#ifndef RAPIDJSON_READER_H_ #define RAPIDJSON_READER_H_ // Copyright (c) 2011 Milo Yip (miloyip@gmail.com) // Version 0.1 #include "rapidjson.h" #include "internal/pow10.h" #include "internal/stack.h" #include #ifdef RAPIDJSON_SSE42 #include #elif defined(RAPIDJSON_SSE2) #include #endif #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable : 4127) // conditional expression is constant #endif #ifdef __clang__ #pragma clang diagnostic push #pragma clang diagnostic ignored "-Wtautological-constant-out-of-range-compare" #endif #ifndef RAPIDJSON_PARSE_ERROR #define RAPIDJSON_PARSE_ERROR(msg, offset) \ RAPIDJSON_MULTILINEMACRO_BEGIN \ parseError_ = msg; \ errorOffset_ = offset; \ longjmp(jmpbuf_, 1); \ RAPIDJSON_MULTILINEMACRO_END #endif namespace rapidjson { /////////////////////////////////////////////////////////////////////////////// // ParseFlag //! Combination of parseFlags enum ParseFlag { kParseDefaultFlags = 0, //!< Default parse flags. Non-destructive parsing. Text strings are decoded into allocated buffer. kParseInsituFlag = 1 //!< In-situ(destructive) parsing. }; /////////////////////////////////////////////////////////////////////////////// // Handler /*! \class rapidjson::Handler \brief Concept for receiving events from GenericReader upon parsing. \code concept Handler { typename Ch; void Null(); void Bool(bool b); void Int(int i); void Uint(unsigned i); void Int64(int64_t i); void Uint64(uint64_t i); void Double(double d); void String(const Ch* str, SizeType length, bool copy); void StartObject(); void EndObject(SizeType memberCount); void StartArray(); void EndArray(SizeType elementCount); }; \endcode */ /////////////////////////////////////////////////////////////////////////////// // BaseReaderHandler //! Default implementation of Handler. /*! This can be used as base class of any reader handler. \implements Handler */ template > struct BaseReaderHandler { typedef typename Encoding::Ch Ch; void Default() {} void Null() { Default(); } void Bool(bool) { Default(); } void Int(int) { Default(); } void Uint(unsigned) { Default(); } void Int64(int64_t) { Default(); } void Uint64(uint64_t) { Default(); } void Double(double) { Default(); } void String(const Ch*, SizeType, bool) { Default(); } void StartObject() { Default(); } void EndObject(SizeType) { Default(); } void StartArray() { Default(); } void EndArray(SizeType) { Default(); } }; /////////////////////////////////////////////////////////////////////////////// // SkipWhitespace //! Skip the JSON white spaces in a stream. /*! \param stream A input stream for skipping white spaces. \note This function has SSE2/SSE4.2 specialization. */ template void SkipWhitespace(Stream& stream) { Stream s = stream; // Use a local copy for optimization while (s.Peek() == ' ' || s.Peek() == '\n' || s.Peek() == '\r' || s.Peek() == '\t') s.Take(); stream = s; } #ifdef RAPIDJSON_SSE42 //! Skip whitespace with SSE 4.2 pcmpistrm instruction, testing 16 8-byte characters at once. inline const char *SkipWhitespace_SIMD(const char* p) { static const char whitespace[16] = " \n\r\t"; __m128i w = _mm_loadu_si128((const __m128i *)&whitespace[0]); for (;;) { __m128i s = _mm_loadu_si128((const __m128i *)p); unsigned r = _mm_cvtsi128_si32(_mm_cmpistrm(w, s, _SIDD_UBYTE_OPS | _SIDD_CMP_EQUAL_ANY | _SIDD_BIT_MASK | _SIDD_NEGATIVE_POLARITY)); if (r == 0) // all 16 characters are whitespace p += 16; else { // some of characters may be non-whitespace #ifdef _MSC_VER // Find the index of first non-whitespace unsigned long offset; if (_BitScanForward(&offset, r)) return