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dlrm_s_pytorch.py
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dlrm_s_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: an implementation of a deep learning recommendation model (DLRM)
# The model input consists of dense and sparse features. The former is a vector
# of floating point values. The latter is a list of sparse indices into
# embedding tables, which consist of vectors of floating point values.
# The selected vectors are passed to mlp networks denoted by triangles,
# in some cases the vectors are interacted through operators (Ops).
#
# output:
# vector of values
# model: |
# /\
# /__\
# |
# _____________________> Op <___________________
# / | \
# /\ /\ /\
# /__\ /__\ ... /__\
# | | |
# | Op Op
# | ____/__\_____ ____/__\____
# | |_Emb_|____|__| ... |_Emb_|__|___|
# input:
# [ dense features ] [sparse indices] , ..., [sparse indices]
#
# More precise definition of model layers:
# 1) fully connected layers of an mlp
# z = f(y)
# y = Wx + b
#
# 2) embedding lookup (for a list of sparse indices p=[p1,...,pk])
# z = Op(e1,...,ek)
# obtain vectors e1=E[:,p1], ..., ek=E[:,pk]
#
# 3) Operator Op can be one of the following
# Sum(e1,...,ek) = e1 + ... + ek
# Dot(e1,...,ek) = [e1'e1, ..., e1'ek, ..., ek'e1, ..., ek'ek]
# Cat(e1,...,ek) = [e1', ..., ek']'
# where ' denotes transpose operation
#
# References:
# [1] Maxim Naumov, Dheevatsa Mudigere, Hao-Jun Michael Shi, Jianyu Huang,
# Narayanan Sundaram, Jongsoo Park, Xiaodong Wang, Udit Gupta, Carole-Jean Wu,
# Alisson G. Azzolini, Dmytro Dzhulgakov, Andrey Mallevich, Ilia Cherniavskii,
# Yinghai Lu, Raghuraman Krishnamoorthi, Ansha Yu, Volodymyr Kondratenko,
# Stephanie Pereira, Xianjie Chen, Wenlin Chen, Vijay Rao, Bill Jia, Liang Xiong,
# Misha Smelyanskiy, "Deep Learning Recommendation Model for Personalization and
# Recommendation Systems", CoRR, arXiv:1906.00091, 2019
from __future__ import absolute_import, division, print_function, unicode_literals
import argparse
# miscellaneous
import builtins
import datetime
import json
import sys
import time
# onnx
# The onnx import causes deprecation warnings every time workers
# are spawned during testing. So, we filter out those warnings.
import warnings
# data generation
import dlrm_data_pytorch as dp
# For distributed run
import extend_distributed as ext_dist
import mlperf_logger
# numpy
import numpy as np
import sklearn.metrics
# pytorch
import torch
import torch.nn as nn
from torch._ops import ops
from torch.autograd.profiler import record_function
from torch.nn.parallel.parallel_apply import parallel_apply
from torch.nn.parallel.replicate import replicate
from torch.nn.parallel.scatter_gather import gather, scatter
from torch.nn.parameter import Parameter
from torch.optim.lr_scheduler import _LRScheduler
import optim.rwsadagrad as RowWiseSparseAdagrad
from torch.utils.tensorboard import SummaryWriter
# mixed-dimension trick
from tricks.md_embedding_bag import PrEmbeddingBag, md_solver
# quotient-remainder trick
from tricks.qr_embedding_bag import QREmbeddingBag
with warnings.catch_warnings():
warnings.filterwarnings("ignore", category=DeprecationWarning)
try:
import onnx
except ImportError as error:
print("Unable to import onnx. ", error)
# from torchviz import make_dot
# import torch.nn.functional as Functional
# from torch.nn.parameter import Parameter
exc = getattr(builtins, "IOError", "FileNotFoundError")
def time_wrap(use_gpu):
if use_gpu:
torch.cuda.synchronize()
return time.time()
def dlrm_wrap(X, lS_o, lS_i, use_gpu, device, ndevices=1):
with record_function("DLRM forward"):
if use_gpu: # .cuda()
