/* -*- 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 "nsSMILParserUtils.h" #include "nsISMILAttr.h" #include "nsSMILValue.h" #include "nsSMILTimeValue.h" #include "nsSMILTimeValueSpecParams.h" #include "nsSMILTypes.h" #include "nsSMILRepeatCount.h" #include "nsContentUtils.h" #include "nsString.h" #include "prdtoa.h" #include "nsCRT.h" #include "nsCOMPtr.h" #include "prlong.h" #include "nsCharSeparatedTokenizer.h" using namespace mozilla::dom; //------------------------------------------------------------------------------ // Helper functions and Constants namespace { const uint32_t MSEC_PER_SEC = 1000; const uint32_t MSEC_PER_MIN = 1000 * 60; const uint32_t MSEC_PER_HOUR = 1000 * 60 * 60; const int32_t DECIMAL_BASE = 10; #define ACCESSKEY_PREFIX_LC NS_LITERAL_STRING("accesskey(") // SMIL2+ #define ACCESSKEY_PREFIX_CC NS_LITERAL_STRING("accessKey(") // SVG/SMIL ANIM #define REPEAT_PREFIX NS_LITERAL_STRING("repeat(") #define WALLCLOCK_PREFIX NS_LITERAL_STRING("wallclock(") // NS_IS_SPACE relies on isspace which may return true for \xB and \xC but // SMILANIM does not consider these characters to be whitespace. inline bool IsSpace(const PRUnichar c) { return (c == 0x9 || c == 0xA || c == 0xD || c == 0x20); } template inline void SkipBeginWsp(T& aStart, T aEnd) { while (aStart != aEnd && IsSpace(*aStart)) { ++aStart; } } inline void SkipBeginEndWsp(const PRUnichar*& aStart, const PRUnichar*& aEnd) { SkipBeginWsp(aStart, aEnd); while (aEnd != aStart && IsSpace(*(aEnd - 1))) { --aEnd; } } double GetFloat(const char*& aStart, const char* aEnd, nsresult* aErrorCode) { char* floatEnd; double value = PR_strtod(aStart, &floatEnd); nsresult rv; if (floatEnd == aStart || floatEnd > aEnd) { rv = NS_ERROR_FAILURE; } else { aStart = floatEnd; rv = NS_OK; } if (aErrorCode) { *aErrorCode = rv; } return value; } size_t GetUnsignedInt(const nsAString& aStr, uint32_t& aResult) { NS_ConvertUTF16toUTF8 cstr(aStr); const char* str = cstr.get(); char* rest; int32_t value = strtol(str, &rest, DECIMAL_BASE); if (rest == str || value < 0) return 0; aResult = static_cast(value); return rest - str; } bool GetUnsignedIntAndEndParen(const nsAString& aStr, uint32_t& aResult) { size_t intLen = GetUnsignedInt(aStr, aResult); const PRUnichar* start = aStr.BeginReading(); const PRUnichar* end = aStr.EndReading(); // Make sure the string is only digit+')' if (intLen == 0 || start + intLen + 1 != end || *(start + intLen) != ')') return false; return true; } inline bool ConsumeSubstring(const char*& aStart, const char* aEnd, const char* aSubstring) { size_t substrLen = strlen(aSubstring); if (static_cast(aEnd - aStart) < substrLen) return false; bool result = false; if (PL_strstr(aStart, aSubstring) == aStart) { aStart += substrLen; result = true; } return result; } bool ParseClockComponent(const char*& aStart, const char* aEnd, double& aResult, bool& aIsReal, bool& aCouldBeMin, bool& aCouldBeSec) { nsresult rv; const char* begin = aStart; double value = GetFloat(aStart, aEnd, &rv); // Check a number was found if (NS_FAILED(rv)) return false; // Check that it's not expressed in exponential form size_t len = aStart - begin; bool isExp = (PL_strnpbrk(begin, "eE", len) != nullptr); if (isExp) return false; // Don't allow real numbers of the form "23." if (*(aStart - 1) == '.') return false; // Number looks good aResult = value; // Set some flags so we can check this number is valid once we know // whether it's an hour, minute string etc. aIsReal = (PL_strnchr(begin, '.', len) != nullptr); aCouldBeMin = (value < 60.0 && (len == 2)); aCouldBeSec = (value < 60.0 || (value == 60.0 && begin[0] == '5')); // Take care of rounding error aCouldBeSec &= (len >= 2 && (begin[2] == '\0' || begin[2] == '.' || IsSpace(begin[2]))); return true; } bool