Lounge<C++>

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04:40

The vaccine stuff seems pretty simple. But if you take a closer look at the data, it's still simple, but bigger. And slightly blurry. Might need reading glasses.

Mikhail

05:13

LandonZeKepitelOfGreytBritn

06:22

only partially true… as a native French speaker even I didn’t notice it before your post here. Never noticed because the spelling is different and because people dont pronounce it the same way either.
Frankly speaking our pronounciation is like saying “pussy (female genitalia), I farted”

Not saying this is much better though…

LandonZeKepitelOfGreytBritn

08:22

@Mgetz hmm, seems like I misunderstood the article's premise. They seem to have created a novel software based virtualization technique and actually did not write a hypervisor

meaning the whole scheduling and memory management stuff that is needed for all the virtualized environments has not been investigated. They "merely" provide a security that ensures a malicious piece of code cannot do any harm

LandonZeKepitelOfGreytBritn

10:59

@Mgetz mmu emulation

If you manage to do that, I think it should be doable. but it has to be done in some kind of optimal way

qemu manages to do it, so technically it must be feasible

Mgetz

13:38

@LandonZeKepitelOfGreytBritn that's been doable for ages, but the performance is generally complete garbage because you can't run the code natively on the processor. You have to emulate the CPU

LandonZeKepitelOfGreytBritn

@Mgetz I think you re mistaken here. There is no emulation involved in that article. Long story short, they moved their virtualization code to another part of memory which gives them more guarantees

Mgetz

while technically plausible.... you can't run privileged code that way. You can only run protected mode. Privileged code would try to access resources and registers that aren't allowed. Again you need an MMU to support protected mode anyway

LandonZeKepitelOfGreytBritn

@Mgetz in this particular case it s an 8 bit mcu. no such thing as privileged mode

Mgetz

then I call BS. Without some way to enforce memory protections that's implausible

you need at a minimum some way to isolate segments

LandonZeKepitelOfGreytBritn

@Mgetz have you even read the article's abstract? :p

I guess not :p

Mgetz

13:44

no because for security reasons I don't visit .ru domains

LandonZeKepitelOfGreytBritn

oh, fair enough

let me copy paste the abstract

Mgetz

or .cn

LandonZeKepitelOfGreytBritn

it s because it s an IEEE article which requires you to have an account

abstract:

Abstract—The Internet of Things (IoT) is shaped by the increasing number of low-cost Internet-connected embedded devices that are
becoming ubiquitous in every aspect of modern life. With their cost-sensitive design, integrating hardware-based security mechanisms
into such devices is undesirable. Therefore, securing these devices is a particularly difficult challenge, especially, due to their growing
popularity as attack targets, via remote malware infestations. The vast majority of such devices are bare-metal, where they execute

long story short:

Mgetz

TLDR they scan the binary and hope it doesn't self modify which 8bit code tends to do all the damn time because of space constraints

that's dumb as hell

LandonZeKepitelOfGreytBritn

No there s more to it

wait...

Mgetz

13:47

maybe AVR requires code to be in ROM? but meh

but software virtualization is CPU emulation FWIW

so... slow as hell

LandonZeKepitelOfGreytBritn

TLDR; they are using an 8 bit mcu with a modified harvard architecture allowing them to put their virtualization software inside the bootloader segment inside the instruction memory as well as the virtualization code's data.

Mgetz

that said I don't understand why this is really necessary?