p + offset; #else if (r != 0) return p + __builtin_ffs(r) - 1; #endif } } } #elif defined(RAPIDJSON_SSE2) //! Skip whitespace with SSE2 instructions, testing 16 8-byte characters at once. inline const char *SkipWhitespace_SIMD(const char* p) { static const char whitespaces[4][17] = { " ", "\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n", "\r\r\r\r\r\r\r\r\r\r\r\r\r\r\r\r", "\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t"}; __m128i w0 = _mm_loadu_si128((const __m128i *)&whitespaces[0][0]); __m128i w1 = _mm_loadu_si128((const __m128i *)&whitespaces[1][0]); __m128i w2 = _mm_loadu_si128((const __m128i *)&whitespaces[2][0]); __m128i w3 = _mm_loadu_si128((const __m128i *)&whitespaces[3][0]); for (;;) { __m128i s = _mm_loadu_si128((const __m128i *)p); __m128i x = _mm_cmpeq_epi8(s, w0); x = _mm_or_si128(x, _mm_cmpeq_epi8(s, w1)); x = _mm_or_si128(x, _mm_cmpeq_epi8(s, w2)); x = _mm_or_si128(x, _mm_cmpeq_epi8(s, w3)); unsigned short r = ~_mm_movemask_epi8(x); if (r == 0) // all 16 characters are whitespace p += 16; else { // some of characters may be non-whitespace #ifdef _MSC_VER // Find the index of first non-whitespace unsigned long offset; if (_BitScanForward(&offset, r)) return p + offset; #else if (r != 0) return p + __builtin_ffs(r) - 1; #endif } } } #endif // RAPIDJSON_SSE2 #ifdef RAPIDJSON_SIMD //! Template function specialization for InsituStringStream template<> inline void SkipWhitespace(InsituStringStream& stream) { stream.src_ = const_cast(SkipWhitespace_SIMD(stream.src_)); } //! Template function specialization for StringStream template<> inline void SkipWhitespace(StringStream& stream) { stream.src_ = SkipWhitespace_SIMD(stream.src_); } #endif // RAPIDJSON_SIMD /////////////////////////////////////////////////////////////////////////////// // GenericReader //! SAX-style JSON parser. Use Reader for UTF8 encoding and default allocator. /*! GenericReader parses JSON text from a stream, and send events synchronously to an object implementing Handler concept. It needs to allocate a stack for storing a single decoded string during non-destructive parsing. For in-situ parsing, the decoded string is directly written to the source text string, no temporary buffer is required. A GenericReader object can be reused for parsing multiple JSON text. \tparam Encoding Encoding of both the stream and the parse output. \tparam Allocator Allocator type for stack. */ template > class GenericReader { public: typedef typename Encoding::Ch Ch; //! Constructor. /*! \param allocator Optional allocator for allocating stack memory. (Only use for non-destructive parsing) \param stackCapacity stack capacity in bytes for storing a single decoded string. (Only use for non-destructive parsing) */ GenericReader(Allocator* allocator = 0, size_t stackCapacity = kDefaultStackCapacity) : stack_(allocator, stackCapacity), parseError_(0), errorOffset_(0) {} //! Parse JSON text. /*! \tparam parseFlags Combination of ParseFlag. \tparam Stream Type of input stream. \tparam Handler Type of handler which must implement Handler concept. \param stream Input stream to be parsed. \param handler The handler to receive events. \return Whether the parsing is successful. */ template bool Parse(Stream& stream, Handler& handler) { parseError_ = 0; errorOffset_ = 0; #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable : 4611) // interaction between '_setjmp' and C++ object destruction is non-portable #endif if (setjmp(jmpbuf_)) { #ifdef _MSC_VER #pragma warning(pop) #endif stack_.Clear(); return