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Cloud-based streaming company StreamElements confirms it suffered a data breach at a third-party service provider after a threat actor leaked samples of stolen data on a hacking forum. [...]

US Department of Government Efficiency tech advisor Edward Coristine previously ran a small infrastructure provider that offered services to a cybercriminal group, it has been alleged.

While in high school in 2022 the then-16-year-old DOGE senior advisor ran a company called DiamondCDN that supported a website used by a cybercriminal group named ‘EGodly’, Reuters reported Wednesday.

The connection between DiamondCDN and EGodly was established through digital records preserved by threat intelligence company DomainTools and online cybersecurity tool Any.Run, the Reuters report said.

It’s not clear that Coristine was aware of EGodly’s activity but in early 2023 the group thanked the company on Telegram for helping to keep its dataleak.fun website up and running:

“We extend our gratitude to our valued partners DiamondCDN for generously providing us with their amazing DDoS protection and caching systems, which allow us to securely host and safeguard our website,” read the message.

Records seen by Reuters show this support ran from October 2022 to June 2023 and that users attempting to reach the dataleak.fun site would first have to pass a DiamondCDN anti-bot ‘security check.’

Breaking into law enforcement accounts

Crimes EGodly boasted it had carried out include cryptocurrency theft, phone number hijacking, and breaking into law enforcement email accounts, Reuters said. The group also circulated personal details of an FBI agent it believed was investigating it, and engaged in swatting, the practice of calling armed police to a target’s house on false pretenses as a form of intimidation.

This is not the first time Coristine’s past has been questioned. In February Bloomberg reported that he was fired in 2022 by cybersecurity company Path Network for allegedly “leaking proprietary information.” Separately, it has been reported that Coristine was associated with a Telegram/Discord cybercriminal social network called ‘The Com.’

However, for now, the allegations against him are just that — allegations. He has not commented on any of them.

None of this would hold wider significance if Coristine, now 19 years old, wasn’t one of DOGE’s super-nerds. His celebrity has also been bolstered by DOGE booster Elon Musk himself, who in February tweeted on X that “Big Balls is awesome,” a reference to his vulgar nickname in high school.

Meanwhile, Coristine has access as part of his job to some of the most confidential servers in the US government, including ones that normally require a high level of security clearance.

It’s a reminder that every job candidate should be carefully vetted, said cybersecurity expert Graham Cluley.

“When you hire someone for a job, you’re wise to take a look at what they’ve done in the past. It gives you an idea of both their achievements, as well as, potentially, anything they might have got up to which would help shine light on their judgement, their ethics, and how they might perform in the role,” Cluley said by email.

A new cybercrime platform named 'Atlantis AIO' provides an automated credential stuffing service against 140 online platforms, including email services, e-commerce sites, banks, and VPNs. [...]

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An analysis of the NSO BLASTPASS iMessage exploit

Posted by Ian Beer, Google Project Zero

On September 7, 2023 Apple issued an out-of-band security update for iOS:

Around the same time on September 7th 2023, Citizen Lab published a blog post linking the two CVEs fixed in iOS 16.6.1 to an "NSO Group Zero-Click, Zero-Day exploit captured in the wild":

"[The target was] an individual employed by a Washington DC-based civil society organization with international offices...

The exploit chain was capable of compromising iPhones running the latest version of iOS (16.6) without any interaction from the victim.

The exploit involved PassKit attachments containing malicious images sent from an attacker iMessage account to the victim."

The day before, on September 6th 2023, Apple reported a vulnerability to the WebP project, indicating in the report that they planned to ship a custom fix for Apple customers the next day.

The WebP team posted their first proposed fix in the public git repo the next day, and five days after that on September 12th Google released a new Chrome stable release containing the WebP fix. Both Apple and Google marked the issue as exploited in the wild, alerting other integrators of WebP that they should rapidly integrate the fix as well as causing the security research community to take a closer look...

A couple of weeks later on September 21st 2023, former Project Zero team lead Ben Hawkes (in collaboration with @mistymntncop) published the first detailed writeup of the root cause of the vulnerability on the Isosceles Blog. A couple of months later, on November 3rd, a group called Dark Navy published their first blog post: a two-part analysis (Part 1 - Part 2) of the WebP vulnerability and a proof-of-concept exploit targeting Chrome (CVE-2023-4863).

 

Whilst the Isosceles and Dark Navy posts explained the underlying memory corruption vulnerability in great detail, they were unable to solve another fascinating part of the puzzle: just how exactly do you land an exploit for this vulnerability in a one-shot, zero-click setup? As we'll soon see, the corruption primitive is very limited. Without access to the samples it was almost impossible to know.

In mid-November, in collaboration with Amnesty International Security Lab, I was able to obtain a number of BLASTPASS PKPass sample files as well as crash logs from failed exploit attempts.

This blog post covers my analysis of those samples and the journey to figure out how one of NSO's recent zero-click iOS exploits really worked. For me that journey began by immediately taking three months of paternity leave, and resumed in March 2024 where this story begins:

Setting the scene

For a detailed analysis of the root-cause of the WebP vulnerability and the primitive it yields, I recommend first reading the three blog posts I mentioned earlier (Isosceles, Dark Navy 1, Dark Navy 2.) I won't restate their analyses here (both because you should read their original work, and because it's quite complicated!) Instead I'll briefly discuss WebP and the corruption primitive the vulnerability yields.

WebP

WebP is a relatively modern image file format, first released in 2010. In reality WebP is actually two completely distinct image formats: a lossy format based on the VP8 video codec and a separate lossless format. The two formats share nothing apart from both using a RIFF container and the string WEBP for the first chunk name. From that point on (12 bytes into the file) they are completely different. The vulnerability is in the lossless format, with the RIFF chunk name VP8L.

