Parameter Server Mode
Ascend
GPU
Distributed Parallel
Whole Process
Overview
A parameter server is a widely used architecture in distributed training. Compared with the synchronous AllReduce training method, a parameter server has better flexibility, scalability, and node failover capabilities. Specifically, the parameter server supports both synchronous and asynchronous SGD training algorithms. In terms of scalability, model computing and update are separately deployed in the worker and server processes, so that resources of the worker and server can be independently scaled out and in horizontally. In addition, in an environment of a large-scale data center, various failures often occur in a computing device, a network, and a storage device, and consequently some nodes are abnormal. However, in an architecture of a parameter server, such a failure can be relatively easily handled without affecting a training job.
In the parameter server implementation of MindSpore, the self-developed communication framework (core) is used as the basic architecture. Based on the remote communication capability provided by the core and abstract Send/Broadcast primitives, the distributed training algorithm of the synchronous SGD is implemented. In addition, with the high-performance collective communication library in Ascend and GPU(HCCL and NCCL), MindSpore also provides the hybrid training mode of parameter server and AllReduce. Some weights can be stored and updated through the parameter server, and other weights are still trained through the AllReduce algorithm.
The ps-lite architecture consists of three independent components: server, worker, and scheduler. Their functions are as follows:
Server: saves model weights and backward computation gradients, and updates the model using gradients pushed by workers.
Worker: performs forward and backward computation on the network. The gradient value for backward computation is uploaded to a server through the
Push
API, and the model updated by the server is downloaded to the worker through thePull
API.Scheduler: establishes the communication relationship between the server and worker.
Preparations
The following describes how to use parameter server to train LeNet on Ascend 910:
Training Script Preparation
Learn how to train a LeNet using the MNIST dataset by referring to https://gitee.com/mindspore/models/tree/r1.5/official/cv/lenet.
Parameter Setting
First of all, use
mindspore.context.set_ps_context(enable_ps=True)
to enable Parameter Server training mode.This method should be called before
mindspore.communication.init()
.If you don’t call this method, the Environment Variable Setting below will not take effect.
Use
mindspore.context.reset_ps_context()
to disable Parameter Server training mode.
In this training mode, you can use either of the following methods to control whether the training parameters are updated by the Parameter Server and whether the training parameters are initialized on Worker or Server:
Use
mindspore.nn.Cell.set_param_ps()
to set all weight recursions ofnn.Cell
.Use
mindspore.Parameter.set_param_ps()
to set the weight.The size of the weight which is updated by Parameter Server should not exceed INT_MAX(2^31 - 1) bytes.
The interface
set_param_ps
can receive abool
parameter:init_in_server
, indicating whether this training parameter is initialized on the Server side.init_in_server
defaults toFalse
, indicating that this training parameter is initialized on Worker. Currently, only the training parameterembedding_table
of theEmbeddingLookup
operator is supported to be initialized on Server side to solve the problem of insufficient memory caused by the initialization of a large shapeembedding_table
on Worker. TheEmbeddingLookup
operator’starget
attribute needs to be set to ‘CPU’. The training parameter initialized on the Server side will no longer be synchronized to Worker. If it involves multi-Server training and saves CheckPoint, each Server will save a CheckPoint after the training.
