Tracing and profiling Julia code with Score-P
- You must be on Linux.
- You must have
gccinstalled (and onPATH).
wget https://perftools.pages.jsc.fz-juelich.de/cicd/scorep/tags/scorep-7.1/scorep-7.1.tar.gz
tar -xf scorep-7.1.tar.gx
cd scorep-7.1/
mkdir build
cd build
../configure --enable-shared
make -j 4
sudo make install
Note: You might want to also provide a --prefix=/my/user/dir/ to configure to install into non-global user directory. In this case, you can drop the sudo in the last line.
] add https://github.com/JuliaPerf/ScoreP.jl# example.jl
using ScoreP
ScoreP.init()
# ScoreP initialization must come before anything else!
X = rand(100_000)
@scorep_user_region "sin" X .= sin.(X)
@scorep_user_region "code block" begin
@scorep_user_region "allocs" begin
A = rand(1000,1000)
B = rand(1000,1000)
end
@scorep_user_region "loop" begin
for _ in 1:10
A * B
end
end
endRunning this (julia example.jl) generates a folder, e.g., scorep-20230127_1603_20921538990107094 (you can set export SCOREP_EXPERIMENT_DIRECTORY=foldername to choose a specific folder name up-front). In it is a profile.cubex file which contains the profiling information. You can open .cubex files with Cube. For the example above, this should give you something like this:
Running the same example with export SCOREP_ENABLE_TRACING=true the output folder will besides the profiling results contain tracing information as well, specifically, a file traces.otf2. The latter can be opened with the (commerical) software Vampir and should give you something like the following.
On Linux and Windows, it should also be possible to use the Intel Trace Analyzer or other OTF2 visualizers.
# mpi_example.jl
using ScoreP
ScoreP.init()
using MPI
using Printf
function get_arguments(rank, com_size)
if rank == 0
a = parse(Float64, get(ARGS, 1, "0.0"))
b = parse(Float64, get(ARGS, 2, "1.0"))
n = parse(Int, get(ARGS, 3, "1000000000"))
for dest in 1:(com_size - 1)
MPI.Send(a, dest, 0, MPI.COMM_WORLD)
MPI.Send(b, dest, 0, MPI.COMM_WORLD)
MPI.Send(n, dest, 0, MPI.COMM_WORLD)
end
else
a, = MPI.Recv(Float64, 0, 0, MPI.COMM_WORLD)
b, = MPI.Recv(Float64, 0, 0, MPI.COMM_WORLD)
n, = MPI.Recv(Int, 0, 0, MPI.COMM_WORLD)
end
return a, b, n
end
f(x) = x * x
F(x) = x^3 / 3
function integrate(left, right, count, len)
estimate = (f(left) + f(right)) / 2.0
for i in 1:(count - 1)
x = left + i * len
estimate += f(x)
end
return estimate * len
end
function main()
MPI.Init(; threadlevel = :funneled) # threadlevel <= funneled required for ScoreP!
rank = MPI.Comm_rank(MPI.COMM_WORLD)
com_size = MPI.Comm_size(MPI.COMM_WORLD)
@scorep_user_region "integration" begin
@scorep_user_region "get_arguments" a, b, n=get_arguments(rank, com_size)
@scorep_user_region "local integration" begin
# h and local_n are the same for all processes
h = (b - a) / n
local_n = n / com_size
# compute integration boundaries for each rank
local_a = a + rank * local_n * h
local_b = local_a + local_n * h
# compute integral in bounds for each rank
local_int = integrate(local_a, local_b, local_n, h)
end
@scorep_user_region "collect results" begin
if rank != 0
# Worker: send local result to master
MPI.Send(local_int, 0, 0, MPI.COMM_WORLD)
else
# Master: add up results
total_int = local_int
for src in 1:(com_size - 1)
worker_int, = MPI.Recv(Float64, src, 0, MPI.COMM_WORLD)
total_int += worker_int
end
end
end
end
# Master: print result
if rank == 0
@printf("With n = %d trapezoids, our estimate of the integral from %f to %f is %.12e (exact: %f)\n",
n, a, b, total_int, F(b)-F(a))
end
MPI.Finalize()
end
# run main function
main()
- The Python analogon scorep_binding_python was as a valuable resource for inspiration.
This package is an effort by the Paderborn Center for Parallel Computing (PC²).