Lossless WebP makes extensive use of Huffman coding; there are at least 10 huffman trees present in the BLASTPASS sample. In the file they're stored as canonical huffman trees, meaning that only the code lengths are retained. At decompression time those lengths are converted directly into a two-level huffman decoding table, with the five largest tables all getting squeezed together into the same pre-allocated buffer. The (it turns out not quite) maximum size of these tables is pre-computed based on the number of symbols they encode. If you're up to this part and you're slightly lost, the other three blogposts referenced above explain this in detail.

With control over the symbol lengths it's possible to define all sorts of strange trees, many of which aren't valid. The fundamental issue was that the WebP code only checked the validity of the tree after building the decoding table. But the pre-computed size of the decoding table was only correct for valid trees.

As the Isosceles blog post points out, this means that a fundamental part of the vulnerability is that triggering the bug is detected, though after memory has been corrupted, and image parsing stops only a few lines of code later. This presents another exploitation mystery: in a zero-click context, how do you exploit a bug where every time the issue is triggered it also stops parsing any attacker-controlled data?

The second mystery involves the actual corruption primitive. The vulnerability will write a HuffmanCode structure at a known offset past the end of the huffman tables buffer:

// Huffman lookup table entry

typedef struct {

  uint8_t bits;

  uint16_t value;

} HuffmanCode;

As DarkNavy point out, whilst the bits and value fields are nominally attacker-controlled, in reality there isn't that much flexibility. The fifth huffman table (the one at the end of the preallocated buffer, part of which can get written out-of-bounds) only has 40 symbols, limiting value to a maximum value of 39 (0x27) and bits will be between 1 and 7 (for a second-level table entry). There's a padding byte between bits and value which makes the largest value that could be written out-of-bounds 0x00270007. And it just so happens that that's exactly the value which the exploit does write — and they likely didn't have that much choice about it.

There's also not much flexibility in the huffman table allocation size. The table allocation in the exploit is 12072 (0x2F28) bytes, which will get rounded up to fit within a 0x3000 byte libmalloc small region. The code lengths are chosen such that the overflow occurs like this:

To summarize: The 32-bit value 0x270007 will be written 0x58 bytes past the end of a 0x3000 byte huffman table allocation. And then WebP parsing will fail, and the decoder will bail out.

Déjà vu?

Long-term readers of the Project Zero blog might be experiencing a sense of déjà vu at this point... haven't I already written a blog post about an NSO zero-click iPhone zero day exploiting a vulnerability in a slightly obscure lossless compression format used in an image parsed from an iMessage attachment?

Indeed.

BLASTPASS has many similarities with FORCEDENTRY, and my initial hunch (which turned out to be completely wrong) was that this exploit might take a similar approach to build a weird machine using some fancier WebP features. To that end I started out by writing a WebP parser to see what features were actually used.

Transformation

In a very similar fashion to JBIG2, WebP also supports invertible transformations on the input pixel data:

My initial theory was that the exploit might operate in a similar fashion to FORCEDENTRY and apply sequences of these transformations outside of the bounds of the image buffer to build a weird machine. But after implementing enough of the WebP format in python to parse every bit of the VP8L chunk it became pretty clear that it was only triggering the Huffman table overflow and nothing more. The VP8L chunk was only 1052 bytes, and pretty much all of it was the 10 Huffman tables needed to trigger the overflow.

What's in a pass?

Although BLASTPASS is often referred to as an exploit for "the WebP vulnerability", the attackers don't actually just send a WebP file (even though that is supported in iMessage). They send a PassKit PKPass file, which contains a WebP. There must be a reason for this. So let's step back and actually take a look at one of the sample files I received:

171K sample.pkpass

$ file sample.pkpass

sample.pkpass: Zip archive data, at least v2.0 to extract, compression method=deflate

There are five files inside the PKPass zip archive:

60K  background.png

5.5M logo.png

175B manifest.json

18B  pass.json

3.3K signature

The 5.5MB logo.png is the WebP image, just with a .png extension instead of .webp:

$ file logo.png:

logo.png:         RIFF (little-endian) data, Web/P image

The closest thing to a specification for the PKPass format appears to be the Wallet Developer Guide, and whilst it doesn't explicitly state that the .png files should actually be Portable Network Graphics images, that's presumably the intention. This is yet another parallel with FORCEDENTRY, where a similar trick was used to reach the PDF parser when attempting to parse a GIF.

PKPass files require a valid signature which is contained in manifest.json and signature. The signature has a presumably fake name and more timestamps indicating that the PKPass is very likely being generated and signed on the fly for each exploit attempt.

pass.json is just this:

{"pass": "PKpass"}

Finally background.png:

$ file background.png

background.png: TIFF image data, big-endian, direntries=15, height=16, bps=0, compression=deflate, PhotometricIntepretation=RGB, orientation=upper-left, width=48

Curious. Another file with a misleading extension; this time a TIFF file with a .png extension.

We'll return to this TIFF later in the analysis as it plays a critical role in the exploit flow, but for now we'll focus on the WebP, with one short diversion:

Blastdoor

So far I've only mentioned the WebP vulnerability, but the Apple advisory I linked at the start of this post mentions two separate CVEs:

The first, CVE-2023-41064 in ImageIO, is the WebP bug (though just to keep things confusing with a different CVE from the upstream WebP fix which is CVE-2023-4863 - they're the same vulnerability though).

The second, CVE-2023-41061 in "Wallet", is described in the Apple advisory as: "A maliciously crafted attachment may result in arbitrary code execution".