false; } SkipWhitespace(stream); if (stream.Peek() == '\0') RAPIDJSON_PARSE_ERROR("Text only contains white space(s)", stream.Tell()); else { switch (stream.Peek()) { case '{': ParseObject(stream, handler); break; case '[': ParseArray(stream, handler); break; default: RAPIDJSON_PARSE_ERROR("Expect either an object or array at root", stream.Tell()); } SkipWhitespace(stream); if (stream.Peek() != '\0') RAPIDJSON_PARSE_ERROR("Nothing should follow the root object or array.", stream.Tell()); } return true; } bool HasParseError() const { return parseError_ != 0; } const char* GetParseError() const { return parseError_; } size_t GetErrorOffset() const { return errorOffset_; } private: // Parse object: { string : value, ... } template void ParseObject(Stream& stream, Handler& handler) { RAPIDJSON_ASSERT(stream.Peek() == '{'); stream.Take(); // Skip '{' handler.StartObject(); SkipWhitespace(stream); if (stream.Peek() == '}') { stream.Take(); handler.EndObject(0); // empty object return; } for (SizeType memberCount = 0;;) { if (stream.Peek() != '"') { RAPIDJSON_PARSE_ERROR("Name of an object member must be a string", stream.Tell()); break; } ParseString(stream, handler); SkipWhitespace(stream); if (stream.Take() != ':') { RAPIDJSON_PARSE_ERROR("There must be a colon after the name of object member", stream.Tell()); break; } SkipWhitespace(stream); ParseValue(stream, handler); SkipWhitespace(stream); ++memberCount; switch(stream.Take()) { case ',': SkipWhitespace(stream); break; case '}': handler.EndObject(memberCount); return; default: RAPIDJSON_PARSE_ERROR("Must be a comma or '}' after an object member", stream.Tell()); } } } // Parse array: [ value, ... ] template void ParseArray(Stream& stream, Handler& handler) { RAPIDJSON_ASSERT(stream.Peek() == '['); stream.Take(); // Skip '[' handler.StartArray(); SkipWhitespace(stream); if (stream.Peek() == ']') { stream.Take(); handler.EndArray(0); // empty array return; } for (SizeType elementCount = 0;;) { ParseValue(stream, handler); ++elementCount; SkipWhitespace(stream); switch (stream.Take()) { case ',': SkipWhitespace(stream); break; case ']': handler.EndArray(elementCount); return; default: RAPIDJSON_PARSE_ERROR("Must be a comma or ']' after an array element.", stream.Tell()); } } } template void ParseNull(Stream& stream, Handler& handler) { RAPIDJSON_ASSERT(stream.Peek() == 'n'); stream.Take(); if (stream.Take() == 'u' && stream.Take() == 'l' && stream.Take() == 'l') handler.Null(); else RAPIDJSON_PARSE_ERROR("Invalid value", stream.Tell() - 1); } template void ParseTrue(Stream& stream, Handler& handler) { RAPIDJSON_ASSERT(stream.Peek() == 't'); stream.Take(); if (stream.Take() == 'r' && stream.Take() == 'u' && stream.Take() == 'e') handler.Bool(true); else RAPIDJSON_PARSE_ERROR("Invalid value", stream.Tell()); } template void ParseFalse(Stream& stream, Handler& handler) { RAPIDJSON_ASSERT(stream.Peek() == 'f'); stream.Take(); if (stream.Take() == 'a' && stream.Take() == 'l' && stream.Take() == 's' && stream.Take() == 'e') handler.Bool(false); else RAPIDJSON_PARSE_ERROR("Invalid value", stream.Tell() - 1); } // Helper function to parse four hexidecimal digits in \uXXXX in ParseString(). template unsigned ParseHex4(Stream& stream) { Stream s = stream; // Use a local copy for optimization unsigned codepoint = 0; for (int i = 0; i < 4; i++) { Ch c = s.Take(); codepoint <<= 4; codepoint += c; if (c >= '0' && c <= '9') codepoint -= '0'; else if (c >= 'A' && c <= 'F') codepoint -= 'A' - 10; else if (c >= 'a' && c <= 'f') codepoint -= 'a' - 10; else RAPIDJSON_PARSE_ERROR("Incorrect