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\input texinfo @c -*-texinfo-*-
@c %**start of header
@setfilename fdroid.info
@documentencoding UTF-8
@settitle F-Droid Server Manual
@c %**end of header
@copying
This manual is for the F-Droid repository server tools.
Copyright @copyright{} 2010, 2011, 2012, 2013, 2014, 2015 Ciaran Gultnieks
Copyright @copyright{} 2011 Henrik Tunedal, Michael Haas, John Sullivan
Copyright @copyright{} 2013 David Black
Copyright @copyright{} 2013, 2014, 2015 Daniel Martí
Copyright @copyright{} 2015 Boris Kraut
@quotation
Permission is granted to copy, distribute and/or modify this document
under the terms of the GNU Free Documentation License, Version 1.3
or any later version published by the Free Software Foundation;
with no Invariant Sections, no Front-Cover Texts, and no Back-Cover Texts.
A copy of the license is included in the section entitled "GNU
Free Documentation License".
@end quotation
@end copying
@titlepage
@title F-Droid Server Manual
@author Ciaran Gultnieks and the F-Droid project
@page
@vskip 0pt plus 1filll
@insertcopying
@end titlepage
@contents
@ifnottex
@node Top
@top F-Droid Server
@insertcopying
@end ifnottex
@menu
* Overview::
* System Requirements::
* Setup::
* Simple Binary Repository::
* Building Applications::
* Importing Applications::
* Metadata::
* Update Processing::
* Build Server::
* Signing::
* GNU Free Documentation License::
* Index::
@end menu
@node Overview
@chapter Overview
The F-Droid server tools provide various scripts and tools that are used
to maintain the main F-Droid application repository. You can use these same
tools to create your own additional or alternative repository for publishing,
or to assist in creating, testing and submitting metadata to the main
repository.
@node System Requirements
@chapter System Requirements
@cindex installation
The system requirements for using the tools will vary depending on your
intended usage. At the very least, you'll need:
@itemize @bullet
@item
GNU/Linux
@item
Python 2.x
To be sure of being able to process all apk files without error, you need
2.7.7 or later. See @code{http://bugs.python.org/issue14315}.
@item
The Android SDK Tools and Build-tools.
Note that F-Droid does not assume that you have the Android SDK in your
@code{PATH}: these directories will be specified in your repository
configuration. Recent revisions of the SDK have @code{aapt} located in
android-sdk/build-tools/ and it may be necessary to make a symlink to it in
android-sdk/platform-tools/
@end itemize
If you intend to build applications from source you'll also need most, if not
all, of the following:
@itemize @bullet
@item
JDK (Debian package openjdk-6-jdk): openjdk-6 is recommended though openjdk-7
should work too
@item
VCS clients: svn, git, git-svn, hg, bzr
@item
A keystore for holding release keys. (Safe, secure and well backed up!)
@end itemize
If you intend to use the 'Build Server' system, for secure and clean builds
(highly recommended), you will also need:
@itemize @bullet
@item
VirtualBox (debian package virtualbox)
@item
Ruby (debian packages ruby and rubygems)
@item
Vagrant (debian package vagrant - 1.4.x or higher required)
@item
vagrant-cachier plugin (unpackaged): `vagrant plugin install vagrant-cachier`
@item
Paramiko (debian package python-paramiko)
@item
Imaging (debian package python-imaging)
@end itemize
On the other hand, if you want to build the apps directly on your system
without the 'Build Server' system, you may need:
@itemize @bullet
@item
All SDK platforms requested by the apps you want to build
(The Android SDK is made available by Google under a proprietary license but
within that, the SDK platforms, support library and some other components are
under the Apache license and source code is provided.
Google APIs, used for building apps using Google Maps, are free to the extent
that the library comes pre-installed on the device.
Google Play Services, Google Admob and others are proprietary and shouldn't be
included in the main F-Droid repository.)
@item
A version of the Android NDK
@item
Ant with Contrib Tasks (Debian packages ant and ant-contrib)
@item
Maven (Debian package maven)
@item
JavaCC (Debian package javacc)
@item
Miscellaneous packages listed in
buildserver/cookbooks/fdroidbuild-general/recipes/default.rb
of the F-Droid server repository
@end itemize
@node Setup
@chapter Setup
@cindex setup, installation
Because the tools and data will always change rapidly, you will almost
certainly want to work from a git clone of the tools at this stage. To
get started:
@example
git clone https://gitlab.com/fdroid/fdroidserver.git
@end example
You now have lots of stuff in the fdroidserver directory, but the most
important is the 'fdroid' command script which you run to perform all tasks.
This script is always run from a repository data directory, so the
most sensible thing to do next is to put your new fdroidserver directory
in your @code{PATH}.
@section Data
To do anything, you'll need at least one repository data directory. It's
from this directory that you run the @code{fdroid} command to perform all
repository management tasks. You can either create a brand new one, or
grab a copy of the data used by the main F-Droid repository:
@example
git clone https://gitlab.com/fdroid/fdroiddata.git
@end example
Regardless of the intended usage of the tools, you will always need to set
up some basic configuration details. This is done by creating a file called
@code{config.py} in the data directory. You should do this by copying the
example file (@code{./examples/config.py}) from the fdroidserver project to
your data directory and then editing according to the instructions within.
Once configured in this way, all the functionality of the tools is accessed
by running the @code{fdroid} command. Run it on its own to get a list of the
available sub-commands.
You can follow any command with @code{--help} to get a list of additional
options available for that command.
@example
fdroid update --help
@end example
@node Simple Binary Repository
@chapter Simple Binary Repository
@cindex binary
If you want to maintain a simple repository hosting only binary APKs obtained
and compiled elsewhere, the process is quite simple:
@enumerate
@item
Set up the server tools, as described in Setup.
@item
Make a directory for your repository. This is the directory from which you
will do all the work with your repository. Create a config file there, called
@code{config.py}, by copying @code{./examples/config.py} from the server
project and editing it.
@item
Within that, make a directory called @code{repo} and put APK files in it.
@item
Run @code{fdroid update}.
@item
If it reports that any metadata files are missing, you can create them
in the @code{metadata} directory and run it again.
@item
To ease creation of metadata files, run @code{fdroid update} with the @code{-c}
option. It will create 'skeleton' metadata files that are missing, and you can
then just edit them and fill in the details.
@item
Then, if you've changed things, run @code{fdroid update} again.
@item
Running @code{fdroid update} adds an Icons directory into the repo directory,
and also creates the repository index (index.xml, and also index.jar if you've
configured the system to use a signed index).