The Isosceles blog post hypothesises:

"Citizen Lab called this attack "BLASTPASS", since the attackers found a clever way to bypass the "BlastDoor" iMessage sandbox. We don't have the full technical details, but it looks like by bundling an image exploit in a PassKit attachment, the malicious image would be processed in a different, unsandboxed process. This corresponds to the first CVE that Apple released, CVE-2023-41061."

This theory makes sense — FORCEDENTRY had a similar trick where the JBIG2 bug was actually exploited inside IMTranscoderAgent instead of the more restrictive sandbox of BlastDoor. But in all my experimentation, as well as all the in-the-wild crash logs I've seen, this hypothesis doesn't seem to hold.

The PKPass file and the images enclosed within do get parsed inside the BlastDoor sandbox and that's where the crashes occur or the payload executes — later on we'll also see evidence that the NSExpression payload which eventually gets evaluated expects to be running inside BlastDoor.

My guess is that CVE-2023-41061 is more likely referring to the lax parsing of PKPasses which didn't reject images which weren't png's.

In late 2024, I received another set of in-the-wild crash logs including two which do in fact strongly indicate that there was also a path to hit the WebP vulnerability in the MobileSMS process, outside the BlastDoor sandbox! Interestingly, the timestamps indicate that these devices were targeted in November 2023, two months after the vulnerability was patched.

In those cases the WebP code was reached inside the MobileSMS process via a ChatKit CKPassPreviewMediaObject created by a CKAttachmentMessagePartChatItem.

What's in a WebP?

I mentioned that the VP8L chunk in the WebP file is only around 1KB. Yet in the file listing above the WebP file is 5.5MB! So what's in the rest of it? Expanding out my WebP parser we see that there's one more RIFF chunk:

EXIF : 0x586bb8

exif is Intel byte alignment

EXIF has n_entries=1

tag=8769 fmt=4 n_components=1 data=1a

subIFD has n_entries=1

tag=927c fmt=7 n_components=586b8c data=2c

It's a (really really huge) EXIF - the standard format which cameras use to store image metadata — stuff like the camera model, exposure time, f-stop etc.

It's a tag-based format and pretty much all 5.5MB is inside one tag with the id 0x927c. So what's that?

Looking through an online list of EXIF tags just below the lens FocalLength tag and above the UserComment tag we spot 0x927c:

It's the very-vague-yet-fascinating sounding: "MakerNote - Manufacturer specific information."

Looking to Wikipedia for some clarification on what that actually is, we learn that

"the "MakerNote" tag contains information normally in a proprietary binary format."

Modifying the webp parser to now dump out the MakerNote tag we see:

$ file sample.makernote

sample.makernote: Apple binary property list

Apple's chosen format for the "proprietary binary format" is binary plist!

And indeed: looking through the ImageIO library in IDA there's a clear path between the WebP parser, the EXIF parser, the MakerNote parser and the binary plist parser.

unbplisting

I covered the binary plist format in a previous blog post. That was the second time I'd had to analyse a large bplist. The first time (for the FORCEDENTRY sandbox escape) it was possible mostly by hand, just using the human-readable output of plutil. Last year, for the Safari sandbox escape analysis, the bplist was 437KB and I had to write a custom bplist parser to figure out what was going on. Keeping the exponential curve going this year the bplist was 10x larger again.

In this case it's fairly clear that the bplist must be a heap groom - and at 5.5MB, presumably a fairly complicated one. So what's it doing?

Switching Views

I had a hunch that the bplist would use duplicate dictionary keys as a fundamental building block for the heap groom, but running my parser it didn't output any... until I realised that my tool stored the parsed dictionaries directly as python dictionaries before dumping them. Fixing the tools to instead keep lists of keys and values it became clear that there were duplicate keys. Lots of them:

In the Safari exploit writeup I described how I used different visualisation techniques to try to explore the structure of the objects, looking for patterns I could use to simplify what was going on. In this case, modifying the parser to emit well-formed curly brackets and indentation then relying on VS Code's automatic code-folding proved to work well enough for browsing around and getting a feel for the structure of the groom object.

Sometimes the right visualisation technique is sufficient to figure out what the exploit is trying to do. In this case, where the primitive is a heap-based buffer overflow, the groom will inevitably try to put two things next to each other in memory and I want to know "what two things?"

But no matter how long I stared and scrolled, I couldn't figure anything out. Time to try something different.

Instrumentation

I wrote a small helper to load the bplist using the same API as the MakerNote parser and ran it using the Mac Instruments app:

Parsing the single 5.5MB bplist causes nearly half a million allocations, churning through nearly a gigabyte of memory. Just looking through this allocation summary it's clear there's lots of CFString and CFData objects, likely used for heap shaping. Looking further down the list there are other interesting numbers:

The 20'000 in the last line is far too round a number to be a coincidence. This number matches up with the number of __NSDictionaryM objects allocated:

Finally, at the very bottom of the list there are two more allocation patterns which stand out:

There are two sets of very large allocations: eighty 1MB allocations and 44 4MB ones.

I modified my bplist tool again to dump out each unique string or data buffer, along with a count of how many times it was seen and its hash. Looking through the file listing there's a clear pattern:

Object Size

Count

0x3FFFFF

44

0xFFFFF

80

0x3FFF

20

0x26A9

24978

0x2554

44

0x23FF

5822

0x22A9

4

0x1FFF

2

0x1EA9

26

0x1D54

40

0x17FF

66

0x13FF

66

0x3FF

322

0x3D7

404

0xF

112882

0x8

3

There are a large number of allocations which fall just below a "round" number in hexadecimal: 0x3ff, 0x13ff, 0x17ff, 0x1fff, 0x23ff, 0x3fff... That heavily hints that they are sized to fall exactly within certain allocator size buckets.

