Skip to content

A simple, portable package manager for applications

License

Notifications You must be signed in to change notification settings

sandialabs/capp

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

CApp

Overview

CApp is like a package manager, but it avoids a lot of package manager responsibilities by building packages just to support one application, hence the name is a shortening of "C Application". CApp depends only on CMake and Git, and is actually written in the CMake language for portability. It assumes all packages have source code stored in Git repositories and are compiled with CMake. CApp is built around the notion of a build repository, which is a Git repository containing "package files": CMake language files which describe packages needed to build the application, their exact version expressed as a Git commit, their dependencies, and the CMake arguments needed to configure each package. By knowing only about exactly one version of each package, CApp avoids any responsibilities related to version compatibility resolution. What CApp does do is automate the process of cloning, configuring, building, installing, and otherwise developing the various packages needed to build an application. It can be used for automated installation, continuous integration, and local developer work, all in a unified system that is portable across operating systems.

Slides describing CApp and modern CMake usage can be found here

Usage

Installing CApp

CApp consists of a CMake script and a Bash environment setup script. These files can be used from the cloned Git repository or the three files can be copied somewhere else (capp.cmake needs to be in the same directory as the setup script).

git clone [email protected]:sandialabs/capp.git
cd capp
cp capp.cmake capp-setup.sh /where/you/want

Setting Up an Application

init command

The first step to using CApp is to create a repository that describes the packages needed for the application. This can be done by using the capp init command. As the name suggests, a build repository is also a Git repository, and capp init will call git init.

git clone [email protected]:sandialabs/capp.git
cd capp
cp capp/capp.cmake capp/capp-setup.sh my-build/
cd my-build
. capp-setup.sh
capp init my-application
vim app.cmake
git commit -a -m "initial application commit"

The setup script must be sourced prior to using CApp in any context

cd my-build
. capp-setup.sh

app.cmake

A build repository needs to have an app.cmake file in the top-level directory. Similar to how Git identifies a Git repository by the presence of a .git directory, CApp identifies a build repository by the presence of an app.cmake file. capp init creates this file with some default content for convenience. An application's app.cmake file should at minimum contain a call to the capp_app command, whose signature is as follows:

capp_app(
  ROOT_PACKAGES package1 [package2 ... ]
  [BUILD_TYPE type])

ROOT_PACKAGES should be the list of packages that CApp must always try to compile. CApp will try to build all packages that ROOT_PACKAGES depend on (see the documentation on capp_package) in the right order. Most applications will have an "application package", which is a package that contains the source code for the application but not any of the other supporting packages. The typical use case will be to list the ROOT_PACKAGES as just the application package. By default, CApp will configure all packages with -DCMAKE_BUILD_TYPE=Release. The BUILD_TYPE argument can be used to change the build type to something else (CMake supports Release, Debug, and None). The build type can also be set on a per-flavor basis by setting CAPP_BUILD_TYPE in a flavor.cmake file.

flavor.cmake

CApp supports multiple flavors, which are just full-build configurations by a different name. Each build flavor is contained in a directory flavor/<flavor_name>/. This allows users to set variables that control the build, such as enabling or disabling options in certain packages. These options should be handled through CMake variables, and should be defined in a file flavor/<flavor_name>/flavor.cmake. This flavor file will be loaded via a cmake include() command prior to including app.cmake.

For example, if there is an option in package foo called FOO_ENABLE_FAST, and you'd like to control this at the overall application layer, you could put the following in the flavor.cmake file:

set(MY_APP_ENABLE_FAST TRUE)

Then the file packages/foo/package.cmake could do the following:

capp_package(
  OPTIONS
  "-DFOO_ENABLE_FAST=${MY_APP_ENABLE_FAST}"
  )

If the flavor.cmake or app.cmake files are altered, the next time that CApp tries to build it will re-configure all packages.

There are two ways the user can select which flavor CApp is operating on:

  1. The CApp command accepts an argument --flavor <flavor_name> or -f <flavor_name> for short
  2. If the CApp command is executed somewhere inside the flavor directory, it will infer the flavor based on the directory.

clone command

The easiest way to add a new package to the build repository is via capp clone:

capp clone [email protected]:Unidata/netcdf-c.git
vim package/netcdf-c/package.cmake 
git commit -a -m "added netcdf package"

package.cmake

The primary package information in a CApp build repository is stored in files:

package/<package_name>/package.cmake

The actual names of packages are the names of the sub-directories in the package directory of the build repository.

A package's package.cmake file should at minimum call capp_package, whose signature is as follows:

capp_package(
  GIT_URL git_url
  COMMIT commit
  [OPTIONS option1 [option2 ...]]
  [DEPENDENCIES dep1 [dep2 ...]]
  [BUILD_TYPE type]
  [NO_CONFIGURE_CACHE]
  [IGNORE_UNCOMMITTED])

The GIT_URL option should be a Git URL suitable for git clone and other commands. An example Git URL would be [email protected]:sandialabs/omega_h.git. While CApp doesn't impose restrictions on the type of Git URL, it has only been tested with SSH protocol URLs and not with HTTPS protocol URLs.

The COMMIT option should be the SHA-1 hash for a certain Git commit, meaning the version of the package repository we want to checkout and build.

Note that by directly listing a SHA-1 commit in package.cmake files, CApp implements a submodule-like system that ensures that the SHA-1 commit hashes of the build repository are tied to the SHA-1 commit hashes of the package repositories. This means that it is enough to know the version of the build repository that was built in order to know the exact versions of all package repositories that were built.