# lS_i can be either a list of tensors or a stacked tensor.
# Handle each case below:
if ndevices == 1:
lS_i = (
[S_i.to(device) for S_i in lS_i]
if isinstance(lS_i, list)
else lS_i.to(device)
)
lS_o = (
[S_o.to(device) for S_o in lS_o]
if isinstance(lS_o, list)
else lS_o.to(device)
)
return dlrm(X.to(device), lS_o, lS_i)
def loss_fn_wrap(Z, T, use_gpu, device):
with record_function("DLRM loss compute"):
if args.loss_function == "mse" or args.loss_function == "bce":
return dlrm.loss_fn(Z, T.to(device))
elif args.loss_function == "wbce":
loss_ws_ = dlrm.loss_ws[T.data.view(-1).long()].view_as(T).to(device)
loss_fn_ = dlrm.loss_fn(Z, T.to(device))
loss_sc_ = loss_ws_ * loss_fn_
return loss_sc_.mean()
# The following function is a wrapper to avoid checking this multiple times in th
# loop below.
def unpack_batch(b):
# Experiment with unweighted samples
return b[0], b[1], b[2], b[3], torch.ones(b[3].size()), None
class LRPolicyScheduler(_LRScheduler):
def __init__(self, optimizer, num_warmup_steps, decay_start_step, num_decay_steps):
self.num_warmup_steps = num_warmup_steps
self.decay_start_step = decay_start_step
self.decay_end_step = decay_start_step + num_decay_steps
self.num_decay_steps = num_decay_steps
if self.decay_start_step < self.num_warmup_steps:
sys.exit("Learning rate warmup must finish before the decay starts")
super(LRPolicyScheduler, self).__init__(optimizer)
def get_lr(self):
step_count = self._step_count
if step_count < self.num_warmup_steps:
# warmup
scale = 1.0 - (self.num_warmup_steps - step_count) / self.num_warmup_steps
lr = [base_lr * scale for base_lr in self.base_lrs]
self.last_lr = lr
elif self.decay_start_step <= step_count and step_count < self.decay_end_step:
# decay
decayed_steps = step_count - self.decay_start_step
scale = ((self.num_decay_steps - decayed_steps) / self.num_decay_steps) ** 2
min_lr = 0.0000001
lr = [max(min_lr, base_lr * scale) for base_lr in self.base_lrs]
self.last_lr = lr
else:
if self.num_decay_steps > 0:
# freeze at last, either because we're after decay
# or because we're between warmup and decay
lr = self.last_lr
else:
# do not adjust
lr = self.base_lrs
return lr
### define dlrm in PyTorch ###
class DLRM_Net(nn.Module):
def create_mlp(self, ln, sigmoid_layer):
# build MLP layer by layer
layers = nn.ModuleList()
for i in range(0, ln.size - 1):
n = ln[i]
m = ln[i + 1]
# construct fully connected operator
LL = nn.Linear(int(n), int(m), bias=True)
# initialize the weights
# with torch.no_grad():
# custom Xavier input, output or two-sided fill
mean = 0.0 # std_dev = np.sqrt(variance)
std_dev = np.sqrt(2 / (m + n)) # np.sqrt(1 / m) # np.sqrt(1 / n)
W = np.random.normal(mean, std_dev, size=(m, n)).astype(np.float32)
std_dev = np.sqrt(1 / m) # np.sqrt(2 / (m + 1))
bt = np.random.normal(mean, std_dev, size=m).astype(np.float32)
# approach 1
LL.weight.data = torch.tensor(W, requires_grad=True)
LL.bias.data = torch.tensor(bt, requires_grad=True)
# approach 2
# LL.weight.data.copy_(torch.tensor(W))
# LL.bias.data.copy_(torch.tensor(bt))
# approach 3
# LL.weight = Parameter(torch.tensor(W),requires_grad=True)
# LL.bias = Parameter(torch.tensor(bt),requires_grad=True)
layers.append(LL)
# construct sigmoid or relu operator
if i == sigmoid_layer:
layers.append(nn.Sigmoid())
else:
layers.append(nn.ReLU())
# approach 1: use ModuleList
# return layers
# approach 2: use Sequential container to wrap all layers
return torch.nn.Sequential(*layers)
def create_emb(self, m, ln, weighted_pooling=None):
emb_l = nn.ModuleList()
v_W_l = []
for i in range(0, ln.size):
if ext_dist.my_size > 1:
if i not in self.local_emb_indices:
continue
n = ln[i]
# construct embedding operator
if self.qr_flag and n > self.qr_threshold:
EE = QREmbeddingBag(
n,
m,
self.qr_collisions,
operation=self.qr_operation,
mode="sum",
sparse=True,
)
elif self.md_flag and n > self.md_threshold:
base = max(m)
_m = m[i] if n > self.md_threshold else base
EE = PrEmbeddingBag(n, _m, base)
