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dlrm_data_pytorch.py
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dlrm_data_pytorch.py
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# Copyright (c) Facebook, Inc. and its affiliates.
#
# This source code is licensed under the MIT license found in the
# LICENSE file in the root directory of this source tree.
#
# Description: generate inputs and targets for the dlrm benchmark
# The inpts and outputs are generated according to the following three option(s)
# 1) random distribution
# 2) synthetic distribution, based on unique accesses and distances between them
# i) R. Hassan, A. Harris, N. Topham and A. Efthymiou "Synthetic Trace-Driven
# Simulation of Cache Memory", IEEE AINAM'07
# 3) public data set
# i) Criteo Kaggle Display Advertising Challenge Dataset
# https://labs.criteo.com/2014/02/kaggle-display-advertising-challenge-dataset
# ii) Criteo Terabyte Dataset
# https://labs.criteo.com/2013/12/download-terabyte-click-logs
from __future__ import absolute_import, division, print_function, unicode_literals
# others
from os import path
import sys
import bisect
import collections
import data_utils
# numpy
import numpy as np
from numpy import random as ra
from collections import deque
# pytorch
import torch
from torch.utils.data import Dataset, RandomSampler
import data_loader_terabyte
import mlperf_logger
# Kaggle Display Advertising Challenge Dataset
# dataset (str): name of dataset (Kaggle or Terabyte)
# randomize (str): determines randomization scheme
# "none": no randomization
# "day": randomizes each day"s data (only works if split = True)
# "total": randomizes total dataset
# split (bool) : to split into train, test, validation data-sets
class CriteoDataset(Dataset):
def __init__(
self,
dataset,
max_ind_range,
sub_sample_rate,
randomize,
split="train",
raw_path="",
pro_data="",
memory_map=False,
dataset_multiprocessing=False,
):
# dataset
# tar_fea = 1 # single target
den_fea = 13 # 13 dense features
# spa_fea = 26 # 26 sparse features
# tad_fea = tar_fea + den_fea
# tot_fea = tad_fea + spa_fea
if dataset == "kaggle":
days = 7
out_file = "kaggleAdDisplayChallenge_processed"
elif dataset == "terabyte":
days = 24
out_file = "terabyte_processed"
else:
raise(ValueError("Data set option is not supported"))
self.max_ind_range = max_ind_range
self.memory_map = memory_map
# split the datafile into path and filename
lstr = raw_path.split("/")
self.d_path = "/".join(lstr[0:-1]) + "/"
self.d_file = lstr[-1].split(".")[0] if dataset == "kaggle" else lstr[-1]
self.npzfile = self.d_path + (
(self.d_file + "_day") if dataset == "kaggle" else self.d_file
)
self.trafile = self.d_path + (
(self.d_file + "_fea") if dataset == "kaggle" else "fea"
)
# check if pre-processed data is available
data_ready = True
if memory_map:
for i in range(days):
reo_data = self.npzfile + "_{0}_reordered.npz".format(i)
if not path.exists(str(reo_data)):
data_ready = False
else:
if not path.exists(str(pro_data)):
data_ready = False
# pre-process data if needed
# WARNNING: when memory mapping is used we get a collection of files
if data_ready:
print("Reading pre-processed data=%s" % (str(pro_data)))
file = str(pro_data)
else:
print("Reading raw data=%s" % (str(raw_path)))
file = data_utils.getCriteoAdData(
raw_path,
out_file,
max_ind_range,
sub_sample_rate,
days,
split,
randomize,
dataset == "kaggle",
memory_map,
dataset_multiprocessing,
)
# get a number of samples per day
total_file = self.d_path + self.d_file + "_day_count.npz"
with np.load(total_file) as data:
total_per_file = data["total_per_file"]
# compute offsets per file
self.offset_per_file = np.array([0] + [x for x in total_per_file])
for i in range(days):
self.offset_per_file[i + 1] += self.offset_per_file[i]
# print(self.offset_per_file)
# setup data
if memory_map:
# setup the training/testing split
self.split = split
if split == 'none' or split == 'train':
self.day = 0
self.max_day_range = days if split == 'none' else days - 1
elif split == 'test' or split == 'val':
self.day = days - 1
num_samples = self.offset_per_file[days] - \
self.offset_per_file[days - 1]
self.test_size = int(np.ceil(num_samples / 2.))
self.val_size = num_samples - self.test_size
else:
sys.exit("ERROR: dataset split is neither none, nor train or test.")