ParseMetricMultiplicand(const char*& aStart, const char* aEnd, int32_t& multiplicand) { bool result = false; size_t len = aEnd - aStart; const char* cur = aStart; if (len) { switch (*cur++) { case 'h': multiplicand = MSEC_PER_HOUR; result = true; break; case 'm': if (len >= 2) { if (*cur == 's') { ++cur; multiplicand = 1; result = true; } else if (len >= 3 && *cur++ == 'i' && *cur++ == 'n') { multiplicand = MSEC_PER_MIN; result = true; } } break; case 's': multiplicand = MSEC_PER_SEC; result = true; break; } } if (result) { aStart = cur; } return result; } nsresult ParseOptionalOffset(const nsAString& aSpec, nsSMILTimeValueSpecParams& aResult) { if (aSpec.IsEmpty()) { aResult.mOffset.SetMillis(0); return NS_OK; } if (aSpec.First() != '+' && aSpec.First() != '-') return NS_ERROR_FAILURE; return nsSMILParserUtils::ParseClockValue(aSpec, &aResult.mOffset, nsSMILParserUtils::kClockValueAllowSign); } nsresult ParseAccessKey(const nsAString& aSpec, nsSMILTimeValueSpecParams& aResult) { NS_ABORT_IF_FALSE(StringBeginsWith(aSpec, ACCESSKEY_PREFIX_CC) || StringBeginsWith(aSpec, ACCESSKEY_PREFIX_LC), "Calling ParseAccessKey on non-accesskey-type spec"); nsSMILTimeValueSpecParams result; result.mType = nsSMILTimeValueSpecParams::ACCESSKEY; NS_ABORT_IF_FALSE( ACCESSKEY_PREFIX_LC.Length() == ACCESSKEY_PREFIX_CC.Length(), "Case variations for accesskey prefix differ in length"); const PRUnichar* start = aSpec.BeginReading() + ACCESSKEY_PREFIX_LC.Length(); const PRUnichar* end = aSpec.EndReading(); // Expecting at least + ')' if (end - start < 2) return NS_ERROR_FAILURE; uint32_t c = *start++; // Process 32-bit codepoints if (NS_IS_HIGH_SURROGATE(c)) { if (end - start < 2) // Expecting at least low-surrogate + ')' return NS_ERROR_FAILURE; uint32_t lo = *start++; if (!NS_IS_LOW_SURROGATE(lo)) return NS_ERROR_FAILURE; c = SURROGATE_TO_UCS4(c, lo); // XML 1.1 says that 0xFFFE and 0xFFFF are not valid characters } else if (NS_IS_LOW_SURROGATE(c) || c == 0xFFFE || c == 0xFFFF) { return NS_ERROR_FAILURE; } result.mRepeatIterationOrAccessKey = c; if (*start++ != ')') return NS_ERROR_FAILURE; SkipBeginWsp(start, end); nsresult rv = ParseOptionalOffset(Substring(start, end), result); if (NS_FAILED(rv)) return rv; aResult = result; return NS_OK; } const PRUnichar* GetTokenEnd(const nsAString& aStr, bool aBreakOnDot) { const PRUnichar* tokenEnd = aStr.BeginReading(); const PRUnichar* const end = aStr.EndReading(); bool escape = false; while (tokenEnd != end) { PRUnichar c = *tokenEnd; if (IsSpace(c) || (!escape && (c == '+' || c == '-' || (aBreakOnDot && c == '.')))) { break; } escape = (!escape && c == '\\'); ++tokenEnd; } return tokenEnd; } void Unescape(nsAString& aStr) { const PRUnichar* read = aStr.BeginReading(); const PRUnichar* const end = aStr.EndReading(); PRUnichar* write = aStr.BeginWriting(); bool escape = false; while (read != end) { NS_ABORT_IF_FALSE(write <= read, "Writing past where we've read"); if (!escape && *read == '\\') { escape = true; ++read; } else { *write++ = *read++; escape = false; } } aStr.SetLength(write - aStr.BeginReading()); } nsresult ParseElementBaseTimeValueSpec(const nsAString& aSpec, nsSMILTimeValueSpecParams& aResult) { nsSMILTimeValueSpecParams result; // // The spec will probably look something like one of these // // element-name.begin // element-name.event-name // event-name // element-name.repeat(3) // event\.name // // Technically `repeat(3)' is permitted but the behaviour in this case is not // defined (for SMIL Animation) so we don't support it here. // const PRUnichar* tokenStart = aSpec.BeginReading(); const PRUnichar* tokenEnd = GetTokenEnd(aSpec, true); nsAutoString token(Substring(tokenStart, tokenEnd)); Unescape(token); if (token.IsEmpty()) return NS_ERROR_FAILURE; // Whether the token is an id-ref