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Table of Contents
The Samba server uses TCP to talk to the client, so if you are trying to see if it performs well, you should really compare it to programs that use the same protocol. The most readily available programs for file transfer that use TCP are ftp or another TCP-based SMB server.
If you want to test against something like an NT or Windows for Workgroups server, then you will have to disable all but TCP on either the client or server. Otherwise, you may well be using a totally different protocol (such as NetBEUI) and comparisons may not be valid.
Generally, you should find that Samba performs similarly to ftp at raw transfer speed. It should perform quite a bit faster than NFS, although this depends on your system.
Several people have done comparisons between Samba and Novell, NFS, or Windows NT. In some cases Samba performed the best, in others the worst. I suspect the biggest factor is not Samba versus some other system, but the hardware and drivers used on the various systems. Given similar hardware, Samba should certainly be competitive in speed with other systems.
There are a number of socket options that can greatly affect the performance of a TCP-based server like Samba.
The socket options that Samba uses are settable both on the command
line with the -O
option and in the smb.conf
file.
The socket options section of the smb.conf
manual page describes how
to set these and gives recommendations.
Getting the socket options correct can make a big difference to your performance, but getting them wrong can degrade it by just as much. The correct settings are very dependent on your local network.
The socket option TCP_NODELAY is the one that seems to make the biggest single difference for most networks. Many people report that adding socket options = TCP_NODELAY doubles the read performance of a Samba drive. The best explanation I have seen for this is that the Microsoft TCP/IP stack is slow in sending TCP ACKs.
There have been reports that setting socket options = SO_RCVBUF=8192
in smb.conf
can seriously degrade Samba performance on the loopback adaptor (IP Address 127.0.0.1). It is strongly
recommended that before specifying any settings for socket options
, the effect
first be quantitatively measured on the server being configured.
The option read size affects the overlap of disk reads/writes with network reads/writes. If the amount of data being transferred in several of the SMB commands (currently SMBwrite, SMBwriteX, and SMBreadbraw) is larger than this value, then the server begins writing the data before it has received the whole packet from the network, or in the case of SMBreadbraw, it begins writing to the network before all the data has been read from disk.
This overlapping works best when the speeds of disk and network access are similar, having little effect when the speed of one is much greater than the other.
The default value is 16384, but little experimentation has been done as yet to determine the optimal value, and it is likely that the best value will vary greatly between systems anyway. A value over 65536 is pointless and will cause you to allocate memory unnecessarily.
At startup the client and server negotiate a maximum transmit
size,
which limits the size of nearly all SMB commands. You can set the
maximum size that Samba will negotiate using the max xmit option
in smb.conf
. Note that this is the maximum size of SMB requests that
Samba will accept, but not the maximum size that the client will accept.
The client maximum receive size is sent to Samba by the client, and Samba
honors this limit.
It defaults to 65536 bytes (the maximum), but it is possible that some clients may perform better with a smaller transmit unit. Trying values of less than 2048 is likely to cause severe problems. In most cases the default is the best option.
If you set the log level (also known as debug level) higher than 2, then you may suffer a large drop in performance. This is because the server flushes the log file after each operation, which can be quite expensive.
The read raw operation is designed to be an optimized, low-latency file read operation. A server may choose to not support it, however, and Samba makes support for read raw optional, with it being enabled by default.
In some cases clients do not handle read raw very well and actually get lower performance using it than they get using the conventional read operations, so you might like to try read raw = no and see what happens on your network. It might lower, raise, or not affect your performance. Only testing can really tell.
The write raw operation is designed to be an optimized, low-latency file write operation. A server may choose to not support it, however, and Samba makes support for write raw optional, with it being enabled by default.
Some machines may find write raw slower than normal write, in which case you may wish to change this option.
Slow logins are almost always due to the password checking time. Using the lowest practical password level will improve things.
Often a speed problem can be traced to the client. The client (for example Windows for Workgroups) can often be tuned for better TCP performance. Check the sections on the various clients in Samba and Other CIFS Clients.
A user wrote the following to the mailing list:
I am running Gentoo on my server and Samba 2.2.8a. Recently I changed kernel versions from
linux-2.4.19-gentoo-r10
tolinux-2.4.20-wolk4.0s
. Now I have a performance issue with Samba. Many of you will probably say, “Move to vanilla sources!” Well, I tried that and it didn't work. I have a 100MB LAN and two computers (Linux and Windows 2000). The Linux server shares directories with DivX files, the client (Windows 2000) plays them via LAN. Before, when I was running the 2.4.19 kernel, everything was fine, but now movies freeze and stop. I tried moving files between the server and Windows, and it is terribly slow.
The answer he was given is:
Our Samba PDC server has been hosting three TB of data to our 500+ users [Windows NT/XP] for the last three
years using Samba without a problem. Today all shares went very slow. Also, the main smbd kept spawning new
processes, so we had 1600+ running SMDB's (normally we average 250). It crashed the SUN E3500 cluster twice.
After a lot of searching, I decided to rm /var/locks/*.tdb
. Happy again.
Question: Is there any method of keeping the *.tdb files in top condition, or how can I detect early corruption?
Answer: Yes, run tdbbackup
each time after stopping nmbd and before starting nmbd.
Question: What I also would like to mention is that the service latency seems a lot lower than before the locks cleanup. Any ideas on keeping it top notch?
Answer: Yes. Same answer as for previous question!
A site reported experiencing very baffling symptoms with MYOB Premier opening and accessing its data files. Some operations on the file would take between 40 and 45 seconds.
It turned out that the printer monitor program running on the Windows clients was causing the problems. From the logs, we saw activity coming through with pauses of about 1 second.
Stopping the monitor software resulted in the networks access at normal (quick) speed. Restarting the program caused the speed to slow down again. The printer was a Canon LBP-810 and the relevant task was something like CAPON (not sure on spelling). The monitor software displayed a "printing now" dialog on the client during printing.
We discovered this by starting with a clean install of Windows and trying the application at every step of the installation of other software process (we had to do this many times).
Moral of the story: Check everything (other software included)!