TCP/IP Network Protocol
Introduction
This document describes the TCP/IP protocol used by Bareos to communicate between the various daemons and services. The definitive definition of the protocol can be found in src/lib/bsock.h, src/lib/bnet.c and src/lib/bnet_server.c.
Bareos’s network protocol is basically a “packet oriented” protocol built on a standard TCP/IP streams. At the lowest level all packet transfers are done with read() and write() requests on system sockets. Pipes are not used as they are considered unreliable for large serial data transfers between various hosts.
The chapter Network Sequence Diagrams contains message sequences of backup, restore and copy jobs as examples, respectively.
Network Routines
Using the routines described below (bnet_open, bnet_write, bnet_recv, and bnet_close) guarantees that the number of bytes you write into the socket will be received as a single record on the other end regardless of how many low level write() and read() calls are needed. All data transferred are considered to be binary data.
bnet and Threads
These bnet routines work fine in a threaded environment. However, they assume that there is only one reader or writer on the socket at any time. It is highly recommended that only a single thread access any BSOCK packet. The exception to this rule is when the socket is first opened and it is waiting for a job to start. The wait in the Storage daemon is done in one thread and then passed to another thread for subsequent handling.
If you envision having two threads using the same BSOCK, think twice, then you must implement some locking mechanism. However, it probably would not be appropriate to put locks inside the bnet subroutines for efficiency reasons.
bnet_open
To establish a connection to a server, use the subroutine:
BSOCK *bnet_open(void *jcr, char *host, char *service, int port, int *fatal) bnet_open(), if successful, returns the Bareos sock descriptor pointer to be used in subsequent bnet_send() and bnet_read() requests. If not successful, bnet_open() returns a NULL. If fatal is set on return, it means that a fatal error occurred and that you should not repeatedly call bnet_open(). Any error message will generally be sent to the JCR.
bnet_send
To send a packet, one uses the subroutine:
int bnet_send(BSOCK *sock) This routine is equivalent to a write() except that it handles the low level details. The data to be sent is expected to be in sock->msg and be sock->msglen bytes. To send a packet, bnet_send() first writes four bytes in network byte order than indicate the size of the following data packet. It returns:
Returns 0 on failure
Returns 1 on success
In the case of a failure, an error message will be sent to the JCR contained within the bsock packet.
bnet_fsend
This form uses:
int bnet_fsend(BSOCK *sock, char *format, …) and it allows you to send a formatted messages somewhat like fprintf(). The return status is the same as bnet_send.
is_bnet_error
Fro additional error information, you can call is_bnet_error(BSOCK *bsock) which will return 0 if there is no error or non-zero if there is an error on the last transmission.
is_bnet_stop
The is_bnet_stop(BSOCK *bsock) function will return 0 if there no errors and you can continue sending. It will return non-zero if there are errors or the line is closed (no more transmissions should be sent).
bnet_recv
To read a packet, one uses the subroutine:
int bnet_recv(BSOCK *sock) This routine is similar to a read() except that it handles the low level details. bnet_read() first reads packet length that follows as four bytes in network byte order. The data is read into sock->msg and is sock->msglen bytes. If the sock->msg is not large enough, bnet_recv() realloc() the buffer. It will return an error (-2) if maxbytes is less than the record size sent.
It returns:
>0: number of bytes read
0: on end of file
-1: on hard end of file (i.e. network connection close)
-2: on error
It should be noted that bnet_recv() is a blocking read.
bnet_sig
To send a “signal” from one daemon to another, one uses the subroutine:
int bnet_sig(BSOCK *sock, SIGNAL) where SIGNAL is one of the following:
BNET_EOF - deprecated use BNET_EOD
BNET_EOD - End of data stream, new data may follow
BNET_EOD_POLL - End of data and poll all in one
BNET_STATUS - Request full status
BNET_TERMINATE - Conversation terminated, doing close()
BNET_POLL - Poll request, I’m hanging on a read
BNET_HEARTBEAT - Heartbeat Response requested
BNET_HB_RESPONSE - Only response permitted to HB
BNET_PROMPT - Prompt for UA
bnet_strerror
Returns a formated string corresponding to the last error that occurred.
bnet_close
The connection with the server remains open until closed by the subroutine:
void bnet_close(BSOCK *sock)
Becoming a Server
The bnet_open() and bnet_close() routines described above are used on the client side to establish a connection and terminate a connection with the server. To become a server (i.e. wait for a connection from a client), use the routine bnet_thread_server. The calling sequence is a bit complicated, please refer to the code in bnet_server.c and the code at the beginning of each daemon as examples of how to call it.
Higher Level Conventions
Within Bareos, we have established the convention that any time a single record is passed, it is sent with bnet_send() and read with bnet_recv(). Thus the normal exchange between the server (S) and the client (C) are:
S: wait for connection C: attempt connection
S: accept connection C: bnet_send() send request
S: bnet_recv() wait for request
S: act on request
S: bnet_send() send ack C: bnet_recv() wait for ack
Thus a single command is sent, acted upon by the server, and then acknowledged.
In certain cases, such as the transfer of the data for a file, all the information or data cannot be sent in a single packet. In this case, the convention is that the client will send a command to the server, who knows that more than one packet will be returned. In this case, the server will enter a loop:
while ((n=bnet_recv(bsock)) > 0) {
act on request
}
if (n < 0)
error
The client will perform the following:
bnet_send(bsock);
bnet_send(bsock);
...
bnet_sig(bsock, BNET_EOD);
Thus the client will send multiple packets and signal to the server when all the packets have been sent by sending a zero length record.
Network startup activity
The following diagram shows the activity on a Bareos TCP server (i.e. a Bareos Director or a Bareos Storage Daemon) when a TCP client initiates a network connection. The connection protocol has two possible handshake modes. Cleartext first or TLS first. Depending on the configuration, the Bareos version and the type of client (i.e. Bareos File Daemon or Bareos Console) the handshake mode will be chosen. See chapter TLS for detailed information.
Debugging
Developers who want to debug the message flow can use the network dump feature. This feature is only for experts and developers and is not intended for use in a production system. Therefore no help will be provided on the command line. The arguments however can be mixed with the standard arguments.
Usage: [bconsole|bareos-dir|bareos-fd|bareos-sd]
-z <filename> name and path of the dumpfile
(setting this switches on the network dump)
-zp use the plantuml notation
-z <stackdepth> for additional stacktrace, stackdepth=-1: print all frames,
stackdepth=n: print up to n frames
Network Sequence Diagrams
This chapter contains diagrams of the network traffic for the most common jobs. The jobs are simplified as much as possible to show the essence of the network traffic. Refer to chapter Job Execution for sequence diagrams with the internal program flow.
Backup of a Single File
Overview
Detailed Diagram
Restore of a Single File
Overview single file restore
Detailed Diagram single file restore
Migration of a Single Volume
Overview single volume migration
Detailed Diagram single volume migration
Verify of a Single File (Mode: Volume to Catalog)
Overview single file verify
Detailed Diagram single file verify