// // MessagePack for C++ deserializing routine // // Copyright (C) 2008-2015 FURUHASHI Sadayuki and KONDO Takatoshi // // Distributed under the Boost Software License, Version 1.0. // (See accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) // #ifndef MSGPACK_UNPACK_HPP #define MSGPACK_UNPACK_HPP #include "msgpack/versioning.hpp" #include "object.hpp" #include "zone.hpp" #include "unpack_define.h" #include "cpp_config.hpp" #include "sysdep.h" #include #include #if !defined(MSGPACK_USE_CPP03) #include #endif #if defined(_MSC_VER) // avoiding confliction std::max, std::min, and macro in windows.h #ifndef NOMINMAX #define NOMINMAX #endif #endif // defined(_MSC_VER) #ifdef _msgpack_atomic_counter_header #include _msgpack_atomic_counter_header #endif const size_t COUNTER_SIZE = sizeof(_msgpack_atomic_counter_t); #ifndef MSGPACK_UNPACKER_INIT_BUFFER_SIZE #define MSGPACK_UNPACKER_INIT_BUFFER_SIZE (64*1024) #endif #ifndef MSGPACK_UNPACKER_RESERVE_SIZE #define MSGPACK_UNPACKER_RESERVE_SIZE (32*1024) #endif // backward compatibility #ifndef MSGPACK_UNPACKER_DEFAULT_INITIAL_BUFFER_SIZE #define MSGPACK_UNPACKER_DEFAULT_INITIAL_BUFFER_SIZE MSGPACK_UNPACKER_INIT_BUFFER_SIZE #endif namespace msgpack { /// @cond MSGPACK_API_VERSION_NAMESPACE(v1) { /// @endcond /// The type of reference or copy judging function. /** * @param type msgpack data type. * @param size msgpack data size. * @param user_data The user_data that is set by msgpack::unpack functions. * * @return If the data should be referenced, then return true, otherwise (should be copied) false. * * This function is called when unpacking STR, BIN, or EXT. * */ typedef bool (*unpack_reference_func)(msgpack::type::object_type type, std::size_t size, void* user_data); struct unpack_error : public std::runtime_error { explicit unpack_error(const std::string& msg) :std::runtime_error(msg) {} #if !defined(MSGPACK_USE_CPP03) explicit unpack_error(const char* msg): std::runtime_error(msg) {} #endif // !defined(MSGPACK_USE_CPP03) }; struct parse_error : public unpack_error { explicit parse_error(const std::string& msg) :unpack_error(msg) {} #if !defined(MSGPACK_USE_CPP03) explicit parse_error(const char* msg) :unpack_error(msg) {} #endif // !defined(MSGPACK_USE_CPP03) }; struct insufficient_bytes : public unpack_error { explicit insufficient_bytes(const std::string& msg) :unpack_error(msg) {} #if !defined(MSGPACK_USE_CPP03) explicit insufficient_bytes(const char* msg) :unpack_error(msg) {} #endif // !defined(MSGPACK_USE_CPP03) }; struct size_overflow : public unpack_error { explicit size_overflow(const std::string& msg) :unpack_error(msg) {} #if !defined(MSGPACK_USE_CPP03) explicit size_overflow(const char* msg) :unpack_error(msg) {} #endif }; struct array_size_overflow : public size_overflow { array_size_overflow(const std::string& msg) :size_overflow(msg) {} #if !defined(MSGPACK_USE_CPP03) array_size_overflow(const char* msg) :size_overflow(msg) {} #endif }; struct map_size_overflow : public size_overflow { map_size_overflow(const std::string& msg) :size_overflow(msg) {} #if !defined(MSGPACK_USE_CPP03) map_size_overflow(const char* msg) :size_overflow(msg) {} #endif }; struct str_size_overflow : public size_overflow { str_size_overflow(const std::string& msg) :size_overflow(msg) {} #if !defined(MSGPACK_USE_CPP03) str_size_overflow(const char* msg) :size_overflow(msg) {} #endif }; struct bin_size_overflow : public size_overflow { bin_size_overflow(const std::string& msg) :size_overflow(msg) {} #if !defined(MSGPACK_USE_CPP03) bin_size_overflow(const char* msg) :size_overflow(msg) {} #endif }; struct ext_size_overflow : public size_overflow { ext_size_overflow(const std::string& msg) :size_overflow(msg) {} #if !defined(MSGPACK_USE_CPP03) ext_size_overflow(const char* msg) :size_overflow(msg) {} #endif }; struct depth_size_overflow : public size_overflow { depth_size_overflow(const std::string& msg) :size_overflow(msg) {} #if !defined(MSGPACK_USE_CPP03) depth_size_overflow(const char* msg) :size_overflow(msg) {} #endif }; class unpack_limit { public: unpack_limit( std::size_t array = 0xffffffff, std::size_t map = 0xffffffff, std::size_t str = 0xffffffff, std::size_t bin = 0xffffffff, std::size_t ext = 0xffffffff, std::size_t depth = 0xffffffff) :array_(array), map_(map), str_(str), bin_(bin), ext_(ext), depth_(depth) {} std::size_t array() const { return array_; } std::size_t map() const { return map_; } std::size_t str() const { return str_; } std::size_t bin() const { return bin_; } std::size_t ext() const { return ext_; } std::size_t depth() const { return depth_; } private: std::size_t array_; std::size_t map_; std::size_t str_; std::size_t bin_; std::size_t ext_; std::size_t depth_; }; namespace detail { class unpack_user { public: unpack_user(unpack_reference_func f = nullptr, void* user_data = nullptr, unpack_limit const& limit = unpack_limit()) :m_func(f), m_user_data(user_data), m_limit(limit) {} msgpack::zone const& zone() const { return *m_zone; } msgpack::zone& zone() { return *m_zone; } void set_zone(msgpack::zone& zone) { m_zone = &zone; } bool referenced() const { return m_referenced; } void set_referenced(bool referenced) { m_referenced = referenced; } unpack_reference_func reference_func() const { return m_func; } void* user_data() const { return m_user_data; } unpack_limit const& limit() const { return m_limit; } unpack_limit& limit() { return m_limit; } private: msgpack::zone* m_zone; bool m_referenced; unpack_reference_func m_func; void* m_user_data; unpack_limit m_limit; }; inline void unpack_uint8(uint8_t d, msgpack::object& o) { o.type = msgpack::type::POSITIVE_INTEGER; o.via.u64 = d; } inline void unpack_uint16(uint16_t d, msgpack::object& o) { o.type = msgpack::type::POSITIVE_INTEGER; o.via.u64 = d; } inline void unpack_uint32(uint32_t d, msgpack::object& o) { o.type = msgpack::type::POSITIVE_INTEGER; o.via.u64 = d; } inline void unpack_uint64(uint64_t d, msgpack::object& o) { o.type = msgpack::type::POSITIVE_INTEGER; o.via.u64 = d; } inline void unpack_int8(int8_t d, msgpack::object& o) { if(d >= 0) { o.type = msgpack::type::POSITIVE_INTEGER; o.via.u64 = d; } else { o.type = msgpack::type::NEGATIVE_INTEGER; o.via.i64 = d; } } inline void unpack_int16(int16_t d, msgpack::object& o) { if(d >= 0) { o.type = msgpack::type::POSITIVE_INTEGER; o.via.u64 = d; } else { o.type = msgpack::type::NEGATIVE_INTEGER; o.via.i64 = d; } } inline void unpack_int32(int32_t d, msgpack::object& o) { if(d >= 0) { o.type = msgpack::type::POSITIVE_INTEGER; o.via.u64 = d; } else { o.type = msgpack::type::NEGATIVE_INTEGER; o.via.i64 = d; } } inline void unpack_int64(int64_t d, msgpack::object& o) { if(d >= 0) { o.type = msgpack::type::POSITIVE_INTEGER; o.via.u64 = d; } else { o.type = msgpack::type::NEGATIVE_INTEGER; o.via.i64 = d; } } inline void unpack_float(float d, msgpack::object& o) { o.type = msgpack::type::FLOAT; o.via.f64 = d; } inline void unpack_double(double d, msgpack::object& o) { o.type = msgpack::type::FLOAT; o.via.f64 = d; } inline void unpack_nil(msgpack::object& o) { o.type = msgpack::type::NIL; } inline void unpack_true(msgpack::object& o) { o.type = msgpack::type::BOOLEAN; o.via.boolean = true; } inline void unpack_false(msgpack::object& o) { o.type = msgpack::type::BOOLEAN; o.via.boolean = false; } struct unpack_array { void operator()(unpack_user& u, uint32_t n, msgpack::object& o) const { if (n > u.limit().array()) throw msgpack::array_size_overflow("array size overflow"); o.type = msgpack::type::ARRAY; o.via.array.size = 0; o.via.array.ptr = static_cast(u.zone().allocate_align(n*sizeof(msgpack::object))); } }; inline void unpack_array_item(msgpack::object& c, msgpack::object const& o) { #if defined(__GNUC__) && !defined(__clang__) std::memcpy(&c.via.array.ptr[c.via.array.size++], &o, sizeof(msgpack::object)); #else /* __GNUC__ && !__clang__ */ c.via.array.ptr[c.via.array.size++] = o; #endif /* __GNUC__ && !__clang__ */ } struct unpack_map { void operator()(unpack_user& u, uint32_t n, msgpack::object& o) const { if (n > u.limit().map()) throw msgpack::map_size_overflow("map size overflow"); o.type = msgpack::type::MAP; o.via.map.size = 0; o.via.map.ptr = static_cast(u.zone().allocate_align(n*sizeof(msgpack::object_kv))); } }; inline void unpack_map_item(msgpack::object& c, msgpack::object const& k, msgpack::object const& v) { #if defined(__GNUC__) && !defined(__clang__) std::memcpy(&c.via.map.ptr[c.via.map.size].key, &k, sizeof(msgpack::object)); std::memcpy(&c.via.map.ptr[c.via.map.size].val, &v, sizeof(msgpack::object)); #else /* __GNUC__ && !__clang__ */ c.via.map.ptr[c.via.map.size].key = k; c.via.map.ptr[c.via.map.size].val = v; #endif /* __GNUC__ && !__clang__ */ ++c.via.map.size; } inline void unpack_str(unpack_user& u, const char* p, uint32_t l, msgpack::object& o) { o.type = msgpack::type::STR; if (u.reference_func() && u.reference_func()(o.type, l, u.user_data())) { o.via.str.ptr = p; u.set_referenced(true); } else { if (l > u.limit().str()) throw msgpack::str_size_overflow("str size overflow"); char* tmp = static_cast(u.zone().allocate_align(l)); std::memcpy(tmp, p, l); o.via.str.ptr = tmp; } o.via.str.size = l; } inline void unpack_bin(unpack_user& u, const char* p, uint32_t l, msgpack::object& o) { o.type = msgpack::type::BIN; if (u.reference_func() && u.reference_func()(o.type, l, u.user_data())) { o.via.bin.ptr = p; u.set_referenced(true); } else { if (l > u.limit().bin()) throw msgpack::bin_size_overflow("bin size overflow"); char* tmp = static_cast(u.zone().allocate_align(l)); std::memcpy(tmp, p, l); o.via.bin.ptr = tmp; } o.via.bin.size = l; } inline void unpack_ext(unpack_user& u, const char* p, std::size_t l, msgpack::object& o) { o.type = msgpack::type::EXT; if (u.reference_func() && u.reference_func()(o.type, l, u.user_data())) { o.via.ext.ptr = p; u.set_referenced(true); } else { if (l > u.limit().ext()) throw msgpack::ext_size_overflow("ext size overflow"); char* tmp = static_cast(u.zone().allocate_align(l)); std::memcpy(tmp, p, l); o.via.ext.ptr = tmp; } o.via.ext.size = static_cast(l - 1); } class unpack_stack { public: msgpack::object const& obj() const { return m_obj; } msgpack::object& obj() { return m_obj; } void set_obj(msgpack::object const& obj) { m_obj = obj; } std::size_t count() const { return m_count; } void set_count(std::size_t count) { m_count = count; } std::size_t decr_count() { return --m_count; } uint32_t container_type() const { return m_container_type; } void set_container_type(uint32_t container_type) { m_container_type = container_type; } msgpack::object const& map_key() const { return m_map_key; } void set_map_key(msgpack::object const& map_key) { m_map_key = map_key; } private: msgpack::object m_obj; std::size_t m_count; uint32_t m_container_type; msgpack::object m_map_key; }; inline void init_count(void* buffer) { #if defined(MSGPACK_USE_CPP03) *reinterpret_cast(buffer) = 1; #else // defined(MSGPACK_USE_CPP03) new (buffer) std::atomic(1); #endif // defined(MSGPACK_USE_CPP03) } inline void decr_count(void* buffer) { #if defined(MSGPACK_USE_CPP03) if(_msgpack_sync_decr_and_fetch(reinterpret_cast(buffer)) == 0) { free(buffer); } #else // defined(MSGPACK_USE_CPP03) if (--*reinterpret_cast*>(buffer) == 0) { free(buffer); } #endif // defined(MSGPACK_USE_CPP03) } inline void incr_count(void* buffer) { #if defined(MSGPACK_USE_CPP03) _msgpack_sync_incr_and_fetch(reinterpret_cast(buffer)); #else // defined(MSGPACK_USE_CPP03) ++*reinterpret_cast*>(buffer); #endif // defined(MSGPACK_USE_CPP03) } #if defined(MSGPACK_USE_CPP03) inline _msgpack_atomic_counter_t get_count(void* buffer) { return *reinterpret_cast(buffer); } #else // defined(MSGPACK_USE_CPP03) inline std::atomic const& get_count(void* buffer) { return *reinterpret_cast*>(buffer); } #endif // defined(MSGPACK_USE_CPP03) struct fix_tag { char f1[65]; // FIXME unique size is required. or use is_same meta function. }; template struct value { typedef T type; }; template <> struct value { typedef uint32_t type; }; template inline void load(uint32_t& dst, const char* n, typename msgpack::enable_if::type* = nullptr) { dst = static_cast(*reinterpret_cast(n)) & 0x0f; } template inline void load(T& dst, const char* n, typename msgpack::enable_if::type* = nullptr) { dst = static_cast(*reinterpret_cast(n)); } template inline void load(T& dst, const char* n, typename