or event-symbol it should be a valid NCName if (NS_FAILED(nsContentUtils::CheckQName(token, false))) return NS_ERROR_FAILURE; // Parse the second token if there is one if (tokenEnd != aSpec.EndReading() && *tokenEnd == '.') { result.mDependentElemID = do_GetAtom(token); tokenStart = ++tokenEnd; tokenEnd = GetTokenEnd(Substring(tokenStart, aSpec.EndReading()), false); // Don't unescape the token unless we need to and not until after we've // tested it const nsAString& rawToken2 = Substring(tokenStart, tokenEnd); // element-name.begin if (rawToken2.Equals(NS_LITERAL_STRING("begin"))) { result.mType = nsSMILTimeValueSpecParams::SYNCBASE; result.mSyncBegin = true; // element-name.end } else if (rawToken2.Equals(NS_LITERAL_STRING("end"))) { result.mType = nsSMILTimeValueSpecParams::SYNCBASE; result.mSyncBegin = false; // element-name.repeat(digit+) } else if (StringBeginsWith(rawToken2, REPEAT_PREFIX)) { result.mType = nsSMILTimeValueSpecParams::REPEAT; if (!GetUnsignedIntAndEndParen( Substring(tokenStart + REPEAT_PREFIX.Length(), tokenEnd), result.mRepeatIterationOrAccessKey)) return NS_ERROR_FAILURE; // element-name.event-symbol } else { nsAutoString token2(rawToken2); Unescape(token2); result.mType = nsSMILTimeValueSpecParams::EVENT; if (token2.IsEmpty() || NS_FAILED(nsContentUtils::CheckQName(token2, false))) return NS_ERROR_FAILURE; result.mEventSymbol = do_GetAtom(token2); } } else { // event-symbol result.mType = nsSMILTimeValueSpecParams::EVENT; result.mEventSymbol = do_GetAtom(token); } // We've reached the end of the token, so we should now be either looking at // a '+', '-', or the end. const PRUnichar* specEnd = aSpec.EndReading(); SkipBeginWsp(tokenEnd, specEnd); nsresult rv = ParseOptionalOffset(Substring(tokenEnd, specEnd), result); if (NS_SUCCEEDED(rv)) { aResult = result; } return rv; } } // end anonymous namespace block //------------------------------------------------------------------------------ // Implementation nsresult nsSMILParserUtils::ParseKeySplines(const nsAString& aSpec, nsTArray& aSplineArray) { nsresult rv = NS_OK; NS_ConvertUTF16toUTF8 spec(aSpec); const char* start = spec.BeginReading(); const char* end = spec.EndReading(); SkipBeginWsp(start, end); int i = 0; while (start != end) { double value = GetFloat(start, end, &rv); if (NS_FAILED(rv)) break; if (value > 1.0 || value < 0.0) { rv = NS_ERROR_FAILURE; break; } if (!aSplineArray.AppendElement(value)) { rv = NS_ERROR_OUT_OF_MEMORY; break; } ++i; SkipBeginWsp(start, end); if (start == end) break; if (i % 4) { if (*start == ',') { ++start; } } else { if (*start != ';') { rv = NS_ERROR_FAILURE; break; } ++start; } SkipBeginWsp(start, end); } if (i % 4) { rv = NS_ERROR_FAILURE; // wrong number of points } return rv; } nsresult nsSMILParserUtils::ParseSemicolonDelimitedProgressList(const nsAString& aSpec, bool aNonDecreasing, nsTArray& aArray) { nsresult rv = NS_OK; NS_ConvertUTF16toUTF8 spec(aSpec); const char* start = spec.BeginReading(); const char* end = spec.EndReading(); SkipBeginWsp(start, end); double previousValue = -1.0; while (start != end) { double value = GetFloat(start, end, &rv); if (NS_FAILED(rv)) break; if (value > 1.0 || value < 0.0 || (aNonDecreasing && value < previousValue)) { rv = NS_ERROR_FAILURE; break; } if (!aArray.AppendElement(value)) { rv = NS_ERROR_OUT_OF_MEMORY; break; } previousValue = value; SkipBeginWsp(start, end); if (start == end) break; if (*start++ != ';') { rv = NS_ERROR_FAILURE; break; } SkipBeginWsp(start, end); } return rv; } // Helper class for ParseValues class SMILValueParser : public nsSMILParserUtils::GenericValueParser { public: SMILValueParser(const SVGAnimationElement* aSrcElement, const