@item
Publish the resulting contents of the @code{repo} directory to your web server.
@end enumerate
Following the above process will result in a @code{repo} directory, which you
simply need to push to any HTTP (or preferably HTTPS) server to make it
accessible.
While some information about the applications (and versions thereof) is
retrieved directly from the APK files, most comes from the corresponding file
in the @code{metadata} directory. The metadata file covering ALL versions of a
particular application is named @code{package.id.txt} where package.id is the
unique identifier for that package.
See the Metadata chapter for details of what goes in the metadata file. All
fields are relevant for binary APKs, EXCEPT for @code{Build:} entries, which
should be omitted.
@node Building Applications
@chapter Building Applications
Instead of (or as well as) including binary APKs from external sources in a
repository, you can build them directly from the source code.
Using this method, it is is possible to verify that the application builds
correctly, corresponds to the source code, and contains only free software.
Unforunately, in the Android world, it seems to be very common for an
application supplied as a binary APK to present itself as Free Software
when in fact some or all of the following are true:
@enumerate
@item
The source code (either for a particular version, or even all versions!) is
unavailable or incomplete.
@item
The source code is not capable of producing the actual binary supplied.
@item
The 'source code' contains binary files of unknown origin, or with proprietary
licenses.
@end enumerate
For this reason, source-built applications are the preferred method for the
main F-Droid repository, although occasionally for technical or historical
reasons, exceptions are made to this policy.
When building applications from source, it should be noted that you will be
signing them (all APK files must be signed to be installable on Android) with
your own key. When an application is already installed on a device, it is not
possible to upgrade it in place to a new version signed with a different key
without first uninstalling the original. This may present an inconvenience to
users, as the process of uninstalling loses any data associated with the
previous installation.
The process for managing a repository for built-from-source applications is
very similar to that described in the Simple Binary Repository chapter,
except now you need to:
@enumerate
@item
Include Build entries in the metadata files.
@item
Run @code{fdroid build} to build any applications that are not already built.
@item
Run @code{fdroid publish} to finalise packaging and sign any APKs that have
been built.
@end enumerate
@section More about "fdroid build"
When run without any parameters, @code{fdroid build} will build any and all
versions of applications that you don't already have in the @code{repo}
directory (or more accurately, the @code{unsigned} directory). There are various
other things you can do. As with all the tools, the @code{--help} option is
your friend, but a few annotated examples and discussion of the more common
usage modes follows:
To build a single version of a single application, you could run the
following:
@example
./fdroid build org.fdroid.fdroid:16
@end example
This attempts to build version code 16 (which is version 0.25) of the F-Droid
client. Many of the tools recognise arguments as packages, allowing their
activity to be limited to just a limited set of packages.
If the build above was successful, two files will have been placed in the
@code{unsigned} directory:
@example
org.fdroid.fdroid_16.apk
org.fdroid.fdroid_16_src.tar.gz
@end example
The first is the (unsigned) APK. You could sign this with a debug key and push
it direct to your device or an emulator for testing. The second is a source
tarball containing exactly the source that was used to generate the binary.
If you were intending to publish these files, you could then run:
@example
./fdroid publish
@end example
The source tarball would move to the @code{repo} directory (which is the
directory you would push to your web server). A signed and zip-aligned version
of the APK would also appear there, and both files would be removed from the
@code{unsigned} directory.
If you're building purely for the purposes of testing, and not intending to
push the results to a repository, at least yet, the @code{--test} option can be
used to direct output to the @code{tmp} directory instead of @code{unsigned}.
A similar effect could by achieved by simply deleting the output files from
@code{unsigned} after the build, but with the risk of forgetting to do so!
Along similar lines (and only in conjunction with @code{--test}, you can use
@code{--force} to force a build of a Disabled application, where normally it
would be completely ignored. Similarly a version that was found to contain
ELFs or known non-free libraries can be forced to build. See also —
@code{scanignore=} and @code{scandelete=} in the @code{Build:} section.
If the build was unsuccessful, you can find out why by looking at the output
in the logs/ directory. If that isn't illuminating, try building the app the
regular way, step by step: android update project, ndk-build, ant debug.
Note that source code repositories often contain prebuilt libraries. If the
app is being considered for the main F-Droid repository, it is important that
all such prebuilts are built either via the metadata or by a reputable third
party.
@section Direct Installation
You can also build and install directly to a connected device or emulator
using the @code{fdroid install} command. If you do this without passing
packages as arguments then all the latest built and signed version available
of each package will be installed . In most cases, this will not be what you
want to do, so execution will stop straight away. However, you can override
this if you're sure that's what you want, by using @code{--all}. Note that
currently, no sanity checks are performed with this mode, so if the files in
the signed output directory were modified, you won't be notified.
@node Importing Applications
@chapter Importing Applications
To help with starting work on including a new application, @code{fdroid import}
will take a URL and optionally some other parameters, and attempt to construct
as much information as possible by analysing the source code. Basic usage is:
@example
./fdroid import --url=http://address.of.project
@end example
For this to work, the URL must point to a project format that the script
understands. Currently this is limited to one of the following:
@enumerate
@item
Gitorious - @code{https://gitorious.org/PROJECTNAME/REPONAME}
@item
Github - @code{https://github.com/USER/PROJECT}
@item
Google Code - @code{http://code.google.com/p/PROJECT/}
Supports git, svn and hg repos.
Some Google Code projects have multiple repositories, identified by a
dropdown list on the @code{source/checkout} page. To access one other than
the default, specify its name using the @code{--repo} switch.
@item
Bitbucket - @code{https://bitbucket.org/USER/PROJECT/}
@item
Git - @code{git://REPO}
@end enumerate
Depending on the project type, more or less information may be gathered. For
example, the license will be retrieved from a Google Code project, but not a
GitHub one. A bare repo url, such as the git:// one, is the least preferable
optional of all, since you will have to enter much more information manually.
If the import is successful, a metadata file will be created. You will need to
edit this further to check the information, and fill in the blanks.
If it fails, you'll be told why. If it got as far as retrieving the source
code, you can inspect it further by looking in @code{tmp/importer} where a full
checkout will exist.
A frequent cause of initial failure is that the project directory is actually
a subdirectory in the repository. In this case, run the importer again using
the @code{--subdir} option to tell it where. It will not attempt to determine
this automatically, since there may be several options.
@node Metadata
@chapter Metadata
@cindex metadata
Information used by update.py to compile the public index comes from two
sources:
@enumerate
@item
the APK files in the repo directory, and
@item
the metadata files in the metadata directory.
