#ifndef RAPIDJSON_WRITER_H_ #define RAPIDJSON_WRITER_H_ #include "rapidjson.h" #include "internal/stack.h" #include "internal/strfunc.h" #include // snprintf() or _sprintf_s() #include // placement new #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable : 4127) // conditional expression is constant #endif namespace rapidjson { //! JSON writer /*! Writer implements the concept Handler. It generates JSON text by events to an output stream. User may programmatically calls the functions of a writer to generate JSON text. On the other side, a writer can also be passed to objects that generates events, for example Reader::Parse() and Document::Accept(). \tparam Stream Type of ouptut stream. \tparam Encoding Encoding of both source strings and output. \implements Handler */ template, typename Allocator = MemoryPoolAllocator<> > class Writer { public: typedef typename Encoding::Ch Ch; Writer(Stream& stream, Allocator* allocator = 0, size_t levelDepth = kDefaultLevelDepth) : stream_(stream), level_stack_(allocator, levelDepth * sizeof(Level)) {} //@name Implementation of Handler //@{ Writer& Null() { Prefix(kNullType); WriteNull(); return *this; } Writer& Bool(bool b) { Prefix(b ? kTrueType : kFalseType); WriteBool(b); return *this; } Writer& Int(int i) { Prefix(kNumberType); WriteInt(i); return *this; } Writer& Uint(unsigned u) { Prefix(kNumberType); WriteUint(u); return *this; } Writer& Int64(int64_t i64) { Prefix(kNumberType); WriteInt64(i64); return *this; } Writer& Uint64(uint64_t u64) { Prefix(kNumberType); WriteUint64(u64); return *this; } Writer& Double(double d) { Prefix(kNumberType); WriteDouble(d); return *this; } Writer& String(const Ch* str, SizeType length, bool copy = false) { (void)copy; Prefix(kStringType); WriteString(str, length); return *this; } Writer& StartObject() { Prefix(kObjectType); new (level_stack_.template Push()) Level(false); WriteStartObject(); return *this; } Writer& EndObject(SizeType memberCount = 0) { (void)memberCount; RAPIDJSON_ASSERT(level_stack_.GetSize() >= sizeof(Level)); RAPIDJSON_ASSERT(!level_stack_.template Top()->inArray); level_stack_.template Pop(1); WriteEndObject(); return *this; } Writer& StartArray() { Prefix(kArrayType); new (level_stack_.template Push()) Level(true); WriteStartArray(); return *this; } Writer& EndArray(SizeType elementCount = 0) { (void)elementCount; RAPIDJSON_ASSERT(level_stack_.GetSize() >= sizeof(Level)); RAPIDJSON_ASSERT(level_stack_.template Top()->inArray); level_stack_.template Pop(1); WriteEndArray(); return *this; } //@} //! Simpler but slower overload. Writer& String(const Ch* str) { return String(str, internal::StrLen(str)); } protected: //! Information for each nested level struct Level { Level(bool inArray_) : inArray(inArray_), valueCount(0) {} bool inArray; //!< true if in array, otherwise in object size_t valueCount; //!< number of values in this level }; static const size_t kDefaultLevelDepth = 32; void WriteNull() { stream_.Put('n'); stream_.Put('u'); stream_.Put('l'); stream_.Put('l'); } void WriteBool(bool b) { if (b) { stream_.Put('t'); stream_.Put('r'); stream_.Put('u'); stream_.Put('e'); } else { stream_.Put('f'); stream_.Put('a'); stream_.Put('l'); stream_.Put('s'); stream_.Put('e'); } } void WriteInt(int i) { if (i < 0) { stream_.Put('-'); i = -i; } WriteUint((unsigned)i); } void WriteUint(unsigned u) { char buffer[10]; char *p = buffer; do { *p++ = (u % 10) + '0'; u /= 10; } while (u > 0); do { --p; stream_.Put(*p); } while (p != buffer); } void WriteInt64(int64_t i64) { if (i64 < 0) { stream_.Put('-'); i64 = -i64; } WriteUint64((uint64_t)i64); } void WriteUint64(uint64_t u64) { char buffer[20]; char *p = buffer; do { *p++ = char(u64 % 10) + '0'; u64 /= 10; } while (u64 > 0); do { --p; stream_.Put(*p); } while (p != buffer); } //! \todo Optimization with custom double-to-string converter. void WriteDouble(double d) { char buffer[100]; #if _MSC_VER int ret = sprintf_s(buffer, sizeof(buffer), "%g", d); #else int ret = snprintf(buffer, sizeof(buffer), "%g", d); #endif RAPIDJSON_ASSERT(ret >= 1); for (int i = 0; i < ret; i++) stream_.Put(buffer[i]); } void WriteString(const Ch* str, SizeType length) { static const char hexDigits[] = "0123456789ABCDEF"; static const char escape[256] = { #define Z16 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 //0 1 2 3 4 5 6 7 8 9 A B C D E F 'u', 'u', 'u', 'u', 'u', 'u', 'u', 'u', 'b', 't', 'n', 'u', 'f', 'r', 'u', 'u', // 00 'u', 'u', 'u', 'u', 'u', 'u', 'u', 'u', 'u', 'u', 'u', 'u', 'u', 'u', 'u', 'u', // 10 0, 0, '"', 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, // 20 Z16, Z16, // 30~4F 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,'\\', 0, 0, 0, // 50 Z16, Z16, Z16, Z16, Z16, Z16, Z16, Z16, Z16, Z16 // 60~FF #undef Z16 }; stream_.Put('\"'); for (const Ch* p = str; p != str + length; ++p) { if ((sizeof(Ch) == 1 || *p < 256) && escape[(unsigned char)*p]) { stream_.Put('\\'); stream_.Put(escape[(unsigned char)*p]); if (escape[(unsigned char)*p] == 'u') { stream_.Put('0'); stream_.Put('0'); stream_.Put(hexDigits[(*p) >> 4]); stream_.Put(hexDigits[(*p) & 0xF]); } } else stream_.Put(*p); } stream_.Put('\"'); } void WriteStartObject() { stream_.Put('{'); } void WriteEndObject() { stream_.Put('}'); } void WriteStartArray() { stream_.Put('['); } void WriteEndArray() { stream_.Put(']'); } void Prefix(Type type) { (void)type; if (level_stack_.GetSize() != 0) { // this value is not at root Level* level = level_stack_.template Top(); if (level->valueCount > 0) { if (level->inArray) stream_.Put(','); // add comma if it is not the first element in array else // in object stream_.Put((level->valueCount % 2 == 0) ? ',' : ':'); } if (!level->inArray && level->valueCount % 2 == 0) RAPIDJSON_ASSERT(type == kStringType); // if it's in object, then even number should be a name level->valueCount++; } else RAPIDJSON_ASSERT(type == kObjectType || type == kArrayType); } Stream& stream_; internal::Stack level_stack_; private: // Prohibit assignment for VC C4512 warning Writer& operator=(const Writer& w); }; } // namespace rapidjson #ifdef _MSC_VER #pragma warning(pop) #endif #endif // RAPIDJSON_RAPIDJSON_H_