From: Daniel Micay Subject: Re: [kernel-hardening] Re: get_random_bytes returns bad randomness before seeding is complete Date: Sat, 3 Jun 2017 19:55:53 -0400 Message-ID: References: <20170602172616.47qcxav6adq52nmk@thunk.org> <20170602190734.6zll7zc5hr66oacl@thunk.org> <20170603050433.4xpvloul25s47f2z@thunk.org> Mime-Version: 1.0 Content-Type: text/plain; charset="UTF-8" Cc: Sandy Harris , "Jason A. Donenfeld" , "Theodore Ts'o" , Stephan Mueller , Linux Crypto Mailing List , LKML , Kernel Hardening To: Jeffrey Walton Return-path: Received: from mail-yb0-f195.google.com ([209.85.213.195]:35940 "EHLO mail-yb0-f195.google.com" rhost-flags-OK-OK-OK-OK) by vger.kernel.org with ESMTP id S1751077AbdFCXzz (ORCPT ); Sat, 3 Jun 2017 19:55:55 -0400 In-Reply-To: Sender: linux-crypto-owner@vger.kernel.org List-ID: On 3 June 2017 at 18:54, Jeffrey Walton wrote: > On Sat, Jun 3, 2017 at 5:45 PM, Sandy Harris wrote: >> ... >> Of course this will fail on systems with no high-res timer. Are there >> still some of those? It might be done in about 1000 times as long on a >> system that lacks the realtime library's nanosecond timer but has the >> Posix standard microsecond timer, implying a delay time in the >> milliseconds. Would that be acceptable in those cases? > > A significant portion of the use cases should include mobile devices. > Device sales outnumbered desktop and server sales several years ago. > > Many devices are sensor rich. Even the low-end ones come with > accelorometers for gaming. A typical one has 3 or 4 sensors, and > higher-end ones have 7 or 8 sensors. An Evo 4G has 7 of them. > > There's no wanting for entropy in many of the use cases. The thing > that is lacking seems to be taking advantage of it. > > Jeff Hardware random number generator support is also standard on even low-end mobile devices. The Linux kernel now knows to feed some of the entropy from those hardware random generators into the kernel CSPRNG when the driver is initialized but that doesn't happen until fairly late in the kernel's boot process. The sensors present the same issue. They aren't available when the kernel starts needing entropy for features like SSP and KASLR or other early boot uses, unlike RDRAND/RDSEED on modern x86_64 CPUs. For userspace, Android's init system blocks until a certain amount of entropy is obtained from one for the kernel CSPRNG. It's possible for there to be no hwrandom but I think that's very rare now since the standard SoCs used everywhere have it available. The device vendor would probably need to go out of the way to break it. Android also regularly saves a persistent random seed and restores it on boot. It also mixes in entropy from the hardware generator regularly since the kernel didn't know how to do that before, just like it didn't know how to grab any initial entropy from the hardware generator. I don't think it's worth worrying too much about mobile. Slimmer embedded devices that probably don't even save / restore a seed in many cases or generate keys on first boot before that helps are the real issue. At least if you're not focused on KASLR and other early probabilistic kernel exploit mitigations where there's a lack of a way to get entropy in early boot right now unless the bootloader helps.