TY - GEN
T1 - Additive and multiplicative notions of leakage, and their capacities
AU - Alvim, Mário S.
AU - Chatzikokolakis, Konstantinos
AU - McIver, Annabelle
AU - Morgan, Carroll
AU - Palamidessi, Catuscia
AU - Smith, Geoffrey
N1 - Publisher Copyright:
© 2014 IEEE.
PY - 2014/11/13
Y1 - 2014/11/13
N2 - Protecting sensitive information from improper disclosure is a fundamental security goal. It is complicated, and difficult to achieve, often because of unavoidable or even unpredictable operating conditions that can lead to breaches in planned security defences. An attractive approach is to frame the goal as a quantitative problem, and then to design methods that measure system vulnerabilities in terms of the amount of information they leak. A consequence is that the precise operating conditions, and assumptions about prior knowledge, can play a crucial role in assessing the severity of any measured vunerability. We develop this theme by concentrating on vulnerability measures that are robust in the sense of allowing general leakage bounds to be placed on a program, bounds that apply whatever its operating conditions and whatever the prior knowledge might be. In particular we propose a theory of channel capacity, generalising the Shannon capacity of information theory, that can apply both to additive- and to multiplicative forms of a recently-proposed measure known as g-leakage. Further, we explore the computational aspects of calculating these (new) capacities: one of these scenarios can be solved efficiently by expressing it as a Kantorovich distance, but another turns out to be NP-complete. We also find capacity bounds for arbitrary correlations with data not directly accessed by the channel, as in the scenario of Dalenius's Desideratum.
AB - Protecting sensitive information from improper disclosure is a fundamental security goal. It is complicated, and difficult to achieve, often because of unavoidable or even unpredictable operating conditions that can lead to breaches in planned security defences. An attractive approach is to frame the goal as a quantitative problem, and then to design methods that measure system vulnerabilities in terms of the amount of information they leak. A consequence is that the precise operating conditions, and assumptions about prior knowledge, can play a crucial role in assessing the severity of any measured vunerability. We develop this theme by concentrating on vulnerability measures that are robust in the sense of allowing general leakage bounds to be placed on a program, bounds that apply whatever its operating conditions and whatever the prior knowledge might be. In particular we propose a theory of channel capacity, generalising the Shannon capacity of information theory, that can apply both to additive- and to multiplicative forms of a recently-proposed measure known as g-leakage. Further, we explore the computational aspects of calculating these (new) capacities: one of these scenarios can be solved efficiently by expressing it as a Kantorovich distance, but another turns out to be NP-complete. We also find capacity bounds for arbitrary correlations with data not directly accessed by the channel, as in the scenario of Dalenius's Desideratum.
KW - Channel capacity
KW - Confidentiality
KW - Dalenius Desideratum
KW - Quantitative information flow
UR - https://www.scopus.com/pages/publications/84939601869
U2 - 10.1109/CSF.2014.29
DO - 10.1109/CSF.2014.29
M3 - Conference contribution
AN - SCOPUS:84939601869
T3 - Proceedings of the Computer Security Foundations Workshop
SP - 308
EP - 322
BT - Proceedings - 2014 IEEE 27th Computer Security Foundations Symposium, CSF 2014
PB - IEEE Computer Society
T2 - 27th IEEE Computer Security Foundations Symposium, CSF 2014
Y2 - 19 July 2014 through 22 July 2014
ER -