Difference between revisions of "AMBuild Tutorial"
Line 206: | Line 206: | ||
<Python> | <Python> | ||
+ | # vim: set sts=2 ts=8 sw=2 tw=99 noet: | ||
+ | import sys, ambuild2.run | ||
+ | |||
+ | prep = run.PrepareBuild(sys.path[0]) | ||
run.options.add_option('--enable-debug', action='store_true', dest='debug', default=False, | run.options.add_option('--enable-debug', action='store_true', dest='debug', default=False, | ||
help='Enable debugging symbols') | help='Enable debugging symbols') | ||
run.options.add_option('--enable-optimize', action='store_true', dest='opt', default=False, | run.options.add_option('--enable-optimize', action='store_true', dest='opt', default=False, | ||
help='Enable optimization') | help='Enable optimization') | ||
+ | prep.Configure() | ||
</Python> | </Python> | ||
Revision as of 03:04, 17 October 2013
Writing project files with AMBuild is fairly easy. This tutorial will guide you through making simple AMBuild scripts to compile and package a C++ project.
Contents
Simple Project
To begin, let's say we have a sample project with the following files:
$ ls goodbye.cpp helpers.cpp README.txt
To start, we need to generate a default AMBuild configure script. This is the script that will perform the "configure" step for your build. You can generate one with the following command:
$ ambuild --gen-configure $ ls configure.py goodbye.cpp helpers.cpp README.txt
The configure script simply invokes AMBuild. It can be modified (as we'll see later) to take extra command line options.
$ cat configure.py # vim: set sts=2 ts=8 sw=2 tw=99 noet: import sys, ambuild2.run prep = run.PrepareBuild(sys.path[0]) prep.Configure()
Now, we're ready to actually make a build script for our project. The master build script must be a file called AMBuildScript, and it must be written in Python syntax. The full Python API on your system is available to AMBuild scripts, but the important aspect we'll deal with here is the AMBuild API.
The first step is to tell AMBuild to detect the first available C or C++ compiler. This is done with the following line:
builder.DetectCompilers()
With just this line in your build script, you can now try to configure build. You should see something like:
$ mkdir build $ cd build $ python ../configure.py Checking CC compiler (vendor test gcc)... ['cc', 'test.c', '-o', 'test'] found gcc version 4.7 Checking CXX compiler (vendor test gcc)... ['c++', '-fno-exceptions', '-fno-rtti', 'test.cpp', '-o', 'testp'] found gcc version 4.7 $
If you get an error - either you don't have a compatible C or C++ compiler installed, or AMBuild has a bug (please report it!).
Now, we're ready to complete our AMBuildScript:
program = builder.compiler.Program("hello") program.sources = [ 'main.cpp', 'helpers.cpp', ] builder.Add(program)
The builder object is an instance of an AMBuild context - more about this is in the AMBuild API documentation. Every AMBuild script has access to a builder. The builder.compiler object has information about the C/C++ compiler for the configure session. The Program() method will return an object used to create C++ compilation tasks. In this case, we're asking to build an executable that will be named 'hello' (or hello.exe on Windows). You can also specified shared libraries with Library, and static libraries with StaticLibrary.
You can attach a list of source files to your Program via the sources attribute. Finally, use builder.Add to take your C++ configuration and construct the necessary dependency graph and build steps.