Almost all of the allocations are just filled with zeros or 'A's. But the 1MB one is quite different:

$ hexdump -C 170ae757_80.bin | head -n 20

00000000  00 00 00 00 00 00 00 00  00 00 00 00 00 00 00 00  |................|

00000010  00 00 00 00 00 00 00 00  80 26 00 00 01 00 00 00  |.........&......|

00000020  1f 00 00 00 00 00 00 00  10 00 8b 56 02 00 00 00  |...........V....|

00000030  b0 c3 31 16 02 00 00 00  60 e3 01 00 00 00 00 00  |..1.....`.......|

00000040  20 ec 46 58 02 00 00 00  00 00 00 00 00 00 00 00  | .FX............|

00000050  00 00 00 00 00 00 00 00  00 00 00 00 00 00 00 00  |................|

00000060  00 00 00 00 00 00 00 00  60 bf 31 16 02 00 00 00  |........`.1.....|

00000070  00 00 00 00 00 00 00 00  00 00 00 00 00 00 00 00  |................|

*

000004b0  00 00 00 00 00 00 00 00  10 c4 31 16 02 00 00 00  |..........1.....|

000004c0  00 00 00 00 00 00 00 00  00 00 00 00 00 00 00 00  |................|

*

000004e0  02 1c 00 00 01 00 00 00  00 00 00 00 00 00 00 00  |................|

000004f0  00 00 00 00 00 00 00 00  00 00 00 00 00 00 00 00  |................|

00000500  00 00 00 00 00 00 00 00  70 80 33 16 02 00 00 00  |........p.3.....|

00000510  b8 b5 e5 57 02 00 00 00  ff ff ff ff ff ff ff ff  |...W............|

00000520  58 c4 31 16 02 00 00 00  00 00 00 00 00 00 00 00  |X.1.............|

00000530  00 00 00 00 00 00 00 00  00 00 00 00 00 00 00 00  |................|

*

00000550  50 75 2c 18 02 00 00 00  01 00 00 00 00 00 00 00  |Pu,.............|

Further on in the hexdump of the 1MB object there's clearly an NSExpression payload - this payload is also visible just running strings on the WebP file. Matthias Frielingsdorf from iVerify gave a talk at BlackHat Asia with an initial analysis of this NSExpression payload, we'll return to that at the end of this blog post.

Equally striking (and visible in the hexdump above): there are clearly pointers in there. It's too early in the analysis to know whether this is a payload which gets rebased somehow, or whether there's a separate ASLR disclosure step.

On a slightly higher level this hexdump looks a little bit like an Objective-C or C++ object, though some things are strange. Why are the first 24 bytes all zero? Why isn't there an isa pointer or vtable? It looks a bit like there are a number of integer fields before the pointers, but what are they? At this stage of the analysis, I had no idea.

Thinking dynamically

I had tried a lot to reproduce the exploit primitives on a real device; I built tooling to dynamically generate and sign legitimate PKPass files that I could send via iMessage to test devices and I could crash a lot, but I never seemed to get very far into the exploit - the iOS version range where the heap grooming works seems to be pretty small, and I didn't have an exact device and iOS version match to test on.

Regardless of what I tried: sending the original exploits via iMessage, sending custom PKPasses with the trigger and groom, rendering the WebP directly in a test app or trying to use the PassKit APIs to render the PKPass file the best I could manage dynamically was to trigger a heap metadata integrity check failure, which I assumed was indicative of the exploit failing.

(Amusingly, using the legitimate APIs to render the PKPass inside an app failed with an error that the PKPass file was malformed. And indeed, the exploit sample PKPass is malformed: it's missing multiple required files. But the "secure" PKPass BlastDoor parser entrypoint (PKPassSecurePreviewContextCreateMessagesPreview) is, in this regard at least, less strict and will attempt to render an incomplete and invalid PKPass).

Though getting the whole PKPass parsed was proving tricky, with a bit of reversing it was possible to call the correct underlying CoreGraphics APIs to render the WebP and also get the EXIF/MakerNote parsed. By then setting a breakpoint when the huffman tables were allocated I had hoped it would be obvious what the overflow target was. But it was actually totally unclear what the following object was: (Here X3 points to the start of the huffman tables which are 0x3000 bytes large)

(lldb) x/6xg $x3+0x3000

0x112000000: 0x0000000111800000 0x0000000000000000

0x112000010: 0x00000000001a1600 0x0000000000000004

0x112000020: 0x0000000000000001 0x0000000000000019

The first qword (0x111800000) is a valid pointer, but this is clearly not an Objective-C object, nor did it seem to look like any other recognizable object or have much to do with either the bplist or WebP. But running the tests a few times, there was a curious pattern:

(lldb) x/6xg $x3+0x3000

0x148000000: 0x0000000147800000 0x0000000000000000

0x148000010: 0x000000000019c800 0x0000000000000004

0x148000020: 0x0000000000000001 0x0000000000000019

The huffman table is 0x2F28 bytes, which the allocator rounds up to 0x3000. And in both of those test runs, adding the allocation size to the huffman table pointer yielded a suspiciously round number. There's no way that's a coincidence. Running a few more tests the table+0x3000 pointer is always 8MB aligned. I remembered from some presentations on the iOS userspace allocator I'd read that 8MB is a meaningful number. Here's one from Synaktiv:

Or this one from Angelboy:

8MB is the size of the iOS userspace default allocator's small rack regions. It looks like they might be trying to groom the allocator not to target application-specific data but allocator metadata. Time to dive into some libmalloc internals!

libmalloc

I'd suggest reading the two presentations linked above for a good overview of the iOS default userspace malloc implementation. Libmalloc manages memory on four levels of abstraction. From largest to smallest those are: rack, magazine, region and block. The size split between the tiny, small and large racks depends on the platform. Almost all the relevant allocations for this exploit come from the small rack, so that's the one I'll focus on.