# use np initialization as below for consistency...
W = np.random.uniform(
low=-np.sqrt(1 / n), high=np.sqrt(1 / n), size=(n, _m)
).astype(np.float32)
EE.embs.weight.data = torch.tensor(W, requires_grad=True)
else:
EE = nn.EmbeddingBag(n, m, mode="sum", sparse=True)
# initialize embeddings
# nn.init.uniform_(EE.weight, a=-np.sqrt(1 / n), b=np.sqrt(1 / n))
W = np.random.uniform(
low=-np.sqrt(1 / n), high=np.sqrt(1 / n), size=(n, m)
).astype(np.float32)
# approach 1
EE.weight.data = torch.tensor(W, requires_grad=True)
# approach 2
# EE.weight.data.copy_(torch.tensor(W))
# approach 3
# EE.weight = Parameter(torch.tensor(W),requires_grad=True)
if weighted_pooling is None:
v_W_l.append(None)
else:
v_W_l.append(torch.ones(n, dtype=torch.float32))
emb_l.append(EE)
return emb_l, v_W_l
def __init__(
self,
m_spa=None,
ln_emb=None,
ln_bot=None,
ln_top=None,
arch_interaction_op=None,
arch_interaction_itself=False,
sigmoid_bot=-1,
sigmoid_top=-1,
sync_dense_params=True,
loss_threshold=0.0,
ndevices=-1,
qr_flag=False,
qr_operation="mult",
qr_collisions=0,
qr_threshold=200,
md_flag=False,
md_threshold=200,
weighted_pooling=None,
loss_function="bce"
):
super(DLRM_Net, self).__init__()
if (
(m_spa is not None)
and (ln_emb is not None)
and (ln_bot is not None)
and (ln_top is not None)
and (arch_interaction_op is not None)
):
# save arguments
self.ndevices = ndevices
self.output_d = 0
self.parallel_model_batch_size = -1
self.parallel_model_is_not_prepared = True
self.arch_interaction_op = arch_interaction_op
self.arch_interaction_itself = arch_interaction_itself
self.sync_dense_params = sync_dense_params
self.loss_threshold = loss_threshold
self.loss_function=loss_function
if weighted_pooling is not None and weighted_pooling != "fixed":
self.weighted_pooling = "learned"
else:
self.weighted_pooling = weighted_pooling
# create variables for QR embedding if applicable
self.qr_flag = qr_flag
if self.qr_flag:
self.qr_collisions = qr_collisions
self.qr_operation = qr_operation
self.qr_threshold = qr_threshold
# create variables for MD embedding if applicable
self.md_flag = md_flag
if self.md_flag:
self.md_threshold = md_threshold
# If running distributed, get local slice of embedding tables
if ext_dist.my_size > 1:
n_emb = len(ln_emb)
if n_emb < ext_dist.my_size:
sys.exit(
"only (%d) sparse features for (%d) devices, table partitions will fail"
% (n_emb, ext_dist.my_size)
)
self.n_global_emb = n_emb
self.n_local_emb, self.n_emb_per_rank = ext_dist.get_split_lengths(
n_emb
)
self.local_emb_slice = ext_dist.get_my_slice(n_emb)
self.local_emb_indices = list(range(n_emb))[self.local_emb_slice]
# create operators
if ndevices <= 1:
self.emb_l, w_list = self.create_emb(m_spa, ln_emb, weighted_pooling)
if self.weighted_pooling == "learned":
self.v_W_l = nn.ParameterList()
for w in w_list:
self.v_W_l.append(Parameter(w))
else:
self.v_W_l = w_list
self.bot_l = self.create_mlp(ln_bot, sigmoid_bot)
self.top_l = self.create_mlp(ln_top, sigmoid_top)
# quantization
self.quantize_emb = False
self.emb_l_q = []
self.quantize_bits = 32
# specify the loss function
if self.loss_function == "mse":
self.loss_fn = torch.nn.MSELoss(reduction="mean")
elif self.loss_function == "bce":
self.loss_fn = torch.nn.BCELoss(reduction="mean")
elif self.loss_function == "wbce":
self.loss_ws = torch.tensor(
np.fromstring(args.loss_weights, dtype=float, sep="-")
)
self.loss_fn = torch.nn.BCELoss(reduction="none")
else:
sys.exit(
"ERROR: --loss-function=" + self.loss_function + " is not supported"
)
def apply_mlp(self, x, layers):
# approach 1: use ModuleList
# for layer in layers:
# x = layer(x)
# return x
# approach 2: use Sequential container to wrap all layers
return layers(x)
def apply_emb(self, lS_o, lS_i, emb_l, v_W_l):
# WARNING: notice that we are processing the batch at once. We implicitly
# assume that the data is laid out such that:
# 1. each embedding is indexed with a group of sparse indices,
# corresponding to a single lookup
# 2. for each embedding the lookups are further organized into a batch
# 3. for a list of embedding tables there is a list of batched lookups
ly = []
for k, sparse_index_group_batch in enumerate(lS_i):
sparse_offset_group_batch = lS_o[k]
