Distcc

Distcc is a program designed to distribute compiling tasks across a network to participating hosts. It is comprised of a server,, and a client program,. Distcc can work transparently with ccache, Portage, and Automake with a small amount of setup.

When planning on using to help bootstrap a Gentoo installation, make sure to read Using distcc to bootstrap.

Installation
Before configuring, let's first look into the installation of the package on all hosts.

Requirements across all hosts
In order to use, all of the computers on the network need to have the same GCC versions. For example, mixing 3.3.x (where the x varies) is okay, but mixing 3.3.x with 3.2.x may result in compilation errors or runtime errors.

Verify that all systems use the same version of binutils (eselect binutils list) or many packages will fail linking with various errors like text relocation.

Emerge
Distcc ships with a graphical monitor to monitor tasks that a computer is sending away for compilation. This monitor is enabled when the  USE flag is set.

After configuring the USE setting, install the package:

Service
In order to have started automatically follow the next set of instructions.

OpenRC
Edit and make sure to set the   directive to allow only trusted clients. For added security, use the  directive to tell the  daemon what IP to listen on (for multi-homed systems). More information on security can be found at Distcc security notes.

The following example allows the distcc clients running at  and   to connect to the  server running locally:

Now start the daemon on all the participating computers:

systemd
Edit the file to add the allowed clients in CIDR format. Matching the example will add all IP addresses in the 192.168.1.xxx range:

Reload the unit files after making such changes:

Enable auto-starting and then start the service:

Specifying participating hosts
Use the command to set the list of hosts.

The following is an example list of host definitions. In most cases, variants of lines 1 and 2 suffice. The latter uses the  syntax to inform  about the maximum amount of jobs to be launched on this node. More information about the syntax used in lines 3 and 4 can be found in the distcc manual page.

There are also several other methods of setting up hosts. See the man page  for more details.

If compilations should also occur on the local machine, put  in the hosts list. Conversely if the local machine is not to be used to compile, omit it from the hosts list. On a slow machine using localhost may actually slow things down. Make sure to test the settings for performance.

Let's configure to use the hosts mentioned on the first line in the example:

Distcc also supports a pump mode, by invoking the command. This may significantly reduce build time when multiple files are compiled in parallel. It caches preprocessed headers on the server side and, as a result, gets rid of repeated uploading and preprocessing of these header files.

To configure a host for pump mode, add the  suffix to the hosts definitions. Pump mode requires both  and   flags (regardless of the files being C or C++).

With Portage
Setting up Portage to use is easy. It is a matter of enabling the feature, and setting a decent value for the number of simultaneous build jobs (as  increases the amount of build resources).

Set the MAKEOPTS variable and FEATURES variable as shown below.

A common strategy is to
 * set the value of  to twice the number of total (local + remote) CPU cores + 1, and
 * set the value of  to the number of local CPU cores

The use of  in the MAKEOPTS variable will prevent spawning too many tasks when some of the  cluster hosts are unavailable (increasing the amount of simultaneous jobs on the other systems) or when an ebuild is configured to disallow remote builds (such as with gcc). This is accomplished by refusing to start additional jobs when the system load is at or above the value of.

For instance, when there are two quad-core host PCs running and the local PC has a dual core CPU, then the MAKEOPTS variable could look like this:

CFLAGS and CXXFLAGS
While editing the file, make sure that it does not have   in the CFLAGS or CXXFLAGS variables. will not distribute work to other machines if  is set to. Instead it should list exact platform and a few extra flags your CPU needs. Something like:

See Inlining  for distcc for more information.

A GCC bug has recently been fixed in the 8.0 dev tree which facilitates a more reliable and succinct mechanism for extrapolating appropriate machine flags. The fix has been backported to the 6 and 7 branches and should be released fairly soon. Some processing is still required and a script can be found in the distccflags repo, or via :

With automake
This is, in some cases, easier than the Portage setup. All that is needed is to update the PATH variable to include in front of the directory that contains. However, there is a caveat. If is used, then put the  location after the  one:

Put this in the user's or equivalent file to have the PATH set every time the user logs in, or set it globally through an  file.

Instead of calling alone, add in   (where   is an integer). The value of  depends on the network and the types of computers that are used to compile. A heuristic approach to the right value is given earlier in this article.

To bootstrap
Using to bootstrap (i.e. build a working toolchain before installing the remainder of the system) requires some additional steps to take.

Step 1: Configure Portage
Boot the new box with a Gentoo Linux LiveCD and follow the installation instructions, while keeping track of the instructions in the Gentoo FAQ for information about bootstrapping. Then configure Portage to use :

Update the PATH variable in the installation session as well:

Step 2: Getting distcc
Install :

You may receive an error similar to the following when attempting to install distcc:

!!! Problem resolving dependencies for sys-devel/distcc

!!! The ebuild selected to satisfy "sys-devel/distcc" has unmet requirements. - sys-devel/distcc-3.2_rc1-r4::gentoo USE="-crossdev -gnome -gssapi -gtk -hardened -ipv6 (-selinux) -xinetd -zeroconf" ABI_X86="(64)" PYTHON_TARGETS="-python2_7"

The following REQUIRED_USE flag constraints are unsatisfied: python_targets_python2_7

This can be fixed using the following command:

Step 3: Setting up distcc
Run to setup distcc; substitute the   in the example with the IP addresses or hostnames of the participating nodes.