hex digit after \\u escape", s.Tell() - 1); } stream = s; // Restore stream return codepoint; } // Parse string, handling the prefix and suffix double quotes and escaping. template void ParseString(Stream& stream, Handler& handler) { #define Z16 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 static const Ch escape[256] = { Z16, Z16, 0, 0,'\"', 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,'/', Z16, Z16, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,'\\', 0, 0, 0, 0, 0,'\b', 0, 0, 0,'\f', 0, 0, 0, 0, 0, 0, 0,'\n', 0, 0, 0,'\r', 0,'\t', 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, Z16, Z16, Z16, Z16, Z16, Z16, Z16, Z16 }; #undef Z16 Stream s = stream; // Use a local copy for optimization RAPIDJSON_ASSERT(s.Peek() == '\"'); s.Take(); // Skip '\"' Ch *head; SizeType len; if (parseFlags & kParseInsituFlag) head = s.PutBegin(); else len = 0; #define RAPIDJSON_PUT(x) \ do { \ if (parseFlags & kParseInsituFlag) \ s.Put(x); \ else { \ *stack_.template Push() = x; \ ++len; \ } \ } while(false) for (;;) { Ch c = s.Take(); if (c == '\\') { // Escape Ch e = s.Take(); if ((sizeof(Ch) == 1 || e < 256) && escape[(unsigned char)e]) RAPIDJSON_PUT(escape[(unsigned char)e]); else if (e == 'u') { // Unicode unsigned codepoint = ParseHex4(s); if (codepoint >= 0xD800 && codepoint <= 0xDBFF) { // Handle UTF-16 surrogate pair if (s.Take() != '\\' || s.Take() != 'u') { RAPIDJSON_PARSE_ERROR("Missing the second \\u in surrogate pair", s.Tell() - 2); return; } unsigned codepoint2 = ParseHex4(s); if (codepoint2 < 0xDC00 || codepoint2 > 0xDFFF) { RAPIDJSON_PARSE_ERROR("The second \\u in surrogate pair is invalid", s.Tell() - 2); return; } codepoint = (((codepoint - 0xD800) << 10) | (codepoint2 - 0xDC00)) + 0x10000; } Ch buffer[4]; SizeType count = SizeType(Encoding::Encode(buffer, codepoint) - &buffer[0]); if (parseFlags & kParseInsituFlag) for (SizeType i = 0; i < count; i++) s.Put(buffer[i]); else { memcpy(stack_.template Push(count), buffer, count * sizeof(Ch)); len += count; } } else { RAPIDJSON_PARSE_ERROR("Unknown escape character", stream.Tell() - 1); return; } } else if (c == '"') { // Closing double quote if (parseFlags & kParseInsituFlag) { size_t length = s.PutEnd(head); RAPIDJSON_ASSERT(length <= 0xFFFFFFFF); RAPIDJSON_PUT('\0'); // null-terminate the string handler.String(head, SizeType(length), false); } else { RAPIDJSON_PUT('\0'); handler.String(stack_.template Pop(len), len - 1, true); } stream = s; // restore stream return; } else if (c == '\0') { RAPIDJSON_PARSE_ERROR("lacks ending quotation before the end of string", stream.Tell() - 1); return; } else if ((unsigned)c < 0x20) { // RFC 4627: unescaped = %x20-21 / %x23-5B / %x5D-10FFFF RAPIDJSON_PARSE_ERROR("Incorrect unescaped character in string", stream.Tell() - 1); return; } else RAPIDJSON_PUT(c); // Normal character, just copy } #undef RAPIDJSON_PUT } template void ParseNumber(Stream& stream, Handler& handler) { Stream s = stream; // Local copy for optimization // Parse minus bool minus = false; if (s.Peek() == '-') { minus = true; s.Take(); } // Parse int: zero / ( digit1-9 *DIGIT ) unsigned i; bool try64bit = false; if (s.Peek() == '0') { i = 0; s.Take(); } else if (s.Peek() >= '1' && s.Peek() <= '9') { i = s.Take() - '0'; if (minus) while (s.Peek() >= '0' && s.Peek() <= '9') { if (i >= 214748364) { // 2^31 = 2147483648 if (i != 214748364 || s.Peek() > '8') { try64bit = true; break; } } i = i * 10 + (s.Take() - '0'); } else while (s.Peek() >= '0' && s.Peek() <= '9') { if (i >= 429496729) { // 2^32 - 