Trivium is a synchronous stream cipher designed to provide a flexible trade-off between speed and gate count in hardware, and reasonably efficient software implementation. Trivium was submitted to the Profile II of the eSTREAM competition by its authors, Christophe De Cannière and Bart Preneel, and has been selected as part of the portfolio for low area hardware ciphers by the eSTREAM project. It is not patented and has been specified as an International Standard under ISO/IEC 29192-3. It generates up to 264 bits of output from an 80-bit key and an 80-bit IV. It is the simplest eSTREAM entrant; while it shows remarkable resistance to cryptanalysis for its simplicity and performance, recent attacks leave the security margin looking rather slim.
Description
Trivium's 288-bit internal state consists of three shift registers of different lengths. At each round, a bit is shifted into each of the three shift registers using a non-linear combination of taps from that and one other register; one bit of output is produced. To initialize the cipher, the key and IV are written into two of the shift registers, with the remaining bits starting in a fixed pattern; the cipher state is then updated 4 × 288 = 1152 times, so that every bit of the internal state depends on every bit of the key and of the IV in a complex nonlinear way. No taps appear on the first 65 bits of each shift register, so each novel state bit is not used until at least 65 rounds after it is generated. This is the key to Trivium's software performance and flexibility in hardware.
Specification
Trivium may be specified very concisely using three recursive equations. Each variable is an element ofGF; they can be represented as bits, with "+" being XOR and "•" being AND.
ai = ci−66 + ci−111 + ci−110 • ci−109 + ai−69
bi = ai−66 + ai−93 + ai−92 • ai−91 + bi−78
ci = bi−69 + bi−84 + bi−83 • bi−82 + ci−87
The output bits r0... r264−1 are then generated by
Given an 80-bit key k0... k79 and an l-bit IV v0... vl−1, Trivium is initialized as follows:
=
=
=
The large negative indices on the initial values reflect the 1152 steps that must take place before output is produced. To map a stream of bits r to a stream of bytes R, we use the little-endian mapping Ri = Σj=0... 7 2jr8i+j.
Performance
A straightforward hardware implementation of Trivium would use 3488 logic gates and produce one bit per clock cycle. However, because each state bit is not used for at least 64 rounds, 64 state bits can be generated in parallel at a slightly greater hardware cost of 5504 gates. Different tradeoffs between speed and area are also possible. The same property allows an efficient bitslice implementation in software; performance testing by eSTREAM give bulk encryption speeds of around 4 cycles/byte on some x86 platforms, which compares well to the 19 cycles/byte of the AESreference implementation on the same platform.
Security
, no cryptanalytic attacks better than brute-force attack are known, but several attacks come close. The cube attack requires 268 steps to break a variant of Trivium where the number of initialization rounds is reduced to 799. Previously other authors speculate that these techniques could lead to a break for 1100 initialisation rounds, or "maybe even the original cipher". This builds on an attack due to Michael Vielhaber that breaks 576 initialization rounds in only 212.3 steps. Another attack recovers the internal state of the full cipher in around 289.5 steps. Reduced variants of Trivium using the same design principles have been broken using an equation-solving technique. These attacks improve on the well-known time-space tradeoff attack on stream ciphers, which with Trivium's 288-bit internal state would take 2144 steps, and show that a variant on Trivium which made no change except to increase the key length beyond the 80 bits mandated by eSTREAM Profile 2 would not be secure. Using optimised solving strategy, it is further possible to reduce the state-recovery complexity to 2132 steps. A detailed justification of the design of Trivium is given in.