Reading through the libmalloc source I noticed that the region trailer, whilst still called a trailer, has been now moved to the start of the region object. The small region manages memory in chunks of 8MB. That 8MB gets split up in to (for our purposes) three relevant parts: a header, an array of metadata words, then blocks of 512 bytes which form the allocations:

The first 0x28 bytes are a header where the first two fields form a linked-list of small regions:

typedef struct region_trailer {

        struct region_trailer *prev;

        struct region_trailer *next;

        unsigned bytes_used;

        unsigned objects_in_use;

        mag_index_t mag_index;

        volatile int32_t pinned_to_depot;

        bool recirc_suitable;

        rack_dispose_flags_t dispose_flags;

} region_trailer_t;

The small region manages memory in units of 512 bytes called blocks. On iOS allocations from the small region consist of contiguous runs of up to 31 blocks. Each block has an associated 16-bit metadata word called a small meta word, which itself is subdivided into a "free" flag in the most-significant bit, and a 15-bit count.

To mark a contiguous run of blocks as in-use (belonging to an allocation) the first meta word has its free flags cleared and the count set to the number of blocks in the run. On free, an allocation is first placed on a lookaside list for rapid reuse without freeing. But once an allocation really gets freed the allocator will attempt to greedily coalesce neighbouring chunks. While in-use runs can never exceed 31 blocks, free runs can grow to encompass the entire region.

The groom

Below you can see the state of the meta words array for the small region directly following the one containing the huffman table as its last allocation:

(lldb) x/200wh 0x148000028

0x148000028: 0x0019 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000038: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000048: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000058: 0x0000 0x0003 0x0000 0x0000 0x0018 0x0000 0x0000 0x0000

0x148000068: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000078: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000088: 0x0000 0x0000 0x0000 0x0000 0x0003 0x0000 0x0000 0x001c

0x148000098: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x1480000a8: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x1480000b8: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x1480000c8: 0x0000 0x0000 0x0000 0x001d 0x0000 0x0000 0x0000 0x0000

With some simple maths we can convert indexes in the meta words array into their corresponding heap pointers. Doing that it's possible to dump the memory associated with the allocations shown above. The larger 0x19, 0x18 and 0x1c allocations all seem to be generic groom allocations, but the two 0x3 block allocations appear more interesting. The first one (with the first metadata word at 0x14800005a, shown in yellow) is the code_lengths array which gets freed directly after the huffman table building fails. The blue 0x3 block run (with the first metadata word at 0x148000090) is the backing buffer for a CFSet object from the MakerNote and contains object pointers.

Recall that the corruption primitive will write the dword 0x270007 0x58 bytes off the end of the 0x3000 allocation (and that allocation happens to sit directly in front of this small region). That corruption has the following effect (shown in bold):

(lldb) x/200wh 0x148000028

0x148000028: 0x0019 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000038: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000048: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000058: 0x0007 0x0027 0x0000 0x0000 0x0018 0x0000 0x0000 0x0000

0x148000068: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000078: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000088: 0x0000 0x0000 0x0000 0x0000 0x0003 0x0000 0x0000 0x001c

0x148000098: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x1480000a8: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x1480000b8: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x1480000c8: 0x0000 0x0000 0x0000 0x001d 0x0000 0x0000 0x0000 0x0000

It's changed the size of an in-use allocation from 3 blocks to 39 (or from 1536 to 19968 bytes). I mentioned before that the maximum size of an in-use allocation is meant to be 31 blocks, but this doesn't seem to be checked in every single free path. If things don't quite work out, you'll hit a runtime check. But if things do work out you end up with a situation like this:

(lldb) x/200wh 0x148000028

0x148000028: 0x0019 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000038: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000048: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000058: 0x0007 0x8027 0x0000 0x0000 0x0018 0x0000 0x0000 0x0000

0x148000068: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000078: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000088: 0x0000 0x0000 0x0000 0x0000 0x0003 0x0000 0x0000 0x001c

0x148000098: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x8027

0x1480000a8: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x1480000b8: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x1480000c8: 0x0000 0x0000 0x0000 0x001d 0x0000 0x0000 0x0000 0x0000

The yellow (0x8027) allocation now extends beyond its original three blocks and completely overlaps the following green (0x18) and blue (0x3) as well as the start of the purple (0x1c) allocation.

But as soon as this corruption occurs WebP parsing fails and it's not going to make any other allocations. So what are they doing? How are they able to leverage these overlapping allocations? I was pretty stumped.

One theory was that perhaps it was some internal ImageIO or BlastDoor specific object which reallocated the overlapping memory. Another theory was that perhaps the exploit had two parts; this first part which puts overlapping entries on the allocator freelist, then another file which is sent to exploit that? And maybe I was lacking that file? But then, why would there be that huge 1MB payload with NSExpressions in it? That didn't add up.

Puzzling pieces

As is so often the case, stepping back and not thinking about the problem for a while I realised that I'd completely overlooked and forgotten something critical. Right at the very start of the analysis I had run file on all the files inside the PKPass and noted that background.png was actually not a png but a TIFF. I had then completely forgotten that. But now the solution seemed obvious: the reason to use a PKPass versus just a WebP is that the PKPass parser will render multiple images in sequence, and there must be something in the TIFF which reallocates the overlapping allocation with something useful.