'''
# text
print("text")
for i in range(days):
fi = self.npzfile + "_{0}".format(i)
with open(fi) as data:
ttt = 0; nnn = 0
for _j, line in enumerate(data):
ttt +=1
if np.int32(line[0]) > 0:
nnn +=1
print("day=" + str(i) + " total=" + str(ttt) + " non-zeros="
+ str(nnn) + " ratio=" +str((nnn * 100.) / ttt) + "%")
# processed
print("processed")
for i in range(days):
fi = self.npzfile + "_{0}_processed.npz".format(i)
with np.load(fi) as data:
yyy = data["y"]
ttt = len(yyy)
nnn = np.count_nonzero(yyy)
print("day=" + str(i) + " total=" + str(ttt) + " non-zeros="
+ str(nnn) + " ratio=" +str((nnn * 100.) / ttt) + "%")
# reordered
print("reordered")
for i in range(days):
fi = self.npzfile + "_{0}_reordered.npz".format(i)
with np.load(fi) as data:
yyy = data["y"]
ttt = len(yyy)
nnn = np.count_nonzero(yyy)
print("day=" + str(i) + " total=" + str(ttt) + " non-zeros="
+ str(nnn) + " ratio=" +str((nnn * 100.) / ttt) + "%")
'''
# load unique counts
with np.load(self.d_path + self.d_file + "_fea_count.npz") as data:
self.counts = data["counts"]
self.m_den = den_fea # X_int.shape[1]
self.n_emb = len(self.counts)
print("Sparse features= %d, Dense features= %d" % (self.n_emb, self.m_den))
# Load the test data
# Only a single day is used for testing
if self.split == 'test' or self.split == 'val':
# only a single day is used for testing
fi = self.npzfile + "_{0}_reordered.npz".format(
self.day
)
with np.load(fi) as data:
self.X_int = data["X_int"] # continuous feature
self.X_cat = data["X_cat"] # categorical feature
self.y = data["y"] # target
else:
# load and preprocess data
with np.load(file) as data:
X_int = data["X_int"] # continuous feature
X_cat = data["X_cat"] # categorical feature
y = data["y"] # target
self.counts = data["counts"]
self.m_den = X_int.shape[1] # den_fea
self.n_emb = len(self.counts)
print("Sparse fea = %d, Dense fea = %d" % (self.n_emb, self.m_den))
# create reordering
indices = np.arange(len(y))
if split == "none":
# randomize all data
if randomize == "total":
indices = np.random.permutation(indices)
print("Randomized indices...")
X_int[indices] = X_int
X_cat[indices] = X_cat
y[indices] = y
else:
indices = np.array_split(indices, self.offset_per_file[1:-1])
# randomize train data (per day)
if randomize == "day": # or randomize == "total":
for i in range(len(indices) - 1):
indices[i] = np.random.permutation(indices[i])
print("Randomized indices per day ...")
train_indices = np.concatenate(indices[:-1])
test_indices = indices[-1]
test_indices, val_indices = np.array_split(test_indices, 2)
print("Defined %s indices..." % (split))
# randomize train data (across days)
if randomize == "total":
train_indices = np.random.permutation(train_indices)
print("Randomized indices across days ...")
# create training, validation, and test sets
if split == 'train':
self.X_int = [X_int[i] for i in train_indices]
self.X_cat = [X_cat[i] for i in train_indices]
self.y = [y[i] for i in train_indices]
elif split == 'val':
self.X_int = [X_int[i] for i in val_indices]
self.X_cat = [X_cat[i] for i in val_indices]
self.y = [y[i] for i in val_indices]
elif split == 'test':
self.X_int = [X_int[i] for i in test_indices]
self.X_cat = [X_cat[i] for i in test_indices]
self.y = [y[i] for i in test_indices]
print("Split data according to indices...")