1 = 4294967295 if (i != 429496729 || s.Peek() > '5') { try64bit = true; break; } } i = i * 10 + (s.Take() - '0'); } } else { RAPIDJSON_PARSE_ERROR("Expect a value here.", stream.Tell()); return; } // Parse 64bit int uint64_t i64 = 0; bool useDouble = false; if (try64bit) { i64 = i; if (minus) while (s.Peek() >= '0' && s.Peek() <= '9') { if (i64 >= 922337203685477580uLL) // 2^63 = 9223372036854775808 if (i64 != 922337203685477580uLL || s.Peek() > '8') { useDouble = true; break; } i64 = i64 * 10 + (s.Take() - '0'); } else while (s.Peek() >= '0' && s.Peek() <= '9') { if (i64 >= 1844674407370955161uLL) // 2^64 - 1 = 18446744073709551615 if (i64 != 1844674407370955161uLL || s.Peek() > '5') { useDouble = true; break; } i64 = i64 * 10 + (s.Take() - '0'); } } // Force double for big integer double d = 0.0; if (useDouble) { d = (double)i64; while (s.Peek() >= '0' && s.Peek() <= '9') { if (d >= 1E307) { RAPIDJSON_PARSE_ERROR("Number too big to store in double", stream.Tell()); return; } d = d * 10 + (s.Take() - '0'); } } // Parse frac = decimal-point 1*DIGIT int expFrac = 0; if (s.Peek() == '.') { if (!useDouble) { d = try64bit ? (double)i64 : (double)i; useDouble = true; } s.Take(); if (s.Peek() >= '0' && s.Peek() <= '9') { d = d * 10 + (s.Take() - '0'); --expFrac; } else { RAPIDJSON_PARSE_ERROR("At least one digit in fraction part", stream.Tell()); return; } while (s.Peek() >= '0' && s.Peek() <= '9') { if (expFrac > -16) { d = d * 10 + (s.Peek() - '0'); --expFrac; } s.Take(); } } // Parse exp = e [ minus / plus ] 1*DIGIT int exp = 0; if (s.Peek() == 'e' || s.Peek() == 'E') { if (!useDouble) { d = try64bit ? (double)i64 : (double)i; useDouble = true; } s.Take(); bool expMinus = false; if (s.Peek() == '+') s.Take(); else if (s.Peek() == '-') { s.Take(); expMinus = true; } if (s.Peek() >= '0' && s.Peek() <= '9') { exp = s.Take() - '0'; while (s.Peek() >= '0' && s.Peek() <= '9') { exp = exp * 10 + (s.Take() - '0'); if (exp > 308) { RAPIDJSON_PARSE_ERROR("Number too big to store in double", stream.Tell()); return; } } } else { RAPIDJSON_PARSE_ERROR("At least one digit in exponent", s.Tell()); return; } if (expMinus) exp = -exp; } // Finish parsing, call event according to the type of number. if (useDouble) { d *= internal::Pow10(exp + expFrac); handler.Double(minus ? -d : d); } else { if (try64bit) { if (minus) handler.Int64(-(int64_t)i64); else handler.Uint64(i64); } else { if (minus) handler.Int(-(int)i); else handler.Uint(i); } } stream = s; // restore stream } // Parse any JSON value template void ParseValue(Stream& stream, Handler& handler) { switch (stream.Peek()) { case 'n': ParseNull (stream, handler); break; case 't': ParseTrue (stream, handler); break; case 'f': ParseFalse (stream, handler); break; case '"': ParseString(stream, handler); break; case '{': ParseObject(stream, handler); break; case '[': ParseArray (stream, handler); break; default : ParseNumber(stream, handler); } } static const size_t kDefaultStackCapacity = 256; //!< Default stack capacity in bytes for storing a single decoded string. internal::Stack stack_; //!< A stack for storing decoded string temporarily during non-destructive parsing. jmp_buf jmpbuf_; //!< setjmp buffer for fast exit from nested parsing function calls. const char* parseError_; size_t errorOffset_; }; // class GenericReader //! Reader with UTF8 encoding and default allocator. typedef GenericReader > Reader; } // namespace rapidjson #ifdef _MSC_VER #pragma warning(pop) #endif #ifdef __clang__ #pragma clang diagnostic pop #endif #endif // RAPIDJSON_READER_H_