Build Instructions ------------------ * Requirements ------------ - A Linux-based system with a standard C development environment - GNU make version 3.81 or later - skalibs version 2.14.0.0 or later: https://skarnet.org/software/skalibs/ This software is Linux-specific. It will run on a Linux kernel, version 3.5 or later. * Standard usage -------------- ./configure && make && sudo make install will work for most users. It will install the binaries in /bin. You can strip the binaries and libraries of their extra symbols via "make strip" before the "make install" phase. It will shave a few bytes off them. * Customization ------------- You can customize paths via flags given to configure. See ./configure --help for a list of all available configure options. * Environment variables --------------------- Controlling a build process via environment variables is a big and dangerous hammer. You should try and pass flags to configure instead; nevertheless, a few standard environment variables are recognized. If the CC environment variable is set, its value will override compiler detection by configure. The --host=HOST option will still add a HOST- prefix to the value of CC. The values of CFLAGS, CPPFLAGS and LDFLAGS will be appended to flags auto-detected by configure. To entirely override the flags set by configure instead, use make variables. * Make variables -------------- You can invoke make with a few variables for more configuration. CC, CFLAGS, CPPFLAGS, LDFLAGS, LDLIBS, AR, RANLIB, STRIP, INSTALL and CROSS_COMPILE can all be overridden on the make command line. This is an even bigger hammer than running ./configure with environment variables, so it is advised to only do this when it is the only way of obtaining the behaviour you want. DESTDIR can be given on the "make install" command line in order to install to a staging directory. * Shared libraries ---------------- Software from skarnet.org is small enough that shared libraries are generally not worth using. Static linking is simpler and incurs less runtime overhead and less points of failure: so by default, shared libraries are not built and binaries are linked against the static versions of the skarnet.org libraries. Nevertheless, you can: * build shared libraries: --enable-shared * link binaries against shared libraries: --disable-allstatic * Static binaries --------------- By default, binaries are linked against static versions of all the libraries they depend on, except for the libc. You can enforce linking against the static libc with --enable-static-libc. Be aware that the GNU libc behaves badly with static linking and produces huge executables, which is why it is not the default. Other libcs are better suited to static linking, for instance musl: http://musl-libc.org/ * Cross-compilation ----------------- skarnet.org packages centralize all the difficulty of cross-compilation in one place: skalibs. Once you have cross-compiled skalibs, the rest is easy. * Use the --host=HOST option to configure, HOST being the triplet for your target. * Make sure your cross-toolchain binaries (i.e. prefixed with HOST-) are accessible via your PATH environment variable. * Make sure to use the correct version of skalibs for your target, and the correct sysdeps directory, making use of the --with-include, --with-lib, --with-dynlib and --with-sysdeps options as necessary. * The slashpackage convention --------------------------- The slashpackage convention (http://cr.yp.to/slashpackage.html) is a package installation scheme that provides a few guarantees over other conventions such as the FHS, for instance fixed absolute pathnames. skarnet.org packages support it: use the --enable-slashpackage option to configure, or --enable-slashpackage=DIR for a prefixed DIR/package tree. This option will activate slashpackage support during the build and set slashpackage-compatible installation directories. If $package_home is the home of the package, defined as DIR/package/$category/$package-$version with the variables read from the package/info file, then: --dynlibdir is set to $package_home/library.so --bindir is set to $package_home/command --sbindir is also set to $package_home/command (slashpackage differentiates root-only binaries by their Unix rights, not their location in the filesystem) --libexecdir is also set to $package_home/command (slashpackage does not need a specific directory for internal binaries) --libdir is set to $package_home/library --includedir is set to $package_home/include --prefix is pretty much ignored when you use --enable-slashpackage. You should probably not use both --enable-slashpackage and --prefix. When using slashpackage, two additional Makefile targets are available after "make install": - "make update" changes the default version of the software to the freshly installed one. (This is useful when you have several installed versions of the same software, which slashpackage supports.) - "make -L global-links" adds links from /command and /library.so to the default version of the binaries and shared libraries. The "-L" option to make is necessary because targets are symbolic links, and the default make behaviour is to check the pointed file's timestamp and not the symlink's timestamp. * Absolute pathnames ------------------ You may want to use fixed absolute pathnames even if you're not following the slashpackage convention: for instance, the Nix packaging system prefers calling binaries with immutable paths rather than rely on PATH resolution. If you are in that case, use the --enable-absolute-paths option to configure. This will ensure that programs calling binaries from this package will call them with their full installation path (in bindir) without relying on a PATH search. * Out-of-tree builds ------------------ skarnet.org packages do not support out-of-tree builds. They are small, so it does not cost much to duplicate the entire source tree if parallel builds are needed. * Multicall binary ---------------- Starting with version 2.6.1.0, the s6-linux-utils package comes with an alternative build in the form of a multicall binary, simply called "s6-linux-utils", that includes the functionality of *all* the other binaries; it switches functionalities depending on the name it is called with, or the subcommand it is given: "s6-linux-utils s6-ps -H" will print a tree of the current running processes, same as "s6-ps -H" if s6-ps is a link to the s6-linux-utils program. To use this, use the --enable-multicall option to configure. Only the s6-linux-utils binary will be built, and other programs will be created as symbolic links to s6-linux-utils at installation time. The multicall setup saves a lot of disk space, at the price of an unnoticeable amount of CPU usage. RAM usage is about equivalent and difficult to assess. The setup is meant for embedded devices or small distributions with a focus on saving disk space.