def __getitem__(self, index):
if isinstance(index, slice):
return [
self[idx] for idx in range(
index.start or 0, index.stop or len(self), index.step or 1
)
]
if self.memory_map:
if self.split == 'none' or self.split == 'train':
# check if need to swicth to next day and load data
if index == self.offset_per_file[self.day]:
# print("day_boundary switch", index)
self.day_boundary = self.offset_per_file[self.day]
fi = self.npzfile + "_{0}_reordered.npz".format(
self.day
)
# print('Loading file: ', fi)
with np.load(fi) as data:
self.X_int = data["X_int"] # continuous feature
self.X_cat = data["X_cat"] # categorical feature
self.y = data["y"] # target
self.day = (self.day + 1) % self.max_day_range
i = index - self.day_boundary
elif self.split == 'test' or self.split == 'val':
# only a single day is used for testing
i = index + (0 if self.split == 'test' else self.test_size)
else:
sys.exit("ERROR: dataset split is neither none, nor train or test.")
else:
i = index
if self.max_ind_range > 0:
return self.X_int[i], self.X_cat[i] % self.max_ind_range, self.y[i]
else:
return self.X_int[i], self.X_cat[i], self.y[i]
def _default_preprocess(self, X_int, X_cat, y):
X_int = torch.log(torch.tensor(X_int, dtype=torch.float) + 1)
if self.max_ind_range > 0:
X_cat = torch.tensor(X_cat % self.max_ind_range, dtype=torch.long)
else:
X_cat = torch.tensor(X_cat, dtype=torch.long)
y = torch.tensor(y.astype(np.float32))
return X_int, X_cat, y
def __len__(self):
if self.memory_map:
if self.split == 'none':
return self.offset_per_file[-1]
elif self.split == 'train':
return self.offset_per_file[-2]
elif self.split == 'test':
return self.test_size
elif self.split == 'val':
return self.val_size
else:
sys.exit("ERROR: dataset split is neither none, nor train nor test.")
else:
return len(self.y)
def collate_wrapper_criteo_offset(list_of_tuples):
# where each tuple is (X_int, X_cat, y)
transposed_data = list(zip(*list_of_tuples))
X_int = torch.log(torch.tensor(transposed_data[0], dtype=torch.float) + 1)
X_cat = torch.tensor(transposed_data[1], dtype=torch.long)
T = torch.tensor(transposed_data[2], dtype=torch.float32).view(-1, 1)
batchSize = X_cat.shape[0]
featureCnt = X_cat.shape[1]
lS_i = [X_cat[:, i] for i in range(featureCnt)]
lS_o = [torch.tensor(range(batchSize)) for _ in range(featureCnt)]
return X_int, torch.stack(lS_o), torch.stack(lS_i), T
def ensure_dataset_preprocessed(args, d_path):
_ = CriteoDataset(
args.data_set,
args.max_ind_range,
args.data_sub_sample_rate,
args.data_randomize,
"train",
args.raw_data_file,
args.processed_data_file,
args.memory_map,
args.dataset_multiprocessing
)
_ = CriteoDataset(
args.data_set,
args.max_ind_range,
args.data_sub_sample_rate,
args.data_randomize,
"test",
args.raw_data_file,
args.processed_data_file,
args.memory_map,
args.dataset_multiprocessing
)
for split in ['train', 'val', 'test']:
print('Running preprocessing for split =', split)
train_files = ['{}_{}_reordered.npz'.format(args.raw_data_file, day)
for
day in range(0, 23)]
test_valid_file = args.raw_data_file + '_23_reordered.npz'
output_file = d_path + '_{}.bin'.format(split)
input_files = train_files if split == 'train' else [test_valid_file]
data_loader_terabyte.numpy_to_binary(input_files=input_files,
output_file_path=output_file,
split=split)
# Conversion from offset to length
def offset_to_length_converter(lS_o, lS_i):
def diff(tensor):
return tensor[1:] - tensor[:-1]
return torch.stack(
[
diff(torch.cat((S_o, torch.tensor(lS_i[ind].shape))).int())
for ind, S_o in enumerate(lS_o)
]
)
def collate_wrapper_criteo_length(list_of_tuples):
# where each tuple is (X_int, X_cat, y)
transposed_data = list(zip(*list_of_tuples))
X_int = torch.log(torch.tensor(transposed_data[0], dtype=torch.float) + 1)
