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Building Packages

This page provides information regarding the package building process. The first section documents building a package with the low level command "package". The second section refers to building packages with the "haikuporter" tool.

Building a Package with the “package” Command

The package file format is specified in detail in a

separate document

. This section presents information from the perspective of how to build a package file with the "package" command.

An hpkg file is an archive file (just like tar or zip files) that additionally contains package meta information in a separate section of the file. When building an hpkg file via the "package" command the meta information must be provided via a ".PackageInfo" file. For convenience, the file itself is added to the archive as well and can be extracted later, but it will be ignored by packagefs.

The ".PackageInfo" file must be located in the top directory that is archived. A "package" invocation usually looks like that:

package create -C foo-4.5.26-1 foo-4.5.26-1-x86.hpkg

or (packaging a gcc2 build from within the folder):

cd foo-4.5.26-1
package create ../foo-4.5.26-1-x86_gcc2.hpkg

The argument of the "-C" option specifies the directory whose contents to archive (by default the current directory), the remaining argument is the path of the package file to be built.

The .PackageInfo

The contents of the ".PackageInfo" adheres to a restricted driver settings syntax. It consists of name-value pairs, following this simple grammar:

package_info  ::= attribute*
attribute     ::= name value_list
value_list    ::= value | ( "{" value* "}" )
value         ::= value_item+ ( '\n' | ';' )

"name" can be one of the attribute names defined below. "value_item" is either an unquoted string not containing any whitespace characters or a string enclosed in quotation marks (""" or "'") which can contain whitespace and also escaped characters (using "\").

The supported attributes are:

entity_name_char    ::= any character but '-', '/', '=', '!', '<', '>', or whitespace

peter.packman@example.com

”).

http://foo.example.com

”).
entity      ::= entity_name [ "=" version_ref ] [ ( "compat" | "compatible" ) ">=" version_ref ]
entity_name ::= [ entity_type ":" ] entity_name_char+
entity_type ::= "lib" | "cmd" | "app" | "add_on"

See the Version Strings section for the "version_ref" definition. The first "version_ref" specifies the version of the provided entity. It can be omitted e.g. for abstract resolvables like “web_browser”. The "version_ref" after the “compat”/”compatible” string specifies the oldest version the resolvable is backwards compatible with. The "entity_type" specifies the type of entity provided: a library (“lib”), a command line program (“cmd”), an application (“app”), or an add-on (“add-on”).

required_entity     ::= entity_name [ version_operator version_ref [ "base" ] ]
version_operator    ::= "<" | "<=" | "==" | "!=" | ">=" | ">"

See the Version Strings section for the "version_ref" definition. If “base” is specified, the specified entity is the base package for this package. The package manager shall ensure that this package is installed in the same installation location as its base package.

global_writable_file_info   ::= path [ "directory" ] [ "keep-old" | "manual" | "auto-merge" ]

"path" is the relative path of the writable file or directory, starting with “settings/” or any other writable directory. If the “directory” keyword is given, the path refers to a directory. If no other keyword is given after the path respectively after the “directory” keyword, the file or directory is not included in the package. It will be created by the software or by the user. If a keyword is given, the file or directory (a default version) is included in the package and it will be extracted on package activation. The keyword specifies what shall happen when the package is updated and a previous default version of the file or directory has been modified by the user:

user_settings_file_info     ::= path [ "directory" | "template" template_path ]

"path" is the relative path of the settings file or directory, starting with “settings/”. It is not included in the package. However, if "template_path" is specified, it is a path to a file included in the package that can serve as a template for the settings file. It doesn’t imply any automatic action on package activation, though. If the “directory” keyword is given, the path refers to a settings directory (typical when a program creates multiple settings files).

user:       ::= name [ "real-name" real_name ] "home" home_path [ "shell" shell_path ] [ "groups" group+ ]

"name" is the name of the Unix user, "real_name", if specified, the real name of the user, "home_path" the path to the user’s home directory, "shell_path" the path to the user’s shell, and "group+" is a list of the names of Unix groups the user is a member of (first one is their primary group). If the respective components are not specified, "name" is also used as the user’s real name, “/bin/bash” is the path of the user’s shell, and the user will belong to the default user group.