@end enumerate
The original metadata files are simple, easy to edit text files,
always named as the application's package ID with '.txt' appended.
Additionally, you can use JSON, XML, or YAML for app metadata, using
the same fields as the original '.txt' format.
Note that although the metadata files are designed to be easily read
and writable by humans, they are also processed and written by various
scripts. The original '.txt' format can be automatically cleaned up
when necessary. The structure and comments will be preserved
correctly, although the order of fields will be standardised. (In the
event that the original file was in a different order, comments are
considered as being attached to the field following them). In fact,
you can standardise all the '.txt' metadata in a single command,
without changing the functional content, by running:
@example
fdroid rewritemeta
@end example
Or just run it on a specific app:
@example
fdroid rewritemeta org.adaway
@end example
The following sections describe the fields recognised within the file.
@menu
* Categories::
* Author Name::
* Author Email::
* License::
* Auto Name::
* Name::
* Provides::
* Web Site::
* Source Code::
* Issue Tracker::
* Changelog::
* Donate::
* FlattrID::
* Bitcoin::
* Litecoin::
* Summary::
* Description::
* Maintainer Notes::
* Repo Type::
* Repo::
* Binaries::
* Build::
* AntiFeatures::
* Disabled::
* Requires Root::
* Archive Policy::
* Update Check Mode::
* Update Check Ignore::
* Vercode Operation::
* Update Check Name::
* Update Check Data::
* Auto Update Mode::
* Current Version::
* Current Version Code::
* No Source Since::
@end menu
@node Categories
@section Categories
Any number of categories for the application to be placed in. There is no
fixed list of categories - both the client and the web site will automatically
show any categories that exist in any applications. However, if your metadata
is intended for the main F-Droid repository, you should use one of the
existing categories (look at the site/client), or discuss the proposal to add
a new one.
Categories must be separated by a single comma character, ','. For backwards
compatibility, F-Droid will use the first category given as <category> element
for older clients to at least see one category.
This is converted to (@code{<categories>}) in the public index file.
@node Author Name
@section Author Name
@cindex Author Name
The name of the author, either full, abbreviated or pseudonym. If
present, it should represent the name(s) as published by upstream,
e.g. in their copyright or authors file. This can be omitted (or left
blank).
This is converted to (@code{<author>}) in the public index file.
@node Author Email
@section Author Email
@cindex Author Email
The e-mail address of the author(s). This can be omitted (or left
blank).
This is converted to (@code{<email>}) in the public index file.
@node License
@section License
@cindex license
The overall license for the application, or in certain cases, for the
source code only.
Common values:
@itemize @bullet
@item
@samp{GPLv2}
GNU GPL version 2
@item
@samp{GPLv2+}
GNU GPL version 2 or later
@item
@samp{GPLv3}
GNU GPL version 3
@item
@samp{GPLv3+}
GNU GPL version 3 or later
@item
@samp{GPL}
An unspecified GPL version. Use this only as a last resort or if there is
some confusion over compatiblity of component licenses: particularly the use of
Apache libraries with GPLv2 source code.
@item
@samp{AGPL}
Afferro GPL version 3.
@item
@samp{Apache2}
Apache 2
@item
@samp{MIT}
MIT X11 license
@item
@samp{BSD}
BSD license - the original '4-clause' version.
@item
@samp{NewBSD}
BSD license - the new, or modified, version.
@end itemize
This is converted to (@code{<license>}) in the public index file.
@node Auto Name
@section Auto Name
@cindex Auto Name
The name of the application as can best be retrieved from the source code.
This is done so that the commitupdates script can put a familiar name in the
description of commits created when a new update of the application is
found. The Auto Name entry is generated automatically when @code{fdroid
checkupdates} is run.
@node Name
@section Name
@cindex Name
The name of the application. Normally, this field should not be present since
the application's correct name is retrieved from the APK file. However, in a
situation where an APK contains a bad or missing application name, it can be
overridden using this. Note that this only overrides the name in the list of
apps presented in the client; it doesn't changed the name or application label
in the source code.
@node Provides
@section Provides
@cindex Provides
Comma-separated list of application IDs that this app provides. In other
words, if the user has any of these apps installed, F-Droid will show this app
as installed instead. It will also appear if the user clicks on urls linking
to the other app IDs. Useful when an app switches package name, or when you
want an app to act as multiple apps.
@node Web Site
@section Web Site
@cindex Web Site
The URL for the application's web site. If there is no relevant web site, this
can be omitted (or left blank).
This is converted to (@code{<web>}) in the public index file.
@node Source Code
@section Source Code
@cindex Source Code
The URL to view or obtain the application's source code. This should be
something human-friendly. Machine-readable source-code is covered in the
'Repo' field.
This is converted to (@code{<source>}) in the public index file.
@node Issue Tracker
@section Issue Tracker
@cindex Issue Tracker
The URL for the application's issue tracker. Optional, since not all
applications have one.
This is converted to (@code{<tracker>}) in the public index file.
@node Changelog
@section Changelog
@cindex Changelog
The URL for the application's changelog. Optional, since not all
applications have one.
This is converted to (@code{<changelog>}) in the public index file.
@node Donate
@section Donate
@cindex Donate
The URL to donate to the project. This should be the project's donate page
if it has one.
It is possible to use a direct PayPal link here, if that is all that is
available. However, bear in mind that the developer may not be aware of
that direct link, and if they later changed to a different PayPal account,
or the PayPal link format changed, things could go wrong. It is always
best to use a link that the developer explicitly makes public, rather than
something that is auto-generated 'button code'.
This is converted to (@code{<donate>}) in the public index file.
@node FlattrID
@section FlattrID
@cindex FlattrID
The project's Flattr (http://flattr.com) ID, if it has one. This should be
a numeric ID, such that (for example) https://flattr.com/thing/xxxx leads
directly to the page to donate to the project.
This is converted to (@code{<flattr>}) in the public index file.
@node Bitcoin
@section Bitcoin
@cindex Bitcoin
A bitcoin address for donating to the project.
This is converted to (@code{<bitcoin>}) in the public index file.
@node Litecoin
@section Litecoin
@cindex Litecoin
A litecoin address for donating to the project.
@node Summary
@section Summary
@cindex Summary
A brief summary of what the application is. Since the summary is only allowed
one line on the list of the F-Droid client, keeping it to within 80 characters
will ensure it fits most screens.
@node Description
@section Description
@cindex Description
A full description of the application, relevant to the latest version.