msgpack::enable_if::type* = nullptr) { _msgpack_load16(T, n, &dst); } template inline void load(T& dst, const char* n, typename msgpack::enable_if::type* = nullptr) { _msgpack_load32(T, n, &dst); } template inline void load(T& dst, const char* n, typename msgpack::enable_if::type* = nullptr) { _msgpack_load64(T, n, &dst); } class context { public: context(unpack_reference_func f, void* user_data, unpack_limit const& limit) :m_trail(0), m_user(f, user_data, limit), m_cs(MSGPACK_CS_HEADER) { m_stack.reserve(MSGPACK_EMBED_STACK_SIZE); m_stack.push_back(unpack_stack()); } void init() { m_cs = MSGPACK_CS_HEADER; m_trail = 0; m_stack.resize(1); m_stack[0].set_obj(msgpack::object()); } msgpack::object const& data() const { return m_stack[0].obj(); } unpack_user& user() { return m_user; } unpack_user const& user() const { return m_user; } int execute(const char* data, std::size_t len, std::size_t& off); private: template static uint32_t next_cs(T p) { return static_cast(*p) & 0x1f; } template int push_aggregate( Func const& f, uint32_t container_type, msgpack::object& obj, const char* load_pos, std::size_t& off) { typename value::type tmp; load(tmp, load_pos); f(m_user, tmp, m_stack.back().obj()); if(tmp == 0) { obj = m_stack.back().obj(); int ret = push_proc(obj, off); if (ret != 0) return ret; } else { m_stack.back().set_container_type(container_type); m_stack.back().set_count(tmp); if (m_stack.size() <= m_user.limit().depth()) { m_stack.push_back(unpack_stack()); } else { throw msgpack::depth_size_overflow("depth size overflow"); } m_cs = MSGPACK_CS_HEADER; ++m_current; } return 0; } int push_item(msgpack::object& obj) { bool finish = false; while (!finish) { if(m_stack.size() == 1) { return 1; } unpack_stack& sp = *(m_stack.end() - 2); switch(sp.container_type()) { case MSGPACK_CT_ARRAY_ITEM: unpack_array_item(sp.obj(), obj); if(sp.decr_count() == 0) { obj = sp.obj(); m_stack.pop_back(); } else { finish = true; } break; case MSGPACK_CT_MAP_KEY: sp.set_map_key(obj); sp.set_container_type(MSGPACK_CT_MAP_VALUE); finish = true; break; case MSGPACK_CT_MAP_VALUE: unpack_map_item(sp.obj(), sp.map_key(), obj); if(sp.decr_count() == 0) { obj = sp.obj(); m_stack.pop_back(); } else { sp.set_container_type(MSGPACK_CT_MAP_KEY); finish = true; } break; default: return -1; } } return 0; } int push_proc(msgpack::object& obj, std::size_t& off) { int ret = push_item(obj); if (ret > 0) { m_stack[0].set_obj(obj); ++m_current; /*printf("-- finish --\n"); */ off = m_current - m_start; } else if (ret < 0) { off = m_current - m_start; } else { m_cs = MSGPACK_CS_HEADER; ++m_current; } return ret; } template static void check_ext_size(std::size_t /*size*/) { } private: char const* m_start; char const* m_current; std::size_t m_trail; unpack_user m_user; uint32_t m_cs; std::vector m_stack; }; template <> inline void context::check_ext_size<4>(std::size_t size) { if (size == 0xffffffff) throw msgpack::ext_size_overflow("ext size overflow"); } inline int context::execute(const char* data, std::size_t len, std::size_t& off) { assert(len >= off); m_start = data; m_current = data + off; const char* const pe = data + len; const char* n = nullptr; msgpack::object obj; if(m_current == pe) { off = m_current - m_start; return 0; } bool fixed_trail_again = false; do { if (m_cs == MSGPACK_CS_HEADER) { fixed_trail_again = false; int selector = *reinterpret_cast(m_current); if (0x00 <= selector && selector <= 0x7f) { // Positive Fixnum unpack_uint8(*reinterpret_cast(m_current), obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } else if(0xe0 <= selector && selector <= 0xff) { // Negative Fixnum unpack_int8(*reinterpret_cast(m_current), obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } else if (0xc4 <= selector && selector <= 0xdf) { const uint32_t trail[] = { 1, // bin 8 0xc4 2, // bin 16 0xc5 4, // bin 32 0xc6 1, // ext 8 0xc7 2, // ext 16 0xc8 4, // ext 32 0xc9 4, // float 32 0xca 8, // float 64 0xcb 1, // uint 8 0xcc 2, // uint 16 0xcd 4, // uint 32 0xce 8, // uint 64 0xcf 1, // int 8 0xd0 2, // int 16 0xd1 4, // int 32 0xd2 8, // int 64 0xd3 2, // fixext 1 0xd4 3, // fixext 2 0xd5 5, // fixext 4 0xd6 9, // fixext 8 0xd7 17,// fixext 16 0xd8 1, // str 8 0xd9 2, // str 16 0xda 4, // str 32 0xdb 2, // array 16 0xdc 4, // array 32 0xdd 2, // map 16 0xde 4, // map 32 0xdf }; m_trail = trail[selector - 0xc4]; m_cs = next_cs(m_current); fixed_trail_again = true; } else if(0xa0 <= selector && selector <= 0xbf) { // FixStr m_trail = static_cast(*m_current) & 0x1f; if(m_trail == 0) { unpack_str(m_user, n, static_cast(m_trail), obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } else { m_cs = MSGPACK_ACS_STR_VALUE; fixed_trail_again = true; } } else if(0x90 <= selector && selector <= 0x9f) { // FixArray int ret = push_aggregate( unpack_array(), MSGPACK_CT_ARRAY_ITEM, obj, m_current, off); if (ret != 0) return ret; } else if(0x80 <= selector && selector <= 0x8f) { // FixMap int ret = push_aggregate( unpack_map(), MSGPACK_CT_MAP_KEY, obj, m_current, off); if (ret != 0) return ret; } else if(selector == 0xc2) { // false unpack_false(obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } else if(selector == 0xc3) { // true unpack_true(obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } else if(selector == 0xc0) { // nil unpack_nil(obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } else { off = m_current - m_start; return -1; } // end MSGPACK_CS_HEADER } if (m_cs != MSGPACK_CS_HEADER || fixed_trail_again) { if (fixed_trail_again) { ++m_current; fixed_trail_again = false; } if(static_cast(pe - m_current) < m_trail) { off = m_current - m_start; return 0; } n = m_current; m_current += m_trail - 1; switch(m_cs) { //case MSGPACK_CS_ //case MSGPACK_CS_ case MSGPACK_CS_FLOAT: { union { uint32_t i; float f; } mem; load(mem.i, n); unpack_float(mem.f, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_CS_DOUBLE: { union { uint64_t i; double f; } mem; load(mem.i, n); #if defined(TARGET_OS_IPHONE) // ok #elif defined(__arm__) && !