Cryptology ePrint Archive: Report 2014/925

Indistinguishability Obfuscation for Turing Machines with Unbounded Memory

Venkata Koppula and Allison Bishop Lewko and Brent Waters

Abstract: We show how to build indistinguishability obfuscation (iO) for Turing Machines where the overhead is polynomial in the security parameter lambda, machine description |M| and input size |x| (with only a negligible correctness error). In particular, we avoid growing polynomially with the maximum space of a computation. Our construction is based on iO for circuits, one way functions and injective pseudo random generators.

Our results are based on new ''selective enforcement'' techniques. Here we first create a primitive called positional accumulators that allows for a small commitment to a much larger storage. The commitment is unconditionally sound for a select piece of the storage. This primitive serves as an ''iO-friendly'' tool that allows us to make two different programs equivalent at different stages of a proof. The pieces of storage that are selected depend on what hybrid stage we are at in a proof.

We first build up our enforcement ideas in a simpler context of ''message hiding encodings'' and work our way up to indistinguishability obfuscation.

Category / Keywords:

Date: received 10 Nov 2014, last revised 2 Dec 2014

Contact author: kvenkata at cs utexas edu, alewko at cs columbia edu, bwaters at cs utexas edu

Available format(s): PDF | BibTeX Citation

Version: 20141202:101344 (All versions of this report)

Short URL:

[ Cryptology ePrint archive ]