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Federated Learning

Data is becoming more and more expensive nowadays, and sharing of raw data is very hard across organizations. Federated Learning aims to solve the problem of data isolation and secure sharing of data knowledge among organizations. The concept of federated learning is proposed by researchers in Google [1, 2, 3].

In PaddleFL, horizontal and vertical federated learning strategies will be implemented according to the categorization given in [4]. Application demonstrations in natural language processing, computer vision and recommendation will be provided in PaddleFL.

A. Federated Learning Strategy

• Vertical Federated Learning: Logistic Regression with PrivC[5], Neural Network with MPC [11]

• Horizontal Federated Learning: Federated Averaging [2], Differential Privacy [6], Secure Aggregation

B. Training Strategy

• Transfer Learning [8]

• Active Learning

There are mainly two components in PaddleFL: Data Parallel and Federated Learning with MPC (PFM).

With Data Parallel, distributed data holders can finish their Federated Learning tasks based on common horizontal federated strategies, such as FedAvg, DPSGD, etc.

Besides, PFM is implemented based on secure multi-party computation (MPC) to enable secure training and prediction. As a key product of PaddleFL, PFM intrinsically supports federated learning well, including horizontal, vertical and transfer learning scenarios. Users with little cryptography expertise can also train models or conduct prediction on encrypted data.

Installation

We highly recommend to run PaddleFL in Docker

#Pull and run the docker
docker run --name <docker_name> --net=host -it -v \$PWD:/paddle <image id> /bin/bash

pip install paddle_fl

We also prepare a stable redis package for you to download and install, which will be used in tasks with MPC.

wget --no-check-certificate https://paddlefl.bj.bcebos.com/redis-stable.tar
tar -xf redis-stable.tar
cd redis-stable &&  make

Easy deployment with kubernetes

Data Parallel




Please refer K8S deployment example for details

You can also refer K8S cluster application and kubectl installation to deploy your K8S cluster

Data Parallel

In Data Parallel, components for defining a federated learning task and training a federated learning job are as follows:

A. Compile Time

• FL-Strategy: a user can define federated learning strategies with FL-Strategy such as Fed-Avg[2]

• User-Defined-Program: PaddlePaddle's program that defines the machine learning model structure and training strategies such as multi-task learning.

• Distributed-Config: In federated learning, a system should be deployed in distributed settings. Distributed Training Config defines distributed training node information.

• FL-Job-Generator: Given FL-Strategy, User-Defined Program and Distributed Training Config, FL-Job for federated server and worker will be generated through FL Job Generator. FL-Jobs will be sent to organizations and federated parameter server for run-time execution.

B. Run Time

• FL-Server: federated parameter server that usually runs in cloud or third-party clusters.

• FL-Worker: Each organization participates in federated learning will have one or more federated workers that will communicate with the federated parameter server.

• FL-scheduler: Decide which set of trainers can join the training before each updating cycle.

For more instructions, please refer to the examples

Federated Learning with MPC

Paddle FL MPC implements secure training and inference tasks based on the underlying MPC protocol like ABY3[11], which is a high efficient three-party computing model.

In ABY3, participants can be classified into roles of Input Party (IP), Computing Party (CP) and Result Party (RP). Input Parties (e.g., the training data/model owners) encrypt and distribute data or models to Computing Parties. Computing Parties (e.g., the VM on the cloud) conduct training or inference tasks based on specific MPC protocols, being restricted to see only the encrypted data or models, and thus guarantee the data privacy. When the computation is completed, one or more Result Parties (e.g., data owners or specified third-party) receive the encrypted results from Computing Parties, and reconstruct the plaintext results. Roles can be overlapped, e.g., a data owner can also act as a computing party.

A full training or inference process in PFM consists of mainly three phases: data preparation, training/inference, and result reconstruction.

A. Data preparation

• Private data alignment: PFM enables data owners (IPs) to find out records with identical keys (like UUID) without revealing private data to each other. This is especially useful in the vertical learning cases where segmented features with same keys need to be identified and aligned from all owners in a private manner before training.

• Encryption and distribution: In PFM, data and models from IPs will be encrypted using Secret-Sharing[10], and then be sent to CPs, via directly transmission or distributed storage like HDFS. Each CP can only obtain one share of each piece of data, and thus is unable to recover the original value in the Semi-honest model.

B. Training/inference

A PFM program is exactly a PaddlePaddle program, and will be executed as normal PaddlePaddle programs. Before training/inference, user needs to choose a MPC protocol, define a machine learning model and their training strategies. Typical machine learning operators are provided in paddle_fl.mpc over encrypted data, of which the instances are created and run in order by Executor during run-time.

C. Result reconstruction

Upon completion of the secure training (or inference) job, the models (or prediction results) will be output by CPs in encrypted form. Result Parties can collect the encrypted results, decrypt them using the tools in PFM, and deliver the plaintext results to users.

For more instructions, please refer to mpc examples

Federated Learning with MPC

We conduct tests on PFM using Boston house price dataset, and the implementation is given in uci_demo

On Going and Future Work

• Vertial Federated Learning will support more algorithms.

• Add K8S deployment scheme for PFM.

• FL mobile simulator will be open sourced in following versions.

Reference

[1]. Jakub Konečný, H. Brendan McMahan, Daniel Ramage, Peter Richtárik. Federated Optimization: Distributed Machine Learning for On-Device Intelligence. 2016

[2]. H. Brendan McMahan, Eider Moore, Daniel Ramage, Blaise Agüera y Arcas. Federated Learning of Deep Networks using Model Averaging. 2017

[3]. Jakub Konečný, H. Brendan McMahan, Felix X. Yu, Peter Richtárik, Ananda Theertha Suresh, Dave Bacon. Federated Learning: Strategies for Improving Communication Efficiency. 2016

[4]. Qiang Yang, Yang Liu, Tianjian Chen, Yongxin Tong. Federated Machine Learning: Concept and Applications. 2019

[5]. Kai He, Liu Yang, Jue Hong, Jinghua Jiang, Jieming Wu, Xu Dong et al. PrivC - A framework for efficient Secure Two-Party Computation. In Proc. of SecureComm 2019

[6]. Martín Abadi, Andy Chu, Ian Goodfellow, H. Brendan McMahan, Ilya Mironov, Kunal Talwar, Li Zhang. Deep Learning with Differential Privacy. 2016

[7]. Virginia Smith, Chao-Kai Chiang, Maziar Sanjabi, Ameet Talwalkar. Federated Multi-Task Learning 2016

[8]. Yang Liu, Tianjian Chen, Qiang Yang. Secure Federated Transfer Learning. 2018

[9]. Balázs Hidasi, Alexandros Karatzoglou, Linas Baltrunas, Domonkos Tikk. Session-based Recommendations with Recurrent Neural Networks. 2016

[11]. Payman Mohassel and Peter Rindal. ABY3: A Mixed Protocol Framework for Machine Learning. In Proc. of CCS 2018

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