Libtiff comes with a suite of tools for parsing tiff files. tiffdump displays the headers and EXIF tags:

$ tiffdump background-15.tiff

background-15.tiff:

Magic: 0x4d4d <big-endian> Version: 0x2a <ClassicTIFF>

Directory 0: offset 68 (0x44) next 0 (0)

ImageWidth (256) SHORT (3) 1<48>

ImageLength (257) SHORT (3) 1<16>

BitsPerSample (258) SHORT (3) 4<8 8 8 8>

Compression (259) SHORT (3) 1<8>

Photometric (262) SHORT (3) 1<2>

StripOffsets (273) LONG (4) 1<8>

Orientation (274) SHORT (3) 1<1>

SamplesPerPixel (277) SHORT (3) 1<4>

StripByteCounts (279) LONG (4) 1<59>

PlanarConfig (284) SHORT (3) 1<1>

ExtraSamples (338) SHORT (3) 1<2>

700 (0x2bc) BYTE (1) 15347<00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 ...>

33723 (0x83bb) UNDEFINED (7) 15347<00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 ...>

34377 (0x8649) BYTE (1) 15347<00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 ...>

ICC Profile (34675) UNDEFINED (7) 15347<00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 ...>

The presence of the four 15KB buffers is notable, but they seemed to mostly just be zeros. Here's the output from tiffinfo:

$ tiffinfo -c -j -d -s -z background-15.tiff

=== TIFF directory 0 ===

TIFF Directory at offset 0x44 (68)

  Image Width: 48 Image Length: 16

  Bits/Sample: 8

  Compression Scheme: AdobeDeflate

  Photometric Interpretation: RGB color

  Extra Samples: 1<unassoc-alpha>

  Orientation: row 0 top, col 0 lhs

  Samples/Pixel: 4

  Planar Configuration: single image plane

  XMLPacket (XMP Metadata):

  RichTIFFIPTC Data: <present>, 15347 bytes

  Photoshop Data: <present>, 15347 bytes

  ICC Profile: <present>, 15347 bytes

  1 Strips:

      0: [       8,       59]

Strip 0:

 00 00 00 00 00 00 00 00 84 13 00 00 01 00 00 00 01 00 00 00 00 00 00 00

 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00

 cd ab 34 12 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00

 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00

 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00

 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00

 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00

 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00

...

This dumps the uncompressed TIFF strip buffer and this looks much more interesting! There's clearly some structure, though not a lot of it. Is this really enough to do something useful? It looks like there could be some sort of object, but I didn't recognise the structure, and had no idea how replacing an object with this would be useful. I explored two possibilities:

1) Alpha blending:

This is actually the raw TIFF strip after decompression but before the rendering step which applies the alpha, so it was possible that this got rendered "on top" of another object. That seemed like a reasonable explanation for why the object seemed so sparse; perhaps the idea was to just "move" a pointer value. The first 16 bytes of the strip look like this:

00 00 00 00 00 00 00 00 84 13 00 00 01 00 00 00

which when viewed as two 64-bit values look like this:

0x0000000000000000 0x0000000100001384

It seemed sort-of plausible that rendering the 0x100001384 on top of another pointer might be a neat primitive, but there was something that didn't quite add up. This pointer-ish value is at the start of the strip buffer, so if the overlapping allocation got reallocated with this strip buffer directly, nothing interesting would happen, as the overlapping parts are further along. Maybe the overlapping buffer gets split up multiple times, but this was seeming less and less likely, and I couldn't reproduce this part of the exploit to actually observe what happened.

2) This is an object:

The other theory I had was that this actually was an object. The 8 zero bytes at the start were certainly strange… so then what's the significance of the next 8 bytes?

84 13 00 00 01 00 00 00

I tried using lldb's memory find command to see if there were other instances of that exact byte sequence occurring in a test iOS app rendering the WebP then the TIFF using the CoreGraphics APIs:

(lldb) memory find -e 0x100001384 -- 0x100000000 0x200000000

data not found within the range.

Nope, plus it was very, very slow.

One thing I had noticed was that this byte sequence was similar to one near the start of the 1MB groom object:

00000000  00 00 00 00 00 00 00 00  00 00 00 00 00 00 00 00  |................|

00000010  00 00 00 00 00 00 00 00  80 26 00 00 01 00 00 00  |.........&......|

00000020  1f 00 00 00 00 00 00 00  10 00 8b 56 02 00 00 00  |...........V....|

00000030  b0 c3 31 16 02 00 00 00  60 e3 01 00 00 00 00 00  |..1.....`.......|

They're not identical, but it seemed a strange coincidence.

I took a bunch of test app core dumps using lldb's process save-core command and wrote some simple code to search for similar-ish byte patterns. After some experimentation I managed to find something:

1c7b2600  49 d2 e4 29 02 00 00 01  84 13 00 00 02 00 00 00  |I..)............|

1c7b2610  42 00 00 00 00 00 00 00  00 00 00 00 00 00 00 00  |B...............|

1c7b2620  00 00 00 00 00 00 00 00  00 00 00 00 00 00 00 00  |................|

1c7b2630  c0 92 d6 83 02 00 00 00  00 93 d6 83 02 00 00 00  |................|

Converting those coredump offsets into VM address and looking them up revealed:

(lldb) x/10xg 0x121E47600

0x121e47600: 0x0100000229e4d249 0x0000000200001384

0x121e47610: 0x0000000000000042 0x0000000000000000

0x121e47620: 0x0000000000000000 0x0000000000000000

(lldb) image lookup --address 0x229e4d248

      Address: CoreFoundation[0x00000001dceed248] (CoreFoundation.__DATA_DIRTY.__objc_data + 7800)

      Summary: (void *)0x0000000229e4d0e0: __NSCFArray

It's an NSCFArray, which is the Foundation (Objective-C) "toll-free bridged" version of the Core Foundation (C) CFArray type! This was the hint that I was looking for to identify the significance of the TIFF and that 1MB groom object, which also contains a similar byte sequence.