This can span multiple lines (which should be kept to a maximum of 80
characters), and is terminated by a line containing a single '.'.
Basic MediaWiki-style formatting can be used. Leaving a blank line starts a
new paragraph. Surrounding text with @code{''} make it italic, and with
@code{'''} makes it bold.
You can link to another app in the repo by using @code{[[app.id]]}. The link
will be made appropriately whether in the Android client, the web repo
browser or the wiki. The link text will be the apps name.
Links to web addresses can be done using @code{[http://example.com Text]}.
For both of the above link formats, the entire link (from opening to closing
square bracket) must be on the same line.
Bulletted lists are done by simply starting each item with a @code{*} on
a new line, and numbered lists are the same but using @code{#}. There is
currently no support for nesting lists - you can have one level only.
It can be helpful to note information pertaining to updating from an
earlier version; whether the app contains any prebuilts built by the
upstream developers or whether non-free elements were removed; whether the
app is in rapid development or whether the latest version lags behind the
current version; whether the app supports multiple architectures or whether
there is a maximum SDK specified (such info not being recorded in the index).
This is converted to (@code{<desc>}) in the public index file.
@node Maintainer Notes
@section Maintainer Notes
@cindex Maintainer Notes
This is a multi-line field using the same rules and syntax as the description.
It's used to record notes for F-Droid maintainers to assist in maintaining and
updating the application in the repository.
This information is also published to the wiki.
@node Repo Type
@section Repo Type
@cindex Repo Type
The type of repository - for automatic building from source. If this is not
specified, automatic building is disabled for this application. Possible
values are:
@itemize @bullet
@item
@samp{git}
@item
@samp{svn}
@item
@samp{git-svn}
@item
@samp{hg}
@item
@samp{bzr}
@item
@samp{srclib}
@end itemize
@node Repo
@section Repo
@cindex Repo
The repository location. Usually a git: or svn: URL, for example.
The git-svn option connects to an SVN repository, and you specify the URL in
exactly the same way, but git is used as a back-end. This is preferable for
performance reasons, and also because a local copy of the entire history is
available in case the upstream repository disappears. (It happens!). In
order to use Tags as update check mode for this VCS type, the URL must have
the tags= special argument set. Likewise, if you intend to use the
RepoManifest/branch scheme, you would want to specify branches= as well.
Finally, trunk= can also be added. All these special arguments will be passed
to "git svn" in order, and their values must be relative paths to the svn repo
root dir.
Here's an example of a complex git-svn Repo URL:
http://svn.code.sf.net/p/project/code/svn;trunk=trunk;tags=tags;branches=branches
If the Repo Type is @code{srclib}, then you must specify the name of the
according srclib .txt file. For example if @code{scrlibs/FooBar.txt} exist
and you want to use this srclib, then you have to set Repo to
@code{FooBar}.
@node Binaries
@section Binaries
@cindex Binaries
The location of binaries used in verification process.
If specified, F-Droid will verify the output apk file of a build against the
one specified. You can use %v and %c to point to the version name and version
code of the current build. To verify the F-Droid client itself you could use:
@code{Binaries:https://f-droid.org/repo/org.fdroid.fdroid_%c.apk}
F-Droid will use upstream binaries if the verification succeeded.
@node Build
@section Build
@cindex Build
Any number of these fields can be present, each specifying a version to
automatically build from source. The value is a comma-separated list.
For example:
@samp{Build:1.2,12}
The above specifies to build version 1.2, which has a version code of 12.
The @code{commit=} parameter specifies the tag, commit or revision number from
which to build it in the source repository. It is the only mandatory flag,
which in this case could for example be @code{commit=v1.2}.
In addition to the three, always required, parameters described above,
further parameters can be added (in name=value format) to apply further
configuration to the build. These are (roughly in order of application):
@table @code
@item disable=<message>
Disables this build, giving a reason why. (For backwards compatibility, this
can also be achieved by starting the commit ID with '!')
The purpose of this feature is to allow non-buildable releases (e.g. the source
is not published) to be flagged, so the scripts don't generate repeated
messages about them. (And also to record the information for review later).
If an apk has already been built, disabling causes it to be deleted once
@code{fdroid update} is run; this is the procedure if ever a version has to
be replaced.
@item subdir=<path>
Specifies to build from a subdirectory of the checked out source code.
Normally this directory is changed to before building,
@item submodules=yes
Use if the project (git only) has submodules - causes @code{git submodule
update --init --recursive} to be executed after the source is cloned.
Submodules are reset and cleaned like the main app repository itself before
each build.
@item init=xxxx
As for 'prebuild', but runs on the source code BEFORE any other processing
takes place.
You can use $$SDK$$, $$NDK$$ and $$MVN3$$ to substitute the paths to the
android SDK and NDK directories, and maven 3 executable respectively. The
following per-build variables are available likewise: $$VERSION$$,
$$VERCODE$$ and $$COMMIT$$.
@item oldsdkloc=yes
The sdk location in the repo is in an old format, or the build.xml is
expecting such. The 'new' format is sdk.dir while the VERY OLD format
is sdk-location. Typically, if you get a message along the lines of:
"com.android.ant.SetupTask cannot be found" when trying to build, then
try enabling this option.
@item target=<target>
Specifies a particular SDK target for compilation, overriding the value
defined in the code by upstream. This has different effects depending on what
build system used — this flag currently affects Ant, Maven and Gradle projects
only. Note that this does not change the target SDK in the
AndroidManifest.xml, which determines the level of features that can be
included in the build.
In the case of an Ant project, it modifies project.properties of the app and
possibly sub-projects. This is likely to cause the whole build.xml to be
rewritten, which is fine if it's a 'standard' android file or doesn't already
exist, but not a good idea if it's heavily customised.
@item update=<auto/dirs>
By default, 'android update' is used in Ant builds to generate or update the
project and all its referenced projects. Specifying update=no bypasses that.
Note that this is useless in builds that don't use Ant.
Default value is '@code{auto}', which recursively uses the paths in
project.properties to find all the subprojects to update.
Otherwise, the value can be a comma-separated list of directories in which to
run 'android update' relative to the application directory.
@item encoding=xxxx
Adds a java.encoding property to local.properties with the given
value. Generally the value will be 'utf-8'. This is picked up by the
SDK's ant rules, and forces the Java compiler to interpret source
files with this encoding. If you receive warnings during the compile
about character encodings, you probably need this.
@item forceversion=yes
If specified, the package version in AndroidManifest.xml is replaced
with the version name for the build as specified in the metadata.