X_cat = torch.tensor(transposed_data[1], dtype=torch.long)
T = torch.tensor(transposed_data[2], dtype=torch.float32).view(-1, 1)
batchSize = X_cat.shape[0]
featureCnt = X_cat.shape[1]
lS_i = torch.stack([X_cat[:, i] for i in range(featureCnt)])
lS_o = torch.stack(
[torch.tensor(range(batchSize)) for _ in range(featureCnt)]
)
lS_l = offset_to_length_converter(lS_o, lS_i)
return X_int, lS_l, lS_i, T
def make_criteo_data_and_loaders(args, offset_to_length_converter=False):
if args.mlperf_logging and args.memory_map and args.data_set == "terabyte":
# more efficient for larger batches
data_directory = path.dirname(args.raw_data_file)
if args.mlperf_bin_loader:
lstr = args.processed_data_file.split("/")
d_path = "/".join(lstr[0:-1]) + "/" + lstr[-1].split(".")[0]
train_file = d_path + "_train.bin"
test_file = d_path + "_test.bin"
# val_file = d_path + "_val.bin"
counts_file = args.raw_data_file + '_fea_count.npz'
if any(not path.exists(p) for p in [train_file,
test_file,
counts_file]):
ensure_dataset_preprocessed(args, d_path)
train_data = data_loader_terabyte.CriteoBinDataset(
data_file=train_file,
counts_file=counts_file,
batch_size=args.mini_batch_size,
max_ind_range=args.max_ind_range
)
mlperf_logger.log_event(key=mlperf_logger.constants.TRAIN_SAMPLES,
value=train_data.num_samples)
train_loader = torch.utils.data.DataLoader(
train_data,
batch_size=None,
batch_sampler=None,
shuffle=False,
num_workers=0,
collate_fn=None,
pin_memory=False,
drop_last=False,
sampler=RandomSampler(train_data) if args.mlperf_bin_shuffle else None
)
test_data = data_loader_terabyte.CriteoBinDataset(
data_file=test_file,
counts_file=counts_file,
batch_size=args.test_mini_batch_size,
max_ind_range=args.max_ind_range
)
mlperf_logger.log_event(key=mlperf_logger.constants.EVAL_SAMPLES,
value=test_data.num_samples)
test_loader = torch.utils.data.DataLoader(
test_data,
batch_size=None,
batch_sampler=None,
shuffle=False,
num_workers=0,
collate_fn=None,
pin_memory=False,
drop_last=False,
)
else:
data_filename = args.raw_data_file.split("/")[-1]
train_data = CriteoDataset(
args.data_set,
args.max_ind_range,
args.data_sub_sample_rate,
args.data_randomize,
"train",
args.raw_data_file,
args.processed_data_file,
args.memory_map,
args.dataset_multiprocessing
)
test_data = CriteoDataset(
args.data_set,
args.max_ind_range,
args.data_sub_sample_rate,
args.data_randomize,
"test",
args.raw_data_file,
args.processed_data_file,
args.memory_map,
args.dataset_multiprocessing
)
train_loader = data_loader_terabyte.DataLoader(
data_directory=data_directory,
data_filename=data_filename,
days=list(range(23)),
batch_size=args.mini_batch_size,
max_ind_range=args.max_ind_range,
split="train"
)
test_loader = data_loader_terabyte.DataLoader(
data_directory=data_directory,
data_filename=data_filename,
days=[23],
batch_size=args.test_mini_batch_size,
max_ind_range=args.max_ind_range,
split="test"
)
else:
train_data = CriteoDataset(
args.data_set,
args.max_ind_range,
args.data_sub_sample_rate,
args.data_randomize,
"train",
args.raw_data_file,
args.processed_data_file,
args.memory_map,
args.dataset_multiprocessing,
)
test_data = CriteoDataset(
args.data_set,
args.max_ind_range,
args.data_sub_sample_rate,
args.data_randomize,
"test",
args.raw_data_file,
args.processed_data_file,
args.memory_map,
args.dataset_multiprocessing,
)
collate_wrapper_criteo = collate_wrapper_criteo_offset
if offset_to_length_converter:
collate_wrapper_criteo = collate_wrapper_criteo_length
train_loader = torch.utils.data.DataLoader(
train_data,
batch_size=args.mini_batch_size,
shuffle=False,
num_workers=args.num_workers,
collate_fn=collate_wrapper_criteo,
pin_memory=False,
drop_last=False, # True
)
test_loader = torch.utils.data.DataLoader(
test_data,
batch_size=args.test_mini_batch_size,