LandonZeKepitelOfGreytBritn

here is +/- the applicable paragraph out of the entire article

Due to the modified Harvard architecture of the AVR, we can simplify our approach to only
protect instruction memory, while data memory operations
remain unmodified and unrestricted. Hence, SmV data is
placed alongside SmV code in instruction memory, which is
permitted by the modified Harvard architecture. The application is not allowed to read the SmV code or data from the
instruction memory, and is only permitted to jump to itself
or select SmV entry points. These restrictions on the instruction memory, in addition to the fact that data memory is not

don't know whether the above exerpt just like that makes a lot of sense to you

Mgetz

right harvard architecture.. yeah that would give them some guarantee... but still the entire thing seems completely pointless and slow. All the code would have to do to escape this is run some cute indirect jumping bs

LandonZeKepitelOfGreytBritn

nope... :p

they have a solution for that

but I must admit I am not a fan of it

wait let me try to find it

here:

Most control transfer instructions, such as programcounter relative branches and calls, have their target
address encoded in the instruction and can be checked statically by the verifier at load time. Store operations to static
variables also use an immediate addressing mode and can
be checked by the verifier. Any instruction of this type that
has an illegal memory address as static argument is
detected, resulting in rejecting the application by the verifier
and canceling its deployment. Applications that contain

(they have their own modified toolchain or smth along those lines)

Mgetz

13:54

that might work for AVR... but again, why?

LandonZeKepitelOfGreytBritn

because you want some sort of cybersecurity measure on low-end mcu s that don't have needed hardware features

Mgetz

if you need hypervisor capability run one of the millions of ARMv7A cores that ship with the virtualization extensions

and cost nothing?

LandonZeKepitelOfGreytBritn

I agree on that

those features are going to become more and more ubiquitous imo

Mgetz

@LandonZeKepitelOfGreytBritn except if you're running an 8bit MCU you're probably not accessing the internet? Even IOT lightbulbs usually run some variant of an ESP32

LandonZeKepitelOfGreytBritn

fair point

Mgetz

13:56

the entire point of using AVR parts is that in the millions it's cheaper. But at the smaller level it's usually not. Usually AVR parts are the building blocks of larger things elsewhere

LandonZeKepitelOfGreytBritn

They have done this for security reasons. So what s the cutting edge research like for cybersecurity in hypervisors in that case?

Is chain of trust and secure booting really the furthest we have gotten as of today?

because to me, afaik, these two things have been around for quite a while now

Mgetz

@LandonZeKepitelOfGreytBritn not sure how to answer this usually this is solved by minimizing surface area and then using write once controllers? If the firmware needs to be updated then usually encrypted and signed binary blobs are used IIRC

LandonZeKepitelOfGreytBritn

have seen some stuff about using trusted execution environments inside hypervisors as well. But yhea, that's boring. As mentioned a couple of days ago, those researchers only write a publication explaining how they managed to write or implement a driver...

@Mgetz well yhea, that's nothing new afaik. that would mean that there has been not much of a progress in that field

Mgetz

There has also been research into signed code segments that are hardware verified

So basically the OS has a special trap where it either supplies or sets the key for drivers to be signed with. Any driver not signed with that key just won't load. Any modification to the segment is also a fault

LandonZeKepitelOfGreytBritn

that's just signing a binary with some extra steps, ie signing every segment individually. boring...

Mgetz

14:02

@LandonZeKepitelOfGreytBritn but do we need progress? If something needs to do one thing and one thing well... then it's fine

where you get into an issue is MCUs that need their firmware updated

but those don't tend to be MCUs in the traditional sense at all

LandonZeKepitelOfGreytBritn

@Mgetz you make it sound as if cybersecurity is a dead end research field

which hurts my feelings

Mgetz

its not, what I'm saying is that the use case for 8bit MCUs doing virtualization is... not really there IMO

LandonZeKepitelOfGreytBritn

I know some people in this chat who would applaud that statement, wrt dead-end

Mgetz

even 16bit MCUs which do tend to have MMUs I'm not sure it's worth it

LandonZeKepitelOfGreytBritn

well what if you'd use a more convoluted embedded system?

