTF8String normalize(in AUTF8String input); */ NS_IMETHODIMP nsIDNService::Normalize(const nsACString & input, nsACString & output) { // protect against bogus input NS_ENSURE_TRUE(IsUTF8(input), NS_ERROR_UNEXPECTED); NS_ConvertUTF8toUTF16 inUTF16(input); normalizeFullStops(inUTF16); // pass the domain name to stringprep label by label nsAutoString outUTF16, outLabel; uint32_t len = 0, offset = 0; nsresult rv; nsAString::const_iterator start, end; inUTF16.BeginReading(start); inUTF16.EndReading(end); while (start != end) { len++; if (*start++ == PRUnichar('.')) { rv = stringPrep(Substring(inUTF16, offset, len - 1), outLabel, true); NS_ENSURE_SUCCESS(rv, rv); outUTF16.Append(outLabel); outUTF16.Append(PRUnichar('.')); offset += len; len = 0; } } if (len) { rv = stringPrep(Substring(inUTF16, offset, len), outLabel, true); NS_ENSURE_SUCCESS(rv, rv); outUTF16.Append(outLabel); } CopyUTF16toUTF8(outUTF16, output); if (!isOnlySafeChars(outUTF16, mIDNBlacklist)) return ConvertUTF8toACE(output, output); return NS_OK; } NS_IMETHODIMP nsIDNService::ConvertToDisplayIDN(const nsACString & input, bool * _isASCII, nsACString & _retval) { // If host is ACE, then convert to UTF-8 if the host is in the IDN whitelist. // Else, if host is already UTF-8, then make sure it is normalized per IDN. nsresult rv; if (IsASCII(input)) { // first, canonicalize the host to lowercase, for whitelist lookup _retval = input; ToLowerCase(_retval); bool isACE; IsACE(_retval, &isACE); if (isACE && !mShowPunycode && isInWhitelist(_retval)) { // ACEtoUTF8() can't fail, but might return the original ACE string nsCAutoString temp(_retval); ACEtoUTF8(temp, _retval, false); *_isASCII = IsASCII(_retval); } else { *_isASCII = true; } } else { // We have to normalize the hostname before testing against the domain // whitelist (see bug 315411), and to ensure the entire string gets // normalized. rv = Normalize(input, _retval); if (NS_FAILED(rv)) return rv; if (mShowPunycode && NS_SUCCEEDED(ConvertUTF8toACE(_retval, _retval))) { *_isASCII = true; return NS_OK; } // normalization could result in an ASCII-only hostname. alternatively, if // the host is converted to ACE by the normalizer, then the host may contain // unsafe characters, so leave it ACE encoded. see bug 283016, bug 301694, and bug 309311. *_isASCII = IsASCII(_retval); if (!*_isASCII && !isInWhitelist(_retval)) { *_isASCII = true; return ConvertUTF8toACE(_retval, _retval); } } return NS_OK; } //----------------------------------------------------------------------------- static void utf16ToUcs4(const nsAString& in, uint32_t *out, uint32_t outBufLen, uint32_t *outLen) { uint32_t i = 0; nsAString::const_iterator start, end; in.BeginReading(start); in.EndReading(end); while (start != end) { PRUnichar curChar; curChar= *start++; if (start != end && NS_IS_HIGH_SURROGATE(curChar) && NS_IS_LOW_SURROGATE(*start)) { out[i] = SURROGATE_TO_UCS4(curChar, *start); ++start; } else out[i] = curChar; i++; if (i >= outBufLen) { NS_ERROR("input too big, the result truncated"); out[outBufLen-1] = (uint32_t)'\0'; *outLen = outBufLen-1; return; } } out[i] = (uint32_t)'\0'; *outLen = i; } static void ucs4toUtf16(const uint32_t *in, nsAString& out) { while (*in) { if (!IS_IN_BMP(*in)) { out.Append((PRUnichar) H_SURROGATE(*in)); out.Append((PRUnichar) L_SURROGATE(*in)); } else out.Append((PRUnichar) *in); in++; } } static nsresult punycode(const char* prefix, const nsAString& in, nsACString& out) { uint32_t ucs4Buf[kMaxDNSNodeLen + 1]; uint32_t