shuffle=False,
num_workers=args.test_num_workers,
collate_fn=collate_wrapper_criteo,
pin_memory=False,
drop_last=False, # True
)
return train_data, train_loader, test_data, test_loader
# uniform ditribution (input data)
class RandomDataset(Dataset):
def __init__(
self,
m_den,
ln_emb,
data_size,
num_batches,
mini_batch_size,
num_indices_per_lookup,
num_indices_per_lookup_fixed,
num_targets=1,
round_targets=False,
data_generation="random",
trace_file="",
enable_padding=False,
reset_seed_on_access=False,
rand_data_dist="uniform",
rand_data_min=1,
rand_data_max=1,
rand_data_mu=-1,
rand_data_sigma=1,
rand_seed=0
):
# compute batch size
nbatches = int(np.ceil((data_size * 1.0) / mini_batch_size))
if num_batches != 0:
nbatches = num_batches
data_size = nbatches * mini_batch_size
# print("Total number of batches %d" % nbatches)
# save args (recompute data_size if needed)
self.m_den = m_den
self.ln_emb = ln_emb
self.data_size = data_size
self.num_batches = nbatches
self.mini_batch_size = mini_batch_size
self.num_indices_per_lookup = num_indices_per_lookup
self.num_indices_per_lookup_fixed = num_indices_per_lookup_fixed
self.num_targets = num_targets
self.round_targets = round_targets
self.data_generation = data_generation
self.trace_file = trace_file
self.enable_padding = enable_padding
self.reset_seed_on_access = reset_seed_on_access
self.rand_seed = rand_seed
self.rand_data_dist = rand_data_dist
self.rand_data_min = rand_data_min
self.rand_data_max = rand_data_max
self.rand_data_mu = rand_data_mu
self.rand_data_sigma = rand_data_sigma
def reset_numpy_seed(self, numpy_rand_seed):
np.random.seed(numpy_rand_seed)
# torch.manual_seed(numpy_rand_seed)
def __getitem__(self, index):
if isinstance(index, slice):
return [
self[idx] for idx in range(
index.start or 0, index.stop or len(self), index.step or 1
)
]
# WARNING: reset seed on access to first element
# (e.g. if same random samples needed across epochs)
if self.reset_seed_on_access and index == 0:
self.reset_numpy_seed(self.rand_seed)
# number of data points in a batch
n = min(self.mini_batch_size, self.data_size - (index * self.mini_batch_size))
# generate a batch of dense and sparse features
if self.data_generation == "random":
(X, lS_o, lS_i) = generate_dist_input_batch(
self.m_den,
self.ln_emb,
n,
self.num_indices_per_lookup,
self.num_indices_per_lookup_fixed,
rand_data_dist=self.rand_data_dist,
rand_data_min=self.rand_data_min,
rand_data_max=self.rand_data_max,
rand_data_mu=self.rand_data_mu,
rand_data_sigma=self.rand_data_sigma,
)
elif self.data_generation == "synthetic":
(X, lS_o, lS_i) = generate_synthetic_input_batch(
self.m_den,
self.ln_emb,
n,
self.num_indices_per_lookup,
self.num_indices_per_lookup_fixed,
self.trace_file,
self.enable_padding
)
else:
sys.exit(
"ERROR: --data-generation=" + self.data_generation + " is not supported"
)
# generate a batch of target (probability of a click)
T = generate_random_output_batch(n, self.num_targets, self.round_targets)
return (X, lS_o, lS_i, T)
def __len__(self):
# WARNING: note that we produce bacthes of outputs in __getitem__
# therefore we should use num_batches rather than data_size below
return self.num_batches
def collate_wrapper_random_offset(list_of_tuples):
# where each tuple is (X, lS_o, lS_i, T)
(X, lS_o, lS_i, T) = list_of_tuples[0]
return (X,
torch.stack(lS_o),
lS_i,
T)
def collate_wrapper_random_length(list_of_tuples):
# where each tuple is (X, lS_o, lS_i, T)
(X, lS_o, lS_i, T) = list_of_tuples[0]
return (X,
offset_to_length_converter(torch.stack(lS_o), lS_i),
lS_i,
T)
def make_random_data_and_loader(args, ln_emb, m_den,
offset_to_length_converter=False,
):
train_data = RandomDataset(
m_den,
ln_emb,
args.data_size,
args.num_batches,
args.mini_batch_size,
args.num_indices_per_lookup,
