/* * ZeroTier One - Global Peer to Peer Ethernet * Copyright (C) 2011-2014 ZeroTier Networks LLC * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . * * -- * * ZeroTier may be used and distributed under the terms of the GPLv3, which * are available at: http://www.gnu.org/licenses/gpl-3.0.html * * If you would like to embed ZeroTier into a commercial application or * redistribute it in a modified binary form, please contact ZeroTier Networks * LLC. Start here: http://www.zerotier.com/ */ #ifndef ZT_CERTIFICATEOFMEMBERSHIP_HPP #define ZT_CERTIFICATEOFMEMBERSHIP_HPP #include #include #include #include #include #include "Constants.hpp" #include "Buffer.hpp" #include "Address.hpp" #include "C25519.hpp" #include "Identity.hpp" namespace ZeroTier { /** * Certificate of network membership * * The COM contains a sorted set of three-element tuples called qualifiers. * These contain an id, a value, and a maximum delta. * * The ID is arbitrary and should be assigned using a scheme that makes * every ID globally unique. IDs beneath 65536 are reserved for global * assignment by ZeroTier Networks. * * The value's meaning is ID-specific and isn't important here. What's * important is the value and the third member of the tuple: the maximum * delta. The maximum delta is the maximum difference permitted between * values for a given ID between certificates for the two certificates to * themselves agree. * * Network membership is checked by checking whether a peer's certificate * agrees with your own. The timestamp provides the fundamental criterion-- * each member of a private network must constantly obtain new certificates * often enough to stay within the max delta for this qualifier. But other * criteria could be added in the future for very special behaviors, things * like latitude and longitude for instance. */ class CertificateOfMembership { public: /** * Certificate type codes, used in serialization * * Only one so far, and only one hopefully there shall be for quite some * time. */ enum Type { COM_UINT64_ED25519 = 1 // tuples of unsigned 64's signed with Ed25519 }; /** * Reserved qualifier IDs * * IDs below 65536 should be considered reserved for future global * assignment here. * * Addition of new required fields requires that code in hasRequiredFields * be updated as well. */ enum ReservedId { /** * Timestamp of certificate issue in milliseconds since epoch * * maxDelta here defines certificate lifetime, and certs are lazily * pushed to other peers on a net with a frequency of 1/2 this time. */ COM_RESERVED_ID_TIMESTAMP = 0, /** * Network ID for which certificate was issued * * maxDelta here is zero, since this must match. */ COM_RESERVED_ID_NETWORK_ID = 1, /** * ZeroTier address to whom certificate was issued * * maxDelta will be 0xffffffffffffffff here since it's permitted to differ * from peers obviously. */ COM_RESERVED_ID_ISSUED_TO = 2 }; /** * Create an empty certificate */ CertificateOfMembership() { memset(_signature.data,0,_signature.size()); } /** * Create from required fields common to all networks * * @param timestamp Timestamp of cert * @param timestampMaxDelta Maximum variation between timestamps on this net * @param nwid Network ID * @param issuedTo Certificate recipient */ CertificateOfMembership(uint64_t timestamp,uint64_t timestampMaxDelta,uint64_t nwid,const Address &issuedTo) { _qualifiers.push_back(_Qualifier(COM_RESERVED_ID_TIMESTAMP,timestamp,timestampMaxDelta)); _qualifiers.push_back(_Qualifier(COM_RESERVED_ID_NETWORK_ID,nwid,0)); _qualifiers.push_back(_Qualifier(COM_RESERVED_ID_ISSUED_TO,issuedTo.toInt(),0xffffffffffffffffULL)); memset(_signature.data,0,_signature.size()); } /** * Create from string-serialized data * * @param s String-serialized COM */ CertificateOfMembership(const char *s) { fromString(s); } /** * Create from string-serialized data * * @param s String-serialized COM */ CertificateOfMembership(const std::string &s) { fromString(s.c_str()); } /** * Create from binary-serialized COM in buffer * * @param b Buffer to deserialize from * @param startAt Position to start in buffer */ template CertificateOfMembership(const Buffer &b,unsigned int startAt = 0) throw(std::out_of_range,std::invalid_argument) { deserialize(b,startAt); } /** * @return True if there's something here */ inline operator bool() const throw() { return (_qualifiers.size() != 0); } /** * Check for presence of all required fields common to all networks * * @return True if all required fields are present */ inline bool hasRequiredFields() const throw() { if (_qualifiers.size() < 3) return false; if (_qualifiers[0].id != COM_RESERVED_ID_TIMESTAMP) return false; if (_qualifiers[1].id != COM_RESERVED_ID_NETWORK_ID) return false; if (_qualifiers[2].id != COM_RESERVED_ID_ISSUED_TO) return false; return true; } /** * @return Maximum delta for mandatory timestamp field or 0 if field missing */ inline uint64_t timestampMaxDelta() const throw() { for(std::vector<_Qualifier>::const_iterator q(_qualifiers.begin());q!=_qualifiers.end();++q) { if (q->id == COM_RESERVED_ID_TIMESTAMP) return q->maxDelta; } return 0ULL; } /** * @return Timestamp for this cert in ms since epoch (according to netconf's clock) */ inline uint64_t timestamp() const throw() { for(std::vector<_Qualifier>::const_iterator q(_qualifiers.begin());q!