Distcc is now set up to bootstrap! Continue with the proper installation instructions and do not forget to run after running. This is to make sure that all of the necessary dependencies are installed.

With ccache
Keks24 (talk) is currently working here. :)

Extras
The application has additional features and applications to support working in a  environment.

Monitoring utilities
Distcc ships with two monitoring utilities. The text-based monitoring utility is always built and is called. Running it for the first time can be a bit confusing, but it is really quite easy to use. If the program is run with no parameter it will run just once. However, if it is passed a number it will update every  seconds, where   is the argument that was passed.

The other monitoring utility is only enabled when the  USE flag is set. This one is GTK based, runs in an X environment, and it is quite lovely. For Gentoo, the GUI monitor has been renamed to to make it less confusing (it is originally called ).

To monitor Portage's usage:

A trick is to set DISTCC_DIR in environment variables:

Now update the environment:

Finally, start the GUI application:

SSH for communication
Setting up distcc via SSH includes some pitfalls. First, generate an SSH key pair without password setup. Be aware that portage compiles programs as the Portage user (or as root if  is not set). The home folder of the Portage user is, which means the keys need to be stored in

Second, create a section for each host in the SSH configuration file:

Send the public key to each compilation node:

Also make sure that each host is available in the file:

Fix the file ownership as follows:

To set up the hosts  and , run:

Please note the  (@ sign), which specifies ssh hosts for distcc.

Finally, tell which SSH binary to use:

It is not necessary to run the initscript on the hosts when  communicates via SSH.

Testing
To test, write a simple Hello distcc program and run in verbose mode to see if it communicates properly.

Next, turn on verbose mode, compile the program using and link the generated object file into an executable:

There should be a bunch of output about finding its configuration, selecting the host to connect to, starting to connect to it, and ultimately compile. If the output does not list the desired hosts, check the configuration.

Finally, ensure the compiled program works properly. To test each host, enumerate each compile host in the hosts file.

Troubleshooting
If a problem occurs while using, then this section might help in resolving the problem.

ERROR: failed to open
As of January 22nd, 2015 emerging fails to create the proper file in. This apparently only effects version 3.1-r8 of distcc. This bug is in the process of being corrected (see ). It is possible to work around this by manually creating the log file, giving it proper ownership, and restarting the distccd daemon:

Next update the path of the  configuration file in  to the  directory created in the step before:

Finally, restart the distccd service:

Some packages do not use distcc
As various packages are installed, users will notice that some of them aren't being distributed (and aren't being built in parallel). This may happen because the package' doesn't support parallel operations, or the maintainer of the ebuild has explicitly disabled parallel operations due to a known problem.

Sometimes might cause a package to fail to compile. If this happens, please report it.

Mixed GCC versions
If the environment hosts different GCC versions, there will likely be very weird problems. The solution is to make certain all hosts have the same GCC version.

Recent Portage updates have made Portage use  (minus gcc) instead of. This means that if i686 machines are mixed with other types (i386, i586) then the builds will run into troubles. A workaround for this may be to run:

It is also possible to set the CC and CXX variables in to the values list in the command above.

-march=native
Starting with GCC 4.3.0, the compiler supports the  option which turns on CPU auto-detection and optimizations that are worth being enabled on the processor on which GCC is running. This creates a problem when using because it allows the mixing of code optimized for different processors. For example, running with   on a system that has an AMD Athlon processor and doing the same on another system that has an Intel Pentium processor will mix code compiled on both processors together.

Heed the following warning:

See the CFLAGS and CXXFLAGS section and Inlining  for distcc for more information.

Network is unreachable
Due to network restrictions introduced by the feature, you may run into this issue. Since contradicts with this security feature, you have to disable it:

Get more output from emerge logs
It is possible to obtain more logging by enabling verbose mode. This is accomplished by adding DISTCC_VERBOSE to :

The verbose logging can then be found in.

Keep in mind that the first invocation visible in  isn’t necessary the first  call during a build process. For example a build server can get a one-minute backoff period during the configuration stage when some checks are performed using a compiler ( sets a backoff period when compilation on a remote server failed, it doesn’t matter whether it failed on local machine or not).

Dig into the directory to investigate such situations. Find other logs, or call explicitly from within the working directory.

Another interesting variable to use is DISTCC_SAVE_TEMPS. When set, it saves the standard output/error from a remote compiler which, for Portage builds, results in files in the directory.

External resources

 * Inlining  for distcc
 * Distcc on Github
 * Distcc homepage