# embedding lookup
# We are using EmbeddingBag, which implicitly uses sum operator.
# The embeddings are represented as tall matrices, with sum
# happening vertically across 0 axis, resulting in a row vector
# E = emb_l[k]
if v_W_l[k] is not None:
per_sample_weights = v_W_l[k].gather(0, sparse_index_group_batch)
else:
per_sample_weights = None
if self.quantize_emb:
s1 = self.emb_l_q[k].element_size() * self.emb_l_q[k].nelement()
s2 = self.emb_l_q[k].element_size() * self.emb_l_q[k].nelement()
print("quantized emb sizes:", s1, s2)
if self.quantize_bits == 4:
QV = ops.quantized.embedding_bag_4bit_rowwise_offsets(
self.emb_l_q[k],
sparse_index_group_batch,
sparse_offset_group_batch,
per_sample_weights=per_sample_weights,
)
elif self.quantize_bits == 8:
QV = ops.quantized.embedding_bag_byte_rowwise_offsets(
self.emb_l_q[k],
sparse_index_group_batch,
sparse_offset_group_batch,
per_sample_weights=per_sample_weights,
)
ly.append(QV)
else:
E = emb_l[k]
V = E(
sparse_index_group_batch,
sparse_offset_group_batch,
per_sample_weights=per_sample_weights,
)
ly.append(V)
# print(ly)
return ly
# using quantizing functions from caffe2/aten/src/ATen/native/quantized/cpu
def quantize_embedding(self, bits):
n = len(self.emb_l)
self.emb_l_q = [None] * n
for k in range(n):
if bits == 4:
self.emb_l_q[k] = ops.quantized.embedding_bag_4bit_prepack(
self.emb_l[k].weight
)
elif bits == 8:
self.emb_l_q[k] = ops.quantized.embedding_bag_byte_prepack(
self.emb_l[k].weight
)
else:
return
self.emb_l = None
self.quantize_emb = True
self.quantize_bits = bits
def interact_features(self, x, ly):
if self.arch_interaction_op == "dot":
# concatenate dense and sparse features
(batch_size, d) = x.shape
T = torch.cat([x] + ly, dim=1).view((batch_size, -1, d))
# perform a dot product
Z = torch.bmm(T, torch.transpose(T, 1, 2))
# append dense feature with the interactions (into a row vector)
# approach 1: all
# Zflat = Z.view((batch_size, -1))
# approach 2: unique
_, ni, nj = Z.shape
# approach 1: tril_indices
# offset = 0 if self.arch_interaction_itself else -1
# li, lj = torch.tril_indices(ni, nj, offset=offset)
# approach 2: custom
offset = 1 if self.arch_interaction_itself else 0
li = torch.tensor([i for i in range(ni) for j in range(i + offset)])
lj = torch.tensor([j for i in range(nj) for j in range(i + offset)])
Zflat = Z[:, li, lj]
# concatenate dense features and interactions
R = torch.cat([x] + [Zflat], dim=1)
elif self.arch_interaction_op == "cat":
# concatenation features (into a row vector)
R = torch.cat([x] + ly, dim=1)
else:
sys.exit(
"ERROR: --arch-interaction-op="
+ self.arch_interaction_op
+ " is not supported"
)
return R
def forward(self, dense_x, lS_o, lS_i):
if ext_dist.my_size > 1:
# multi-node multi-device run
return self.distributed_forward(dense_x, lS_o, lS_i)
elif self.ndevices <= 1:
# single device run
return self.sequential_forward(dense_x, lS_o, lS_i)
else:
# single-node multi-device run
return self.parallel_forward(dense_x, lS_o, lS_i)
def distributed_forward(self, dense_x, lS_o, lS_i):
batch_size = dense_x.size()[0]
# WARNING: # of ranks must be <= batch size in distributed_forward call
if batch_size < ext_dist.my_size:
sys.exit(
"ERROR: batch_size (%d) must be larger than number of ranks (%d)"
% (batch_size, ext_dist.my_size)
)
if batch_size % ext_dist.my_size != 0:
sys.exit(
"ERROR: batch_size %d can not split across %d ranks evenly"
% (batch_size, ext_dist.my_size)
)
dense_x = dense_x[ext_dist.get_my_slice(batch_size)]
lS_o = lS_o[self.local_emb_slice]
lS_i = lS_i[self.local_emb_slice]
if (len(self.emb_l) != len(lS_o)) or (len(self.emb_l) != len(lS_i)):
sys.exit(
"ERROR: corrupted model input detected in distributed_forward call"
)
# embeddings
with record_function("DLRM embedding forward"):
ly = self.apply_emb(lS_o, lS_i, self.emb_l, self.v_W_l)
