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# Copyright 2023 The TensorFlow Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
#     http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.

"""Test NCF data pipeline."""

from __future__ import absolute_import
from __future__ import division
from __future__ import print_function

from collections import defaultdict
import hashlib
import os

import mock

import numpy as np
import scipy.stats
import tensorflow as tf, tf_keras

from official.recommendation import constants as rconst
from official.recommendation import data_preprocessing
from official.recommendation import movielens
from official.recommendation import popen_helper

DATASET = "ml-test"
NUM_USERS = 1000
NUM_ITEMS = 2000
NUM_PTS = 50000
BATCH_SIZE = 2048
EVAL_BATCH_SIZE = 4000
NUM_NEG = 4

END_TO_END_TRAIN_MD5 = "b218738e915e825d03939c5e305a2698"
END_TO_END_EVAL_MD5 = "d753d0f3186831466d6e218163a9501e"
FRESH_RANDOMNESS_MD5 = "63d0dff73c0e5f1048fbdc8c65021e22"


def mock_download(*args, **kwargs):
  return


# The forkpool used by data producers interacts badly with the threading
# used by TestCase. Without this patch tests will hang, and no amount
# of diligent closing and joining within the producer will prevent it.
@mock.patch.object(popen_helper, "get_forkpool", popen_helper.get_fauxpool)
class BaseTest(tf.test.TestCase):

  def setUp(self):
    tf.compat.v1.disable_eager_execution()
    self.temp_data_dir = self.get_temp_dir()
    ratings_folder = os.path.join(self.temp_data_dir, DATASET)
    tf.io.gfile.makedirs(ratings_folder)
    np.random.seed(0)
    raw_user_ids = np.arange(NUM_USERS * 3)
    np.random.shuffle(raw_user_ids)
    raw_user_ids = raw_user_ids[:NUM_USERS]

    raw_item_ids = np.arange(NUM_ITEMS * 3)
    np.random.shuffle(raw_item_ids)
    raw_item_ids = raw_item_ids[:NUM_ITEMS]

    users = np.random.choice(raw_user_ids, NUM_PTS)
    items = np.random.choice(raw_item_ids, NUM_PTS)
    scores = np.random.randint(low=0, high=5, size=NUM_PTS)
    times = np.random.randint(low=1000000000, high=1200000000, size=NUM_PTS)

    self.rating_file = os.path.join(ratings_folder, movielens.RATINGS_FILE)
    self.seen_pairs = set()
    self.holdout = {}
    with tf.io.gfile.GFile(self.rating_file, "w") as f:
      f.write("user_id,item_id,rating,timestamp\n")
      for usr, itm, scr, ts in zip(users, items, scores, times):
        pair = (usr, itm)
        if pair in self.seen_pairs:
          continue
        self.seen_pairs.add(pair)
        if usr not in self.holdout or (ts, itm) > self.holdout[usr]:
          self.holdout[usr] = (ts, itm)

        f.write("{},{},{},{}\n".format(usr, itm, scr, ts))

    movielens.download = mock_download
    movielens.NUM_RATINGS[DATASET] = NUM_PTS
    movielens.DATASET_TO_NUM_USERS_AND_ITEMS[DATASET] = (NUM_USERS, NUM_ITEMS)

  def make_params(self, train_epochs=1):
    return {
        "train_epochs": train_epochs,
        "batches_per_step": 1,
        "use_seed": False,
        "batch_size": BATCH_SIZE,
        "eval_batch_size": EVAL_BATCH_SIZE,
        "num_neg": NUM_NEG,
        "match_mlperf": True,
        "use_tpu": False,
        "use_xla_for_gpu": False,
        "stream_files": False,
    }

  def test_preprocessing(self):
    # For the most part the necessary checks are performed within
    # _filter_index_sort()

    cache_path = os.path.join(self.temp_data_dir, "test_cache.pickle")
    data, valid_cache = data_preprocessing._filter_index_sort(
        self.rating_file, cache_path=cache_path)

    assert len(data[rconst.USER_MAP]) == NUM_USERS
    assert len(data[rconst.ITEM_MAP]) == NUM_ITEMS