(__ARM_EABI__) // arm-oabi // https://github.com/msgpack/msgpack-perl/pull/1 mem.i = (mem.i & 0xFFFFFFFFUL) << 32UL | (mem.i >> 32UL); #endif unpack_double(mem.f, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_CS_UINT_8: { uint8_t tmp; load(tmp, n); unpack_uint8(tmp, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_CS_UINT_16: { uint16_t tmp; load(tmp, n); unpack_uint16(tmp, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_CS_UINT_32: { uint32_t tmp; load(tmp, n); unpack_uint32(tmp, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_CS_UINT_64: { uint64_t tmp; load(tmp, n); unpack_uint64(tmp, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_CS_INT_8: { int8_t tmp; load(tmp, n); unpack_int8(tmp, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_CS_INT_16: { int16_t tmp; load(tmp, n); unpack_int16(tmp, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_CS_INT_32: { int32_t tmp; load(tmp, n); unpack_int32(tmp, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_CS_INT_64: { int64_t tmp; load(tmp, n); unpack_int64(tmp, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_CS_FIXEXT_1: { unpack_ext(m_user, n, 1+1, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_CS_FIXEXT_2: { unpack_ext(m_user, n, 2+1, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_CS_FIXEXT_4: { unpack_ext(m_user, n, 4+1, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_CS_FIXEXT_8: { unpack_ext(m_user, n, 8+1, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_CS_FIXEXT_16: { unpack_ext(m_user, n, 16+1, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_CS_STR_8: { uint8_t tmp; load(tmp, n); m_trail = tmp; if(m_trail == 0) { unpack_str(m_user, n, static_cast(m_trail), obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } else { m_cs = MSGPACK_ACS_STR_VALUE; fixed_trail_again = true; } } break; case MSGPACK_CS_BIN_8: { uint8_t tmp; load(tmp, n); m_trail = tmp; if(m_trail == 0) { unpack_bin(m_user, n, static_cast(m_trail), obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } else { m_cs = MSGPACK_ACS_BIN_VALUE; fixed_trail_again = true; } } break; case MSGPACK_CS_EXT_8: { uint8_t tmp; load(tmp, n); m_trail = tmp + 1; if(m_trail == 0) { unpack_ext(m_user, n, m_trail, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } else { m_cs = MSGPACK_ACS_EXT_VALUE; fixed_trail_again = true; } } break; case MSGPACK_CS_STR_16: { uint16_t tmp; load(tmp, n); m_trail = tmp; if(m_trail == 0) { unpack_str(m_user, n, static_cast(m_trail), obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } else { m_cs = MSGPACK_ACS_STR_VALUE; fixed_trail_again = true; } } break; case MSGPACK_CS_BIN_16: { uint16_t tmp; load(tmp, n); m_trail = tmp; if(m_trail == 0) { unpack_bin(m_user, n, static_cast(m_trail), obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } else { m_cs = MSGPACK_ACS_BIN_VALUE; fixed_trail_again = true; } } break; case MSGPACK_CS_EXT_16: { uint16_t tmp; load(tmp, n); m_trail = tmp + 1; if(m_trail == 0) { unpack_ext(m_user, n, m_trail, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } else { m_cs = MSGPACK_ACS_EXT_VALUE; fixed_trail_again = true; } } break; case MSGPACK_CS_STR_32: { uint32_t tmp; load(tmp, n); m_trail = tmp; if(m_trail == 0) { unpack_str(m_user, n, static_cast(m_trail), obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } else { m_cs = MSGPACK_ACS_STR_VALUE; fixed_trail_again = true; } } break; case MSGPACK_CS_BIN_32: { uint32_t tmp; load(tmp, n); m_trail = tmp; if(m_trail == 0) { unpack_bin(m_user, n, static_cast(m_trail), obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } else { m_cs = MSGPACK_ACS_BIN_VALUE; fixed_trail_again = true; } } break; case MSGPACK_CS_EXT_32: { uint32_t tmp; load(tmp, n); check_ext_size(tmp); m_trail = tmp; ++m_trail; if(m_trail == 0) { unpack_ext(m_user, n, m_trail, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } else { m_cs = MSGPACK_ACS_EXT_VALUE; fixed_trail_again = true; } } break; case MSGPACK_ACS_STR_VALUE: { unpack_str(m_user, n, static_cast(m_trail), obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_ACS_BIN_VALUE: { unpack_bin(m_user, n, static_cast(m_trail), obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_ACS_EXT_VALUE: { unpack_ext(m_user, n, m_trail, obj); int ret = push_proc(obj, off); if (ret != 0) return ret; } break; case MSGPACK_CS_ARRAY_16: { int ret = push_aggregate( unpack_array(), MSGPACK_CT_ARRAY_ITEM, obj, n, off); if (ret != 0) return ret; } break; case MSGPACK_CS_ARRAY_32: { /* FIXME security guard */ int ret = push_aggregate( unpack_array(), MSGPACK_CT_ARRAY_ITEM, obj, n, off); if (ret != 0) return ret; } break; case MSGPACK_CS_MAP_16: { int ret = push_aggregate( unpack_map(), MSGPACK_CT_MAP_KEY, obj, n, off); if (ret != 0) return ret; } break; case MSGPACK_CS_MAP_32: { /* FIXME security guard */ int ret = push_aggregate( unpack_map(), MSGPACK_CT_MAP_KEY, obj, n, off); if (ret != 0) return ret; } break; default: off = m_current - m_start; return -1; } } } while(m_current != pe); off = m_current - m_start; return 0; } } // detail typedef object_handle unpacked; /// Unpacking class for a stream deserialization. class unpacker { public: /// Constructor /** * @param referenced If the unpacked object contains reference of the buffer, then set as true, otherwise false. * @param f A judging function that msgpack::object refer to the buffer. * @param user_data This parameter is passed to f. * @param initial_buffer_size The memory size to allocate when unpacker is constructed. * @param limit The size limit information of msgpack::object. * */ unpacker(unpack_reference_func f = &unpacker::default_reference_func, void* user_data = nullptr, std::size_t initial_buffer_size = MSGPACK_UNPACKER_INIT_BUFFER_SIZE, unpack_limit const& limit = unpack_limit()); #if !defined(MSGPACK_USE_CPP03) unpacker(unpacker&& other); unpacker& operator=(unpacker&& other); #endif // !defined(MSGPACK_USE_CPP03) ~unpacker(); public: /// Reserve a buffer memory. /** * @param size The size of allocating memory. * * After returning this function, buffer_capacity() returns at least 'size'. * See: * https://github.com/msgpack/msgpack-c/wiki/v1_1_cpp_unpacker#msgpack-controls-a-buffer */ void reserve_buffer(std::size_t size = MSGPACK_UNPACKER_RESERVE_SIZE); /// Get buffer pointer. /** * You need to care about the memory is enable between buffer() and buffer() + buffer_capacity() * See: * https://github.com/msgpack/msgpack-c/wiki/v1_1_cpp_unpacker#msgpack-controls-a-buffer */ char* buffer(); /// Get buffer capacity. /** * @return The memory size that you can write. * * See: * https://github.com/msgpack/msgpack-c/wiki/v1_1_cpp_unpacker#msgpack-controls-a-buffer */ std::size_t buffer_capacity() const; /// Notify a buffer consumed information to msgpack::unpacker. /** * @param size The size of memory that you consumed. * * After copying the data to the memory that is pointed by buffer(), you need to call the * function to notify how many bytes are consumed. Then you can call next() functions. * * See: * https://github.com/msgpack/msgpack-c/wiki/v1_1_cpp_unpacker#msgpack-controls-a-buffer */ void buffer_consumed(std::size_t size); /// Unpack one msgpack::object. [obsolete] /** * * @param result The object that contains unpacked data. * * @return If one msgpack::object is unpacked, then return true, if msgpack::object is incomplete * and additional data is required, then return false. If data format is invalid, throw * msgpack::parse_error. * * See: * https://github.com/msgpack/msgpack-c/wiki/v1_1_cpp_unpacker#msgpack-controls-a-buffer * This function is obsolete. Use the reference inteface version of next() function instead of * the pointer interface version. */ bool next(unpacked* result); /// Unpack one msgpack::object. /** * * @param result The object that contains unpacked data. * @param referenced If the unpacked object contains reference of the buffer, * then set as true, otherwise false. * * @return If one msgpack::object is unpacked, then return true, if msgpack::object is incomplete * and additional data is required, then return false. If data format is invalid, throw * msgpack::parse_error. * * See: * https://github.com/msgpack/msgpack-c/wiki/v1_1_cpp_unpacker#msgpack-controls-a-buffer */ bool next(unpacked& result, bool& referenced); /// Unpack one msgpack::object. /** * * @param result The object that contains unpacked data. * * @return If one msgpack::object is unpacked, then return true, if msgpack::object is incomplete * and additional data is required, then return false. If data format is invalid, throw * msgpack::parse_error. * * See: * https://github.com/msgpack/msgpack-c/wiki/v1_1_cpp_unpacker#msgpack-controls-a-buffer */ bool next(unpacked& result); /// Get message size. /** * @return Returns parsed_size() + nonparsed_size() */ std::size_t message_size() const; /*! for backward compatibility */ bool execute(); /*! for backward compatibility */ msgpack::object const& data(); /*! for backward compatibility */ msgpack::zone* release_zone(); /*! for backward compatibility */ void reset_zone(); /*! for backward compatibility */ void reset(); public: /// Get parsed message size. /** * @return Parsed message size. * * This function is usable when non-MessagePack message follows after * MessagePack message. */ std::size_t parsed_size() const; /// Get the address that is not parsed in the buffer. /** * @return Address of the buffer that is not parsed * * This function is usable when non-MessagePack message follows after * MessagePack message. */ char* nonparsed_buffer(); /// Get the size of the buffer that is not parsed. /** * @return Size of the buffer that is not parsed * * This function is usable when non-MessagePack message follows after * MessagePack message. */ std::size_t nonparsed_size() const; /// Skip the specified size of non-parsed buffer. /** * @param size to skip * * Note that the `size' argument must be smaller than nonparsed_size(). * This function is usable when non-MessagePack message follows after * MessagePack message. */ void skip_nonparsed_buffer(std::size_t size); /// Remove nonparsed buffer and reset the current position as a new start point. /** * This function is usable when non-MessagePack message follows after * MessagePack message. */ void remove_nonparsed_buffer(); private: void expand_buffer(std::size_t size); int execute_imp(); bool flush_zone(); static bool default_reference_func(msgpack::type::object_type type, std::size_t len, void*); private: char* m_buffer; std::size_t m_used; std::size_t m_free; std::size_t m_off; std::size_t m_parsed; msgpack::unique_ptr m_z; std::size_t m_initial_buffer_size; detail::context m_ctx; #if defined(MSGPACK_USE_CPP03) private: unpacker(const unpacker&); unpacker& operator=(const unpacker&); #else // defined(MSGPACK_USE_CPP03) unpacker(const unpacker&) = delete; unpacker& operator=(const unpacker&) = delete; #endif // defined(MSGPACK_USE_CPP03) }; /// Unpack msgpack::object from a buffer. /** * @param data The pointer to the buffer. * @param len The length of the buffer. * @param off The offset position of the buffer. It is read and overwritten. * @param referenced If the unpacked object contains reference of the buffer, then set as true, otherwise false. * @param f A judging function that msgpack::object refer to the buffer. * @param user_data This parameter is passed to f. * @param limit The size limit information of msgpack::object. * * @return unpacked object that contains unpacked data. * */ unpacked unpack( const char* data, std::size_t len, std::size_t& off, bool& referenced, unpack_reference_func f = nullptr, void* user_data = nullptr, unpack_limit const& limit = unpack_limit()); /// Unpack msgpack::object from a buffer. /** * @param data The pointer to the buffer. * @param len The length of the buffer. * @param off The offset position of the buffer. It is read and overwritten. * @param f A judging function that msgpack::object refer to the buffer. * @param user_data This parameter is passed to f. * @param limit The size limit information of msgpack::object. * * @return unpacked object that contains unpacked data. * */ unpacked unpack( const char* data, std::size_t len, std::size_t& off, unpack_reference_func f = nullptr, void* user_data = nullptr, unpack_limit const& limit = unpack_limit()); /// Unpack msgpack::object from a buffer. /** * @param data The pointer to the buffer. * @param len The length of the buffer. * @param referenced If the unpacked object contains reference of the buffer, then set as true, otherwise false. * @param f A judging function that msgpack::object refer to the buffer. * @param user_data This