4 extern cvar_t crypto_developer;
5 extern cvar_t crypto_aeslevel;
6 #define ENCRYPTION_REQUIRED (crypto_aeslevel.integer >= 3)
8 extern int crypto_keyfp_recommended_length; // applies to LOCAL IDs, and to ALL keys
10 #define CRYPTO_HEADERSIZE 31
11 // AES case causes 16 to 31 bytes overhead
12 // SHA256 case causes 16 bytes overhead as we truncate to 128bit
21 unsigned char dhkey[DHKEY_SIZE]; // shared key, not NUL terminated
22 char client_idfp[FP64_SIZE+1];
23 char client_keyfp[FP64_SIZE+1]; // NULL if signature fail
24 char server_idfp[FP64_SIZE+1];
25 char server_keyfp[FP64_SIZE+1]; // NULL if signature fail
26 qboolean authenticated;
32 void Crypto_Init(void);
33 void Crypto_Init_Commands(void);
34 void Crypto_Shutdown(void);
35 qboolean Crypto_Available(void);
36 void sha256(unsigned char *out, const unsigned char *in, int n); // may ONLY be called if Crypto_Available()
37 const void *Crypto_EncryptPacket(crypto_t *crypto, const void *data_src, size_t len_src, void *data_dst, size_t *len_dst, size_t len);
38 const void *Crypto_DecryptPacket(crypto_t *crypto, const void *data_src, size_t len_src, void *data_dst, size_t *len_dst, size_t len);
39 #define CRYPTO_NOMATCH 0 // process as usual (packet was not used)
40 #define CRYPTO_MATCH 1 // process as usual (packet was used)
41 #define CRYPTO_DISCARD 2 // discard this packet
42 #define CRYPTO_REPLACE 3 // make the buffer the current packet
43 int Crypto_ClientParsePacket(const char *data_in, size_t len_in, char *data_out, size_t *len_out, lhnetaddress_t *peeraddress);
44 int Crypto_ServerParsePacket(const char *data_in, size_t len_in, char *data_out, size_t *len_out, lhnetaddress_t *peeraddress);
46 // if len_out is nonzero, the packet is to be sent to the client
48 qboolean Crypto_ServerAppendToChallenge(const char *data_in, size_t len_in, char *data_out, size_t *len_out, size_t maxlen);
49 crypto_t *Crypto_ServerGetInstance(lhnetaddress_t *peeraddress);
50 qboolean Crypto_ServerFinishInstance(crypto_t *out, crypto_t *in); // also clears allocated memory
51 const char *Crypto_GetInfoResponseDataString(void);
53 // retrieves a host key for an address (can be exposed to menuqc, or used by the engine to look up stored keys e.g. for server bookmarking)
54 // pointers may be NULL
55 qboolean Crypto_RetrieveHostKey(lhnetaddress_t *peeraddress, int *keyid, char *keyfp, size_t keyfplen, char *idfp, size_t idfplen, int *aeslevel);
56 int Crypto_RetrieveLocalKey(int keyid, char *keyfp, size_t keyfplen, char *idfp, size_t idfplen); // return value: -1 if more to come, +1 if valid, 0 if end of list
58 size_t Crypto_SignData(const void *data, size_t datasize, int keyid, void *signed_data, size_t signed_size);
59 size_t Crypto_SignDataDetached(const void *data, size_t datasize, int keyid, void *signed_data, size_t signed_size);
66 // < accept (or: reject)
69 // < challenge SP <challenge> NUL vlen <size> d0pk <fingerprints I can auth to> NUL NUL <other fingerprints I accept>
72 // d0pk\cnt\0\challenge\<challenge>\aeslevel\<level> NUL <serverfp> NUL <clientfp>
74 // check if client would get accepted; if not, do "reject" now
75 // require non-control packets to be encrypted require non-control packets to be encrypted
76 // do not send anything yet do not send anything yet
77 // RESET to serverfp RESET to serverfp
78 // d0_blind_id_authenticate_with_private_id_start() = 1
79 // < d0pk\cnt\1\aes\<aesenabled> NUL *startdata*
80 // d0_blind_id_authenticate_with_private_id_challenge() = 1
81 // d0pk\cnt\2 NUL *challengedata* >
