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parallel_autotuning_mpipool.py
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parallel_autotuning_mpipool.py
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#from charm4py import entry_method, chare, Chare, Array, Reducer, Future, charm
#from charm4py.pool import PoolScheduler, Pool
#from charm4py.charm import Charm, CharmRemote
#from charm4py.chare import GROUP, MAINCHARE, ARRAY, CHARM_TYPES, Mainchare, Group, ArrayMap
#from charm4py.sections import SectionManager
#import inspect
#import sys
import hjson
import pyopencl as cl
import numpy as np
import grudge.loopy_dg_kernels as dgk
import os
import grudge.grudge_array_context as gac
import loopy as lp
from os.path import exists
from grudge.loopy_dg_kernels.run_tests import run_single_param_set, generic_test
from grudge.grudge_array_context import convert
#from grudge.execution import diff_prg, elwise_linear
import mpi4py.MPI as MPI
#from mpi4py.futures import MPIPoolExecutor, MPICommExecutor
from mpipool import MPIPool, MPIExecutor
def get_queue(pe_num, platform_num):
platforms = cl.get_platforms()
gpu_devices = platforms[platform_num].get_devices(device_type=cl.device_type.GPU)
ctx = cl.Context(devices=[gpu_devices[pe_num % len(gpu_devices)]])
queue = cl.CommandQueue(ctx, properties=cl.command_queue_properties.PROFILING_ENABLE)
return queue
def test(args):
#print(args)
platform_id, knl, tlist_generator, params, test_fn = args
comm = MPI.COMM_WORLD # Assume we're using COMM_WORLD. May need to change this in the future
queue = get_queue(comm.Get_rank(), platform_id)
result = run_single_param_set(queue, knl, tlist_generator, params, test_fn)
return result
def unpickle_kernel(fname):
from pickle import load
f = open(fname, "rb")
program = load(f)
f.close()
return program
def autotune_pickled_kernels(path, platform_id, actx_class, comm):
from os import listdir
dir_list = listdir(path)
for f in dir_list:
if f.endswith(".pickle"):
fname = path + "/" + f
print("===============================================")
print("Autotuning", fname)
knl = unpickle_kernel(fname)
knl_id = f.split(".")[0]
knl_id = knl_id.split("_")[-1]
print("Kernel ID", knl_id)
print("New kernel ID", gac.unique_program_id(knl))
assert knl_id == gac.unique_program_id(knl)
knl = lp.set_options(knl, lp.Options(no_numpy=True, return_dict=True))
knl = gac.set_memory_layout(knl)
assert knl_id == gac.unique_program_id(knl)
print(knl)
pid = gac.unique_program_id(knl)
hjson_file_str = f"hjson/{knl.default_entrypoint.name}_{pid}.hjson"
if not exists(hjson_file_str):
parallel_autotune(knl, platform_id, actx_class, comm)
else:
print("hjson file exists, skipping")
def parallel_autotune(knl, platform_id, actx_class, comm):
# Create queue, assume all GPUs on the machine are the same
platforms = cl.get_platforms()
gpu_devices = platforms[platform_id].get_devices(device_type=cl.device_type.GPU)
n_gpus = len(gpu_devices)
ctx = cl.Context(devices=[gpu_devices[comm.Get_rank() % n_gpus]])
profiling = cl.command_queue_properties.PROFILING_ENABLE
queue = cl.CommandQueue(ctx, properties=profiling)
import pyopencl.tools as cl_tools
actx = actx_class(
comm,
queue,
allocator=cl_tools.MemoryPool(cl_tools.ImmediateAllocator(queue)))
knl = lp.set_options(knl, lp.Options(no_numpy=True, return_dict=True))
knl = gac.set_memory_layout(knl)
pid = gac.unique_program_id(knl)
os.makedirs(os.getcwd() + "/hjson", exist_ok=True)
hjson_file_str = f"hjson/{knl.default_entrypoint.name}_{pid}.hjson"
#assert comm.Get_size() > 1
#assert charm.numPes() > 1
#assert charm.numPes() - 1 <= charm.numHosts()*len(gpu_devices)
#assert charm.numPes() <= charm.numHosts()*(len(gpu_devices) + 1)
# Check that it can assign one PE to each GPU
# The first PE is used for scheduling
# Not certain how this will work with multiple nodes
from run_tests import run_single_param_set
tlist_generator, pspace_generator = actx.get_generators(knl)
params_list = pspace_generator(actx.queue, knl)
# Could make a massive list with all kernels and parameters
args = [(platform_id, knl, tlist_generator, p, generic_test,) for p in params_list]
# May help to balance workload
# Should test if shuffling matters
from random import shuffle
shuffle(args)
#a = Array(AutotuneTask, dims=(len(args)), args=args[0])
#a.get_queue()
#result = charm.pool.map(do_work, args)
#pool_proxy = Chare(BalancedPoolScheduler, onPE=0) # Need to use own charm++ branch to make work
#pool_proxy = Chare(PoolScheduler, onPE=0)
sort_key = lambda entry: entry[0]
transformations = {}
if len(args) > 0: # Guard against empty list
with MPIExecutor() as mypool:
mypool.workers_exit()
results = mypool.map(test, args[:6])
results.sort(key=sort_key)
#for r in results:
# print(r)
# Workaround for pocl CUDA bug
# whereby times are imprecise
ret_index = 0
for i, result in enumerate(results):
if result[0] > 1e-7:
ret_index = i
break
avg_time, transformations, data = results[ret_index]
od = {"transformations": transformations}
out_file = open(hjson_file_str, "wt+")
hjson.dump(od, out_file,default=convert)
out_file.close()
return transformations
"""
def main(args):
# Create queue, assume all GPUs on the machine are the same
platforms = cl.get_platforms()
platform_id = 0
gpu_devices = platforms[platform_id].get_devices(device_type=cl.device_type.GPU)
n_gpus = len(gpu_devices)
ctx = cl.Context(devices=[gpu_devices[charm.myPe() % n_gpus]])
profiling = cl.command_queue_properties.PROFILING_ENABLE
queue = cl.CommandQueue(ctx, properties=profiling)
assert charm.numPes() > 1
#assert charm.numPes() - 1 <= charm.numHosts()*len(gpu_devices)
assert charm.numPes() <= charm.numHosts()*(len(gpu_devices) + 1)
# Check that it can assign one PE to each GPU
# The first PE is used for scheduling
# Not certain how this will work with multiple nodes
from grudge.execution import diff_prg, elwise_linear_prg
knl = diff_prg(3, 1000000, 3, np.float64)
params = dgk.run_tests.gen_autotune_list(queue, knl)
args = [[param, knl] for param in params]
# May help to balance workload
from random import shuffle
shuffle(args)
#a = Array(AutotuneTask, dims=(len(args)), args=args[0])
#a.get_queue()
#result = charm.pool.map(do_work, args)
pool_proxy = Chare(BalancedPoolScheduler, onPE=0)
mypool = Pool(pool_proxy)
result = mypool.map(do_work, args)
sort_key = lambda entry: entry[0]
result.sort(key=sort_key)
for r in result:
print(r)
"""
def main():
from mirgecom.array_context import MirgecomAutotuningArrayContext as Maac
comm = MPI.COMM_WORLD
autotune_pickled_kernels("./pickled_programs", 0, Maac, comm)
print("DONE!")
exit()
if __name__ == "__main__":
import sys
main()
#pool = MPIPool()
#if not pool.is_master():
# pool.wait()
# sys.exit(0)