Mgetz

14:05

FWIW the cost of 32bit MCUs has dropped so much I'm actually worried people will stop making 8bit and 16bit MCUs

LandonZeKepitelOfGreytBritn

afaik the answer remains the same: blob signature, with some additional steps if you want

Mgetz

well more complicated MCU mo problems

LandonZeKepitelOfGreytBritn

dunno... the underlying mechanism remains the same

signature is still being used

unless a whole new cybersec world suddenly opens up, which I am not aware of as of right now

Mgetz

well consider that a signature isn't needed if you're using a write once MCU

the fuse prevents that from being an issue

most write once MCUs are strict Harvard anyway

LandonZeKepitelOfGreytBritn

@Mgetz what research do the cool kids do nowadays in that case?

and don't speak to me about blockchain...

it's as if every university tries to push AI/ML and blockchain technology into everything they touch

Mgetz

14:12

IOT is a thing but also sidechannels

LandonZeKepitelOfGreytBritn

@Mgetz most iot security issues could be solved with write once mcu s, apparently

Mgetz

not always

protocols, communications, sidebands etc.

a write once MCU can't be fixed if it has for example a bad TLSv3 implementation

or doesn't have one

LandonZeKepitelOfGreytBritn

the problem with attacks at the protocol level is that very often you cannot know what kind of payload an application is expecting. Like I mentioned here:

2 days ago, by LandonZeKepitelOfGreytBritn

They do give some partial answer to what I mentioned above, ie wrt datagrams' payloads etc, But IMO the router's antivirus has actually now way of knowing what payload the receiving application is expecting and thus what is ok or really malicious

Mgetz

@LandonZeKepitelOfGreytBritn it's actually easier than you think, protocols are very defined so you just gather enough data and you can sideband it

I'm waiting for the first credit card skimmer that someone just places under the cash register at a fast food place

that said... credit card companies are getting wiser to that and are shielding their stuff better

LandonZeKepitelOfGreytBritn

@Mgetz Not sure why you think it is that easy. Could you clarify? I really believe that figuring out there is an "attack" somehow is not that easy at all

Mgetz

14:24

@LandonZeKepitelOfGreytBritn figuring out there is an attack isn't easy, which is why researchers try to find novel ones and publish papers. Because the bad guys don't

Generally you find out about attack in the wild when someone finds the thing doing the attack

much like "The thing"

things like data exfiltration via fan controller ;p

LandonZeKepitelOfGreytBritn

Yhea, what I thought... WHich is why I was surprized that you mentioned it would be easier than I think to identify an attack at the protocol level

Mgetz

well protocols can make it easier to attack

look no further than the evolution of TLS

if I'm sending commands, say to lightbulbs... they are going to be the same commands all the time. So if my protocol isn't careful someone can figure out which command is being sent. That then could identify who is in the house, or where they are, or both

that information could be safety critical in some cases

LandonZeKepitelOfGreytBritn

@Mgetz as can any form of input... It's just far from being easy to differentiate a legitimate action from an attack. Unless you just try to detect a predetermined series of attacks

Mgetz

well this is why protocols these days do their best to obfuscate what's actually happening, so command A and command B are hard to differentiate

LandonZeKepitelOfGreytBritn

Maybe I am too stupid to figure these things out :p

Just look at that guy:

GOD MODE UNLOCKED - Hardware Backdoors in x86 CPUs

►

wrote 35 lines of Assembly inside main, bypassed all security and became root

Yhea Christopher Domas, that was his name

Christopher Domas (xoreaxeaxeax) leads the Core Client and BIOS/UEFI offensive security research teams at Intel. His specializations are reverse engineering, processor exploitation, and automated firmware analysis.

I am wondering what a working day would look like for that guy. What concretely is he doing research on. It struck me that he in some sense stated that not all of his research is public

Feeds

22:12

Standard C++ | Articles & Books: AddressSanitizer continue_on_error -- Jim Radigan

posted on July 25, 2023 by Blog Staff

Visual Studio 17.6 comes with new functionality in the Address Sanitizer runtime which provides a new “checked build” for C and C++. This new runtime mode diagnoses and reports hidden memory safety errors, with zero false positives, as your app runs. AddressSanitizer continue_on_error by Jim Radigan From the article: C++ memory safety errors are a …

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