# WARNING: Note that at this point we have the result of the embedding lookup
# for the entire batch on each rank. We would like to obtain partial results
# corresponding to all embedding lookups, but part of the batch on each rank.
# Therefore, matching the distribution of output of bottom mlp, so that both
# could be used for subsequent interactions on each device.
if len(self.emb_l) != len(ly):
sys.exit("ERROR: corrupted intermediate result in distributed_forward call")
a2a_req = ext_dist.alltoall(ly, self.n_emb_per_rank)
with record_function("DLRM bottom nlp forward"):
x = self.apply_mlp(dense_x, self.bot_l)
ly = a2a_req.wait()
ly = list(ly)
# interactions
with record_function("DLRM interaction forward"):
z = self.interact_features(x, ly)
# top mlp
with record_function("DLRM top nlp forward"):
p = self.apply_mlp(z, self.top_l)
# clamp output if needed
if 0.0 < self.loss_threshold and self.loss_threshold < 1.0:
z = torch.clamp(p, min=self.loss_threshold, max=(1.0 - self.loss_threshold))
else:
z = p
return z
def sequential_forward(self, dense_x, lS_o, lS_i):
# process dense features (using bottom mlp), resulting in a row vector
x = self.apply_mlp(dense_x, self.bot_l)
# debug prints
# print("intermediate")
# print(x.detach().cpu().numpy())
# process sparse features(using embeddings), resulting in a list of row vectors
ly = self.apply_emb(lS_o, lS_i, self.emb_l, self.v_W_l)
# for y in ly:
# print(y.detach().cpu().numpy())
# interact features (dense and sparse)
z = self.interact_features(x, ly)
# print(z.detach().cpu().numpy())
# obtain probability of a click (using top mlp)
p = self.apply_mlp(z, self.top_l)
# clamp output if needed
if 0.0 < self.loss_threshold and self.loss_threshold < 1.0:
z = torch.clamp(p, min=self.loss_threshold, max=(1.0 - self.loss_threshold))
else:
z = p
return z
def parallel_forward(self, dense_x, lS_o, lS_i):
### prepare model (overwrite) ###
# WARNING: # of devices must be >= batch size in parallel_forward call
batch_size = dense_x.size()[0]
ndevices = min(self.ndevices, batch_size, len(self.emb_l))
device_ids = range(ndevices)
# WARNING: must redistribute the model if mini-batch size changes(this is common
# for last mini-batch, when # of elements in the dataset/batch size is not even
if self.parallel_model_batch_size != batch_size:
self.parallel_model_is_not_prepared = True
if self.parallel_model_is_not_prepared or self.sync_dense_params:
# replicate mlp (data parallelism)
self.bot_l_replicas = replicate(self.bot_l, device_ids)
self.top_l_replicas = replicate(self.top_l, device_ids)
self.parallel_model_batch_size = batch_size
if self.parallel_model_is_not_prepared:
# distribute embeddings (model parallelism)
t_list = []
w_list = []
for k, emb in enumerate(self.emb_l):
d = torch.device("cuda:" + str(k % ndevices))
t_list.append(emb.to(d))
if self.weighted_pooling == "learned":
w_list.append(Parameter(self.v_W_l[k].to(d)))
elif self.weighted_pooling == "fixed":
w_list.append(self.v_W_l[k].to(d))
else:
w_list.append(None)
self.emb_l = nn.ModuleList(t_list)
if self.weighted_pooling == "learned":
self.v_W_l = nn.ParameterList(w_list)
else:
self.v_W_l = w_list
self.parallel_model_is_not_prepared = False
### prepare input (overwrite) ###
# scatter dense features (data parallelism)
# print(dense_x.device)
dense_x = scatter(dense_x, device_ids, dim=0)
# distribute sparse features (model parallelism)
if (len(self.emb_l) != len(lS_o)) or (len(self.emb_l) != len(lS_i)):
sys.exit("ERROR: corrupted model input detected in parallel_forward call")
t_list = []
i_list = []
for k, _ in enumerate(self.emb_l):
d = torch.device("cuda:" + str(k % ndevices))
t_list.append(lS_o[k].to(d))
i_list.append(lS_i[k].to(d))
