""" Copyright 2020 The Microsoft DeepSpeed Team Licensed under the MIT license. Functionality of swapping optimizer tensors to/from (NVMe) storage devices. """ import torch import os import time from deepspeed.ops.aio import AsyncIOBuilder from multiprocessing import Pool, Barrier from test_ds_aio_utils import report_results, task_log, task_barrier def pre_basic(args, tid, read_op): io_string = "Read" if read_op else "Write" num_bytes = os.path.getsize(args.read_file) if read_op else args.write_size file = args.read_file if read_op else f'{args.write_file}.{tid}' task_log(tid, f'Allocate tensor of size {num_bytes} bytes') buffer = torch.empty(num_bytes, dtype=torch.uint8, device='cpu').pin_memory() task_log( tid, f'{io_string} file {file} of size {num_bytes} bytes from buffer on device {buffer.device}' ) ctxt = {} ctxt['file'] = file ctxt['num_bytes'] = num_bytes ctxt['buffer'] = buffer ctxt['elapsed_sec'] = 0 return ctxt def pre_basic_read(pool_params): args, tid = pool_params ctxt = pre_basic(args, tid, True) return ctxt def pre_basic_write(pool_params): args, tid = pool_params ctxt = pre_basic(args, tid, False) return ctxt def post_basic(pool_params): _, _, ctxt = pool_params ctxt["buffer"].detach() ctxt["buffer"] = None return ctxt def main_basic_read(pool_params): args, tid, ctxt = pool_params start_time = time.time() AsyncIOBuilder().load().aio_read(ctxt['buffer'], ctxt['file'], args.block_size, args.queue_depth, args.single_submit, args.overlap_events, args.validate) end_time = time.time() ctxt['elapsed_sec'] += end_time - start_time return ctxt def main_basic_write(pool_params): args, tid, ctxt = pool_params start_time = time.time() AsyncIOBuilder().load().aio_write(ctxt['buffer'], ctxt['file'], args.block_size, args.queue_depth, args.single_submit, args.overlap_events, args.validate) end_time = time.time() ctxt['elapsed_sec'] += end_time - start_time return ctxt def get_schedule(args, read_op): schedule = {} if read_op: schedule['pre'] = pre_basic_read schedule['post'] = post_basic schedule['main'] = main_basic_read else: schedule['pre'] = pre_basic_write schedule['post'] = post_basic schedule['main'] = main_basic_write return schedule def _aio_handle_tasklet(pool_params): args, tid, read_op = pool_params # Create schedule schedule = get_schedule(args, read_op) task_log(tid, f'schedule = {schedule}') task_barrier(aio_barrier, args.threads) # Run pre task task_log(tid, f'running pre-task') ctxt = schedule["pre"]((args, tid)) task_barrier(aio_barrier, args.threads) # Run main tasks in a loop ctxt["main_task_sec"] = 0 for i in range(args.loops): task_log(tid, f'running main task {i}') start_time = time.time() ctxt = schedule["main"]((args, tid, ctxt)) task_barrier(aio_barrier, args.threads) stop_time = time.time() ctxt["main_task_sec"] += stop_time - start_time # Run post task task_log(tid, f'running post-task') ctxt = schedule["post"]((args, tid, ctxt)) task_barrier(aio_barrier, args.threads) return ctxt["main_task_sec"], ctxt["elapsed_sec"], ctxt["num_bytes"] * args.loops def _init_tasklet(b): global aio_barrier aio_barrier = b def aio_basic_multiprocessing(args, read_op): b = Barrier(args.threads) pool_params = [(args, p, read_op) for p in range(args.threads)] with Pool(processes=args.threads, initializer=_init_tasklet, initargs=(b, )) as p: pool_results = p.map(_aio_handle_tasklet, pool_params) report_results(args, read_op, pool_results)