On the basis of the original training script, set all LeNet model weights to be trained on the parameter server:
context.set_ps_context(enable_ps=True) network = LeNet5(cfg.num_classes) network.set_param_ps()
[optional configuration] For a large shape
embedding_table
, because the device can not store a full amount ofembedding_table
. You can configure thevocab_cache_size
of EmbeddingLookup operator to enable the cache function ofEmbeddingLookup
in the Parameter Server training mode. Thevocab_cache_size
ofembedding_table
is trained on device, and a full amount ofembedding_table
is stored in the Server. Theembedding_table
of the next batch is swapped to the cache in advance, and the expiredembedding_table
is put back to the Server when the cache cannot be placed, to achieve the purpose of improving the training performance. Each Server could save a checkpoint containing the trainedembedding_table
after the training. Detailed network training script can be referred to https://gitee.com/mindspore/models/tree/r1.5/official/recommend/wide_and_deep.context.set_auto_parallel_context(full_batch=True, parallel_mode=ParallelMode.AUTO_PARALLEL) context.set_context(enable_sparse=True) network = Net() model = Model(network) model.train(epoch, train_dataset, dataset_sink_mode=True)
In the information:
dataset_sink_mode
: whether to enable the sink mode of dataset or not. WhenTrue
, it indicates enabled, and pass the data through the dataset channel. It must be set toTrue
in this scenario (The inference during training also needs to enable the sink mode of dataset).full_batch
: whether to load the dataset in full or not. WhenTrue
, it indicates fully load, and data of each device is the same. It must be set toTrue
in the multi-workers scenario.parallel_mode
:parallel mode, auto parallel mode must be enabled in the multi-workers scenario, please setparallel_mode
=ParallelMode.AUTO_PARALLEL
.enable_sparse
: whether to enable sparse training, default:False
.enable_sparse
=True
indicates enabling sparse training. The parametersparse
of allEmbeddingLookup
kernels which enable cache must be equal to the value ofenable_sparse
in the parameter server mode.
Environment Variable Setting
MindSpore reads environment variables to control parameter server training. The environment variables include the following options (all scripts of MS_SCHED_HOST
and MS_SCHED_PORT
must be consistent):
export MS_SERVER_NUM=1 # Server number
export MS_WORKER_NUM=1 # Worker number
export MS_SCHED_HOST=XXX.XXX.XXX.XXX # Scheduler IP address
export MS_SCHED_PORT=XXXX # Scheduler port
export MS_ROLE=MS_SCHED # The role of this process: MS_SCHED represents the scheduler, MS_WORKER represents the worker, MS_PSERVER represents the Server
Training
Shell scripts
Provide the shell scripts corresponding to the worker, server, and scheduler roles to start training:
Scheduler.sh
:#!/bin/bash export MS_SERVER_NUM=1 export MS_WORKER_NUM=1 export MS_SCHED_HOST=XXX.XXX.XXX.XXX export MS_SCHED_PORT=XXXX export MS_ROLE=MS_SCHED python train.py --device_target=Ascend --data_path=path/to/dataset
Server.sh
:#!/bin/bash export MS_SERVER_NUM=1 export MS_WORKER_NUM=1 export MS_SCHED_HOST=XXX.XXX.XXX.XXX export MS_SCHED_PORT=XXXX export MS_ROLE=MS_PSERVER python train.py --device_target=Ascend --data_path=path/to/dataset
Worker.sh
:#!/bin/bash export MS_SERVER_NUM=1 export MS_WORKER_NUM=1 export MS_SCHED_HOST=XXX.XXX.XXX.XXX export MS_SCHED_PORT=XXXX export MS_ROLE=MS_WORKER python train.py --device_target=Ascend --data_path=path/to/dataset
Run the following commands separately:
sh Scheduler.sh > scheduler.log 2>&1 & sh Server.sh > server.log 2>&1 & sh Worker.sh > worker.log 2>&1 &
Start training.
Viewing result
Run the following command to view the communication logs between the server and worker in the
scheduler.log
file:The server node id:b5d8a47c-46d7-49a5-aecf-d29d7f8b6124,node ip: 10.*.*.*,node port:46737 assign rank id:0 The worker node id:55e86d4b-d717-4930-b414-ebd80082f541 assign rank id:1 Start the scheduler node is successful!
The preceding information indicates that the communication between the server, worker, and scheduler is established successfully.
Check the training result in the
worker.log
file:epoch: 1 step: 1, loss is 2.302287 epoch: 1 step: 2, loss is 2.304071 epoch: 1 step: 3, loss is 2.308778 epoch: 1 step: 4, loss is 2.301943 ...