parameter is passed to f. * @param limit The size limit information of msgpack::object. * * @return unpacked object that contains unpacked data. * */ unpacked unpack( const char* data, std::size_t len, bool& referenced, unpack_reference_func f = nullptr, void* user_data = nullptr, unpack_limit const& limit = unpack_limit()); /// Unpack msgpack::object from a buffer. /** * @param data The pointer to the buffer. * @param len The length of the buffer. * @param f A judging function that msgpack::object refer to the buffer. * @param user_data This parameter is passed to f. * @param limit The size limit information of msgpack::object. * * @return unpacked object that contains unpacked data. * */ unpacked unpack( const char* data, std::size_t len, unpack_reference_func f = nullptr, void* user_data = nullptr, unpack_limit const& limit = unpack_limit()); /// Unpack msgpack::object from a buffer. /** * @param result The object that contains unpacked data. * @param data The pointer to the buffer. * @param len The length of the buffer. * @param off The offset position of the buffer. It is read and overwritten. * @param referenced If the unpacked object contains reference of the buffer, then set as true, otherwise false. * @param f A judging function that msgpack::object refer to the buffer. * @param user_data This parameter is passed to f. * @param limit The size limit information of msgpack::object. * * */ void unpack(unpacked& result, const char* data, std::size_t len, std::size_t& off, bool& referenced, unpack_reference_func f = nullptr, void* user_data = nullptr, unpack_limit const& limit = unpack_limit()); /// Unpack msgpack::object from a buffer. /** * @param result The object that contains unpacked data. * @param data The pointer to the buffer. * @param len The length of the buffer. * @param off The offset position of the buffer. It is read and overwritten. * @param f A judging function that msgpack::object refer to the buffer. * @param user_data This parameter is passed to f. * @param limit The size limit information of msgpack::object. * * */ void unpack(unpacked& result, const char* data, std::size_t len, std::size_t& off, unpack_reference_func f = nullptr, void* user_data = nullptr, unpack_limit const& limit = unpack_limit()); /// Unpack msgpack::object from a buffer. /** * @param result The object that contains unpacked data. * @param data The pointer to the buffer. * @param len The length of the buffer. * @param referenced If the unpacked object contains reference of the buffer, then set as true, otherwise false. * @param f A judging function that msgpack::object refer to the buffer. * @param user_data This parameter is passed to f. * @param limit The size limit information of msgpack::object. * * */ void unpack(unpacked& result, const char* data, std::size_t len, bool& referenced, unpack_reference_func f = nullptr, void* user_data = nullptr, unpack_limit const& limit = unpack_limit()); /// Unpack msgpack::object from a buffer. /** * @param result The object that contains unpacked data. * @param data The pointer to the buffer. * @param len The length of the buffer. * @param f A judging function that msgpack::object refer to the buffer. * @param user_data This parameter is passed to f. * @param limit The size limit information of msgpack::object. * * */ void unpack(unpacked& result, const char* data, std::size_t len, unpack_reference_func f = nullptr, void* user_data = nullptr, unpack_limit const& limit = unpack_limit()); /// Unpack msgpack::object from a buffer. /** * @param z The msgpack::zone that is used as a memory of unpacked msgpack objects. * @param data The pointer to the buffer. * @param len The length of the buffer. * @param off The offset position of the buffer. It is read and overwritten. * @param referenced If the unpacked object contains reference of the buffer, then set as true, otherwise false. * @param f A judging function that msgpack::object refer to the buffer. * @param user_data This parameter is passed to f. * @param limit The size limit information of msgpack::object. * * @return msgpack::object that contains unpacked data. * */ msgpack::object unpack( msgpack::zone& z, const char* data, std::size_t len, std::size_t& off, bool& referenced, unpack_reference_func f = nullptr, void* user_data = nullptr, unpack_limit const& limit = unpack_limit()); /// Unpack msgpack::object from a buffer. /** * @param z The msgpack::zone that is used as a memory of unpacked msgpack objects. * @param data The pointer to the buffer. * @param len The length of the buffer. * @param off The offset position of the buffer. It is read and overwritten. * @param f A judging function that msgpack::object refer to the buffer. * @param user_data This parameter is passed to f. * @param limit The size limit information of msgpack::object. * * @return msgpack::object that contains unpacked data. * */ msgpack::object unpack( msgpack::zone& z, const char* data, std::size_t len, std::size_t& off, unpack_reference_func f = nullptr, void* user_data = nullptr, unpack_limit const& limit = unpack_limit()); /// Unpack msgpack::object from a buffer. /** * @param z The msgpack::zone that is used as a memory of unpacked msgpack objects. * @param data The pointer to the buffer. * @param len The length of the buffer. * @param referenced If the unpacked object contains reference of the buffer, then set as true, otherwise false. * @param f A judging function that msgpack::object refer to the buffer. * @param user_data This parameter is passed to f. * @param limit The size limit information of msgpack::object. * * @return msgpack::object that contains unpacked data. * */ msgpack::object unpack( msgpack::zone& z, const char* data, std::size_t len, bool& referenced, unpack_reference_func f = nullptr, void* user_data = nullptr, unpack_limit const& limit = unpack_limit()); /// Unpack msgpack::object from a buffer. /** * @param z The msgpack::zone that is used as a memory of unpacked msgpack objects. * @param data The pointer to the buffer. * @param len The length of the buffer. * @param f A judging function that msgpack::object refer to the buffer. * @param user_data This parameter is passed to f. * @param limit