This is useful for cases when upstream repo failed to update it for
specific tag; to build an arbitrary revision; to make it apparent that
the version differs significantly from upstream; or to make it apparent
which architecture or platform the apk is designed to run on.
@item forcevercode=yes
If specified, the package version code in the AndroidManifest.xml is
replaced with the version code for the build. See also forceversion.
@item rm=<path1>[,<path2>,...]
Specifies the relative paths of files or directories to delete before
the build is done. The paths are relative to the base of the build
directory - i.e. the root of the directory structure checked out from
the source respository - not necessarily the directory that contains
AndroidManifest.xml.
Multiple files/directories can be specified by separating them with ','.
Directories will be recursively deleted.
@item extlibs=<lib1>[,<lib2>,...]
Comma-separated list of external libraries (jar files) from the
@code{build/extlib} library, which will be placed in the @code{libs} directory
of the project.
@item srclibs=[n:]a@@r,[n:]b@@r1,...
Comma-separated list of source libraries or Android projects. Each item is of
the form name@@rev where name is the predefined source library name and rev is
the revision or tag to use in the respective source control.
For Ant projects, you can optionally append a number with a colon at the
beginning of a srclib item to automatically place it in project.properties as
a library under the specified number. For example, if you specify
@code{1:somelib@@1.0}, F-Droid will automatically do the equivalent of the
legacy practice @code{prebuild=echo "android.library.reference.1=$$somelib$$"
>> project.properties}.
Each srclib has a metadata file under srclibs/ in the repository directory,
and the source code is stored in build/srclib/.
Repo Type: and Repo: are specified in the same way as for apps; Subdir: can be
a comma separated list, for when directories are renamed by upstream; Update
Project: updates the projects in the working directory and one level down;
Prepare: can be used for any kind of preparation: in particular if you need to
update the project with a particular target. You can then also use $$name$$ in
the init/prebuild/build command to substitute the relative path to the library
directory, but it could need tweaking if you've changed into another directory.
Currently srclibs are necessary when upstream uses jar files or pulls
dependencies from non-trusted repositories. While there is no guarantee that
those binaries are free and correspondent to the source code, F-Droid allows
the following known repositories until a source-built alternative is available:
@itemize @bullet
@item
@samp{mavenCentral} - the original repo, hardcoded in Maven and Gradle.
@item
@samp{jCenter} - hardcoded in Gradle, this repo by Bintray tries to provide
easier handling. It should sync with mavenCentral from time to time.
@item
@samp{OSS Sonatype} - maintained by the people behind mavenCentral, this
repository focuses on hosting services for open source project binaries.
@item
@samp{JitPack.io} - builds directly from Github repositories. However,
they do not provide any option to reproduce or verify the resulting
binaries. Builds pre-release versions in some cases.
@item
@samp{Clojars} - Clojure libraries repo.
@item
@samp{CommonsWare} - repo holding a collection of open-source libs.
@end itemize
@item patch=x
Apply patch(es). 'x' names one (or more - comma-seperated) files within a
directory below the metadata, with the same name as the metadata file but
without the extension. Each of these patches is applied to the code in turn.
@item prebuild=xxxx
Specifies a shell command (or commands - chain with &&) to run before the
build takes place. Backslash can be used as an escape character to insert
literal commas, or as the last character on a line to join that line with the
next. It has no special meaning in other contexts; in particular, literal
backslashes should not be escaped.
The command runs using bash.
Note that nothing should be built during this prebuild phase - scanning of the
code and building of the source tarball, for example, take place after this.
For custom actions that actually build things or produce binaries, use 'build'
instead.
You can use $$name$$ to substitute the path to a referenced srclib - see
the @code{srclib} directory for details of this.
You can use $$SDK$$, $$NDK$$ and $$MVN3$$ to substitute the paths to the
android SDK and NDK directories, and Maven 3 executable respectively e.g.
for when you need to run @code{android update project} explicitly. The
following per-build variables are available likewise: $$VERSION$$, $$VERCODE$$
and $$COMMIT$$.
@item scanignore=<path1>[,<path2>,...]
Enables one or more files/paths to be excluded from the scan process.
This should only be used where there is a very good reason, and
probably accompanied by a comment explaining why it is necessary.
When scanning the source tree for problems, matching files whose relative
paths start with any of the paths given here are ignored.
@item scandelete=<path1>[,<path2>,...]
When running the scan process, any files that trigger errors - like binaries -
will be removed. It acts just like scanignore=, but instead of ignoring the
files, it removes them.
Useful when a source code repository includes binaries or other unwanted files
which are not needed for the build. Instead of removing them manually via rm=,
using scandelete= is easier.
@item build=xxxx
As for 'prebuild', but runs during the actual build phase (but before the
main Ant/Maven build). Use this only for actions that do actual building.
Any prepartion of the source code should be done using 'init' or 'prebuild'.
Any building that takes place before build= will be ignored, as either Ant,
mvn or gradle will be executed to clean the build environment right before
build= (or the final build) is run.
You can use $$SDK$$, $$NDK$$ and $$MVN3$$ to substitute the paths to the
android SDK and NDK directories, and maven 3 executable respectively. The
following per-build variables are available likewise: $$VERSION$$,
$$VERCODE$$ and $$COMMIT$$.
@item buildjni=[yes|no|<dir list>]
Enables building of native code via the ndk-build script before doing
the main Ant build. The value may be a list of directories relative
to the main application directory in which to run ndk-build, or 'yes'
which corresponds to '.' . Using explicit list may be useful to build
multi-component projects.
The build and scan processes will complain (refuse to build) if this
parameter is not defined, but there is a @code{jni} directory present.
If the native code is being built by other means like a Gradle task, you
can specify @code{no} here to avoid that. However, if the native code is
actually not required or used, remove the directory instead (using
@code{rm=jni} for example). Using @code{buildjni=no} when the jni code
isn't used nor built will result in an error saying that native
libraries were expected in the resulting package.
@item ndk=<version>
Version of the NDK to use in this build. Defaults to the latest NDK release
that included legacy toolchains, so as to not break builds that require
toolchains no longer included in current versions of the NDK.
The buildserver supports r9b with its legacy toolchains and the latest release
as of writing this document, r10e. You may add support for more versions by
adding them to 'ndk_paths' in your config file.
@item gradle=<flavour1>[,<flavour2>,...]
Build with Gradle instead of Ant, specifying what flavours to use. Flavours
are case sensitive since the path to the output apk is as well.
If only one flavour is given and it is 'yes', no flavour will be used.
Note that for projects with flavours, you must specify at least one
valid flavour since 'yes' will build all of them separately.