Cores and Foundations

Even though Apple hasn't updated the open-source version of CoreFoundation for almost a decade, the old source is still helpful. Here's what a CoreFoundation object looks like:

/* All CF "instances" start with this structure.  Never refer to

 * these fields directly -- they are for CF's use and may be added

 * to or removed or change format without warning.  Binary

 * compatibility for uses of this struct is not guaranteed from

 * release to release.

 */

typedef struct __CFRuntimeBase {

    uintptr_t _cfisa;

    uint8_t _cfinfo[4];

#if __LP64__

    uint32_t _rc;

#endif

} CFRuntimeBase;

So the header is an Objective-C isa pointer followed by four bytes of _cfinfo, followed by a reference count. Taking a closer look at the uses of __cfinfo:

CF_INLINE CFTypeID __CFGenericTypeID_inline(const void *cf) {

  // yes, 10 bits masked off, though 12 bits are

  // there for the type field; __CFRuntimeClassTableSize is 1024

  uint32_t *cfinfop = (uint32_t *)&(((CFRuntimeBase *)cf)->_cfinfo);

  CFTypeID typeID = (*cfinfop >> 8) & 0x03FF; // mask up to 0x0FFF

  return typeID;

}

It seems that the second byte in __cfinfo is a type identifier. And indeed, running expr (int) CFArrayGetTypeID() in lldb prints: 19 (0x13) which matches up with both the object found in the coredump as well as the strange (or now not so strange) object in the TIFF strip buffer.

X steps forwards, Y steps back

Looking through more of the CoreFoundation code it seems that the object in the TIFF strip buffer is a CFArray with inline storage containing one element with the value 0x1234abcd. It also seems that it's possible for CF objects to have NULL isa pointers, which explains why the first 8 bytes of the fake object are zero.

This is interesting, but it still doesn't actually get us any closer to figuring out what the next step of the exploit actually is. If the CFArray is meant to overlap with something, then what? And what interesting side-effects could having an CFArray with only a single element with the value 0x1234abcd possibly have?

This seems like one step forward and two steps back, but there's something else which we can now figure out: what that 1MB groom object actually is. Let's take a look at the start of it again:

00000000  00 00 00 00 00 00 00 00  00 00 00 00 00 00 00 00  |................|

00000010  00 00 00 00 00 00 00 00  80 26 00 00 01 00 00 00  |.........&......|

00000020  1f 00 00 00 00 00 00 00  10 00 8b 56 02 00 00 00  |...........V....|

00000030  b0 c3 31 16 02 00 00 00  48 e3 01 00 00 00 00 00  |..1.....H.......|

00000040  20 ec 46 58 02 00 00 00  00 00 00 00 00 00 00 00  | .FX............|

00000050  00 00 00 00 00 00 00 00  00 00 00 00 00 00 00 00  |................|

00000060  00 00 00 00 00 00 00 00  60 bf 31 16 02 00 00 00  |........`.1.....|

00000070  00 00 00 00 00 00 00 00  00 00 00 00 00 00 00 00  |................|

It looks like another CF object, starting at +0x10 in the buffer with the same NULL isa pointer, a reference count of 1 and a __cfinfo of {0x80, 0x26, 0, 0}. The type identifiers aren't actually fixed, they're allocated dynamically via calls to _CFRuntimeRegisterClass like this:

CFTypeID CFArrayGetTypeID(void) {

    static dispatch_once_t initOnce;

    dispatch_once(&initOnce, ^{ __kCFArrayTypeID = _CFRuntimeRegisterClass(&__CFArrayClass); });

    return __kCFArrayTypeID;

}

The CFTypeIDs are really just indexes into the __CFRuntimeClassTable array, and even though the types are allocated dynamically the ordering seems sufficiently stable that the hardcoded type values in the exploit work. 0x26 is the CFTypeID for CFReadStream:

struct _CFStream {

    CFRuntimeBase _cfBase;

    CFOptionFlags flags;

    CFErrorRef error;

    struct _CFStreamClient *client;

    void *info;

    const struct _CFStreamCallBacks *callBacks;

    CFLock_t streamLock;

    CFArrayRef previousRunloopsAndModes;

    dispatch_queue_t queue;

};

Looking through the CFStream code it seems to call various callback functions during object destruction — that seems like a very likely path towards code execution, though with some significant caveats:

Caveat I: It's still unclear how an overlapping allocation in the small malloc region could lead to a CFRelease being called on this 1MB allocation.

Caveat II: What about ASLR? There have been some tricks in the past targeting "universal gadgets" which work across multiple slides. Nemo also had a neat objective-c trick for defeating ASLR in the past, so it's plausible that there's something like that here.

Caveat III: What about PAC? If it's a data-only attack then maybe PAC isn't an issue, but if they are trying to JOP they'd need a trick beyond just an ASLR leak, as all forward control flow edges should be protected by PAC.

Special Delivery

Around this time in my analysis Matthias Frielingsdorf offered me the use of an iPhone running 16.6, the same version as the targeted ITW victim. With Matthias' vulnerable iPhone, I was able to use the Dopamine jailbreak to attach lldb to MessagesBlastDoorService and after a few tries was able to reproduce the exploit right up to the CFRelease call on the fake CFReadStream, confirming that that part of my analysis was correct!