The size limit information of msgpack::object. * * @return msgpack::object that contains unpacked data. * */ msgpack::object unpack( msgpack::zone& z, const char* data, std::size_t len, unpack_reference_func f = nullptr, void* user_data = nullptr, unpack_limit const& limit = unpack_limit()); /// Unpack msgpack::object from a buffer. [obsolete] /** * @param result The object that contains unpacked data. * @param data The pointer to the buffer. * @param len The length of the buffer. * @param off The offset position of the buffer. It is read and overwritten. * @param referenced If the unpacked object contains reference of the buffer, then set as true, otherwise false. * @param f A judging function that msgpack::object refer to the buffer. * @param user_data This parameter is passed to f. * @param limit The size limit information of msgpack::object. * * This function is obsolete. Use the reference inteface version of unpack functions instead of the pointer interface version. */ void unpack(unpacked* result, const char* data, std::size_t len, std::size_t* off = nullptr, bool* referenced = nullptr, unpack_reference_func f = nullptr, void* user_data = nullptr, unpack_limit const& limit = unpack_limit()); // for internal use typedef enum { UNPACK_SUCCESS = 2, UNPACK_EXTRA_BYTES = 1, UNPACK_CONTINUE = 0, UNPACK_PARSE_ERROR = -1 } unpack_return; inline unpacker::unpacker(unpack_reference_func f, void* user_data, std::size_t initial_buffer_size, unpack_limit const& limit) :m_z(new msgpack::zone), m_ctx(f, user_data, limit) { if(initial_buffer_size < COUNTER_SIZE) { initial_buffer_size = COUNTER_SIZE; } char* buffer = static_cast(::malloc(initial_buffer_size)); if(!buffer) { throw std::bad_alloc(); } m_buffer = buffer; m_used = COUNTER_SIZE; m_free = initial_buffer_size - m_used; m_off = COUNTER_SIZE; m_parsed = 0; m_initial_buffer_size = initial_buffer_size; detail::init_count(m_buffer); m_ctx.init(); m_ctx.user().set_zone(*m_z); m_ctx.user().set_referenced(false); } #if !defined(MSGPACK_USE_CPP03) // Move constructor and move assignment operator inline unpacker::unpacker(unpacker&& other) :m_buffer(other.m_buffer), m_used(other.m_used), m_free(other.m_free), m_off(other.m_off), m_parsed(other.m_parsed), m_z(std::move(other.m_z)), m_initial_buffer_size(other.m_initial_buffer_size), m_ctx(other.m_ctx) { other.m_buffer = nullptr; } inline unpacker& unpacker::operator=(unpacker&& other) { this->~unpacker(); new (this) unpacker(std::move(other)); return *this; } #endif // !defined(MSGPACK_USE_CPP03) inline unpacker::~unpacker() { // These checks are required for move operations. if (m_buffer) detail::decr_count(m_buffer); } inline void unpacker::reserve_buffer(std::size_t size) { if(m_free >= size) return; expand_buffer(size); } inline void unpacker::expand_buffer(std::size_t size) { if(m_used == m_off && detail::get_count(m_buffer) == 1 && !m_ctx.user().referenced()) { // rewind buffer m_free += m_used - COUNTER_SIZE; m_used = COUNTER_SIZE; m_off = COUNTER_SIZE; if(m_free >= size) return; } if(m_off == COUNTER_SIZE) { std::size_t next_size = (m_used + m_free) * 2; // include COUNTER_SIZE while(next_size < size + m_used) { std::size_t tmp_next_size = next_size * 2; if (tmp_next_size <= next_size) { next_size = size + m_used; break; } next_size = tmp_next_size; } char* tmp = static_cast(::realloc(m_buffer, next_size)); if(!tmp) { throw std::bad_alloc(); } m_buffer = tmp; m_free = next_size - m_used; } else { std::size_t next_size = m_initial_buffer_size; // include COUNTER_SIZE std::size_t not_parsed = m_used - m_off; while(next_size < size + not_parsed + COUNTER_SIZE) { std::size_t tmp_next_size = next_size * 2; if (tmp_next_size <= next_size) { next_size = size + not_parsed + COUNTER_SIZE; break; } next_size = tmp_next_size; } char* tmp = static_cast(::malloc(next_size)); if(!tmp) { throw std::bad_alloc(); } detail::init_count(tmp); std::memcpy(tmp+COUNTER_SIZE, m_buffer + m_off, not_parsed); if(m_ctx.user().referenced()) { try { m_z->push_finalizer(&detail::decr_count, m_buffer); } catch (...) { ::free(tmp); throw; } m_ctx.user().set_referenced(false); } else { detail::decr_count(m_buffer); } m_buffer = tmp; m_used = not_parsed + COUNTER_SIZE; m_free = next_size - m_used; m_off = COUNTER_SIZE; } } inline char* unpacker::buffer() { return m_buffer + m_used; } inline std::size_t unpacker::buffer_capacity() const { return m_free; } inline void unpacker::buffer_consumed(std::size_t size) { m_used += size; m_free -= size; } inline bool unpacker::next(unpacked& result, bool& referenced) { referenced = false; int ret = execute_imp(); if(ret < 0) { throw msgpack::parse_error("parse error"); } if(ret == 0) { result.zone().reset(); result.set(object()); return false; } else { referenced = m_ctx.user().referenced(); result.zone().reset( release_zone() ); result.set(data()); reset(); return true; } } inline bool unpacker::next(unpacked& result) { bool referenced; return next(result, referenced); } inline bool unpacker::next(unpacked* result) { return next(*result); } inline bool unpacker::execute() { int ret = execute_imp(); if(ret < 0) { throw msgpack::parse_error("parse error"); } else if(ret == 0) { return false; } else { return true; } } inline int unpacker::execute_imp() { std::size_t off = m_off; int ret = m_ctx.execute(m_buffer, m_used, m_off); if(m_off > off) { m_parsed += m_off - off; } return ret; } inline msgpack::object const& unpacker::data() { return m_ctx.data(); } inline msgpack::zone* unpacker::release_zone() { if(!flush_zone()) { return nullptr; } msgpack::zone* r = new msgpack::zone; msgpack::zone* old = m_z.release(); m_z.reset(r); m_ctx.user().set_zone(*m_z); return old; } inline void unpacker::reset_zone() { m_z->clear(); } inline bool unpacker::flush_zone() { if(m_ctx.user().referenced()) { try { m_z->push_finalizer(&detail::decr_count, m_buffer); } catch (...) { return false; } m_ctx.user().set_referenced(false); detail::incr_count(m_buffer); } return true; } inline void unpacker::reset() { m_ctx.init(); // don't reset referenced flag m_parsed = 0; } inline std::size_t unpacker::message_size() const { return m_parsed - m_off + m_used; } inline std::size_t unpacker::parsed_size() const { return m_parsed; } inline char* unpacker::nonparsed_buffer() { return m_buffer + m_off; } inline std::size_t unpacker::nonparsed_size() const { return m_used - m_off; } inline void unpacker::skip_nonparsed_buffer(std::size_t size) { m_off += size; } inline void unpacker::remove_nonparsed_buffer() { m_used = m_off; } namespace detail { inline unpack_return unpack_imp(const char* data, std::size_t len, std::size_t& off, msgpack::zone& result_zone, msgpack::object& result, bool& referenced, unpack_reference_func f = nullptr, void* user_data = nullptr, unpack_limit const& limit = unpack_limit()) { std::size_t noff = off; if(len <= noff) { // FIXME return UNPACK_CONTINUE; } detail::context ctx(f, user_data, limit); ctx.init(); ctx.user().set_zone(result_zone); ctx.user().set_referenced(false); referenced = false; int e = ctx.execute(data, len, noff); if(e < 0) { return UNPACK_PARSE_ERROR; } referenced = ctx.user().referenced(); off = noff; if(e == 0) { return UNPACK_CONTINUE; } result = ctx.data(); if(noff < len) { return UNPACK_EXTRA_BYTES; } return UNPACK_SUCCESS; } } // detail // reference version inline unpacked unpack( const char* data, std::size_t len, std::size_t& off, bool& referenced, unpack_reference_func f, void* user_data, unpack_limit const& limit) { msgpack::object obj; msgpack::unique_ptr z(new msgpack::zone); referenced = false; std::size_t noff = off; unpack_return ret = detail::unpack_imp( data, len, noff, *z, obj, referenced, f, user_data, limit); switch(ret) { case UNPACK_SUCCESS: off = noff; return unpacked(obj, msgpack::move(z)); case UNPACK_EXTRA_BYTES: off = noff; return unpacked(obj, msgpack::move(z)); case UNPACK_CONTINUE: throw msgpack::insufficient_bytes("insufficient bytes"); case UNPACK_PARSE_ERROR: default: throw msgpack::parse_error("parse error"); } return unpacked(); } inline unpacked unpack( const char* data, std::size_t len, std::size_t& off, unpack_reference_func f, void* user_data, unpack_limit const& limit) { bool referenced; return unpack(data, len, off, referenced, f, user_data, limit); } inline unpacked unpack( const char* data, std::size_t len, bool& referenced, unpack_reference_func f, void* user_data, unpack_limit const& limit) { std::size_t off = 0; return unpack(data, len, off, referenced, f, user_data, limit); } inline unpacked unpack( const char* data, std::size_t len, unpack_reference_func f, void* user_data, unpack_limit const& limit) { bool referenced; std::size_t off = 0; return unpack(data, len, off, referenced, f, user_data, limit); } inline void unpack(unpacked& result, const char* data, std::size_t len, std::size_t& off, bool& referenced, unpack_reference_func f, void* user_data, unpack_limit const& limit) { msgpack::object obj; msgpack::unique_ptr z(new msgpack::zone); referenced = false; std::size_t noff = off; unpack_return ret = detail::unpack_imp( data, len, noff, *z, obj, referenced, f, user_data, limit); switch(ret) { case UNPACK_SUCCESS: off = noff; result.set(obj); result.zone() = msgpack::move(z); return; case UNPACK_EXTRA_BYTES: off = noff; result.set(obj); result.zone() = msgpack::move(z); return; case UNPACK_CONTINUE: throw msgpack::insufficient_bytes("insufficient bytes"); case UNPACK_PARSE_ERROR: default: throw msgpack::parse_error("parse error"); } } inline void unpack(unpacked& result, const char* data, std::size_t len, std::size_t& off, unpack_reference_func f, void* user_data, unpack_limit const& limit) { bool referenced; unpack(result, data, len, off, referenced, f, user_data, limit); } inline void unpack(unpacked& result, const char* data, std::size_t len, bool& referenced, unpack_reference_func f, void* user_data, unpack_limit const& limit) { std::size_t off = 0; unpack(result, data, len, off, referenced, f, user_data, limit); } inline void unpack(unpacked& result, const char* data, std::size_t len, unpack_reference_func f, void* user_data, unpack_limit const& limit) { bool referenced; std::size_t off = 0; unpack(result, data, len, off, referenced, f, user_data, limit); } inline msgpack::object unpack( msgpack::zone& z, const char* data, std::size_t len, std::size_t& off, bool& referenced, unpack_reference_func f, void* user_data, unpack_limit const& limit) { msgpack::object obj; std::size_t noff = off; referenced = false; unpack_return ret = detail::unpack_imp( data, len, noff, z, obj, referenced, f, user_data, limit); switch(ret) { case UNPACK_SUCCESS: off = noff; return obj; case UNPACK_EXTRA_BYTES: off = noff; return obj; case UNPACK_CONTINUE: throw msgpack::insufficient_bytes("insufficient bytes"); case UNPACK_PARSE_ERROR: default: throw msgpack::parse_error("parse error"); } return obj; } inline msgpack::object unpack( msgpack::zone& z, const char* data, std::size_t len, std::size_t& off, unpack_reference_func f, void* user_data, unpack_limit const& limit) { bool referenced; return unpack(z, data, len, off, referenced, f, user_data, limit); } inline msgpack::object unpack( msgpack::zone& z, const char* data, std::size_t len, bool& referenced, unpack_reference_func f, void* user_data, unpack_limit const& limit) { std::size_t off = 0; return unpack(z, data, len, off, referenced, f, user_data, limit); } inline msgpack::object unpack( msgpack::zone& z, const char* data, std::size_t len, unpack_reference_func f, void* user_data, unpack_limit const& limit) { bool referenced; std::size_t off = 0; return unpack(z, data, len, off, referenced, f, user_data, limit); } // obsolete // pointer version inline void unpack(unpacked* result, const char* data, std::size_t len, std::size_t* off, bool* referenced, unpack_reference_func f, void* user_data, unpack_limit const& limit) { if (off) if (referenced) unpack(*result, data, len, *off, *referenced, f, user_data, limit); else unpack(*result, data, len, *off, f, user_data, limit); else if (referenced) unpack(*result, data, len, *referenced, f, user_data, limit); else unpack(*result, data, len, f, user_data, limit); } inline bool unpacker::default_reference_func(msgpack::type::object_type /*type*/, std::size_t /*len*/, void*) { return true; } /// @cond } // MSGPACK_API_VERSION_NAMESPACE(v1) /// @endcond } // namespace msgpack #endif /* msgpack/unpack.hpp */