@item maven=yes[@@<dir>]
Build with Maven instead of Ant. An extra @@<dir> tells F-Droid to run Maven
inside that relative subdirectory. Sometimes it is needed to use @@.. so that
builds happen correctly.
@item preassemble=<task1>[,<task2>,...]
List of Gradle tasks to be run before the assemble task in a Gradle project
build.
@item gradleprops=<prop1>[,<prop2>,...]
List of Gradle properties to pass via the command line to Gradle. A property
can be of the form @code{foo} or of the form @code{key=value}.
For example: @code{gradleprops=enableFoo,someSetting=bar} will result in
@code{gradle -PenableFoo -PsomeSetting=bar}.
@item antcommands=<target1>[,<target2>,...]
Specify an alternate set of Ant commands (target) instead of the default
'release'. It can't be given any flags, such as the path to a build.xml.
@item output=glob/to/output.apk
Specify a glob path where the resulting unsigned release apk from the
build should be. This can be used in combination with build methods like
@code{gradle=yes} or @code{maven=yes}, but if no build method is
specified, the build is manual. You should run your build commands, such
as @code{make}, in @code{build=}.
@item novcheck=yes
Don't check that the version name and code in the resulting apk are
correct by looking at the build output - assume the metadata is
correct. This takes away a useful level of sanity checking, and should
only be used if the values can't be extracted.
@end table
Another example, using extra parameters:
@samp{Build Version:1.09.03,10903,45,subdir=Timeriffic,oldsdkloc=yes}
@node AntiFeatures
@section AntiFeatures
@cindex AntiFeatures
This is optional - if present, it contains a comma-separated list of any of
the following values, describing an anti-feature the application has.
It is a good idea to mention the reasons for the anti-feature(s) in the
description:
@itemize @bullet
@item
@samp{Ads} - the application contains advertising.
@item
@samp{Tracking} - the application tracks and reports your activity to
somewhere without your consent. It's commonly used for when developers
obtain crash logs without the user's consent, or when an app is useless
without some kind of authentication.
@item
@samp{NonFreeNet} - the application relies on computational services that
are impossible to replace or that the replacement cannot be connected to
without major changes to the app.
@item
@samp{NonFreeAdd} - the application promotes non-free add-ons, such that the
app is effectively an advert for other non-free software and such software is
not clearly labelled as such.
@item
@samp{NonFreeDep} - the application depends on a non-free application (e.g.
Google Maps) - i.e. it requires it to be installed on the device, but does not
include it.
@item
@samp{UpstreamNonFree} - the application is or depends on non-free software.
This does not mean that non-free software is included with the app: Most
likely, it has been patched in some way to remove the non-free code. However,
functionality may be missing.
@item
@samp{NonFreeAssets} - the application contains and makes use of non-free
assets. The most common case is apps using artwork - images, sounds, music,
etc - under a non-commercial license.
@end itemize
@node Disabled
@section Disabled
@cindex Disabled
If this field is present, the application does not get put into the public
index. This allows metadata to be retained while an application is temporarily
disabled from being published. The value should be a description of why the
application is disabled. No apks or source code archives are deleted: to purge
an apk see the Build Version section or delete manually for developer builds.
The field is therefore used when an app has outlived it's usefulness, because
the source tarball is retained.
@node Requires Root
@section Requires Root
@cindex Requires Root
Set this optional field to "Yes" if the application requires root
privileges to be usable. This lets the client filter it out if the
user so desires. Whether root is required or not, it is good to give
a paragraph in the description to the conditions on which root may be
asked for and the reason for it.
@node Archive Policy
@section Archive Policy
@cindex Archive Policy
This determines the policy for moving old versions of an app to the archive
repo, if one is configured. The configuration sets a default maximum number
of versions kept in the main repo, after which older ones are moved to the
archive. This app-specific policy setting can override that.
Currently the only supported format is "n versions", where n is the number
of versions to keep.
@node Update Check Mode
@section Update Check Mode
@cindex Update Check Mode
This determines the method using for determining when new releases are
available - in other words, the updating of the Current Version and Current
Version Code fields in the metadata by the @code{fdroid checkupdates} process.
Valid modes are:
@itemize
@item
@code{None} - No checking is done because there's no appropriate automated way
of doing so. Updates should be checked for manually. Use this, for example,
when deploying betas or patched versions; when builds are done in a directory
different to where the AndroidManifest.xml is; if the developers use the
Gradle build system and store version info in a separate file; if the
developers make a new branch for each release and don't make tags; or if you've
changed the package name or version code logic.
@item
@code{Static} - No checking is done - either development has ceased or new versions
are not desired. This method is also used when there is no other checking method
available and the upstream developer keeps us posted on new versions.
@item
@code{RepoManifest} - At the most recent commit, the AndroidManifest.xml file
is looked for in the directory where it was found in the the most recent build.
The appropriateness of this method depends on the development process used by
the application's developers. You should not specify this method unless you're
sure it's appropriate. For example, some developers bump the version when
commencing development instead of when publishing.
It will return an error if the AndroidManifest.xml has moved to a different
directory or if the package name has changed.
The current version that it gives may not be accurate, since not all
versions are fit to be published. Therefore, before building, it is often
necessary to check if the current version has been published somewhere by the
upstream developers, either by checking for apks that they distribute or for
tags in the source code repository.
It currently works for every repository type to different extents, except
the srclib repo type. For git, git-svn and hg repo types, you may use
"RepoManifest/yourbranch" as UCM so that "yourbranch" would be the branch used
in place of the default one. The default values are "master" for git,
"default" for hg and none for git-svn (it stays in the same branch).
On the other hand, branch support hasn't been implemented yet in bzr and svn,
but RepoManifest may still be used without it.
@item
@code{RepoTrunk} - For svn and git-svn repositories, especially those who
don't have a bundled AndroidManifest.xml file, the Tags and RepoManifest
checks will not work, since there is no version information to obtain. But,
for those apps who automate their build process with the commit ref that HEAD
points to, RepoTrunk will set the Current Version and Current Version Code to
that number.
@item
@code{Tags} - The AndroidManifest.xml file in all tagged revisions in the
source repository is checked, looking for the highest version code. The
appropriateness of this method depends on the development process used by the
application's developers. You should not specify this method unless you're sure
it's appropriate. It shouldn't be used if the developers like to tag betas or
are known to forget to tag releases. Like RepoManifest, it will not return the
correct value if the directory containing the AndroidManifest.xml has moved.
Despite these caveats, it is the often the favourite update check mode.
