# PROTOCOL DEFINITION Messages communicated between the client and server follow the same format, but have different meanings depending on which end is the recipient. A message's intent is determined by its packet ID, a unique identifier that tells the client or server how it should react to the received message. A message id that incites bidirectional communication between the client and server should typically be associated with the same message id on the client as on the server, so as to avoid confusion. A packet of communication between the client and server is considered to be a seamlessly connected regions of bytes, the boundaries of which are defined in the header of the packet. All references to the 'byte' in this document refers to individual 8-bit octets, as is the de facto standard in modern computing. All binary-encoded multi-byte quantities sent in a packet are to be sent in network byte order (big endian). ## Header Because the body of the packet is a sequence of many different regions of byte data that is not delimited, it is necessary for the header of the packet to determine boundaries for the regions of data. * The first four bytes will always be 0xF0, 0x9F, 0xA6, 0x91. If this is not set properly, the endpoint must close the connection. * The fifth byte is the packet id, the meanings of which are defined in the [_Packet IDs_](#packet-ids) section. * The sixth byte is the number of byte regions in the packet. * The bytes following the sixth byte are a list of binary length segments, each of which correspond to the number of bytes in its respective region. They each follow this format: * If length is less than 254, the length of the region is stored in a single byte. * If length is greater than or equal to 254 but less than 65,536, the first byte of the lenght segment should be 254 and the following two bytes is the length of the region. * If length is greater than or equal to 65,536, the first byte of the length segment should be 255 and the following four bytes is the length of the region. The number of length segments should be equal to the number of byte regions as defined in the second byte. The length of any single section may not exceed (2^32)-1 bytes. ## Body The message body immediately follows the header with no separator, and consists of a sequence of byte regions as defined in the header that are joined together without any separator. The position of a byte region in the body should correspond to the offset of the length segment in the header. ### Numeric Packing All numbers, unless otherwise specified, are the string representation of a base 10 number. Common exceptions are listed below: * User IDs: Hex string, 8 bytes unsigned * Co-ordinates: 8 bytes, double-precision float * Big Int: Hex string, variable size ### Packet IDs A packet ID may have a specific "direction" of communication, in that an endpoint may either act as a _requester_ or a _responder_. A _requester_ is an endpoint that drives all of the communication on that specific packet ID, while the _responder_ is responsible for providing a timely response to the requests it receives. A _responder_ for a specific packet ID should never send that packet ID unsolicited; either the packet will be ignored or the other endpoint will close the connection. Any packet ID marked as bidirectional may be initiated by either endpoint at any time. A _blind requester_ is an endpoint that sends out a packet of a certain ID and either does not expect a response or expects a response on a different packet ID. #### Server to Client TODO: populate #### Client to Server TODO: populate ## Master/Slave Servers To keep track of the status of multiple servers from a centralized point that the client may query, each server must be able to communicate with a "master" server that will record and dispense information regarding all servers to clients. All servers that report to the master server will hereby be refered to as "slave" servers. Communication between master and slave servers will be done over a UDP connection on a port that is defined by the master server's configuration. The protocol used for this communication is identical to the protocol defined for standard client/server communication; however, the [_Packet IDs_](#TODO) are defined differently. Communication between the master server and clients will be done over a WebSocket connection on a port that is defined by the master server's configuration. The protocol used for this communication is identical to the protocol defined for standard client/server communication; however, the [_Packet IDs_](#TODO) are defined differently. ### Master/Slave Packet IDs #### Master to Slave
ID 1: Key Exchange
Requester (resp. StM ID 0)
# Region Type
1 Generator Big Int
2 Modulus Big Int
3 Server Key Big Int
ID 2: Positive ACK
[Encrypted] Responder
# Region Type
1 Request Packet ID Byte
ID 3: Negative ACK
[Encrypted] Responder
# Region Type
1 Request Packet ID Byte
2 Error Message String
ID 4: Encryption Error
Responder
# Region Type
1 Error Message String
#### Slave to Master
ID 0: Initiation Attempt
Blind Requester
# Region Type
1 Secret String
ID 1: Key Exchange
Responder
# Region Type
1 Client Key Big Int
ID 2: Status Update
[Encrypted] Blind Requester
# (r) Region Type
1 Server Count (n) Unsigned Byte
r > 1 Iterated over n (0 ≤ in - 1)
2 + 4i Server Id Packed Unsigned Short
3 + 4i User Count Packed Unsigned Short
4 + 4i IPv4 Address Bytes (4)
5 + 4i Port Packed Unsigned Short
### Master/Client Packet IDs #### Master to Client
ID 1: Key Exchange
Requester
# Region Type
1 Generator Big Int
2 Modulus Big Int
3 Server Key Big Int
ID 2: Login Attempt
[Encrypted] Responder
# Region Type
1 Succeeded Boolean
2 Message String
ID 3: Registration Attempt
[Encrypted] Responder
# Region Type
1 Succeeded Boolean
2 Message String
#### Client to Master
ID 1: Key Exchange
Responder
# Region Type
1 Secret String
ID 2: Login Attempt
[Encrypted] Requester
# Region Type
1 Username String
2 Password String
ID 3: Registration Attempt
[Encrypted] Requester
# Region Type
1 Username String
2 Password String
3 Email String
## Sockstamps Because epoch time is not standardized across systems, an intermediate layer of date/time transmission must be used between the client and server so as to handle time dependent interactions. Therefore, a "sockstamp" will be used in place of the context-dependent implementations of epoch time. A sockstamp is a sequence of six bytes that represent a fully qualified UTC date and time on the Gregorian calendar. For the best use of space without obfuscating the data too much, the year's lower four bits and the four bits signifying the month are shared in the same byte, but no other components are joined. The 12 bits signifying the year are an unsigned quanitity, and indicate the number of years since 0 AD; any date prior to the year of Christ's birth cannot be represented in this format, but this should never be necessary. The effective range of years that can be expressed by this format is 1 AD to 4095 AD. Because the year 0 AD is not a legal year in the Gregorian calendar, this value should never be zero. The indexed list below indicates which byte (first byte being the MSB) contains what information: 1. Upper 8 bits of the year quantifier. 2. Upper 4 bits are the four least significant bits of the 12-bit year quantifier. The lower 4 bits are the month quantifier, ranging from 0 to 11. 3. Day of month quanitifier. Ranges from 0 to 30. 4. Hour quantifier. Ranges from 0 to 23. 5. Minute quantifier. Ranges from 0 to 59. 6. Second quantifier. Ranges from 0 to 59. In the event that an endpoint cannot evaluate a date required by the protocol as a result of some error, an error sockstamp will be sent in its place. An error sockstamp takes the form of zeroes in all bits. If an endpoint receives a sockstamp where the year quantifier is zero but any other quantifiers are nonzero, there is a communication error and the endpoint must close the connection.