|Version 1 (modified by simonmar, 4 years ago)|
Idiom: phase ordering
NB. you need to understand this section if either (a) you are modifying parts of the build system that include automatically-generated Makefile code, or (b) you need to understand why we have a top-level Makefile that recursively invokes make.
The main hitch with non-recursive make arises when parts of the build system are automatically-generated. The automatically-generated parts of our build system fall into two main categories:
- Dependencies: we use ghc -M to generate make-dependencies for Haskell source files, and similarly gcc -M to do the same for C files. The dependencies are normally generated into a file .depend, which is included as normal.
- Makefile binding generated from .cabal package descriptions. See "Idiom: interaction with Cabal".
Now, we also want to be able to use make to build these files, since they have complex dependencies themselves. For example, in order to build package-data.mk we need to first build ghc-cabal etc.; similarly, a .depend file needs to be re-generated if any of the source files have changed.
GNU make has a clever strategy for handling this kind of scenario. It first reads all the included Makefiles, and then tries to build each one if it is out-of-date, using the rules in the Makefiles themselves. When it has brought all the included Makefiles up-to-date, it restarts itself to read the newly-generated Makefiles.
This works fine, unless there are dependencies between the Makefiles. For example in the GHC build, the .depend file for a package cannot be generated until package-data.mk has been generated and make has been restarted to read in its contents, because it is the package-data.mk file that tells us which modules are in the package. But make always makes all the included Makefiles before restarting - it doesn't know how to restart itself earlier when there is a dependency between included Makefiles.
Consider the following Makefile:
all : include inc1.mk inc1.mk : Makefile echo "X = C" >$@ include inc2.mk inc2.mk : inc1.mk echo "Y = $(X)" >$@
Now try it:
$ make -f fail.mk fail.mk:3: inc1.mk: No such file or directory fail.mk:8: inc2.mk: No such file or directory echo "X = C" >inc1.mk echo "Y = " >inc2.mk make: Nothing to be done for `all'.
make built both inc1.mk and inc2.mk without restarting itself between the two (even though we added a dependency on inc1.mk from inc2.mk).
The solution we adopt in the GHC build system is as follows. We have two Makefiles, the first a wrapper around the second.
# top-level Makefile % : $(MAKE) -f inc.mk PHASE=0 just-makefiles $(MAKE) -f inc.mk $<
# inc.mk include inc1.mk ifeq "$(PHASE)" "0" inc1.mk : inc.mk echo "X = C" >$@ else include inc2.mk inc2.mk : inc1.mk echo "Y = $(X)" >$@ endif just-makefiles: @: # do nothing clean : rm -f inc1.mk inc2.mk
Each time make is invoked, we recursively invoke make in several phases:
- Phase 0: invoke inc.mk with PHASE=0. This brings inc1.mk up-to-date (and only inc1.mk).
- Final phase: invoke inc.mk again (with PHASE unset). Now we can be sure that inc1.mk is up-to-date and proceed to generate inc2.mk. If this changes inc2.mk, then make automatically re-invokes itself, repeating the final phase.
We could instead have abandoned make's automatic re-invocation mechanism altogether, and used three explicit phases (0, 1, and final), but in practice it's very convenient to use the automatic re-invocation when there are no problematic dependencies.
Note that the inc1.mk rule is only enabled in phase 0, so that if we accidentally call inc.mk without first performing phase 0, we will either get a failure (if inc1.mk doesn't exist), or otherwise make will not update inc1.mk if it is out-of-date.
In the case of the GHC build system we need 4 such phases, see the comments in the top-level ghc.mk for details.
This approach is not at all pretty, and re-invoking make every time is slow, but we don't know of a better workaround for this problem.