args.num_indices_per_lookup_fixed,
1, # num_targets
args.round_targets,
args.data_generation,
args.data_trace_file,
args.data_trace_enable_padding,
reset_seed_on_access=True,
rand_data_dist=args.rand_data_dist,
rand_data_min=args.rand_data_min,
rand_data_max=args.rand_data_max,
rand_data_mu=args.rand_data_mu,
rand_data_sigma=args.rand_data_sigma,
rand_seed=args.numpy_rand_seed
) # WARNING: generates a batch of lookups at once
test_data = RandomDataset(
m_den,
ln_emb,
args.data_size,
args.num_batches,
args.mini_batch_size,
args.num_indices_per_lookup,
args.num_indices_per_lookup_fixed,
1, # num_targets
args.round_targets,
args.data_generation,
args.data_trace_file,
args.data_trace_enable_padding,
reset_seed_on_access=True,
rand_data_dist=args.rand_data_dist,
rand_data_min=args.rand_data_min,
rand_data_max=args.rand_data_max,
rand_data_mu=args.rand_data_mu,
rand_data_sigma=args.rand_data_sigma,
rand_seed=args.numpy_rand_seed
)
collate_wrapper_random = collate_wrapper_random_offset
if offset_to_length_converter:
collate_wrapper_random = collate_wrapper_random_length
train_loader = torch.utils.data.DataLoader(
train_data,
batch_size=1,
shuffle=False,
num_workers=args.num_workers,
collate_fn=collate_wrapper_random,
pin_memory=False,
drop_last=False, # True
)
test_loader = torch.utils.data.DataLoader(
test_data,
batch_size=1,
shuffle=False,
num_workers=args.num_workers,
collate_fn=collate_wrapper_random,
pin_memory=False,
drop_last=False, # True
)
return train_data, train_loader, test_data, test_loader
def generate_random_data(
m_den,
ln_emb,
data_size,
num_batches,
mini_batch_size,
num_indices_per_lookup,
num_indices_per_lookup_fixed,
num_targets=1,
round_targets=False,
data_generation="random",
trace_file="",
enable_padding=False,
length=False, # length for caffe2 version (except dlrm_s_caffe2)
):
nbatches = int(np.ceil((data_size * 1.0) / mini_batch_size))
if num_batches != 0:
nbatches = num_batches
data_size = nbatches * mini_batch_size
# print("Total number of batches %d" % nbatches)
# inputs
lT = []
lX = []
lS_offsets = []
lS_indices = []
for j in range(0, nbatches):
# number of data points in a batch
n = min(mini_batch_size, data_size - (j * mini_batch_size))
# generate a batch of dense and sparse features
if data_generation == "random":
(Xt, lS_emb_offsets, lS_emb_indices) = generate_uniform_input_batch(
m_den,
ln_emb,
n,
num_indices_per_lookup,
num_indices_per_lookup_fixed,
length,
)
elif data_generation == "synthetic":
(Xt, lS_emb_offsets, lS_emb_indices) = generate_synthetic_input_batch(
m_den,
ln_emb,
n,
num_indices_per_lookup,
num_indices_per_lookup_fixed,
trace_file,
enable_padding
)
else:
sys.exit(
"ERROR: --data-generation=" + data_generation + " is not supported"
)
# dense feature
lX.append(Xt)
# sparse feature (sparse indices)
lS_offsets.append(lS_emb_offsets)
lS_indices.append(lS_emb_indices)
# generate a batch of target (probability of a click)
P = generate_random_output_batch(n, num_targets, round_targets)
lT.append(P)
return (nbatches, lX, lS_offsets, lS_indices, lT)
def generate_random_output_batch(n, num_targets, round_targets=False):
# target (probability of a click)
if round_targets:
P = np.round(ra.rand(n, num_targets).astype(np.float32)).astype(np.float32)
else:
P = ra.rand(n, num_targets).astype(np.float32)
return torch.tensor(P)
# uniform ditribution (input data)
def generate_uniform_input_batch(
m_den,
ln_emb,
n,
num_indices_per_lookup,
num_indices_per_lookup_fixed,
length,
):
# dense feature
Xt = torch.tensor(ra.rand(n, m_den).astype(np.float32))
# sparse feature (sparse indices)
lS_emb_offsets = []
lS_emb_indices = []
# for each embedding generate a list of n lookups,
# where each lookup is composed of multiple sparse indices
for size in ln_emb:
lS_batch_offsets = []