  def drain_dataset(self, dataset, g):
    # type: (tf.data.Dataset, tf.Graph) -> list
    with self.session(graph=g) as sess:
      with g.as_default():
        batch = tf.compat.v1.data.make_one_shot_iterator(dataset).get_next()
      output = []
      while True:
        try:
          output.append(sess.run(batch))
        except tf.errors.OutOfRangeError:
          break
    return output

  def _test_end_to_end(self, constructor_type):
    params = self.make_params(train_epochs=1)
    _, _, producer = data_preprocessing.instantiate_pipeline(
        dataset=DATASET,
        data_dir=self.temp_data_dir,
        params=params,
        constructor_type=constructor_type,
        deterministic=True)

    producer.start()
    producer.join()
    assert producer._fatal_exception is None

    user_inv_map = {v: k for k, v in producer.user_map.items()}
    item_inv_map = {v: k for k, v in producer.item_map.items()}

    # ==========================================================================
    # == Training Data =========================================================
    # ==========================================================================
    g = tf.Graph()
    with g.as_default():
      input_fn = producer.make_input_fn(is_training=True)
      dataset = input_fn(params)

    first_epoch = self.drain_dataset(dataset=dataset, g=g)

    counts = defaultdict(int)
    train_examples = {
        True: set(),
        False: set(),
    }

    md5 = hashlib.md5()
    for features, labels in first_epoch:
      data_list = [
          features[movielens.USER_COLUMN].flatten(),
          features[movielens.ITEM_COLUMN].flatten(),
          features[rconst.VALID_POINT_MASK].flatten(),
          labels.flatten()
      ]
      for i in data_list:
        md5.update(i.tobytes())

      for u, i, v, l in zip(*data_list):
        if not v:
          continue  # ignore padding

        u_raw = user_inv_map[u]
        i_raw = item_inv_map[i]
        if ((u_raw, i_raw) in self.seen_pairs) != l:
          # The evaluation item is not considered during false negative
          # generation, so it will occasionally appear as a negative example
          # during training.
          assert not l
          self.assertEqual(i_raw, self.holdout[u_raw][1])
        train_examples[l].add((u_raw, i_raw))
        counts[(u_raw, i_raw)] += 1

    self.assertRegexpMatches(md5.hexdigest(), END_TO_END_TRAIN_MD5)

    num_positives_seen = len(train_examples[True])
    self.assertEqual(producer._train_pos_users.shape[0], num_positives_seen)

    # This check is more heuristic because negatives are sampled with
    # replacement. It only checks that negative generation is reasonably random.
    self.assertGreater(
        len(train_examples[False]) / NUM_NEG / num_positives_seen, 0.9)

    # This checks that the samples produced are independent by checking the
    # number of duplicate entries. If workers are not properly independent there
    # will be lots of repeated pairs.
    self.assertLess(np.mean(list(counts.values())), 1.1)

    # ==========================================================================
    # == Eval Data =============================================================
    # ==========================================================================
    with g.as_default():
      input_fn = producer.make_input_fn(is_training=False)
      dataset = input_fn(params)

    eval_data = self.drain_dataset(dataset=dataset, g=g)

    current_user = None
    md5 = hashlib.md5()
    for features in eval_data:
      data_list = [
          features[movielens.USER_COLUMN].flatten(),
          features[movielens.ITEM_COLUMN].flatten(),
          features[rconst.DUPLICATE_MASK].flatten()
      ]
      for i in data_list:
        md5.update(i.tobytes())

      for idx, (u, i, d) in enumerate(zip(*data_list)):
        u_raw = user_inv_map[u]
        i_raw = item_inv_map[i]
        if current_user is None:
          current_user = u

        # Ensure that users appear in blocks, as the evaluation logic expects
        # this structure.
        self.assertEqual(u, current_user)

