I know that to allow
make to be multithreaded, I use the command
make --jobs=X where
X is usually equal to number of cores (or twice that or whatever).
I am debugging a makefile - actually consists of many makefiles - to work with the
--jobs=X option. Here's an example of why it currently doesn't:
T1: mkdir D1 output_makefile.bat > ./D1/makefile T2: cd D1 make
Executing this with
--jobs=X will lead to a race condition because
T1 is not specified as a dependency of
T2 and eventually
T2 will get built ahead of
T1; most of the bugs I need to fix are of this variety.
--jobs=X is greater than the number of ?logical or physical? cores, the number of jobs executed simultaneously will be capped at the number of ?logical or physical? cores.
My machine has 4 physical/8 logical cores but the build machine that will be running our builds will have as many as 64 cores.
So I'm concerned that just because my makefile (a) builds the final output correctly (b) runs without errors on my machine with
--jobs=4 does not mean it'll run correctly and without errors with
--jobs=64 on a 64-core machine.
Is there a tool that will simulate
make executing in an environment that has more cores than the physical machine?
What about creating a virtual machine with 64 cores and run it on my 4-core machine; is that even allowed by VMPlayer?
I realized that my understanding of
make was incorrect: the number of job slots
make creates is equal to the
--jobs=N argument and not the number of cores or threads my PC has.
However, this by itself doesn't necessarily mean that
make will also execute those jobs in parallel even if I have fewer cores than jobs by using task-switching.
I need to confirm that ALL the jobs are being executed in parallel vs merely 'queued up' and waiting for the actively executing jobs to finish.
So I created a makefile with 16 targets - more than the num of threads or cores I have - and each recipe merely
echos the name of the target a configurable number of times.
all: 1 2 3 4 ... 14 15 16 <target X>: @loop_output.bat $@
@FOR /L %%G IN (1,1,2048) DO @echo (%1-%%G)
The output will be something like
(16-1) <-- Job 16 (6-1400) (12-334) (1-1616) <-- Job 1 (4-1661) (15-113) (11-632) (2-1557) (10-485) (7-1234) (5-1530)
The format is
Job#X-Echo#Y. The fact that I see
(16-1) means that
make is indeed executing target
16 at the same time as target
The alternative is that
make finishes jobs (1-#of cores/threads) and then takes another chunk of jobs equal to #num cores/threads but that's not what's happening.