Your search keyword '"Noah M. Johnson"' showing total 2 results

1. Chorus: a Programming Framework for Building Scalable Differential Privacy Mechanisms

Author

Joseph P. Near, Dawn Song, Joseph M. Hellerstein, and Noah M. Johnson

Subjects

FOS: Computer and information sciences, Computer Science - Cryptography and Security, biology, Mechanism (biology), Computer science, Distributed computing, Chorus, 020207 software engineering, 02 engineering and technology, biology.organism_classification, computer.software_genre, Software framework, Scalability, 0202 electrical engineering, electronic engineering, information engineering, Differential privacy, 020201 artificial intelligence & image processing, Statistical analysis, Cryptography and Security (cs.CR), Implementation, computer

Abstract

Differential privacy is fast becoming the gold standard in enabling statistical analysis of data while protecting the privacy of individuals. However, practical use of differential privacy still lags behind research progress because research prototypes cannot satisfy the scalability requirements of production deployments. To address this challenge, we present Chorus, a framework for building scalable differential privacy mechanisms which is based on cooperation between the mechanism itself and a high-performance production database management system (DBMS). We demonstrate the use of Chorus to build the first highly scalable implementations of complex mechanisms like Weighted PINQ, MWEM, and the matrix mechanism. We report on our experience deploying Chorus at Uber, and evaluate its scalability on real-world queries.

Published

2020

2. Differential Slicing: Identifying Causal Execution Differences for Security Applications

Author

Noah M. Johnson, Pongsin Poosankam, Stephen McCamant, Dawn Song, Juan Caballero, Kevin Zhijie Chen, and Daniel Reynaud

Subjects

Computer science, Vulnerability assessment, Vulnerability, Program slicing, Malware, Data mining, computer.software_genre, computer, Slicing

Abstract

A security analyst often needs to understand two runs of the same program that exhibit a difference in program state or output. This is important, for example, for vulnerability analysis, as well as for analyzing a malware program that features different behaviors when run in different environments. In this paper we propose a differential slicing approach that automates the analysis of such execution differences. Differential slicing outputs a causal difference graph that captures the input differences that triggered the observed difference and the causal path of differences that led from those input differences to the observed difference. The analyst uses the graph to quickly understand the observed difference. We implement differential slicing and evaluate it on the analysis of 11 real-world vulnerabilities and 2 malware samples with environment-dependent behaviors. We also evaluate it in an informal user study with two vulnerability analysts. Our results show that differential slicing successfully identifies the input differences that caused the observed difference and that the causal difference graph significantly reduces the amount of time and effort required for an analyst to understand the observed difference.

Published

2011