nsISMILAttr* aSMILAttr, nsTArray* aValuesArray, bool* aPreventCachingOfSandwich) : mSrcElement(aSrcElement), mSMILAttr(aSMILAttr), mValuesArray(aValuesArray), mPreventCachingOfSandwich(aPreventCachingOfSandwich) {} virtual nsresult Parse(const nsAString& aValueStr) { nsSMILValue newValue; bool tmpPreventCachingOfSandwich = false; nsresult rv = mSMILAttr->ValueFromString(aValueStr, mSrcElement, newValue, tmpPreventCachingOfSandwich); if (NS_FAILED(rv)) return rv; if (!mValuesArray->AppendElement(newValue)) { return NS_ERROR_OUT_OF_MEMORY; } if (tmpPreventCachingOfSandwich) { *mPreventCachingOfSandwich = true; } return NS_OK; } protected: const SVGAnimationElement* mSrcElement; const nsISMILAttr* mSMILAttr; nsTArray* mValuesArray; bool* mPreventCachingOfSandwich; }; nsresult nsSMILParserUtils::ParseValues(const nsAString& aSpec, const SVGAnimationElement* aSrcElement, const nsISMILAttr& aAttribute, nsTArray& aValuesArray, bool& aPreventCachingOfSandwich) { // Assume all results can be cached, until we find one that can't. aPreventCachingOfSandwich = false; SMILValueParser valueParser(aSrcElement, &aAttribute, &aValuesArray, &aPreventCachingOfSandwich); return ParseValuesGeneric(aSpec, valueParser); } nsresult nsSMILParserUtils::ParseValuesGeneric(const nsAString& aSpec, GenericValueParser& aParser) { nsCharSeparatedTokenizer tokenizer(aSpec, ';'); if (!tokenizer.hasMoreTokens()) { // Empty list return NS_ERROR_FAILURE; } while (tokenizer.hasMoreTokens()) { nsresult rv = aParser.Parse(tokenizer.nextToken()); if (NS_FAILED(rv)) { return NS_ERROR_FAILURE; } } return NS_OK; } nsresult nsSMILParserUtils::ParseRepeatCount(const nsAString& aSpec, nsSMILRepeatCount& aResult) { nsresult rv = NS_OK; NS_ConvertUTF16toUTF8 spec(aSpec); const char* start = spec.BeginReading(); const char* end = spec.EndReading(); SkipBeginWsp(start, end); if (start != end) { if (ConsumeSubstring(start, end, "indefinite")) { aResult.SetIndefinite(); } else { double value = GetFloat(start, end, &rv); if (NS_SUCCEEDED(rv)) { /* Repeat counts must be > 0 */ if (value <= 0.0) { rv = NS_ERROR_FAILURE; } else { aResult = value; } } } /* Check for trailing junk */ SkipBeginWsp(start, end); if (start != end) { rv = NS_ERROR_FAILURE; } } else { /* Empty spec */ rv = NS_ERROR_FAILURE; } if (NS_FAILED(rv)) { aResult.Unset(); } return rv; } nsresult nsSMILParserUtils::ParseTimeValueSpecParams(const nsAString& aSpec, nsSMILTimeValueSpecParams& aResult) { nsresult rv = NS_ERROR_FAILURE; const PRUnichar* start = aSpec.BeginReading(); const PRUnichar* end = aSpec.EndReading(); SkipBeginEndWsp(start, end); if (start == end) return rv; const nsAString &spec = Substring(start, end); // offset type if (*start == '+' || *start == '-' || NS_IsAsciiDigit(*start)) { rv = ParseClockValue(spec, &aResult.mOffset, nsSMILParserUtils::kClockValueAllowSign); if (NS_SUCCEEDED(rv)) { aResult.mType = nsSMILTimeValueSpecParams::OFFSET; } } // indefinite else if (spec.Equals(NS_LITERAL_STRING("indefinite"))) { aResult.mType = nsSMILTimeValueSpecParams::INDEFINITE; rv = NS_OK; } // wallclock type else if (StringBeginsWith(spec, WALLCLOCK_PREFIX)) { rv = NS_ERROR_NOT_IMPLEMENTED; } // accesskey type else if (StringBeginsWith(spec, ACCESSKEY_PREFIX_LC) || StringBeginsWith(spec, ACCESSKEY_PREFIX_CC)) { rv = ParseAccessKey(spec, aResult); } // event, syncbase, or repeat else { rv = ParseElementBaseTimeValueSpec(spec, aResult); } return rv; } nsresult nsSMILParserUtils::ParseClockValue(const nsAString& aSpec, nsSMILTimeValue* aResult, uint32_t aFlags, // = 0 bool* aIsMedia) // = nullptr { nsSMILTime offset = 0L; double component = 0.0; int8_t sign = 0; uint8_t colonCount = 0; // Indicates we have started parsing a clock-value (not including the optional // +/- that precedes the clock-value) or keyword ("media", "indefinite") bool started = false; int32_t metricMultiplicand = MSEC_PER_SEC; bool