82 // d0_blind_id_authenticate_with_private_id_response() = 0
83 // < d0pk\cnt\3 NUL *responsedata*
84 // d0_blind_id_authenticate_with_private_id_verify() = 1
85 // store server's fingerprint NOW
86 // d0_blind_id_sessionkey_public_id() = 1 d0_blind_id_sessionkey_public_id() = 1
88 // IF clientfp AND NOT serverfp:
89 // RESET to clientfp RESET to clientfp
90 // d0_blind_id_authenticate_with_private_id_start() = 1
91 // d0pk\cnt\0\challenge\<challenge>\aeslevel\<level> NUL NUL <clientfp> NUL *startdata*
93 // check if client would get accepted; if not, do "reject" now
94 // require non-control packets to be encrypted require non-control packets to be encrypted
95 // d0_blind_id_authenticate_with_private_id_challenge() = 1
96 // < d0pk\cnt\5\aes\<aesenabled> NUL *challengedata*
98 // IF clientfp AND serverfp:
99 // RESET to clientfp RESET to clientfp
100 // d0_blind_id_authenticate_with_private_id_start() = 1
101 // d0pk\cnt\4 NUL *startdata* >
102 // d0_blind_id_authenticate_with_private_id_challenge() = 1
103 // < d0pk\cnt\5 NUL *challengedata*
106 // d0_blind_id_authenticate_with_private_id_response() = 0
107 // d0pk\cnt\6 NUL *responsedata* >
108 // d0_blind_id_authenticate_with_private_id_verify() = 1
109 // store client's fingerprint NOW
110 // d0_blind_id_sessionkey_public_id() = 1 d0_blind_id_sessionkey_public_id() = 1
111 // note: the ... is the "connect" message, except without the challenge. Reinterpret as regular connect message on server side
113 // enforce encrypted transmission (key is XOR of the two DH keys)
116 // < challenge (mere sync message)
119 // < accept (ALWAYS accept if connection is encrypted, ignore challenge as it had been checked before)
121 // commence with ingame protocol
125 // getchallenge NUL d0_blind_id: reply with challenge with added fingerprints
126 // cnt=0: IF server will auth, cnt=1, ELSE cnt=5
129 // cnt=6: send "challenge"
131 // challenge with added fingerprints: cnt=0; if client will auth but not server, append client auth start
133 // cnt=3: IF client will auth, cnt=4, ELSE rewrite as "challenge"
134 // cnt=5: cnt=6, server will continue by sending "challenge" (let's avoid sending two packets as response to one)
136 // accept empty "challenge", and challenge-less connect in case crypto protocol has executed and finished
137 // statusResponse and infoResponse get an added d0_blind_id key that lists
138 // the keys the server can auth with and to in key@ca SPACE key@ca notation
139 // any d0pk\ message has an appended "id" parameter; messages with an unexpected "id" are ignored to prevent errors from multiple concurrent auth runs
142 // comparison to OTR:
144 // - authentication: yes
145 // - deniability: no (attacker requires the temporary session key to prove you
146 // have sent a specific message, the private key itself does not suffice), no
147 // measures are taken to provide forgeability to even provide deniability
148 // against an attacker who knows the temporary session key, as using CTR mode
149 // for the encryption - which, together with deriving the MAC key from the
150 // encryption key, and MACing the ciphertexts instead of the plaintexts,
151 // would provide forgeability and thus deniability - requires longer
152 // encrypted packets and deniability was not a goal of this, as we may e.g.
153 // reserve the right to capture packet dumps + extra state info to prove a
154 // client/server has sent specific packets to prove cheating)
155 // - perfect forward secrecy: yes (session key is derived via DH key exchange)