M. Beunardeau, Aisling Connolly, R. Géraud, D. Naccache
{"title":"The Case for System Command Encryption","authors":"M. Beunardeau, Aisling Connolly, R. Géraud, D. Naccache","doi":"10.1145/3052973.3056129","DOIUrl":null,"url":null,"abstract":"In several popular standards (e.g. ISO 7816, ISO 14443 or ISO 11898) and IoT applications, a node (transponder, terminal) sends commands and data to another node (transponder, card) to accomplish an applicative task (e.g. a payment or a measurement). Most standards encrypt and authenticate the data. However, as an application of Kerckhoffs' principle, system designers usually consider that commands are part of the system specifications and must hence be transmitted in clear while the data that these commands process is encrypted and signed. While this assumption holds in systems representable by relatively simple state machines, leaking command information is undesirable when the addressed nodes offer the caller a large \"toolbox\" of commands that the addressing node can activate in many different orders to accomplish different applicative goals. This work proposes protections allowing encrypting and protecting not only the data but also the commands associated to them. The practical implementation of this idea raises a number of difficulties. The first is that of defining a clear adversarial model, a question that we will not address in this paper. The difficulty comes from the application-specific nature of the harm that may possibly stem from leaking the command sequence as well as from the modeling of the observations that the attacker has on the target node's behavior (is a transaction accepted? is a door opened? is a packet routed etc). This paper proposes a collection of empirical protection techniques allowing the sender to hide the sequence of commands sent. We discuss the advantages and the shortcomings of each proposed method. Besides the evident use of nonces (or other internal system states) to render the encryption of identical commands different in time, we also discuss the introduction of random delays between commands (to avoid inferring the next command based on the time elapsed since the previous command), the splitting of a command followed by n data bytes into a collection of encrypted sub-commands conveying the n bytes in chunks of random sizes and the appending of a random number of useless bytes to each packet. Independent commands can be permuted in time or sent ahead of time and buffered. Another practically useful countermeasure consists in masking the number of commands by adding useless \"null\" command packets. In its best implementation, the flow of commands is sent in packets in which, at times, the sending node addresses several data and command chunks belonging to different successive commands in the sequence.","PeriodicalId":20540,"journal":{"name":"Proceedings of the 2017 ACM on Asia Conference on Computer and Communications Security","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2017-04-02","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"2","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Proceedings of the 2017 ACM on Asia Conference on Computer and Communications Security","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1145/3052973.3056129","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 2
Abstract
In several popular standards (e.g. ISO 7816, ISO 14443 or ISO 11898) and IoT applications, a node (transponder, terminal) sends commands and data to another node (transponder, card) to accomplish an applicative task (e.g. a payment or a measurement). Most standards encrypt and authenticate the data. However, as an application of Kerckhoffs' principle, system designers usually consider that commands are part of the system specifications and must hence be transmitted in clear while the data that these commands process is encrypted and signed. While this assumption holds in systems representable by relatively simple state machines, leaking command information is undesirable when the addressed nodes offer the caller a large "toolbox" of commands that the addressing node can activate in many different orders to accomplish different applicative goals. This work proposes protections allowing encrypting and protecting not only the data but also the commands associated to them. The practical implementation of this idea raises a number of difficulties. The first is that of defining a clear adversarial model, a question that we will not address in this paper. The difficulty comes from the application-specific nature of the harm that may possibly stem from leaking the command sequence as well as from the modeling of the observations that the attacker has on the target node's behavior (is a transaction accepted? is a door opened? is a packet routed etc). This paper proposes a collection of empirical protection techniques allowing the sender to hide the sequence of commands sent. We discuss the advantages and the shortcomings of each proposed method. Besides the evident use of nonces (or other internal system states) to render the encryption of identical commands different in time, we also discuss the introduction of random delays between commands (to avoid inferring the next command based on the time elapsed since the previous command), the splitting of a command followed by n data bytes into a collection of encrypted sub-commands conveying the n bytes in chunks of random sizes and the appending of a random number of useless bytes to each packet. Independent commands can be permuted in time or sent ahead of time and buffered. Another practically useful countermeasure consists in masking the number of commands by adding useless "null" command packets. In its best implementation, the flow of commands is sent in packets in which, at times, the sending node addresses several data and command chunks belonging to different successive commands in the sequence.
在一些流行的标准(例如ISO 7816, ISO 14443或ISO 11898)和物联网应用中,节点(转发器,终端)向另一个节点(转发器,卡)发送命令和数据以完成应用任务(例如支付或测量)。大多数标准对数据进行加密和身份验证。然而,作为Kerckhoffs原理的应用,系统设计者通常认为命令是系统规范的一部分,因此必须明确传输,而这些命令处理的数据是加密和签名的。虽然这种假设在可以用相对简单的状态机表示的系统中成立,但是当寻址节点为调用者提供大量命令“工具箱”时,命令信息泄漏是不希望出现的,寻址节点可以以许多不同的顺序激活这些命令以实现不同的应用程序目标。这项工作提出的保护措施不仅允许加密和保护数据,还允许加密和保护与数据相关的命令。这一想法的实际实施提出了一些困难。首先是定义一个明确的对抗性模型,这是我们在本文中不会讨论的问题。困难来自于特定于应用程序的危害,这种危害可能源于命令序列的泄露,以及攻击者对目标节点行为的观察的建模(是否接受事务?有门开着吗?是一个数据包路由等)。本文提出了一套经验保护技术,允许发送方隐藏发送的命令序列。我们讨论了每种方法的优点和缺点。除了明显使用nonce(或其他内部系统状态)使相同命令的加密在时间上不同之外,我们还讨论了命令之间引入的随机延迟(以避免根据自上一个命令以来经过的时间来推断下一个命令)。将后跟n个数据字节的命令拆分为加密的子命令集合,以随机大小的块传输n个字节,并向每个数据包附加随机数量的无用字节。独立的命令可以及时排列,也可以提前发送并进行缓冲。另一个实际有用的对策是通过添加无用的“null”命令包来掩盖命令的数量。在其最佳实现中,命令流以数据包的形式发送,在数据包中,发送节点有时会处理序列中属于不同连续命令的几个数据和命令块。