ucs4Len; utf16ToUcs4(in, ucs4Buf, kMaxDNSNodeLen, &ucs4Len); // need maximum 20 bits to encode 16 bit Unicode character // (include null terminator) const uint32_t kEncodedBufSize = kMaxDNSNodeLen * 20 / 8 + 1 + 1; char encodedBuf[kEncodedBufSize]; punycode_uint encodedLength = kEncodedBufSize; enum punycode_status status = punycode_encode(ucs4Len, ucs4Buf, nullptr, &encodedLength, encodedBuf); if (punycode_success != status || encodedLength >= kEncodedBufSize) return NS_ERROR_FAILURE; encodedBuf[encodedLength] = '\0'; out.Assign(nsDependentCString(prefix) + nsDependentCString(encodedBuf)); return NS_OK; } static nsresult encodeToRACE(const char* prefix, const nsAString& in, nsACString& out) { // need maximum 20 bits to encode 16 bit Unicode character // (include null terminator) const uint32_t kEncodedBufSize = kMaxDNSNodeLen * 20 / 8 + 1 + 1; // set up a work buffer for RACE encoder PRUnichar temp[kMaxDNSNodeLen + 2]; temp[0] = 0xFFFF; // set a place holder (to be filled by get_compress_mode) temp[in.Length() + 1] = (PRUnichar)'\0'; nsAString::const_iterator start, end; in.BeginReading(start); in.EndReading(end); for (uint32_t i = 1; start != end; i++) temp[i] = *start++; // encode nodes if non ASCII char encodedBuf[kEncodedBufSize]; idn_result_t result = race_compress_encode((const unsigned short *) temp, get_compress_mode((unsigned short *) temp + 1), encodedBuf, kEncodedBufSize); if (idn_success != result) return NS_ERROR_FAILURE; out.Assign(prefix); out.Append(encodedBuf); return NS_OK; } // RFC 3454 // // 1) Map -- For each character in the input, check if it has a mapping // and, if so, replace it with its mapping. This is described in section 3. // // 2) Normalize -- Possibly normalize the result of step 1 using Unicode // normalization. This is described in section 4. // // 3) Prohibit -- Check for any characters that are not allowed in the // output. If any are found, return an error. This is described in section // 5. // // 4) Check bidi -- Possibly check for right-to-left characters, and if any // are found, make sure that the whole string satisfies the requirements // for bidirectional strings. If the string does not satisfy the requirements // for bidirectional strings, return an error. This is described in section 6. // // 5) Check unassigned code points -- If allowUnassigned is false, check for // any unassigned Unicode points and if any are found return an error. // This is described in section 7. // nsresult nsIDNService::stringPrep(const nsAString& in, nsAString& out, bool allowUnassigned) { if (!mNamePrepHandle || !mNormalizer) return NS_ERROR_FAILURE; nsresult rv = NS_OK; uint32_t ucs4Buf[kMaxDNSNodeLen + 1]; uint32_t ucs4Len; utf16ToUcs4(in, ucs4Buf, kMaxDNSNodeLen, &ucs4Len); // map idn_result_t idn_err; uint32_t namePrepBuf[kMaxDNSNodeLen * 3]; // map up to three characters idn_err = idn_nameprep_map(mNamePrepHandle, (const uint32_t *) ucs4Buf, (uint32_t *) namePrepBuf, kMaxDNSNodeLen * 3); NS_ENSURE_TRUE(idn_err == idn_success, NS_ERROR_FAILURE); nsAutoString namePrepStr; ucs4toUtf16(namePrepBuf, namePrepStr); if (namePrepStr.Length() >= kMaxDNSNodeLen) return NS_ERROR_FAILURE; // normalize nsAutoString normlizedStr; rv = mNormalizer->NormalizeUnicodeNFKC(namePrepStr, normlizedStr); if (normlizedStr.Length() >= kMaxDNSNodeLen) return NS_ERROR_FAILURE; // prohibit const uint32_t *found = nullptr; idn_err = idn_nameprep_isprohibited(mNamePrepHandle, (const uint32_t *) ucs4Buf, &found); if (idn_err != idn_success || found) return NS_ERROR_FAILURE; // check bidi idn_err = idn_nameprep_isvalidbidi(mNamePrepHandle, (const uint32_t *) ucs4Buf, &found); if (idn_err != idn_success || found) return NS_ERROR_FAILURE; if (!allowUnassigned) { // check unassigned code points idn_err = idn_nameprep_isunassigned(mNamePrepHandle, (const uint32_t *) ucs4Buf, &found); if (idn_err != idn_success || found) return NS_ERROR_FAILURE; } // set the result string out.Assign(normlizedStr); return rv; } nsresult nsIDNService::encodeToACE(const nsAString& in, nsACString& out) { // RACE encode is supported for existing testing environment if (!strcmp("bq--", mACEPrefix)) return encodeToRACE(mACEPrefix, in, out); // use punycoce return punycode(mACEPrefix, in, out); } nsresult nsIDNService::stringPrepAndACE(const nsAString& in, nsACString& out, bool allowUnassigned) { nsresult rv = NS_OK; out.Truncate(); if (in.Length() > kMaxDNSNodeLen) { NS_WARNING("IDN node too large"); return NS_ERROR_FAILURE; } if (IsASCII(in)) LossyCopyUTF16toASCII(in, out); else { nsAutoString strPrep; rv = stringPrep(in, strPrep, allowUnassigned); if (NS_SUCCEEDED(rv)) { if (IsASCII(strPrep)) LossyCopyUTF16toASCII(strPrep, out); else rv = encodeToACE(strPrep, out); } } if (out.Length() > kMaxDNSNodeLen) { NS_WARNING("IDN node too large"); return NS_ERROR_FAILURE; } return rv; } // RFC 3490 // 1) Whenever dots are used as label separators, the following characters // MUST be recognized as dots: U+002E (full stop), U+3002 (ideographic full // stop), U+FF0E (fullwidth full stop), U+FF61 (halfwidth ideographic full // stop). void nsIDNService::normalizeFullStops(nsAString& s) { nsAString::const_iterator start, end; s.BeginReading(start); s.EndReading(end); int32_t index = 0; while (start != end) { switch (*start) { case 0x3002: case 0xFF0E: case 0xFF61: s.Replace(index, 1, NS_LITERAL_STRING(".")); break; default: break; } start++; index++; } } nsresult nsIDNService::decodeACE(const nsACString& in, nsACString& out, bool allowUnassigned) { bool isAce; IsACE(in, &isAce); if (!isAce) { out.Assign(in); return NS_OK; } // RFC 3490 - 4.2 ToUnicode // The ToUnicode output never contains more code points than its input. punycode_uint output_length = in.Length() - kACEPrefixLen + 1; punycode_uint *output = new punycode_uint[output_length]; NS_ENSURE_TRUE(output, NS_ERROR_OUT_OF_MEMORY); enum punycode_status status = punycode_decode(in.Length() - kACEPrefixLen, PromiseFlatCString(in).get() + kACEPrefixLen, &output_length, output, nullptr); if (status != punycode_success) { delete [] output; return NS_ERROR_FAILURE; } // UCS4 -> UTF8 output[output_length] = 0; nsAutoString utf16; ucs4toUtf16(output, utf16); delete [] output; if (!isOnlySafeChars(utf16, mIDNBlacklist)) return NS_ERROR_FAILURE; CopyUTF16toUTF8(utf16, out); // Validation: encode back to ACE and compare the strings nsCAutoString ace; nsresult rv = UTF8toACE(out, ace, allowUnassigned); NS_ENSURE_SUCCESS(rv, rv); if (!ace.Equals(in, nsCaseInsensitiveCStringComparator())) return NS_ERROR_FAILURE; return NS_OK; } bool nsIDNService::isInWhitelist(const nsACString &host) { if (mIDNWhitelistPrefBranch) { nsCAutoString tld(host); // make sure the host is ACE for lookup and check that there are no // unassigned codepoints if (!IsASCII(tld) && NS_FAILED(UTF8toACE(tld, tld, false))) { return false; } // truncate trailing dots first tld.Trim("."); int32_t pos = tld.RFind("."); if (pos == kNotFound) return false; tld.Cut(0, pos + 1); bool safe; if (NS_SUCCEEDED(mIDNWhitelistPrefBranch->GetBoolPref(tld.get(), &safe))) return safe; } return false; }