/* * Copyright (c) 2016 The ZLMediaKit project authors. All Rights Reserved. * * This file is part of ZLMediaKit(https://github.com/xiongziliang/ZLMediaKit). * * Use of this source code is governed by MIT license that can be found in the * LICENSE file in the root of the source tree. All contributing project authors * may be found in the AUTHORS file in the root of the source tree. */ #include #include #include "amf.h" #include "utils.h" #include "Util/util.h" #include "Util/logger.h" #include "Network/sockutil.h" #include "Util/util.h" using namespace toolkit; /////////////////////AMFValue///////////////////////////// inline void AMFValue::destroy() { switch (_type) { case AMF_STRING: if (_value.string) { delete _value.string; _value.string = nullptr; } break; case AMF_OBJECT: case AMF_ECMA_ARRAY: if (_value.object) { delete _value.object; _value.object = nullptr; } break; case AMF_STRICT_ARRAY: if (_value.array) { delete _value.array; _value.array = nullptr; } break; default: break; } } inline void AMFValue::init() { switch (_type) { case AMF_OBJECT: case AMF_ECMA_ARRAY: _value.object = new mapType; break; case AMF_STRING: _value.string = new std::string; break; case AMF_STRICT_ARRAY: _value.array = new arrayType; break; default: break; } } AMFValue::AMFValue(AMFType type) : _type(type) { init(); } AMFValue::~AMFValue() { destroy(); } AMFValue::AMFValue(const char *s) : _type(AMF_STRING) { init(); *_value.string = s; } AMFValue::AMFValue(const std::string &s) : _type(AMF_STRING) { init(); *_value.string = s; } AMFValue::AMFValue(double n) : _type(AMF_NUMBER) { init(); _value.number = n; } AMFValue::AMFValue(int i) : _type(AMF_INTEGER) { init(); _value.integer = i; } AMFValue::AMFValue(bool b) : _type(AMF_BOOLEAN) { init(); _value.boolean = b; } AMFValue::AMFValue(const AMFValue &from) : _type(AMF_NULL) { *this = from; } AMFValue& AMFValue::operator = (const AMFValue &from) { destroy(); _type = from._type; init(); switch (_type) { case AMF_STRING: *_value.string = (*from._value.string); break; case AMF_OBJECT: case AMF_ECMA_ARRAY: *_value.object = (*from._value.object); break; case AMF_STRICT_ARRAY: *_value.array = (*from._value.array); break; case AMF_NUMBER: _value.number = from._value.number; break; case AMF_INTEGER: _value.integer = from._value.integer; break; case AMF_BOOLEAN: _value.boolean = from._value.boolean; break; default: break; } return *this; } void AMFValue::clear() { switch (_type) { case AMF_STRING: _value.string->clear(); break; case AMF_OBJECT: case AMF_ECMA_ARRAY: _value.object->clear(); break; default: break; } } AMFType AMFValue::type() const { return _type; } const std::string &AMFValue::as_string() const { if(_type != AMF_STRING){ throw std::runtime_error("AMF not a string"); } return *_value.string; } double AMFValue::as_number() const { switch (_type) { case AMF_NUMBER: return _value.number; case AMF_INTEGER: return _value.integer; case AMF_BOOLEAN: return _value.boolean; default: throw std::runtime_error("AMF not a number"); } } int AMFValue::as_integer() const { switch (_type) { case AMF_NUMBER: return _value.number; case AMF_INTEGER: return _value.integer; case AMF_BOOLEAN: return _value.boolean; default: throw std::runtime_error("AMF not a integer"); } } bool AMFValue::as_boolean() const { switch (_type) { case AMF_NUMBER: return _value.number; case AMF_INTEGER: return _value.integer; case AMF_BOOLEAN: return _value.boolean; default: throw std::runtime_error("AMF not a boolean"); } } string AMFValue::to_string() const{ switch (_type) { case AMF_NUMBER: return StrPrinter << _value.number; case AMF_INTEGER: return StrPrinter << _value.integer; case AMF_BOOLEAN: return _value.boolean ? "true" : "false"; case AMF_STRING: return *(_value.string); case AMF_OBJECT: return "object"; case AMF_NULL: return "null"; case AMF_UNDEFINED: return "undefined"; case AMF_ECMA_ARRAY: return "ecma_array"; case AMF_STRICT_ARRAY: return "strict_array"; default: throw std::runtime_error("can not convert to string "); } } const AMFValue& AMFValue::operator[](const char *str) const { if (_type != AMF_OBJECT && _type != AMF_ECMA_ARRAY) { throw std::runtime_error("AMF not a object"); } auto i = _value.object->find(str); if (i == _value.object->end()) { static AMFValue val(AMF_NULL); return val; } return i->second; } void AMFValue::object_for_each(const function &fun) const { if (_type != AMF_OBJECT && _type != AMF_ECMA_ARRAY) { throw std::runtime_error("AMF not a object"); } for (auto & pr : *(_value.object)) { fun(pr.first, pr.second); } } AMFValue::operator bool() const{ return _type != AMF_NULL; } void AMFValue::set(const std::string &s, const AMFValue &val) { if (_type != AMF_OBJECT && _type != AMF_ECMA_ARRAY) { throw std::runtime_error("AMF not a object"); } _value.object->emplace(s, val); } void AMFValue::add(const AMFValue &val) { if (_type != AMF_STRICT_ARRAY) { throw std::runtime_error("AMF not a array"); } assert(_type == AMF_STRICT_ARRAY); _value.array->push_back(val); } const AMFValue::mapType &AMFValue::getMap() const { if (_type != AMF_OBJECT && _type != AMF_ECMA_ARRAY) { throw std::runtime_error("AMF not a object"); } return *_value.object; } const AMFValue::arrayType &AMFValue::getArr() const { if (_type != AMF_STRICT_ARRAY) { throw std::runtime_error("AMF not a array"); } return *_value.array; } /////////////////////////////////////////////////////////////////////////// enum { AMF0_NUMBER, AMF0_BOOLEAN, AMF0_STRING, AMF0_OBJECT, AMF0_MOVIECLIP, AMF0_NULL, AMF0_UNDEFINED, AMF0_REFERENCE, AMF0_ECMA_ARRAY, AMF0_OBJECT_END, AMF0_STRICT_ARRAY, AMF0_DATE, AMF0_LONG_STRING, AMF0_UNSUPPORTED, AMF0_RECORD_SET, AMF0_XML_OBJECT, AMF0_TYPED_OBJECT, AMF0_SWITCH_AMF3, }; enum { AMF3_UNDEFINED, AMF3_NULL, AMF3_FALSE, AMF3_TRUE, AMF3_INTEGER, AMF3_NUMBER, AMF3_STRING, AMF3_LEGACY_XML, AMF3_DATE, AMF3_ARRAY, AMF3_OBJECT, AMF3_XML, AMF3_BYTE_ARRAY, }; ////////////////////////////////Encoder////////////////////////////////////////// AMFEncoder & AMFEncoder::operator <<(const char *s) { if (s) { buf += char(AMF0_STRING); uint16_t str_len = htons(strlen(s)); buf.append((char *) &str_len, 2); buf += s; } else { buf += char(AMF0_NULL); } return *this; } AMFEncoder & AMFEncoder::operator <<(const std::string &s) { if (!s.empty()) { buf += char(AMF0_STRING); uint16_t str_len = htons(s.size()); buf.append((char *) &str_len, 2); buf += s; } else { buf += char(AMF0_NULL); } return *this; } AMFEncoder & AMFEncoder::operator <<(std::nullptr_t) { buf += char(AMF0_NULL); return *this; } AMFEncoder & AMFEncoder::write_undefined() { buf += char(AMF0_UNDEFINED); return *this; } AMFEncoder & AMFEncoder::operator <<(const int n){ return (*this) << (double)n; } AMFEncoder & AMFEncoder::operator <<(const double n) { buf += char(AMF0_NUMBER); uint64_t encoded = 0; memcpy(&encoded, &n, 8); uint32_t val = htonl(encoded >> 32); buf.append((char *) &val, 4); val = htonl(encoded); buf.append((char *) &val, 4); return *this; } AMFEncoder & AMFEncoder::operator <<(const bool b) { buf += char(AMF0_BOOLEAN); buf += char(b); return *this; } AMFEncoder & AMFEncoder::operator <<(const AMFValue& value) { switch ((int) value.type()) { case AMF_STRING: *this << value.as_string(); break; case AMF_NUMBER: *this << value.as_number(); break; case AMF_INTEGER: *this << value.as_integer(); break; case AMF_BOOLEAN: *this << value.as_boolean(); break; case AMF_OBJECT: { buf += char(AMF0_OBJECT); for (auto &pr : value.getMap()) { write_key(pr.first); *this << pr.second; } write_key(""); buf += char(AMF0_OBJECT_END); } break; case AMF_ECMA_ARRAY: { buf += char(AMF0_ECMA_ARRAY); uint32_t sz = htonl(value.getMap().size()); buf.append((char *) &sz, 4); for (auto &pr : value.getMap()) { write_key(pr.first); *this << pr.second; } write_key(""); buf += char(AMF0_OBJECT_END); } break; case AMF_NULL: *this << nullptr; break; case AMF_UNDEFINED: this->write_undefined(); break; case AMF_STRICT_ARRAY: { buf += char(AMF0_STRICT_ARRAY); uint32_t sz = htonl(value.getArr().size()); buf.append((char *) &sz, 4); for (auto &val : value.getArr()) { *this << val; } //write_key(""); //buf += char(AMF0_OBJECT_END); } break; } return *this; } void AMFEncoder::write_key(const std::string& s) { uint16_t str_len = htons(s.size()); buf.append((char *) &str_len, 2); buf += s; } void AMFEncoder::clear() { buf.clear(); } const std::string& AMFEncoder::data() const { return buf; } //////////////////Decoder////////////////// uint8_t AMFDecoder::front() { if (pos >= buf.size()) { throw std::runtime_error("Not enough data"); } return uint8_t(buf[pos]); } uint8_t AMFDecoder::pop_front() { if (version == 0 && front() == AMF0_SWITCH_AMF3) { InfoL << "entering AMF3 mode"; pos++; version = 3; } if (pos >= buf.size()) { throw std::runtime_error("Not enough data"); } return uint8_t(buf[pos++]); } template<> double AMFDecoder::load() { if (pop_front() != AMF0_NUMBER) { throw std::runtime_error("Expected a number"); } if (pos + 8 > buf.size()) { throw std::runtime_error("Not enough data"); } uint64_t val = ((uint64_t) load_be32(&buf[pos]) << 32) | load_be32(&buf[pos + 4]); double n = 0; memcpy(&n, &val, 8); pos += 8; return n; } template<> bool AMFDecoder::load() { if (pop_front() != AMF0_BOOLEAN) { throw std::runtime_error("Expected a boolean"); } return pop_front() != 0; } template<> unsigned int AMFDecoder::load() { unsigned int value = 0; for (int i = 0; i < 4; ++i) { uint8_t b = pop_front(); if (i == 3) { /* use all bits from 4th byte */ value = (value << 8) | b; break; } value = (value << 7) | (b & 0x7f); if ((b & 0x80) == 0) break; } return value; } template<> int AMFDecoder::load() { if (version == 3) { return load(); } else { return load(); } } template<> std::string AMFDecoder::load() { size_t str_len = 0; uint8_t type = pop_front(); if (version == 3) { if (type != AMF3_STRING) { throw std::runtime_error("Expected