        # The structure of evaluation data is 999 negative examples followed
        # by the holdout positive.
        if not (idx + 1) % (rconst.NUM_EVAL_NEGATIVES + 1):
          # Check that the last element in each chunk is the holdout item.
          self.assertEqual(i_raw, self.holdout[u_raw][1])
          current_user = None

        elif i_raw == self.holdout[u_raw][1]:
          # Because the holdout item is not given to the negative generation
          # process, it can appear as a negative. In that case, it should be
          # masked out as a duplicate. (Since the true positive is placed at
          # the end and would therefore lose the tie.)
          assert d

        else:
          # Otherwise check that the other 999 points for a user are selected
          # from the negatives.
          assert (u_raw, i_raw) not in self.seen_pairs

    self.assertRegexpMatches(md5.hexdigest(), END_TO_END_EVAL_MD5)

  def _test_fresh_randomness(self, constructor_type):
    train_epochs = 5
    params = self.make_params(train_epochs=train_epochs)
    _, _, producer = data_preprocessing.instantiate_pipeline(
        dataset=DATASET,
        data_dir=self.temp_data_dir,
        params=params,
        constructor_type=constructor_type,
        deterministic=True)

    producer.start()

    results = []
    g = tf.Graph()
    with g.as_default():
      for _ in range(train_epochs):
        input_fn = producer.make_input_fn(is_training=True)
        dataset = input_fn(params)
        results.extend(self.drain_dataset(dataset=dataset, g=g))

    producer.join()
    assert producer._fatal_exception is None

    positive_counts, negative_counts = defaultdict(int), defaultdict(int)
    md5 = hashlib.md5()
    for features, labels in results:
      data_list = [
          features[movielens.USER_COLUMN].flatten(),
          features[movielens.ITEM_COLUMN].flatten(),
          features[rconst.VALID_POINT_MASK].flatten(),
          labels.flatten()
      ]
      for i in data_list:
        md5.update(i.tobytes())

      for u, i, v, l in zip(*data_list):
        if not v:
          continue  # ignore padding

        if l:
          positive_counts[(u, i)] += 1
        else:
          negative_counts[(u, i)] += 1

    self.assertRegexpMatches(md5.hexdigest(), FRESH_RANDOMNESS_MD5)

    # The positive examples should appear exactly once each epoch
    self.assertAllEqual(
        list(positive_counts.values()), [train_epochs for _ in positive_counts])

    # The threshold for the negatives is heuristic, but in general repeats are
    # expected, but should not appear too frequently.

    pair_cardinality = NUM_USERS * NUM_ITEMS
    neg_pair_cardinality = pair_cardinality - len(self.seen_pairs)

    # Approximation for the expectation number of times that a particular
    # negative will appear in a given epoch. Implicit in this calculation is the
    # treatment of all negative pairs as equally likely. Normally is not
    # necessarily reasonable; however the generation in self.setUp() will
    # approximate this behavior sufficiently for heuristic testing.
    e_sample = len(self.seen_pairs) * NUM_NEG / neg_pair_cardinality

    # The frequency of occurance of a given negative pair should follow an
    # approximately binomial distribution in the limit that the cardinality of
    # the negative pair set >> number of samples per epoch.
    approx_pdf = scipy.stats.binom.pmf(
        k=np.arange(train_epochs + 1), n=train_epochs, p=e_sample)

    # Tally the actual observed counts.
    count_distribution = [0 for _ in range(train_epochs + 1)]
    for i in negative_counts.values():
      i = min([i, train_epochs])  # round down tail for simplicity.
      count_distribution[i] += 1
    count_distribution[0] = neg_pair_cardinality - sum(count_distribution[1:])

    # Check that the frequency of negative pairs is approximately binomial.
    for i in range(train_epochs + 1):
      if approx_pdf[i] < 0.05:
        continue  # Variance will be high at the tails.

      observed_fraction = count_distribution[i] / neg_pair_cardinality
      deviation = (2 * abs(observed_fraction - approx_pdf[i]) /
                   (observed_fraction + approx_pdf[i]))

      self.assertLess(deviation, 0.2)

  def test_end_to_end_materialized(self):
    self._test_end_to_end("materialized")

  def test_end_to_end_bisection(self):
    self._test_end_to_end("bisection")

  def test_fresh_randomness_materialized(self):
    self._test_fresh_randomness("materialized")

  def test_fresh_randomness_bisection(self):
    self._test_fresh_randomness("bisection")


if __name__ == "__main__":
  tf.test.main()