Signed-off-by: David Oberhollenzer <david.oberhollenzer@tele2.at>
12 KiB
The Pygos Build System
The Pygos system can be built by running the mk.sh
shell script with
the following two arguments:
- the target board to build the system for
- the product to build
The shell script can be run from anywhere on the file system. All configuration files and scripts are accessed relative to the source location of the script and all generated files are accessed relative to the current working directory.
Actually it is even strongly encouraged to run the build system from outside the git tree to have the generated files cleanly separated from the build system.
A second script named check_update.sh
is provided to automatically query
all upstream package sources to check if newer versions are available.
The mk.sh
creates a download
and a src
directory. In the former it stores
downloaded package tar balls, in the later it extracts the tar balls.
For target specific files, a <BOARD>-<PRODUCT>
directory is created.
Throughout the build system, this directory is refereed to as build root.
Inside the build root a deploy
directory is created. Build output for each
package is deployed to a sub directory named after the package.
The cross toolchain is stored in <BOARD>-<PRODUCT>/toolchain
.
Outputs and diagnostic messages of the build processes are stored in
<BOARD>-<PRODUCT>/toolchain/log/<package>-<stage>.log
.
Package Build Scripts
The directory pkg
contains a sub directory for each package. Each package
directory is expected to contain a shell script named build
.
The build script is expected to set the following variables:
VERSION
containing a package version number.URL
containig a URL from which to download a source tar ball.TARBALL
containing the name of the source tar ball. This is appended to the URL to download the package.SHA256SUM
containing the SHA-256 check sum of the source tar ball.SRCDIR
containing the name of the source directory unpacked from the tar ball.DEPENDS
containing a space separated list of packages that the package in question depends on. Those packages are built first. Their headers and libraries are copied into the cross toolchain before building the current package and removed after building it.
Using the specified variables, the build system automatically downloads, verifies and unpacks the source tar balls (unless that has already been done) and determines the order in which to build the packages.
The build
script is also expected to implement the following functions:
prepare
is run after unpacking the source tar ball. The current working directory is set to the source directory. The path to the package directory is passed as first argument, so the function can easily access patch files stored in the package directory. All output and error messages from the script are stored in<packagename>-prepare.log
.build
is run to compile the package. The current working directory is a temporary directory inside the build root directory. The source directory is passed as first argument. The second argument is a path to the deploy directory where generated files are installed. All standard output and error messages from the script are piped to<packagename>-build.log
.deploy
is run after compilation to install the build output to the deploy directory. Arguments and working directory are the same as forbuild
. All output and error messages from the script are piped to<packagename>-deploy.log
. Once the function returns, themk.sh
script strips everything installed tobin
andlib
, so the implementation doesn't have to do that. In factinstall-strip
Makefile targets should not be used since many implementations are broken for cross compilation.check_update
is only used by thecheck_update.sh
script. It is supposed to find out if the package has a newer version available, and if so, echo it to stdout.
Environment Variables
The mk.sh
sets a number of shell variables that package scripts can use.
The following variables describe the target system and the build environment:
BOARD
contains the target board specified on the command linePRODUCT
contains the product name specified on the command lineTARGET
specifies the host triplet of the target boardOS_NAME
is statically set toPygos
OS_RELEASE
holds a version string generated usinggit-describe
NUMJOBS
contains the number of processors available for parallel buildsHOSTTUPLE
contains the host triplet of the machine that the build system is running on for compiling toolchain packages.CMAKETCFILE
contains the absolute path to a CMake toolchain file that can be used for compiling CMake based packages with the cross toolchain.
And a number of variables containing special directories:
BUILDROOT
contains the absolute path to the build root directory, i.e. the working directory in which themk.sh
script was executed.SCRIPTDIR
contains the absolute path to the script directory, i.e. the git tree with the build system in it.TCDIR
contains the absolute path to the cross toolchain directory.PKGBUILDDIR
contains the absolute path of the temporary directory in which the package is being built.PKGSRCDIR
contains the root directory of all unpacked package tar ballsPKGDEPLOYDIR
contains the root directory of all package deploy directoriesPKGLOGDIR
holds the absolute path of the directory containing all log filesPKGDOWNLOADDIR
holds the absolute path of the directory containing all package tar balls
The toolchain bin directory containing the executable prefixed with $TARGET-
is also prepended to PATH
.
