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/ python / data_workers.py
## @package data_workers
# Module caffe2.python.data_workers
'''
This module provides a python-land multithreaded data input mechanism
for Caffe2 nets.
Basic usage is as follows:
coordinator = data_workers.init_data_input_workers(
net,
["data", "label"],
my_fetch_fun,
batch_size=32,
input_source_name="train",
dont_rebatch=False
)
...
coordinator.start()
First argument is the Caffe2 net (or model helper), and second argument
is list of input blobs that are to be fed.
Argument 'input_source_name' is used to distinguish different sources of data,
such as train or test data. This is to ensure the data does not get mixed up,
although two nets would share blobs.
To do the actual data loading, one defines a "fetcher function"
that has call signature
my_fetch_fun(worker_id, batch_size)
Optionally, one can define a "init function" that is called once before
threads start, and has call signature:
my_init_fun(data_coordinator, global_coordinator)
If dont_rebatch is set to True, the data input is not batched into equal sized
chunks but data directly provided by fetchers is used.
'batch_columns' can be used to specify which dimension is the batch dimension,
for each of the inputs. Default is 0 for all iputs.
'timeout' is the timeout in seconds after which if no data is available, the
net will fail (default 600s = 10 mins).
This function returns a list of numpy arrays corresponding to the different
input blobs. In the example above, it would return two arrays, one for the
data blob and another for the labels. These arrays can have arbitrary number
of elements (i.e they do not need to match the batch size). The batch size
is provided for the function as a hint only.
For example, fetcher function could download images from a remote service or
load random images from a directory on a file system.
For a dummy example, see the data_workers_test unit test.
Note that for data_parallel_models, init_data_input_workers will be called
for each GPU. Note that the 'coordinator' returned by the function is same
each time.
'''
try:
import Queue
except ImportError:
# Py3
import queue as Queue
from itertools import chain
import logging
import threading
import numpy as np
import time
from caffe2.python import workspace, core, scope, utils
from caffe2.proto import caffe2_pb2
from caffe2.python.parallel_workers import Metrics, State, \
WorkerCoordinator, GlobalWorkerCoordinator, Worker, run_worker
log = logging.getLogger("data_workers")
log.setLevel(logging.INFO)
LOG_INT_SECS = 60
def get_worker_ids(num_workers):
return list(range(0, num_workers))
def init_data_input_workers(
net,
input_blob_names,
fetch_fun,
batch_size,
num_worker_threads=2,
input_source_name="train",
max_buffered_batches=800,
init_fun=None,
external_loggers=None,
dont_rebatch=False,
batch_columns=None,
timeout=600
):
global global_coordinator
device_option = scope.CurrentDeviceScope()
if (device_option is None):
device_option = caffe2_pb2.DeviceOption(device_type=caffe2_pb2.CPU)
metrics = Metrics(external_loggers)
batch_feeder = BatchFeeder(
net,
input_blob_names,
batch_size,
device_option,
scope.CurrentNameScope(),
input_source_name,
global_coordinator.get_queue(input_source_name, max_buffered_batches),
metrics,
dont_rebatch,
batch_columns,
timeout=timeout
)
# Launch fetch worker threads
worker_ids = [
global_coordinator.get_new_worker_id()
for i in range(num_worker_threads)
]
# Create coordinator object
coordinator = WorkerCoordinator(
input_source_name, worker_ids, init_fun, batch_feeder)
workers = [
threading.Thread(
target=run_worker,
name="data_workers fetcher id {}".format(worker_id),
args=[coordinator,
DataWorker(coordinator, worker_id, fetch_fun, metrics,
batch_size, batch_feeder)],
) for worker_id in worker_ids
]
workers.append(threading.Thread(
target=enqueuer,
name="Enqueuer {} {}".format(input_source_name, scope.CurrentNameScope()),
args=[coordinator, batch_feeder]))
coordinator._workers = workers
global_coordinator.add(coordinator)
return global_coordinator
class BatchFeeder(State):
def __init__(self, net, input_blob_names, batch_size,
device_option, namescope, input_source_name, queue,
metrics, dont_rebatch, batch_columns, timeout=600):
self._counter = 0
self._input_blob_names = input_blob_names
self._batch_size = batch_size
self._internal_queue = queue
self._queues = []
self._device_option = device_option
self._namescope = namescope
self._timeout = timeout
self._input_source_name = input_source_name
self._c2_queue_capacity = 4
self._create_caffe2_queues(net)
self._create_caffe2_ops(net)
self._inputs = 0
self._prev_seconds = 0
self._last_warning = time.time()