lS_batch_indices = []
offset = 0
for _ in range(n):
# num of sparse indices to be used per embedding (between
if num_indices_per_lookup_fixed:
sparse_group_size = np.int64(num_indices_per_lookup)
else:
# random between [1,num_indices_per_lookup])
r = ra.random(1)
sparse_group_size = np.int64(
np.round(max([1.0], r * min(size, num_indices_per_lookup)))
)
# sparse indices to be used per embedding
r = ra.random(sparse_group_size)
sparse_group = np.unique(np.round(r * (size - 1)).astype(np.int64))
# reset sparse_group_size in case some index duplicates were removed
sparse_group_size = np.int32(sparse_group.size)
# store lengths and indices
if length: # for caffe2 version
lS_batch_offsets += [sparse_group_size]
else:
lS_batch_offsets += [offset]
lS_batch_indices += sparse_group.tolist()
# update offset for next iteration
offset += sparse_group_size
lS_emb_offsets.append(torch.tensor(lS_batch_offsets))
lS_emb_indices.append(torch.tensor(lS_batch_indices))
return (Xt, lS_emb_offsets, lS_emb_indices)
# random data from uniform or gaussian ditribution (input data)
def generate_dist_input_batch(
m_den,
ln_emb,
n,
num_indices_per_lookup,
num_indices_per_lookup_fixed,
rand_data_dist,
rand_data_min,
rand_data_max,
rand_data_mu,
rand_data_sigma,
):
# dense feature
Xt = torch.tensor(ra.rand(n, m_den).astype(np.float32))
# sparse feature (sparse indices)
lS_emb_offsets = []
lS_emb_indices = []
# for each embedding generate a list of n lookups,
# where each lookup is composed of multiple sparse indices
for size in ln_emb:
lS_batch_offsets = []
lS_batch_indices = []
offset = 0
for _ in range(n):
# num of sparse indices to be used per embedding (between
if num_indices_per_lookup_fixed:
sparse_group_size = np.int64(num_indices_per_lookup)
else:
# random between [1,num_indices_per_lookup])
r = ra.random(1)
sparse_group_size = np.int64(
np.round(max([1.0], r * min(size, num_indices_per_lookup)))
)
# sparse indices to be used per embedding
if rand_data_dist == "gaussian":
if rand_data_mu == -1:
rand_data_mu = (rand_data_max + rand_data_min) / 2.0
r = ra.normal(rand_data_mu, rand_data_sigma, sparse_group_size)
sparse_group = np.clip(r, rand_data_min, rand_data_max)
sparse_group = np.unique(sparse_group).astype(np.int64)
elif rand_data_dist == "uniform":
r = ra.random(sparse_group_size)
sparse_group = np.unique(np.round(r * (size - 1)).astype(np.int64))
else:
raise(rand_data_dist, "distribution is not supported. \
please select uniform or gaussian")
# reset sparse_group_size in case some index duplicates were removed
sparse_group_size = np.int64(sparse_group.size)
# store lengths and indices
lS_batch_offsets += [offset]
lS_batch_indices += sparse_group.tolist()
# update offset for next iteration
offset += sparse_group_size
lS_emb_offsets.append(torch.tensor(lS_batch_offsets))
lS_emb_indices.append(torch.tensor(lS_batch_indices))
return (Xt, lS_emb_offsets, lS_emb_indices)
# synthetic distribution (input data)
def generate_synthetic_input_batch(
m_den,
ln_emb,
n,
num_indices_per_lookup,
num_indices_per_lookup_fixed,
trace_file,
enable_padding=False,
):
# dense feature
Xt = torch.tensor(ra.rand(n, m_den).astype(np.float32))
# sparse feature (sparse indices)
lS_emb_offsets = []
lS_emb_indices = []
# for each embedding generate a list of n lookups,
# where each lookup is composed of multiple sparse indices
for i, size in enumerate(ln_emb):
lS_batch_offsets = []
lS_batch_indices = []
offset = 0
for _ in range(n):
# num of sparse indices to be used per embedding (between
if num_indices_per_lookup_fixed:
sparse_group_size = np.int64(num_indices_per_lookup)
else:
# random between [1,num_indices_per_lookup])
r = ra.random(1)
sparse_group_size = np.int64(
max(1, np.round(r * min(size, num_indices_per_lookup))[0])