Now, we can actually attempt to build. First, let's make sure AMBuild computed our graph and dependencies correctly:
$ python ../configure.py $ ambuild --show-graph : mkdir "hello" - hello/hello - c++ main.o helpers.o -o hello - hello/main.o - [gcc] -> c++ -H -c /home/dvander/projects/ambuild/ambuild2/main.cpp -o main.o - /home/dvander/projects/ambuild/ambuild2/main.cpp - hello/helpers.o - [gcc] -> c++ -H -c /home/dvander/projects/ambuild/ambuild2/helpers.cpp -o helpers.o - /home/dvander/projects/ambuild/ambuild2/helpers.cpp $ ambuild --show-steps mkdir -p hello task 0: [gcc] -> c++ -H -c /home/dvander/projects/ambuild/ambuild2/main.cpp -o main.o -> hello/main.o task 1: [gcc] -> c++ -H -c /home/dvander/projects/ambuild/ambuild2/helpers.cpp -o helpers.o -> hello/helpers.o task 2: c++ main.o helpers.o -o hello -> hello/hello
It looks good! Now we can build:
$ ambuild mkdir -p hello Spawned task master (pid: 15563) Spawned worker (pid: 15564) Spawned worker (pid: 15565) [15564] c++ -H -c /home/dvander/projects/ambuild/ambuild2/helpers.cpp -o helpers.o [15565] c++ -H -c /home/dvander/projects/ambuild/ambuild2/main.cpp -o main.o [15565] c++ main.o helpers.o -o hello [15565] Child process terminating normally. [15564] Child process terminating normally. [15563] Child process terminating normally. Build succeeded. $ ./hello/hello Hello!
Note that AMBuild gives each C++ binary its own folder. For example, if you build a static library called egg.a, a shared library called egg.so, and an executable called egg all in the same folder, AMBuild will actually perform each of these builds in separate folders, and the binary paths will look like:
- egg.a/egg.a
- egg.so/egg.so
- egg/egg
This is to allow complex build scenarios where the same files are rebuilt multiple times.
Packaging
Now that our project builds, let's add to our build script so that we can create a build package. We'd like to make a folder we can zip or tar for distribution, with the following files:
- README.txt, our readme
- hello, our final binary
First, we have to add a step to the build to create the distribution folder:
dist_folder = builder.AddFolder('dist')
The return value from AddFolder is a dependency graph node, that we can use as an input to future steps.
Now we can copy our files:
outputs = builder.Add(program) folder = builder.AddFolder('dist') builder.AddCopy(os.path.join(builder.sourcePath, 'README.txt'), folder) builder.AddCopy(outputs.binary, folder)
README.txt can be copied directly from the source tree. To copy the executable, we use the return value of builder.Add(). We could construct its path ourselves, but having the dependency object already available is much more convenient.
Now, when we build, we see:
[5952] cp "/home/dvander/projects/ambuild/ambuild2/README.txt" "./dist/README.txt" Spawned worker (pid: 5953) [5952] c++ -H -c /home/dvander/projects/ambuild/ambuild2/helpers.cpp -o helpers.o [5954] c++ -H -c /home/dvander/projects/ambuild/ambuild2/main.cpp -o main.o [5954] c++ main.o helpers.o -o hello [5954] cp "hello/hello" "./dist/hello"
Since copying README.txt has no dependencies, it can execute in parallel with other jobs, even before compilation has finished. It won't be copied again unless README.txt changes. However the copy of hello/hello has to occur last. We can see that it succeeded with:
$ ls -l dist/ total 12 -rwxr-xr-x 1 dvander dvander 7036 Oct 16 22:32 hello -rw-r--r-- 1 dvander dvander 23 Oct 16 22:32 README.txt
It is also possible to add a step to execute a command like "tar" or "zip", but there's a complication. There must be a dependency to every file that would be included in the command, otherwise, the commands might occur out of order. We are still looking into easier ways to automate this.
Multiple Scripts
Non-trivial projects usually need more than one build script. AMBuild allows build scripts to nest; any script can run another script. Each script gets its own builder, known internally as a context. All jobs are created within a context and associated with that context. This allows AMBuild to reparse a minimal number of build scripts when a build script changes.
Contexts, by default, are associated with the folder they exist in relative to the source tree. For example, a build script in /source-tree/src/game/AMBuild will have a context associated with src/game. This folder structure is mirrored in the build folder, and all jobs occur within the context's local folder. For example, let's move our packaging into a separate script, PackageScript:
# PackageScript import os builder.SetBuildFolder('dist') builder.AddCopy(os.path.join(builder.sourcePath, 'README.txt'), '.') builder.AddCopy(Hello.binary, '.')