a string"); } str_len = load() / 2; } else { if (type != AMF0_STRING) { throw std::runtime_error("Expected a string"); } if (pos + 2 > buf.size()) { throw std::runtime_error("Not enough data"); } str_len = load_be16(&buf[pos]); pos += 2; } if (pos + str_len > buf.size()) { throw std::runtime_error("Not enough data"); } std::string s = buf.substr(pos, str_len); pos += str_len; return s; } template<> AMFValue AMFDecoder::load() { uint8_t type = front(); if (version == 3) { switch (type) { case AMF3_STRING: return load(); case AMF3_NUMBER: return load(); case AMF3_INTEGER: return load(); case AMF3_FALSE: pos++; return false; case AMF3_TRUE: pos++; return true; case AMF3_OBJECT: return load_object(); case AMF3_ARRAY: return load_ecma(); case AMF3_NULL: pos++; return AMF_NULL; case AMF3_UNDEFINED: pos++; return AMF_UNDEFINED; default: throw std::runtime_error( StrPrinter << "Unsupported AMF3 type:" << (int) type << endl); } } else { switch (type) { case AMF0_STRING: return load(); case AMF0_NUMBER: return load(); case AMF0_BOOLEAN: return load(); case AMF0_OBJECT: return load_object(); case AMF0_ECMA_ARRAY: return load_ecma(); case AMF0_NULL: pos++; return AMF_NULL; case AMF0_UNDEFINED: pos++; return AMF_UNDEFINED; case AMF0_STRICT_ARRAY: return load_arr(); default: throw std::runtime_error( StrPrinter << "Unsupported AMF type:" << (int) type << endl); } } } std::string AMFDecoder::load_key() { if (pos + 2 > buf.size()) { throw std::runtime_error("Not enough data"); } size_t str_len = load_be16(&buf[pos]); pos += 2; if (pos + str_len > buf.size()) { throw std::runtime_error("Not enough data"); } std::string s = buf.substr(pos, str_len); pos += str_len; return s; } AMFValue AMFDecoder::load_object() { AMFValue object(AMF_OBJECT); if (pop_front() != AMF0_OBJECT) { throw std::runtime_error("Expected an object"); } while (1) { std::string key = load_key(); if (key.empty()) break; AMFValue value = load(); object.set(key, value); } if (pop_front() != AMF0_OBJECT_END) { throw std::runtime_error("expected object end"); } return object; } AMFValue AMFDecoder::load_ecma() { /* ECMA array is the same as object, with 4 extra zero bytes */ AMFValue object(AMF_ECMA_ARRAY); if (pop_front() != AMF0_ECMA_ARRAY) { throw std::runtime_error("Expected an ECMA array"); } if (pos + 4 > buf.size()) { throw std::runtime_error("Not enough data"); } pos += 4; while (1) { std::string key = load_key(); if (key.empty()) break; AMFValue value = load(); object.set(key, value); } if (pop_front() != AMF0_OBJECT_END) { throw std::runtime_error("expected object end"); } return object; } AMFValue AMFDecoder::load_arr() { /* ECMA array is the same as object, with 4 extra zero bytes */ AMFValue object(AMF_STRICT_ARRAY); if (pop_front() != AMF0_STRICT_ARRAY) { throw std::runtime_error("Expected an STRICT array"); } if (pos + 4 > buf.size()) { throw std::runtime_error("Not enough data"); } int arrSize = load_be32(&buf[pos]); pos += 4; while (arrSize--) { AMFValue value = load(); object.add(value); } /*pos += 2; if (pop_front() != AMF0_OBJECT_END) { throw std::runtime_error("expected object end"); }*/ return object; } AMFDecoder::AMFDecoder(const BufferLikeString &buf_in, size_t pos_in, int version_in) : buf(buf_in), pos(pos_in), version(version_in) { }