lS_o = t_list
lS_i = i_list
### compute results in parallel ###
# bottom mlp
# WARNING: Note that the self.bot_l is a list of bottom mlp modules
# that have been replicated across devices, while dense_x is a tuple of dense
# inputs that has been scattered across devices on the first (batch) dimension.
# The output is a list of tensors scattered across devices according to the
# distribution of dense_x.
x = parallel_apply(self.bot_l_replicas, dense_x, None, device_ids)
# debug prints
# print(x)
# embeddings
ly = self.apply_emb(lS_o, lS_i, self.emb_l, self.v_W_l)
# debug prints
# print(ly)
# butterfly shuffle (implemented inefficiently for now)
# WARNING: Note that at this point we have the result of the embedding lookup
# for the entire batch on each device. We would like to obtain partial results
# corresponding to all embedding lookups, but part of the batch on each device.
# Therefore, matching the distribution of output of bottom mlp, so that both
# could be used for subsequent interactions on each device.
if len(self.emb_l) != len(ly):
sys.exit("ERROR: corrupted intermediate result in parallel_forward call")
t_list = []
for k, _ in enumerate(self.emb_l):
d = torch.device("cuda:" + str(k % ndevices))
y = scatter(ly[k], device_ids, dim=0)
t_list.append(y)
# adjust the list to be ordered per device
ly = list(map(lambda y: list(y), zip(*t_list)))
# debug prints
# print(ly)
# interactions
z = []
for k in range(ndevices):
zk = self.interact_features(x[k], ly[k])
z.append(zk)
# debug prints
# print(z)
# top mlp
# WARNING: Note that the self.top_l is a list of top mlp modules that
# have been replicated across devices, while z is a list of interaction results
# that by construction are scattered across devices on the first (batch) dim.
# The output is a list of tensors scattered across devices according to the
# distribution of z.
p = parallel_apply(self.top_l_replicas, z, None, device_ids)
### gather the distributed results ###
p0 = gather(p, self.output_d, dim=0)
# clamp output if needed
if 0.0 < self.loss_threshold and self.loss_threshold < 1.0:
z0 = torch.clamp(
p0, min=self.loss_threshold, max=(1.0 - self.loss_threshold)
)
else:
z0 = p0
return z0
def dash_separated_ints(value):
vals = value.split("-")
for val in vals:
try:
int(val)
except ValueError:
raise argparse.ArgumentTypeError(
"%s is not a valid dash separated list of ints" % value
)
return value
def dash_separated_floats(value):
vals = value.split("-")
for val in vals:
try:
float(val)
except ValueError:
raise argparse.ArgumentTypeError(
"%s is not a valid dash separated list of floats" % value
)
return value
def inference(
args,
dlrm,
best_acc_test,
best_auc_test,
test_ld,
device,
use_gpu,
log_iter=-1,
):
test_accu = 0
test_samp = 0
if args.mlperf_logging:
scores = []
targets = []
for i, testBatch in enumerate(test_ld):
# early exit if nbatches was set by the user and was exceeded
if nbatches > 0 and i >= nbatches:
break
X_test, lS_o_test, lS_i_test, T_test, W_test, CBPP_test = unpack_batch(
testBatch
)
# Skip the batch if batch size not multiple of total ranks
if ext_dist.my_size > 1 and X_test.size(0) % ext_dist.my_size != 0:
print("Warning: Skiping the batch %d with size %d" % (i, X_test.size(0)))
continue
# forward pass
Z_test = dlrm_wrap(
X_test,
lS_o_test,
lS_i_test,
use_gpu,
device,
ndevices=ndevices,
)
### gather the distributed results on each rank ###
# For some reason it requires explicit sync before all_gather call if
# tensor is on GPU memory
if Z_test.is_cuda:
torch.cuda.synchronize()
(_, batch_split_lengths) = ext_dist.get_split_lengths(X_test.size(0))
if ext_dist.my_size > 1:
Z_test = ext_dist.all_gather(Z_test, batch_split_lengths)
if args.mlperf_logging:
S_test = Z_test.detach().cpu().numpy() # numpy array
T_test = T_test.detach().cpu().numpy() # numpy array
scores.append(S_test)
targets.append(T_test)
else:
with record_function("DLRM accuracy compute"):
# compute loss and accuracy
S_test = Z_test.detach().cpu().numpy() # numpy array