Then we modify our main AMBuildScript:
# AMBuildScript builder.DetectCompilers() program = builder.compiler.Program("hello") program.sources = [ 'main.cpp', 'helpers.cpp', ] outputs = builder.Add(program) builder.RunBuildScripts( ['PackageScript'], { 'Hello': outputs } )
The first parameter is an array of script paths to run, and the second is a dictionary of global variables to give each script. Note that since our PackageScript is in the root of the source tree, by default its build folder is '.', so we manually override its build folder.
When PackageScript is parsed during the configure step, all of its jobs will automatically be configured to occur inside a dist folder within the build folder, so '.' actually refers to ./dist/.
Custom Options
It is possible to add custom options to the configure step using Python's optparse module. Recall the default configure.py that AMBuild generates:
# vim: set sts=2 ts=8 sw=2 tw=99 noet: import sys, ambuild2.run prep = run.PrepareBuild(sys.path[0]) prep.Configure()
The prep object has an options attribute, which is an instance of optparse.OptionParser. You can add to it, for example,
# vim: set sts=2 ts=8 sw=2 tw=99 noet: import sys, ambuild2.run prep = run.PrepareBuild(sys.path[0]) run.options.add_option('--enable-debug', action='store_true', dest='debug', default=False, help='Enable debugging symbols') run.options.add_option('--enable-optimize', action='store_true', dest='opt', default=False, help='Enable optimization') prep.Configure()
These options can be accessed from any builder object, like so:
if builder.options.debug: builder.compiler.cflags += ['-O0', '-ggdb3'] builder.compiler.cdefines += ['DEBUG'] if builder.options.opt: builder.compiler.cflags += ['-O3'] builder.compiler.cdefines += ['NDEBUG']
Task Groups
Sometimes it is useful to force build steps to occur in distinct phases. Normally, this would be the antithesis of what we want: the dependency graph should precisely and perfectly represent dependencies, and there should be no need to enforce order manually. That's true, but there are situations what warrant relaxing how we construct the graph.
Generated headers in particular pose a problem. If we created dependencies on a "generate headers" task, then generating new headers would trigger recompiling every source file - even ones that never included those headers. Furthermore, if we created dependencies on each individual generated header, we'd have a huge dependency graph - 50 includes and 800 source files would mean 80,000 dependency links. AMBuild solves these problem in the same way tup does.
First, we introduce the concept of a weak dependency. A weak dependency is one that theoretically exists, and must exist for ordering, but does not propagate damage. For example, let's say that hello.cpp has a weak dependency on generated.h. If hello.cpp doesn't #include "generated.h", then no changes to generated.h should ever trigger a rebuild of hello.cpp. However, if hello.cpp is changed to include generated.h, then the weak dependency ensures those jobs are executed in the right order. (It is illegal in AMBuild to depend on a generated file without having an explicit dependency.) The weak dependency can then be upgraded to a strong dependency, and possibly downgraded again later if the #include is removed.
Second, we introduce the concept of groups. A group associates a set of jobs together so they can function as one logical dependency. In the example earlier, our 50 include files would be represented by one meta-job, and the number of dependency edges would be reduced to the number of source files. Groups do not imply that all tasks in the group run at the same time, to the exclusion of all other tasks. They are simply an optimization in building weak dependencies, which enforce ordering along those dependencies.
Reconfiguring
Reconfiguring can happen for two reasons. One is that you want to change some properties of the build, for example, switching from an optimized build to a debug build. Another is that a build script changes, and AMBuild will automatically reparse any affected build scripts to reshape the dependency graph.
When a reconfigure occurs, AMBuild will produce a new dependency graph alongside the old dependency graph. These graphs are then merged. Any generated files in the old graph that are not present in the new graph, are removed from the file system. This is necessary to ensure that builds do not become corrupt. This has an unusual side effect of making it possible to reconfigure an old build over entirely new build scripts - AMBuild will dutifully clean all previously compiled or generated files and folders.