self._dont_rebatch = dont_rebatch
self._init_scratch()
self._metrics = metrics
if batch_columns is None:
batch_columns = [0 for _ in input_blob_names]
self._batch_columns = batch_columns
def start(self):
self._inputs = 0
self._prev_seconds = time.time()
def stop(self):
try:
for q in self._queues:
workspace.RunOperatorOnce(
core.CreateOperator("CloseBlobsQueue", [q], [])
)
finally:
self._log_inputs_per_interval(0, force=True)
def cleanup(self):
utils.ResetBlobs(self._scratch_blob.values())
utils.ResetBlobs(self._scratch_status.values())
def _get(self, data_input_coordinator):
start_time = time.time()
last_warning = time.time()
while data_input_coordinator.is_active():
try:
return self._internal_queue.get(block=True, timeout=0.5)
except Queue.Empty:
if time.time() - last_warning > 10.0:
log.warning("** Data input is slow: (still) no data in {} secs.".format(
time.time() - start_time))
last_warning = time.time()
continue
return None
def _validate_chunk(self, chunk):
if chunk is None:
log.warning("Fetcher function returned None")
return False
assert len(chunk) == len(self._input_blob_names), \
"Expecting data blob for each input"
for d in chunk:
assert isinstance(d, np.ndarray), \
"Fetcher function must return a numpy array"
if not self._dont_rebatch:
j = 1
for d in chunk[1:]:
assert d.shape[self._batch_columns[j]] == \
chunk[0].shape[self._batch_columns[0]], \
"Each returned input must have equal number of samples"
j += 1
if len(chunk) == 0:
log.warning("Worker provided zero length input")
return False
return True
def put(self, chunk, data_input_coordinator):
if not self._validate_chunk(chunk):
return
while data_input_coordinator.is_active():
try:
qsize = self._internal_queue.qsize()
if qsize < 2 and (time.time() - self._last_warning) > LOG_INT_SECS:
log.warning("Warning, data loading lagging behind: " +
"queue size={}, name={}".format(qsize, self._input_source_name))
self._last_warning = time.time()
self._counter += 1
self._internal_queue.put(chunk, block=True, timeout=0.5)
self._log_inputs_per_interval(chunk[0].shape[0])
return
except Queue.Full:
log.debug("Queue full: stalling fetchers...")
continue
def _enqueue_batch_direct(self, data_input_coordinator):
data = self._get(data_input_coordinator)
if data is None:
return
if data_input_coordinator.is_active():
for b, q, c in zip(self._input_blob_names, self._queues, data):
self._enqueue(b, q, c)
def _enqueue_batch(self, data_input_coordinator):
'''
This pulls data from the python-side queue and collects them
into batch-sized pieces, unless dont_rebatch is set to true.
'''
if self._dont_rebatch:
self._enqueue_batch_direct(data_input_coordinator)
return
cur_batch = [np.array([]) for d in self._input_blob_names]
first_batch_col = self._batch_columns[0]
# Collect data until we have a full batch size
while (
cur_batch[0].shape[0] == 0 or
cur_batch[0].shape[first_batch_col] < self._batch_size
) and data_input_coordinator.is_active():
chunk = self._get(data_input_coordinator)
if chunk is None:
continue
for j, chunk_elem in enumerate(chunk):
if cur_batch[j].shape[0] == 0:
cur_batch[j] = chunk_elem.copy()
else:
cur_batch[j] = np.append(
cur_batch[j], chunk_elem, axis=self._batch_columns[j]
)
start_time = time.time()
try:
# Return data over the batch size back to queue
if cur_batch[0].shape[0] > 0 and cur_batch[0].shape[
first_batch_col
] > self._batch_size:
leftover = []
trimmed_batch = []
for j, b in enumerate(cur_batch):
[c, l] = np.split(
b, [self._batch_size], axis=self._batch_columns[j]
)
leftover.append(l)
trimmed_batch.append(c)
cur_batch = trimmed_batch
try:
self._internal_queue.put(leftover, block=False)
except Queue.Full:
pass
assert cur_batch[0].shape[first_batch_col] == self._batch_size
if data_input_coordinator.is_active():
for b, q, c in zip(
self._input_blob_names, self._queues, cur_batch
):
self._enqueue(b, q, c)
finally:
self._metrics.put_metric('enqueue_time', time.time() - start_time)
def _init_scratch(self):
self._scratch_blob = {}
self._scratch_status = {}
for blob_name in self._input_blob_names:
scratch_name = self._namescope + blob_name + \
"_scratch_" + self._input_source_name
self._scratch_blob[blob_name] = core.BlobReference(scratch_name)
self._scratch_status[blob_name] = core.BlobReference(
scratch_name + "_status"
)
# Feed empty arrays to the scratch blobs here, so that there won't be
# race conditions when calling FeedBlob (which calls wworkspace
# CreateBlob()) from enqueue threads
for b in chain(
self._scratch_blob.values(), self._scratch_status.values()
):
workspace.FeedBlob(
b,
np.array([]).astype(np.float32),
device_option=self._device_option,
)
def _enqueue(self, blob_name, queue, data_arr):