It currently only works for git, hg, bzr and git-svn repositories. In the case
of the latter, the repo URL must contain the path to the trunk and tags or
else no tags will be found.
Optionally append a regex pattern at the end - separated with a space - to
only check the tags matching said pattern. Useful when apps tag non-release
versions such as X.X-alpha, so you can filter them out with something like
@code{.*[0-9]$} which requires tag names to end with a digit.
@item
@code{HTTP} - HTTP requests are used to determine the current version code and
version name. This is controlled by the @code{Update Check Data} field, which
is of the form @code{urlcode|excode|urlver|exver}.
Firstly, if @code{urlcode} is non-empty, the document from that URL is
retrieved, and matched against the regular expression @code{excode}, with the
first group becoming the version code.
Secondly, if @code{urlver} is non-empty, the document from that URL is
retrieved, and matched against the regular expression @code{exver}, with the
first group becoming the version name. The @code{urlver} field can be set to
simply '.' which says to use the same document returned for the version code
again, rather than retrieving a different one.
@end itemize
@node Vercode Operation
@section Vercode Operation
@cindex Vercode Operation
Operation to be applied to the vercode obtained by the defined @code{Update
Check Mode}. @code{%c} will be replaced by the actual vercode, and the whole
string will be passed to python's @code{eval} function.
Especially useful with apps that we want to compile for different ABIs, but
whose vercodes don't always have trailing zeros. For example, with
@code{Vercode Operation} set at something like @code{%c*10 + 4}, we will be
able to track updates and build up to four different versions of every
upstream version.
@node Update Check Ignore
@section Update Check Ignore
@cindex Update Check Ignore
When checking for updates (via @code{Update Check Mode}) this can be used to
specify a regex which, if matched against the version name, causes that version
to be ignored. For example, 'beta' could be specified to ignore version names
that include that text.
@node Update Check Name
@section Update Check Name
@cindex Update Check Name
When checking for updates (via @code{Update Check Mode}) this can be used to
specify the package name to search for. Useful when apps have a static package
name but change it programmatically in some app flavors, by e.g. appending
".open" or ".free" at the end of the package name.
You can also use @code{Ignore} to ignore package name searching. This should
only be used in some specific cases, for example if the app's build.gradle
file does not contain the package name.
@node Update Check Data
@section Update Check Data
@cindex Update Check Data
Used in conjunction with @code{Update Check Mode} for certain modes.
@node Auto Update Mode
@section Auto Update Mode
@cindex Auto Update Mode
This determines the method using for auto-generating new builds when new
releases are available - in other words, adding a new Build Version line to the
metadata.
This happens in conjunction with the 'Update Check Mode' functionality - i.e.
when an update is detected by that, it is also processed by this.
Valid modes are:
@itemize
@item
@code{None} - No auto-updating is done
@item
@code{Version} - Identifies the target commit (i.e. tag) for the new build based
on the given version specification, which is simply text in which %v and %c are
replaced with the required version name and version code respectively.
For example, if an app always has a tag "2.7.2" corresponding to version 2.7.2,
you would simply specify "Version %v". If an app always has a tag "ver_1234"
for a version with version code 1234, you would specify "Version ver_%c".
Additionally, a suffix can be added to the version name at this stage, to
differentiate F-Droid's build from the original. Continuing the first example
above, you would specify that as "Version +-fdroid %v" - "-fdroid" is the suffix.
@end itemize
@node Current Version
@section Current Version
@cindex Current Version
The name of the version that is current. There may be newer versions of the
application than this (e.g. betas), and there will almost certainly be older
ones. This should be the one that is recommended for general use.
In the event that there is no source code for the current version, or that
non-free libraries are being used, this would ideally be the latest
version that is still free, though it may still be expedient to
retain the automatic update check — see No Source Since.
This field is normally automatically updated - see Update Check Mode.
This is converted to (@code{<marketversion>}) in the public index file.
@node Current Version Code
@section Current Version Code
@cindex Current Version Code
The version code corresponding to the Current Version field. Both these fields
must be correct and matching although it's the current version code that's
used by Android to determine version order and by F-Droid client to determine
which version should be recommended.
This field is normally automatically updated - see Update Check Mode.
If not set or set to @code{0}, clients will recommend the highest version they
can, as if the @code{Current Version Code} was infinite.
This is converted to (@code{<marketvercode>}) in the public index file.
@node No Source Since
@section No Source Since
@cindex No Source Since
In case we are missing the source code for the Current Version reported by
Upstream, or that non-free elements have been introduced, this defines the
first version that began to miss source code.
Apps that are missing source code for just one or a few versions, but provide
source code for newer ones are not to be considered here - this field is
intended to illustrate which apps do not currently distribute source code, and
since when have they been doing so.
@node Update Processing
@chapter Update Processing
@section Detecting
There are various mechanisms in place for automatically detecting that updates
are available for applications, with the @code{Update Check Mode} field in the
metadata determining which method is used for a particular application.
Running the @code{fdroid checkupdates} command will apply this method to each
application in the repository and update the @code{Current Version} and
@code{Current Version Code} fields in the metadata accordingly.
As usual, the @code{-p} option can be used with this, to restrict processing
to a particular application.
Note that this only updates the metadata such that we know what the current
published/recommended version is. It doesn't make that version available in
the repository - for that, see the next section.
@section Adding
Adding updates (i.e. new versions of applications already included in the
repository) happens in two ways. The simple case is applications where the
APK files are binaries, retrieved from a developer's published build. In this
case, all that's required is to place the new binary in the @code{Repo}
directory, and the next run of @code{fdroid update} will pick it up.
For applications built from source, it is necessary to add a new
@code{Build Version} line to the metadata file. At the very least, the version
name, version code and commit will be different. It is also possible that the
additional build flags will change between versions.
For processing multiple updates in the metadata at once, it can be useful to
run @code{fdroid update --interactive}. This will check all the applications
in the repository, and where updates are required you will be prompted to
[E]dit the metadata, [I]gnore the update, or [Q]uit altogether.
@node Build Server
@chapter Build Server
The Build Server system isolates the builds for each package within a clean,
isolated and secure throwaway virtual machine environment.
@section Overview
Building applications in this manner on a large scale, especially with the
involvement of automated and/or unattended processes, could be considered
a dangerous pastime from a security perspective. This is even more the case
when the products of the build are also distributed widely and in a
semi-automated ("you have updates available") fashion.
Assume that an upstream source repository is compromised. A small selection
of things that an attacker could do in such a situation:
@enumerate
@item
Use custom Ant build steps to execute virtually anything as the user doing
the build.