Version Strings

Versions strings are used in three contexts: For the package version, for resolvable versions ("provides"), and in dependency version expressions ("requires", "supplements", "conflicts", "freshens"). They are structurally identical, with the exception that the former requires a revision component ("version"), while the latter two don’t ("version_ref"):

version       ::= major [ "." minor [ "." micro ] ] [ "~" pre_release ] "-" revision
version_ref   ::= major [ "." minor [ "." micro ] ] [ "~" pre_release ] [ "-" revision ]
major         ::= alphanum_underline+
minor         ::= alphanum_underline+
micro         ::= alphanum_underline_dot+
pre_release   ::= alphanum_underline_dot+
revision      ::= positive_non_zero_integer

The meaning of the major, minor, and micro version parts is vendor specific. A typical, but not universal (!), convention is to increment the major version when breaking binary compatibility (i.e. version a.d.e is backwards compatible to version a.b.c for all b.c <= d.e), to increment the minor version when adding new features (in a binary compatible way), and to increment the micro version for bug fix releases. There are, however, projects that use different conventions which don’t imply that e.g. version 1.4 is backwards compatible with version 1.2. Which convention is used is important for the packager to know, as it is required for a correct declaration of the compatibility versions for the provided resolvables. The compatibility version specifies the oldest version the provided resolvable is backwards compatible with, thus implying the version range requested by a dependent package the resolvable can satisfy. When following the aforementioned convention a resolvable of version 2.4.3 should have compatibility version 2 (or, semantically virtually identical, 2.0.0). Not following the convention 2.4 may be correct instead. If no compatibility version is specified, the resolvable can only satisfy dependency constraints with an exactly matching version.

The pre-release part of the version string has special semantics for comparison. Unlike minor and micro its presence makes the version older. E.g. version R1.0~alpha1 is considered to be older than version R1.0. When both version strings have a pre-release part, that part is compared naturally after the micro part (R1.0.1~alpha1 > R1.0 > R1.0~beta1 > R1.0~alpha2).

The revision part of the version string is assigned by the packager (not by the vendor). It allows to uniquely identify updated packages of the same vendor version of a software.

Package File Names

A package file name should have the following form:

file_name     ::= name "-" version "-" architecture ".hpkg"

Example package file

name                  example
version               42.17-12
architecture          x86_gcc2
summary               "This is an example package file"
description           "Haiku has a very powerful package management system. Really, you should try it!
it even supports muliline strings in package descriptions"
packager              "John Doe <test@example.com>"
vendor                "Haiku Project"
licenses {
      "MIT"
}
copyrights {
      "Copyright (C) 1812-2013 by John Doe <test@example.com>"
}
provides {
      example = 42.17-12
      cmd:example = 3.1
}
requires {
      haiku >= r1~alpha4_pm_hrev46213-1
      lib:libpython2.6 >= 1.0
}
urls {
      "http://example.com/"
}
global-writable-files {
      "settings/example/configurationFile" keep-old
      "settings/example/servers" directory keep-old
}
source-urls {
      "Download <http://example.com/source.zip>"
}

Building a Package with “haikuporter”

"haikuporter" is a high level tool for building packages. As input it reads a build recipe file for a certain version of a software (aka port) and produces one or more packages, as declared in the recipe. A recipe specifies package requirements similar to how it is done in a ".PackageInfo" file. When asked to build a port, "haikuporter" resolves the respective dependencies and recursively builds all not-yet-built ports required for the requested port. "haikuporter" itself and a large library of recipe files are hosted at

HaikuPorts

. A detailed

documentation for haikuporter

and the

recipe format

can also be found there.