T_test = T_test.detach().cpu().numpy() # numpy array
mbs_test = T_test.shape[0] # = mini_batch_size except last
A_test = np.sum((np.round(S_test, 0) == T_test).astype(np.uint8))
test_accu += A_test
test_samp += mbs_test
if args.mlperf_logging:
with record_function("DLRM mlperf sklearn metrics compute"):
scores = np.concatenate(scores, axis=0)
targets = np.concatenate(targets, axis=0)
metrics = {
"recall": lambda y_true, y_score: sklearn.metrics.recall_score(
y_true=y_true, y_pred=np.round(y_score)
),
"precision": lambda y_true, y_score: sklearn.metrics.precision_score(
y_true=y_true, y_pred=np.round(y_score)
),
"f1": lambda y_true, y_score: sklearn.metrics.f1_score(
y_true=y_true, y_pred=np.round(y_score)
),
"ap": sklearn.metrics.average_precision_score,
"roc_auc": sklearn.metrics.roc_auc_score,
"accuracy": lambda y_true, y_score: sklearn.metrics.accuracy_score(
y_true=y_true, y_pred=np.round(y_score)
),
}
validation_results = {}
for metric_name, metric_function in metrics.items():
validation_results[metric_name] = metric_function(targets, scores)
writer.add_scalar(
"mlperf-metrics-test/" + metric_name,
validation_results[metric_name],
log_iter,
)
acc_test = validation_results["accuracy"]
else:
acc_test = test_accu / test_samp
writer.add_scalar("Test/Acc", acc_test, log_iter)
model_metrics_dict = {
"nepochs": args.nepochs,
"nbatches": nbatches,
"nbatches_test": nbatches_test,
"state_dict": dlrm.state_dict(),
"test_acc": acc_test,
}
if args.mlperf_logging:
is_best = validation_results["roc_auc"] > best_auc_test
if is_best:
best_auc_test = validation_results["roc_auc"]
model_metrics_dict["test_auc"] = best_auc_test
print(
"recall {:.4f}, precision {:.4f},".format(
validation_results["recall"],
validation_results["precision"],
)
+ " f1 {:.4f}, ap {:.4f},".format(
validation_results["f1"], validation_results["ap"]
)
+ " auc {:.4f}, best auc {:.4f},".format(
validation_results["roc_auc"], best_auc_test
)
+ " accuracy {:3.3f} %, best accuracy {:3.3f} %".format(
validation_results["accuracy"] * 100, best_acc_test * 100
),
flush=True,
)
else:
is_best = acc_test > best_acc_test
if is_best:
best_acc_test = acc_test
print(
" accuracy {:3.3f} %, best {:3.3f} %".format(
acc_test * 100, best_acc_test * 100
),
flush=True,
)
return model_metrics_dict, is_best
def run():
### parse arguments ###
parser = argparse.ArgumentParser(
description="Train Deep Learning Recommendation Model (DLRM)"
)
# model related parameters
parser.add_argument("--arch-sparse-feature-size", type=int, default=2)
parser.add_argument(
"--arch-embedding-size", type=dash_separated_ints, default="4-3-2"
)
# j will be replaced with the table number
parser.add_argument("--arch-mlp-bot", type=dash_separated_ints, default="4-3-2")
parser.add_argument("--arch-mlp-top", type=dash_separated_ints, default="4-2-1")
parser.add_argument(
"--arch-interaction-op", type=str, choices=["dot", "cat"], default="dot"
)
parser.add_argument("--arch-interaction-itself", action="store_true", default=False)
parser.add_argument("--weighted-pooling", type=str, default=None)
# embedding table options
parser.add_argument("--md-flag", action="store_true", default=False)
parser.add_argument("--md-threshold", type=int, default=200)
parser.add_argument("--md-temperature", type=float, default=0.3)
parser.add_argument("--md-round-dims", action="store_true", default=False)
parser.add_argument("--qr-flag", action="store_true", default=False)
parser.add_argument("--qr-threshold", type=int, default=200)
parser.add_argument("--qr-operation", type=str, default="mult")
parser.add_argument("--qr-collisions", type=int, default=4)
# activations and loss
parser.add_argument("--activation-function", type=str, default="relu")
parser.add_argument("--loss-function", type=str, default="mse") # or bce or wbce
parser.add_argument(
"--loss-weights", type=dash_separated_floats, default="1.0-1.0"
) # for wbce
parser.add_argument("--loss-threshold", type=float, default=0.0) # 1.0e-7