numIsReal = false; bool prevNumCouldBeMin = false; bool numCouldBeMin = false; bool numCouldBeSec = false; bool isIndefinite = false; if (aIsMedia) { *aIsMedia = false; } NS_ConvertUTF16toUTF8 spec(aSpec); const char* start = spec.BeginReading(); const char* end = spec.EndReading(); while (start != end) { if (IsSpace(*start)) { ++start; if (started) { break; } } else if (!started && (aFlags & kClockValueAllowSign) && (*start == '+' || *start == '-')) { // check sign has not already been set (e.g. ++10s) if (sign != 0) { return NS_ERROR_FAILURE; } sign = (*start == '+') ? 1 : -1; ++start; // The NS_IS_DIGIT etc. macros are not locale-specific } else if (NS_IS_DIGIT(*start)) { prevNumCouldBeMin = numCouldBeMin; if (!ParseClockComponent(start, end, component, numIsReal, numCouldBeMin, numCouldBeSec)) { return NS_ERROR_FAILURE; } started = true; } else if (started && *start == ':') { ++colonCount; // Neither minutes nor hours can be reals if (numIsReal) { return NS_ERROR_FAILURE; } // Can't have more than two colons if (colonCount > 2) { return NS_ERROR_FAILURE; } // Multiply the offset by 60 and add the last accumulated component offset = offset * 60 + nsSMILTime(component); component = 0.0; ++start; } else if (NS_IS_ALPHA(*start)) { if (colonCount > 0) { return NS_ERROR_FAILURE; } if (!started && (aFlags & kClockValueAllowIndefinite) && ConsumeSubstring(start, end, "indefinite")) { // We set a separate flag because we don't know what the state of the // passed in time value is and we shouldn't change it in the case of a // bad input string (so we can't initialise it to 0ms for example). isIndefinite = true; if (aResult) { aResult->SetIndefinite(); } started = true; } else if (!started && aIsMedia && ConsumeSubstring(start, end, "media")) { *aIsMedia = true; started = true; } else if (!ParseMetricMultiplicand(start, end, metricMultiplicand)) { return NS_ERROR_FAILURE; } // Nothing must come after the string except whitespace break; } else { return NS_ERROR_FAILURE; } } // Whitespace/empty string if (!started) { return NS_ERROR_FAILURE; } // Process remainder of string (if any) to ensure it is only trailing // whitespace (embedded whitespace is not allowed) SkipBeginWsp(start, end); if (start != end) { return NS_ERROR_FAILURE; } // No more processing required if the value was "indefinite" or "media". if (isIndefinite || (aIsMedia && *aIsMedia)) { return NS_OK; } // If there is more than one colon then the previous component must be a // correctly formatted minute (i.e. two digits between 00 and 59) and the // latest component must be a correctly formatted second (i.e. two digits // before the .) if (colonCount > 0 && (!prevNumCouldBeMin || !numCouldBeSec)) { return NS_ERROR_FAILURE; } // Tack on the last component if (colonCount > 0) { offset *= 60 * 1000; component *= 1000; // rounding component = (component >= 0) ? component + 0.5 : component - 0.5; offset += nsSMILTime(component); } else { component *= metricMultiplicand; // rounding component = (component >= 0) ? component + 0.5 : component - 0.5; offset = nsSMILTime(component); } // we haven't applied the sign yet so if the result is negative we must have // overflowed if (offset < 0) { return NS_ERROR_FAILURE; } if (aResult) { if (sign == -1) { offset = -offset; } aResult->SetMillis(offset); } return NS_OK; } int32_t nsSMILParserUtils::CheckForNegativeNumber(const nsAString& aStr) { int32_t absValLocation = -1; nsAString::const_iterator start, end; aStr.BeginReading(start); aStr.EndReading(end); // Skip initial whitespace SkipBeginWsp(start, end); // Check for dash if (start != end && *start == '-') { ++start; // Check for numeric character if (start != end && NS_IS_DIGIT(*start)) { absValLocation = start.get() - start.start(); } } return absValLocation; }