Tiago Perez

Tiago Perez, Samuel Pagliarini

Owning a high-end semiconductor foundry is a luxury very few companies can afford. Thus, fabless design companies outsource integrated circuit fabrication to third parties. Within foundries, rogue elements may gain access to the customer's layout and perform malicious acts, including the insertion of a hardware trojan (HT). Many works focus on the structure/effects of a HT, while very few have demonstrated the viability of their HTs in silicon. Even fewer disclose how HTs are inserted or the time required for this activity. Our work details, for the first time, how effortlessly a HT can be inserted into a finalized layout by presenting an insertion framework based on the engineering change order flow. For validation, we have built an ASIC prototype in 65nm CMOS technology comprising of four trojaned cryptocores. A side-channel HT is inserted in each core with the intent of leaking the cryptokey over a power channel. Moreover, we have determined that the entire attack can be mounted in a little over one hour. We also show that the attack was successful for all tested samples. Finally, our measurements demonstrate the robustness of our SCT against skews in the manufacturing process.

Tiago Perez, Malik Imran, Pablo Vaz et al.

Design companies often outsource their integrated circuit (IC) fabrication to third parties where ICs are susceptible to malicious acts such as the insertion of a side-channel hardware trojan horse (SCT). In this paper, we present a framework for designing and inserting an SCT based on an engineering change order (ECO) flow, which makes it the first to disclose how effortlessly a trojan can be inserted into an IC. The trojan is designed with the goal of leaking multiple bits per power signature reading. Our findings and results show that a rogue element within a foundry has, today, all means necessary for performing a foundry-side attack via ECO.