=_qualifiers.end();++q) { if (q->id == COM_RESERVED_ID_TIMESTAMP) return q->value; } return 0ULL; } /** * @return Address to which this cert was issued */ inline Address issuedTo() const throw() { for(std::vector<_Qualifier>::const_iterator q(_qualifiers.begin());q!=_qualifiers.end();++q) { if (q->id == COM_RESERVED_ID_ISSUED_TO) return Address(q->value); } return Address(); } /** * @return Network ID for which this cert was issued */ inline uint64_t networkId() const throw() { for(std::vector<_Qualifier>::const_iterator q(_qualifiers.begin());q!=_qualifiers.end();++q) { if (q->id == COM_RESERVED_ID_NETWORK_ID) return q->value; } return 0ULL; } /** * Add or update a qualifier in this certificate * * Any signature is invalidated and signedBy is set to null. * * @param id Qualifier ID * @param value Qualifier value * @param maxDelta Qualifier maximum allowed difference (absolute value of difference) */ void setQualifier(uint64_t id,uint64_t value,uint64_t maxDelta); inline void setQualifier(ReservedId id,uint64_t value,uint64_t maxDelta) { setQualifier((uint64_t)id,value,maxDelta); } /** * @return String-serialized representation of this certificate */ std::string toString() const; /** * Set this certificate equal to the hex-serialized string * * Invalid strings will result in invalid or undefined certificate * contents. These will subsequently fail validation and comparison. * Empty strings will result in an empty certificate. * * @param s String to deserialize */ void fromString(const char *s); inline void fromString(const std::string &s) { fromString(s.c_str()); } /** * Compare two certificates for parameter agreement * * This compares this certificate with the other and returns true if all * paramters in this cert are present in the other and if they agree to * within this cert's max delta value for each given parameter. * * Tuples present in other but not in this cert are ignored, but any * tuples present in this cert but not in other result in 'false'. * * @param other Cert to compare with * @return True if certs agree and 'other' may be communicated with */ bool agreesWith(const CertificateOfMembership &other) const throw(); /** * Sign this certificate * * @param with Identity to sign with, must include private key * @return True if signature was successful */ bool sign(const Identity &with); /** * Verify certificate against an identity * * @param id Identity to verify against * @return True if certificate is signed by this identity and verification was successful */ bool verify(const Identity &id) const; /** * @return True if signed */ inline bool isSigned() const throw() { return (_signedBy); } /** * @return Address that signed this certificate or null address if none */ inline const Address &signedBy() const throw() { return _signedBy; } template inline void serialize(Buffer &b) const throw(std::out_of_range) { b.append((unsigned char)COM_UINT64_ED25519); b.append((uint16_t)_qualifiers.size()); for(std::vector<_Qualifier>::const_iterator q(_qualifiers.begin());q!=_qualifiers.end();++q) { b.append(q->id); b.append(q->value); b.append(q->maxDelta); } _signedBy.appendTo(b); if (_signedBy) b.append(_signature.data,(unsigned int)_signature.size()); } template inline unsigned int deserialize(const Buffer &b,unsigned int startAt = 0) throw(std::out_of_range,std::invalid_argument) { unsigned int p = startAt; _qualifiers.clear(); _signedBy.zero(); if (b[p++] != COM_UINT64_ED25519) throw std::invalid_argument("unknown certificate of membership type"); unsigned int numq = b.template at(p); p += sizeof(uint16_t); uint64_t lastId = 0; for(unsigned int i=0;i(p); if (tmp < lastId) throw std::invalid_argument("certificate qualifiers are not sorted"); else lastId = tmp; _qualifiers.push_back(_Qualifier( tmp, b.template at(p + 8), b.template at(p + 16) )); p += 24; } _signedBy.setTo(b.field(p,ZT_ADDRESS_LENGTH),ZT_ADDRESS_LENGTH); p += ZT_ADDRESS_LENGTH; if (_signedBy) { memcpy(_signature.data,b.field(p,(unsigned int)_signature.size()),_signature.size()); p += (unsigned int)_signature.size(); } return (p - startAt); } inline bool operator==(const CertificateOfMembership &c) const throw() { if (_signedBy != c._signedBy) return false; // We have to compare in depth manually since == only compares id if (_qualifiers.size() != c._qualifiers.size()) return false; for(unsigned long i=0;i<_qualifiers.size();++i) { const _Qualifier &a = _qualifiers[i]; const _Qualifier &b = c._qualifiers[i]; if ((a.id != b.id)||(a.value != b.value)||(a.maxDelta != b.maxDelta)) return false; } return (_signature == c._signature); } inline bool operator!=(const CertificateOfMembership &c) const throw() { return (!(*this == c)); } private: struct _Qualifier { _Qualifier() throw() {} _Qualifier(uint64_t i,uint64_t v,uint64_t m) throw() : id(i), value(v), maxDelta(m) {} uint64_t id; uint64_t value; uint64_t maxDelta; inline bool operator==(const _Qualifier &q) const throw() { return (id == q.id); } // for unique inline bool operator<(const _Qualifier &q) const throw() { return (id < q.id); } // for sort }; Address _signedBy; std::vector<_Qualifier> _qualifiers; // sorted by id and unique C25519::Signature _signature; }; } // namespace ZeroTier #endif