parser.add_argument("--round-targets", type=bool, default=False)
# data
parser.add_argument("--data-size", type=int, default=1)
parser.add_argument("--num-batches", type=int, default=0)
parser.add_argument(
"--data-generation", type=str, default="random"
) # synthetic or dataset
parser.add_argument(
"--rand-data-dist", type=str, default="uniform"
) # uniform or gaussian
parser.add_argument("--rand-data-min", type=float, default=0)
parser.add_argument("--rand-data-max", type=float, default=1)
parser.add_argument("--rand-data-mu", type=float, default=-1)
parser.add_argument("--rand-data-sigma", type=float, default=1)
parser.add_argument("--data-trace-file", type=str, default="./input/dist_emb_j.log")
parser.add_argument("--data-set", type=str, default="kaggle") # or terabyte
parser.add_argument("--raw-data-file", type=str, default="")
parser.add_argument("--processed-data-file", type=str, default="")
parser.add_argument("--data-randomize", type=str, default="total") # or day or none
parser.add_argument("--data-trace-enable-padding", type=bool, default=False)
parser.add_argument("--max-ind-range", type=int, default=-1)
parser.add_argument("--data-sub-sample-rate", type=float, default=0.0) # in [0, 1]
parser.add_argument("--num-indices-per-lookup", type=int, default=10)
parser.add_argument("--num-indices-per-lookup-fixed", type=bool, default=False)
parser.add_argument("--num-workers", type=int, default=0)
parser.add_argument("--memory-map", action="store_true", default=False)
# training
parser.add_argument("--mini-batch-size", type=int, default=1)
parser.add_argument("--nepochs", type=int, default=1)
parser.add_argument("--learning-rate", type=float, default=0.01)
parser.add_argument("--print-precision", type=int, default=5)
parser.add_argument("--numpy-rand-seed", type=int, default=123)
parser.add_argument("--sync-dense-params", type=bool, default=True)
parser.add_argument("--optimizer", type=str, default="sgd")
parser.add_argument(
"--dataset-multiprocessing",
action="store_true",
default=False,
help="The Kaggle dataset can be multiprocessed in an environment \
with more than 7 CPU cores and more than 20 GB of memory. \n \
The Terabyte dataset can be multiprocessed in an environment \
with more than 24 CPU cores and at least 1 TB of memory.",
)
# inference
parser.add_argument("--inference-only", action="store_true", default=False)
# quantize
parser.add_argument("--quantize-mlp-with-bit", type=int, default=32)
parser.add_argument("--quantize-emb-with-bit", type=int, default=32)
# onnx
parser.add_argument("--save-onnx", action="store_true", default=False)
# gpu
parser.add_argument("--use-gpu", action="store_true", default=False)
# distributed
parser.add_argument("--local_rank", type=int, default=-1)
parser.add_argument("--dist-backend", type=str, default="")
# debugging and profiling
parser.add_argument("--print-freq", type=int, default=1)
parser.add_argument("--test-freq", type=int, default=-1)
parser.add_argument("--test-mini-batch-size", type=int, default=-1)
parser.add_argument("--test-num-workers", type=int, default=-1)
parser.add_argument("--print-time", action="store_true", default=False)
parser.add_argument("--print-wall-time", action="store_true", default=False)
parser.add_argument("--debug-mode", action="store_true", default=False)
parser.add_argument("--enable-profiling", action="store_true", default=False)
parser.add_argument("--plot-compute-graph", action="store_true", default=False)
parser.add_argument("--tensor-board-filename", type=str, default="run_kaggle_pt")
# store/load model
parser.add_argument("--save-model", type=str, default="")
parser.add_argument("--load-model", type=str, default="")
# mlperf logging (disables other output and stops early)
parser.add_argument("--mlperf-logging", action="store_true", default=False)
# stop at target accuracy Kaggle 0.789, Terabyte (sub-sampled=0.875) 0.8107
parser.add_argument("--mlperf-acc-threshold", type=float, default=0.0)
# stop at target AUC Terabyte (no subsampling) 0.8025