def test_split_join_resorting(self):
X = np.array([1, 2, 3, 4, 5, 6, 7, 8, 9, 10])
y = np.array([1, 1, 1, 1, 1, 2, 2, 2, 2, 2])
kwargs = {"test": np.array([-1, -2, -3, -4, -5, -6, -7, -8, -9, -10])}
X_new, y_new, kwargs_new = list(), list(), dict()
# first randomly split the data and append them to X_new, y_new, kwargs_new
idx_list_one, idx_list_two = list(), list()
for idx in range(len(X)):
if bool(random.getrandbits(1)):
idx_list_one.append(idx)
else:
idx_list_two.append(idx)
for ilist in [idx_list_two, idx_list_one]:
for idx in ilist:
X_batched, y_batched, kwargs_batched = PhotonDataHelper.split_data(
X, y, kwargs, idx, idx)
# test if batching works
self.assertEqual(X_batched, X[idx])
self.assertEqual(y_batched, y[idx])
self.assertDictEqual(kwargs_batched,
{"test": [kwargs["test"][idx]]})
# then join again
X_new, y_new, kwargs_new = PhotonDataHelper.join_data(
X_new, X_batched, y_new, y_batched, kwargs_new,
kwargs_batched)
# test if joining works
joined_idx = PhotonDataHelper.stack_data_vertically(
idx_list_two, idx_list_one)
self.assertTrue(np.array_equal(X_new, X[joined_idx]))
self.assertTrue(np.array_equal(y_new, y[joined_idx]))
self.assertTrue(
np.array_equal(kwargs_new["test"], kwargs["test"][joined_idx]))
# now resort and see if that works too
X_resorted, y_resorted, kwargs_resorted = PhotonDataHelper.resort_splitted_data(
X_new, y_new, kwargs_new, joined_idx)
self.assertTrue(np.array_equal(X_resorted, X))
self.assertTrue(np.array_equal(y_resorted, y))
self.assertListEqual(list(kwargs_resorted.keys()), list(kwargs.keys()))
self.assertTrue(np.array_equal(kwargs_resorted["test"],
kwargs["test"]))
def load_or_save_cached_data(self,
name,
X,
y,
kwargs,
transformer,
fit=False,
needed_for_further_computation=False,
initial_X=None):
if not self.single_subject_caching:
# if we do it group-wise then its easy
if self.skip_loading and not needed_for_further_computation:
# check if data is already calculated
if self.cache_man.check_cache(name):
# if so, do nothing
return X, y, kwargs
else:
# otherwise, do the calculation and save it
cached_result = None
else:
start_time_for_loading = datetime.datetime.now()
cached_result = self.cache_man.load_cached_data(name)
if cached_result is None:
X, y, kwargs = self._do_timed_fit_transform(
name, transformer, fit, X, y, **kwargs)
start_time_saving = datetime.datetime.now()
self.cache_man.save_data_to_cache(name, (X, y, kwargs))
saving_duration = (datetime.datetime.now() -
start_time_saving).total_seconds()
self.time_monitor['transform_cached'].append(
(name, saving_duration, 1))
else:
X, y, kwargs = cached_result[0], cached_result[
1], cached_result[2]
loading_duration = (datetime.datetime.now() -
start_time_for_loading).total_seconds()
n = PhotonDataHelper.find_n(X)
self.time_monitor['transform_cached'].append(
(name, loading_duration, n))
return X, y, kwargs
else:
# if we do it subject-wise we need to iterate and collect the results
processed_X, processed_y, processed_kwargs = list(), list(), dict()
X_uncached, y_uncached, kwargs_uncached, initial_X_uncached = list(
), list(), dict(), list()
list_of_idx_cached, list_of_idx_non_cached = list(), list()
nr = PhotonDataHelper.find_n(X)
for start, stop in PhotonDataHelper.chunker(nr, 1):
# split data in single entities, find key from first element = PATH to file
X_key, _, _ = PhotonDataHelper.split_data(
initial_X, None, {}, start, stop)
X_batched, y_batched, kwargs_dict_batched = PhotonDataHelper.split_data(
X, y, kwargs, start, stop)
self.cache_man.update_single_subject_state_info(X_key)
# check if item has been processed
if self.cache_man.check_cache(name):
list_of_idx_cached.append(start)
else:
list_of_idx_non_cached.append(start)
X_uncached = PhotonDataHelper.stack_data_vertically(
X_uncached, X_batched)
y_uncached = PhotonDataHelper.stack_data_vertically(
y_uncached, y_batched)
initial_X_uncached = PhotonDataHelper.stack_data_vertically(
initial_X_uncached, X_key)
kwargs_uncached = PhotonDataHelper.join_dictionaries(
kwargs_uncached, kwargs_dict_batched)
# now we know which part can be loaded and which part should be transformed
# first apply the transformation to the group, then save it single-subject-wise
if len(list_of_idx_non_cached) > 0:
# apply transformation groupwise
new_group_X, new_group_y, new_group_kwargs = self._do_timed_fit_transform(
name, transformer, fit, X_uncached, y_uncached,
**kwargs_uncached)
# then save it single
nr = PhotonDataHelper.find_n(new_group_X)
for start in range(nr):
# split data in single entities
X_batched, y_batched, kwargs_dict_batched = PhotonDataHelper.split_data(
new_group_X, new_group_y, new_group_kwargs, start,
start)
X_key, _, _ = PhotonDataHelper.split_data(
initial_X_uncached, None, {}, start, start)
# we save the data in relation to the input path (X_key = hash(input X))
self.cache_man.update_single_subject_state_info(X_key)
start_time_saving = datetime.datetime.now()
self.cache_man.save_data_to_cache(
name, (X_batched, y_batched, kwargs_dict_batched))
saving_duration = (datetime.datetime.now() -
start_time_saving).total_seconds()
self.time_monitor['transform_cached'].append(
(name, saving_duration, 1))
# we need to collect the data only when we want to load them
# we can skip that process if we only want them to get into the cache (case: parallelisation)
if not self.skip_loading or needed_for_further_computation:
# stack results
processed_X, processed_y, processed_kwargs = new_group_X, new_group_y, new_group_kwargs
# afterwards load everything that has been cached
if len(list_of_idx_cached) > 0:
if not self.skip_loading or needed_for_further_computation:
for cache_idx in list_of_idx_cached:
# we identify the data according to the input path (X before any transformation)
self.cache_man.update_single_subject_state_info(
[initial_X[cache_idx]])
# time the loading of the cached item
start_time_for_loading = datetime.datetime.now()
transformed_X, transformed_y, transformed_kwargs = self.cache_man.load_cached_data(
name)
loading_duration = (
datetime.datetime.now() -
start_time_for_loading).total_seconds()
self.time_monitor['transform_cached'].append(
(name, loading_duration,
PhotonDataHelper.find_n(X)))
processed_X, processed_y, processed_kwargs = PhotonDataHelper.join_data(
processed_X, transformed_X, processed_y,
transformed_y, processed_kwargs,
transformed_kwargs)
logger.debug(name + " loaded " + str(len(list_of_idx_cached)) +
" items from cache and computed " +
str(len(list_of_idx_non_cached)))
if not self.skip_loading or needed_for_further_computation:
# now sort the data in the correct order again
processed_X, processed_y, processed_kwargs = PhotonDataHelper.resort_splitted_data(
processed_X, processed_y, processed_kwargs,
PhotonDataHelper.stack_data_vertically(
list_of_idx_cached, list_of_idx_non_cached))
return processed_X, processed_y, processed_kwargs