@item
Access the keystore.
@item
Modify the built apk files or source tarballs for other applications in the
repository.
@item
Modify the metadata (which includes build scripts, which again, also includes
the ability to execute anything) for other applications in the repository.
@end enumerate
Through complete isolation, the repurcussions are at least limited to the
application in question. Not only is the build environment fresh for each
build, and thrown away afterwards, but it is also isolated from the signing
environment.
Aside from security issues, there are some applications which have strange
requirements such as custom versions of the NDK. It would be impractical (or
at least extremely messy) to start modifying and restoring the SDK on a
multi-purpose system, but within the confines of a throwaway single-use
virtual machine, anything is possible.
All this is in addition to the obvious advantage of having a standardised
and completely reproducible environment in which builds are made. Additionally,
it allows for specialised custom build environments for particular
applications.
@section Setting up a build server
In addition to the basic setup previously described, you will also need
a Vagrant-compatible Debian Testing base box called 'jessie32' (or jessie64
for a 64-bit VM, if you want it to be much slower, and require more disk
space).
You can use a different version or distro for the base box, so long as you
don't expect any help making it work. One thing to be aware of is that
working copies of source trees are moved from the host to the guest, so
for example, having subversion v1.6 on the host and v1.7 on the guest
would fail.
@subsection Creating the Debian base box
The output of this step is a minimal Debian VM that has support for remote
login and provisioning.
Unless you're very trusting, you should create one of these for yourself
from verified standard Debian installation media. However, by popular
demand, the @code{makebuildserver} script will automatically download a
prebuilt image unless instructed otherwise. If you choose to use the
prebuilt image, you may safely skip the rest of this section.
Documentation for creating a base box can be found at
@url{http://docs.vagrantup.com/v1/docs/base_boxes.html}.
In addition to carefully following the steps described there, you should
consider the following:
@enumerate
@item
It is advisable to disable udev network device persistence, otherwise any
movement of the VM between machines, or reconfiguration, will result in
broken networking.
For a Debian/Ubuntu default install, just
@code{touch /etc/udev/rules.d/75-persistent-net-generator.rules} to turn
off rule generation, and at the same time, get rid of any rules it's
already created in @code{/etc/udev/rules.d/70-persistent-net.rules}.
@item
Unless you want the VM to become totally inaccessible following a failed
boot, you need to set @code{GRUB_RECORDFAIL_TIMEOUT} to a value other than
-1 in @code{/etc/grub/default} and then run @code{update-grub}.
@end enumerate
@subsection Creating the F-Droid base box
The next step in the process is to create @code{makebs.config.py},
using @code{./examples/makebs.config.py} as a reference - look at the settings and
documentation there to decide if any need changing to suit your environment.
There is a path for retrieving the base box if it doesn't exist, and an apt
proxy definition, both of which may need customising for your environment.
You can then go to the @code{fdroidserver} directory and run this:
@example
./makebuildserver
@end example
This will take a long time, and use a lot of bandwidth - most of it spent
installing the necessary parts of the Android SDK for all the various
platforms. Luckily you only need to do it occasionally. Once you have a
working build server image, if the recipes change (e.g. when packages need
to be added) you can just run that script again and the existing one will
be updated in place.
The main sdk/ndk downloads will automatically be cached to speed things
up the next time, but there's no easy way of doing this for the longer
sections which use the SDK's @code{android} tool to install platforms,
add-ons and tools. However, instead of allowing automatic caching, you
can supply a pre-populated cache directory which includes not only these
downloads, but also .tar.gz files for all the relevant additions. If the
provisioning scripts detect these, they will be used in preference to
running the android tools. For example, if you have
@code{buildserver/addons/cache/platforms/android-19.tar.gz} that will be
used when installing the android-19 platform, instead of re-downloading it
using @code{android update sdk --no-ui -t android-19}. It is possible to
create the cache files of this additions from a local installation of the
SDK including these:
@example
cd /path/to/android-sdk/platforms
tar czf android-19.tar.gz android-19
mv android-19.tar.gz /path/to/buildserver/addons/cache/platforms/
@end example
If you have already built a buildserver it is also possible to get this
files directly from the buildserver:
@example
vagrant ssh -- -C 'tar -C ~/android-sdk/platforms czf android-19.tar.gz android-19'
vagrant ssh -- -C 'cat ~/android-sdk/platforms/android-19.tar.gz' > /path/to/fdroidserver/buildserver/cache/platforms/android19.tar.gz
@end example
Once it's complete you'll have a new base box called 'buildserver' which is
what's used for the actual builds. You can then build packages as normal,
but with the addition of the @code{--server} flag to @code{fdroid build} to
instruct it to do all the hard work within the virtual machine.
The first time a build is done, a new virtual machine is created using the
'buildserver' box as a base. A snapshot of this clean machine state is saved
for use in future builds, to improve performance. You can force discarding
of this snapshot and rebuilding from scratch using the @code{--resetserver}
switch with @code{fdroid build}.
@node Signing
@chapter Signing
There are two kinds of signing involved in running a repository - the signing
of the APK files generated from source builds, and the signing of the repo
index itself. The latter is optional, but very strongly recommended.
@section Repo Index Signing
When setting up the repository, one of the first steps should be to generate
a signing key for the repository index. This will also create a keystore, which
is a file that can be used to hold this and all other keys used. Consider the
location, security and backup status of this file carefully, then create it as
follows:
@code{keytool -genkey -v -keystore my.keystore -alias repokey -keyalg RSA -keysize 2048 -validity 10000}
In the above, replace 'my.keystore' with the name of the keystore file to be
created, and 'repokey' with a name to identify the repo index key by.
You'll be asked for a password for the keystore, AND a password for the key.
They shouldn't be the same. In between, you'll be asked for some identifying
details which will go in the certificate.
The two passwords entered go into @code{config.py}, as @code{keystorepass} and
@code{keypass} respectively. The path to the keystore file, and the alias you
chose for the key also go into that file, as @code{keystore} and
@code{repo_keyalias} respectively.
@section Package Signing
With the repo index signing configured, all that remains to be done for package
signing to work is to set the @code{keydname} field in @code{config.py} to
contain the same identifying details you entered before.
A new key will be generated using these details, for each application that is
built. (If a specific key is required for a particular application, this system
can be overridden using the @code{keyaliases} config settings.
@node GNU Free Documentation License
@appendix GNU Free Documentation License
@include fdl.texi
@node Index
@unnumbered Index
@printindex cp
@bye