The OPTIONS list should be a list of command line arguments to CMake when configuring the package. For example, an item option1 might be -DFOO_ENABLE_FAST=ON. Note that CApp already defines CMAKE_BUILD_TYPE and CMAKE_INSTALL_PREFIX when configuring a package.

The DEPENDENCIES list should be a list of package names on which the current package directly depends. Recall that package names are the names of subdirectories of the package directory of the build repository.

If the BUILD_TYPE option is present, it sets the value of CMAKE_BUILD_TYPE for just this package. Otherwise, the value of BUILD_TYPE given to capp_app is used. If neither are given, Release is used.

If the NO_CONFIGURE_CACHE option is present, then when CApp tries to re-configure a package it will first remove the CMakeCache.txt file. This is useful when packages have buggy CMake files that produce different results when incrementally reconfigured than they do when configured without a cache, even with the same arguments supplied.

The capp commit command discussed later will check whether there are uncommitted changes to a package's source repository. However, some packages modify their source directory during their configure, build, and install process even though this is bad practice. For those packages, one can add IGNORE_UNCOMMITTED to the capp_package arguments to tell CApp to ignore uncommitted changes to that package.

Building an Application

Recall that the setup script must be sourced prior to using CApp:

cd my-build
. capp-setup.sh

build command

With a copy of the build repository available, CApp can build it with the capp build command.

capp build -f plain

Directory structure

CApp will create sub-directories in the build repository directory called source, build, and install. Each package will have its Git repository cloned into:

source/<package-name>

Each package will have its CMake binary directory (where CMake is configured and all intermediate build files are stored) at:

flavor/<flavor_name>/build/<package-name>

Each package will be installed by setting CMAKE_INSTALL_PREFIX equal to:

flavor/<flavor_name>/install/<package-name>

The capp init command populates .gitignore to ignore these directories, since their content is an artifact of the current build and not part of the fundamental specification of a build repository.

Installing an Application

CApp has an install command which will copy files from its internal installation directories to a directory that must be specified via the --prefix flag. Because it copies the files, this could be problematic for dynamically linked packages using RPATH, and is only advised for statically linked packages. Like other commands, the install command accepts a list of packages and will install all packages if not given any.

Recall that the setup script must be sourced prior to using CApp:

cd my-build
. capp-setup.sh
capp install my_root_package -f plain --prefix /usr

Developing an Application

Possibly the most productive use of CApp is actual application development. CApp was designed specifically for users to radidly conduct multi-package development.

Recall that the setup script must be sourced prior to using CApp:

cd my-build
. capp-setup.sh

Rebuilding a Package

Users of CApp are encouraged to edit package source code in the the source/ subdirectory of the build repository and follow the normal Git workflow for each package as desired. At some point, to see the effects of the source code changes, users may want to rebuild a package and all downstream dependencies. This can be done with the capp rebuild command:

cd source/package1
vim package_function.c
capp rebuild -f plain package1

If given no arguments, the capp rebuild command will rebuild all packages.

Reconfiguring a Package

Sometimes a change to a package is substantial enough that it requires CMake reconfiguration in order to properly update the build. This can be done with the capp reconfig command, which works just like capp rebuild but will force a fresh CMake configuration of the package prior to rebuilding. If given no arguments, the capp reconfig command will reconfigure and rebuild all packages.

Testing a Package

Since CApp assumes all packages use CMake to compile, it also assumes that CTest is used for testing. The command capp test is used to test packages. Like other commands, it accepts one or more package names as arguments, and if not given any arguments then all packages are tested. CApp will simply call ctest in the appropriate package build directory in order to test a package.

capp test -f plain package1

Accepting a New Package Version

After a developer is done modifying a package, the natural next step is getting the build repository to accept and point to the new modified version of the package. This is done by the capp commit command, which will update the git URL and git commit that the build repository points to.

cd source/package1
git pull
capp commit package1
git commit -a -m "updated version of package1"

capp commit will fail if there are uncommitted changes to the package's source repository, thereby helping to ensure that the current state of the source code really gets captured. This behavior can be avoided by specifying IGNORE_UNCOMMITTED in package.cmake files.

If given no package arguments, capp commit will operate on all packages.

Checking Out New Package Versions

An inverse of the prior function is to update the package source in the source directory to be exactly the version pointed to by the build repository. We do this with the capp checkout command. This is especially helpful to run after other developers have made changes to package versions.

git pull
capp checkout
capp build -f plain

Even easier, the capp pull command is equivalent to git pull followed by capp checkout:

capp pull
capp build -f plain

Exporting Build Information

CApp has a capp export command which produces a file capp.json describing the build in a way that can be used by other tools to automatically derive useful information. The capp.json file encodes a JSON array of JSON objects, one object per package. Each JSON package object has the following members:

  1. name: the package name
  2. git: the package's Git URL
  3. commit: the package's Git commit hash
  4. submodules: a JSON boolean which is true if the checked out source has submodules
  5. depedencies: a JSON array of JSON strings which are the names of upstream dependencies
  6. options: a JSON array of JSON strings which are the command line options to be passed to the CMake configuration for this package.

Note that the description of the build is affected by options such as flavor. For best results, please specify a flavor when using capp export:

capp export -f plain
cat capp.json

At Sandia, CApp is SCR# 2639.0