Utility Functions
Some utility functions are provided for common package build tasks:
apply_patches
can be used inside theprepare
function to automatically apply patches stored in the package directory to the source tree.strip_files
takes a list of files as argument and runs the cross toolchain strip program on those that are valid ELF binaries. If a directory is encountered, the function recursively processes the sub directory. Usually you don't need to use this. Themk.sh
script uses this function to after the deploy step to process thebin
andlib
directories.verson_find_greatest
can be used incheck_update
to find the largest version number from a list. The list of version numbers is read from stdin. Version numbers can have up to four dot separated numbers or characters.
Configuration Files
Generally, when the build system tries to access configuration files, it checks the following three locations in order:
product/<product>/<board>
product/<product>/
board/<board>/
In most cases, if one location contains a file, searching stops. This means, that a product configuration can override settings from the basic board configuration and the product itself can contain board specific settings that can override the generic product configuration.
In some cases, it makes more sense to merge the files from all three locations to achieve the desired behavior. For files that contains shell variables, merging is done in reverse order, this results in the same override behavior, but on shell variable level.
The build system currently uses the following configuration files:
ROOTFS
contains a list of packages that should be built and installed to the root filesystem. This file is merged from all three config locations.TOOLCHAIN
contains shell variables for the cross compiler toolchain. Merged from all three config locations. See below for more detail.LDPATH
contains a list of directories where the loader should look for dynamic libraries. Merged from all three config locations.INIT
contains shell variables configuring the init system. Merged from all three config locations. See below for more detail.BOARDS
contains a list of supported boards. It is directly read from the product directory to check if a product can be built for the specified board.
Utility Functions
For working with configuration files, the following utility functions can be used:
file_path_override
takes a file name and looks for it in the standard config locations. The absolute path of the first found file is returned.cat_file_override
takes a file name and looks for it in the standard config locations. The first file found is printed to stdout.cat_file_merge
takes a file name and looks for it in the standard config locations. Every found file is printed to stdout.include_override
takes a file name and looks for it in the standard config locations. The first file found is included using thesource
shell builtin.include_merge
takes a file name and looks for it in the standard config locations. Every found file is included using thesource
shell builtin. Locations are processed in reverse to get default override behavior on shell variable and function level.
Toolchain Configuration
The toolchain configuration file contains a list of shell variables for configuring the cross toolchain packages, as well as some other packages that need to know information about the target system.
Currently, the following variables are used:
TARGET
specifies the target triplet for the cross toolchain, which is also the host triplet for packages cross compiled with autotools.GCC_CPU
specifies the target processor for GCC.GCC_EXTRACFG
extra configure arguments passed to GCC. For instance, this may contain FPU configuration for ARM targets.MUSL_CPU
contains the target CPU architecture for the Musl C library.LINUXPKG
contains the name of the kernel package. There is a default package called 'linux' that builds a standard, main line kernel. Other packages can be specified for building vendor kernels.LINUX_CPU
contains the value of theARCH
variable passed to the kernel build system. Used by the generic main line kernel package.LINUX_TGT
contains the make target for the generic main line kernel package.OPENSSL_TARGET
contains the target architecture for the OpenSSL package.
Init System Configuration
The INIT configuration file contains a list of shell variables for configuring the init system.
Currently, the following variables are used:
GETTY_TTY
contains a space separated list of ttys on which to start agetty on system boot.HWCLOCK
is set to yes if the system has a hardware clock that the time should be synchronized with during system boot and shutdown.DHCP_PORTS
contains a space separated list of network interfaces on which to operate a DHCP client for network auto configuration.SERVICES
contains a space separated list of raw service names to enable.
For configuring network interfaces, a file ifrename
exists that assigns
persistent, predictable names to network interfaces.
The default naming scheme of the Pygos system is to rename the Ethernet interfaces installed on the board to port where X is an index starting with 0.
For each network interface, addresses, mtu, offloading, etc can be configured
in a file interfaces/<name>
, where name is the interface name after
renaming.
For more details, please refer to the not yet existing network documentation.
Package Specific Configuration Files
Additional configuration files may be present that are used by various packages.
The following files are currently used (with default override behavior):
linux.config
contains the kernel build configuration. The same name is currently used by both the main line and the board specific vendor kernels.dnsmasq.conf
is installed to/etc
by the dnsmasq package.unbound.conf
is installed to/etc
by the unbound package.dhcpcd.conf
is installed to/etc
by the dhcpcd package.