Build Framework =============== The perf build framework was adopted from the kernel build system, hence the idea and the way how objects are built is the same. Basically the user provides set of 'Build' files that list objects and directories to nest for specific target to be build. Unlike the kernel we don't have a single build object 'obj-y' list that where we setup source objects, but we support more. This allows one 'Build' file to carry a sources list for multiple build objects. Build framework makefiles ------------------------- The build framework consists of 2 Makefiles: Build.include Makefile.build While the 'Build.include' file contains just some generic definitions, the 'Makefile.build' file is the makefile used from the outside. It's interface/usage is following: $ make -f tools/build/Makefile.build srctree=$(KSRC) dir=$(DIR) obj=$(OBJECT) where: KSRC - is the path to kernel sources DIR - is the path to the project to be built OBJECT - is the name of the build object When succefully finished the $(DIR) directory contains the final object file called $(OBJECT)-in.o: $ ls $(DIR)/$(OBJECT)-in.o which includes all compiled sources described in 'Build' makefiles. Build makefiles --------------- The user supplies 'Build' makefiles that contains a objects list, and connects the build to nested directories. Assume we have the following project structure: ex/a.c /b.c /c.c /d.c /arch/e.c /arch/f.c Out of which you build the 'ex' binary ' and the 'libex.a' library: 'ex' - consists of 'a.o', 'b.o' and libex.a 'libex.a' - consists of 'c.o', 'd.o', 'e.o' and 'f.o' The build framework does not create the 'ex' and 'libex.a' binaries for you, it only prepares proper objects to be compiled and grouped together. To follow the above example, the user provides following 'Build' files: ex/Build: ex-y += a.o ex-y += b.o ex-y += b.o # duplicates in the lists are allowed libex-y += c.o libex-y += d.o libex-y += arch/ ex/arch/Build: libex-y += e.o libex-y += f.o and runs: $ make -f tools/build/Makefile.build dir=. obj=ex $ make -f tools/build/Makefile.build dir=. obj=libex which creates the following objects: ex/ex-in.o ex/libex-in.o that contain request objects names in Build files. It's only a matter of 2 single commands to create the final binaries: $ ar rcs libex.a libex-in.o $ gcc -o ex ex-in.o libex.a You can check the 'ex' example in 'tools/build/tests/ex' for more details. Makefile.include ---------------- The tools/build/Makefile.include makefile could be included via user makefiles to get usefull definitions. It defines following interface: - build macro definition: build := -f $(srctree)/tools/build/Makefile.build dir=. obj to make it easier to invoke build like: make $(build)=ex Fixdep ------ It is necessary to build the fixdep helper before invoking the build. The Makefile.include file adds the fixdep target, that could be invoked by the user. Rules ----- The build framework provides standard compilation rules to handle .S and .c compilation. It's possible to include special rule if needed (like we do for flex or bison code generation). CFLAGS ------ It's possible to alter the standard object C flags in the following way: CFLAGS_perf.o += '...' - adds CFLAGS for perf.o object CFLAGS_gtk += '...' - adds CFLAGS for gtk build object CFLAGS_REMOVE_perf.o += '...' - removes CFLAGS for perf.o object CFLAGS_REMOVE_gtk += '...' - removes CFLAGS for gtk build object This C flags changes has the scope of the Build makefile they are defined in. Dependencies ------------ For each built object file 'a.o' the '.a.cmd' is created and holds: - Command line used to built that object (for each object) - Dependency rules generated by 'gcc -Wp,-MD,...' (for compiled object) All existing '.cmd' files are included in the Build process to follow properly the dependencies and trigger a rebuild when necessary. Single rules ------------ It's possible to build single object file by choice, like: $ make util/map.o # objects $ make util/map.i # preprocessor $ make util/map.s # assembly lass='ctrl'>mode:
authorThomas Gleixner <tglx@linutronix.de>2017-01-10 14:01:05 +0100
committerThomas Gleixner <tglx@linutronix.de>2017-01-16 13:20:05 +0100
commit4205e4786d0b9fc3b4fec7b1910cf645a0468307 (patch)
tree685ccb486409197b936c785eb9d173c3edff45a1 /net/ipv6/mip6.c
parent7e164ce4e8ecd7e9a58a83750bd3ee03125df154 (diff)
cpu/hotplug: Provide dynamic range for prepare stage
Mathieu reported that the LTTNG modules are broken as of 4.10-rc1 due to the removal of the cpu hotplug notifiers. Usually I don't care much about out of tree modules, but LTTNG is widely used in distros. There are two ways to solve that: 1) Reserve a hotplug state for LTTNG 2) Add a dynamic range for the prepare states. While #1 is the simplest solution, #2 is the proper one as we can convert in tree users, which do not care about ordering, to the dynamic range as well. Add a dynamic range which allows LTTNG to request states in the prepare stage. Reported-and-tested-by: Mathieu Desnoyers <mathieu.desnoyers@efficios.com> Signed-off-by: Thomas Gleixner <tglx@linutronix.de> Reviewed-by: Mathieu Desnoyers <mathieu.desnoyers@efficios.com> Cc: Peter Zijlstra <peterz@infradead.org> Cc: Sebastian Sewior <bigeasy@linutronix.de> Cc: Steven Rostedt <rostedt@goodmis.org> Link: http://lkml.kernel.org/r/alpine.DEB.2.20.1701101353010.3401@nanos Signed-off-by: Thomas Gleixner <tglx@linutronix.de>
Diffstat (limited to 'net/ipv6/mip6.c')