Collecting a few crashes led, yet again, to even more questions...

Caveat I: Mysterious Pointers

Similar to the analysis of the huffman tables, there was a clear pattern in the fake object pointers, which this time were even stranger than the huffman tables. The crash site was here:

LDR    X8, [X19,#0x30]

LDR    X8, [X8,#0x58]

At this point X19 points to the fake CFReadStream object, and collecting a few X19 values there's a pretty clear pattern:

0x000000075f000010

0x0000000d4f000010

The fake object is inside a 1MB heap allocation, but all those fake object addresses are always 16 bytes above a 16MB-aligned address. It seemed really strange to me to end up with a pointer 0x10 bytes past such a round number. What kind of construct would lead to the creation of such a pointer? Even though I did have a debugger attached to MessagesBlastDoorService, it wasn't a time-travel debugger, so figuring out the history of such a pointer was non-trivial. Using the same core dump analysis techniques I could see that the pointer which would end up in X19 was also present in the backing buffer of the CFSet described earlier. But how did it get there?

Having found the strange CFArray inside the TIFF I was heavily biased towards believing that this must have something to do with it, so I wrote some tooling to modify the fake CFArray's in the TIFF in the exploit. The theory was that by messing with that CFArray, I could cause a crash when it was used and figure out what was going on. But making minor changes to the strip buffer didn't seem to have any effect — the exploit still worked! Even replacing the entire strip buffer with A's didn't stop the exploit working... What's going on?

Stepping back

I had made a list of the primitives I thought might lead to the creation of such a strange looking pointer — first on the list was a partial pointer overwrite. But then why the CFArray? But now having shown that the CFArray can't be involved, it was time to go back to the list. And step back even further and make sure I'd really looked at all of that TIFF...

There were still those four other metadata buffers in the tiffdump output I'd shown earlier:

700 (0x2bc) BYTE (1) 15347<00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 ...>

33723 (0x83bb) UNDEFINED (7) 15347<00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 ...>

34377 (0x8649) BYTE (1) 15347<00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 ...>

ICC Profile (34675) UNDEFINED (7) 15347<00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 ...>

I'd just dismissed them, but, maybe I shouldn't have done that? I had actually already dumped the full contents of each of those buffers and checked that there wasn't something else apart from the zeros. They were all zeros, except the third-to-last bytes which were 0x10, which I'd considered completely uninteresting. Uninteresting, unless you wanted to partially overwrite the three least-significant bytes of a little-endian pointer value with 0x000010 that is!

Let's look back at the SMALL metadata:

0x148000058: 0x0007 0x8027 0x0000 0x0000 0x0018 0x0000 0x0000 0x0000

0x148000068: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000078: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000088: 0x0000 0x0000 0x0000 0x0000 0x0003 0x0000 0x0000 0x001c

0x148000098: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x8027

Each of those four metadata buffers in the TIFF is 15347 bytes, which is 0x3bf3 — looked at another way that's 0x3c00 (the size rounded up to the next 0x200 block size), minus 5, minus 8.

0x3c00 is exactly 30 0x200 byte blocks. Each 16-bit word in the metadata array shown above corresponds to one 0x200 block, where the overlapping chunk in yellow starts at 0x14800005a. Counting forwards 30 chunks means that the end of a 0x3c00 allocation overlaps perfectly with the end of the original blue three-chunk allocation:

0x148000058: 0x0007 0x8027 0x0000 0x0000 0x0018 0x0000 0x0000 0x0000

0x148000068: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000078: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000

0x148000088: 0x0000 0x0000 0x0000 0x0000 0x0003 0x0000 0x0000 0x001c

0x148000098: 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x0000 0x8027

This has the effect of overwriting all but the last 16 bytes of the blue allocation with zeros, then overwriting the three least-significant bytes of the second-to-last pointer-sized value with 0x10 00 00; which, if that memory happened to contain a pointer, has the effect of "shifting" that pointer down to the nearest 16MB boundary, then adding 0x10 bytes! (For those who saw my 2024 Offensivecon talk, this was the missing link between the overlapping allocations and code execution I mentioned.)

As mentioned earlier, that blue allocation starting with 0x0003 is the backing buffer of a CFSet object from the bplist inside the WebP MakerNote. The set is constructed in a very precise fashion such that the target pointer (the one to be rounded down) ends up as the second-to-last pointer in the backing buffer. The 1MB object is then also groomed such that it falls on a 16MB boundary below the object which the CFSet entry originally points to. Then when that CFSet is destructed it calls CFRelease on each object, causing the fake CFReadStream destructor to run.

Caveat II: ASLR

We've looked at the whole flow from huffman table overflow to CFRelease being invoked on a fake CFReadStream — but there's still stuff missing. The second open question I discussed earlier was ASLR. I had theorised that maybe it used a trick like a universal gadget, but is that the case?

In addition to the samples, I was also able to obtain a number of crash logs from failed exploit attempts where those samples were thrown, which meant I could figure out the ASLR slide of the MessagesBlastDoorService when the exploit failed. In combination with the target device and exact OS build (also contained in the crash log) I could then obtain the matching dyld_shared_cache, subtract the runtime ASLR slide from a bunch of the pointer-looking things in the 1MB object and take a look at them.

The simple answer is: the 1MB object contains a large number of hardcoded, pre-slid, valid pointers. There's no weird machine, tricks or universal gadget here. By the time the PKPass is built and sent by the attackers they already know both the target device type and build as well as the runtime ASLR slide of the MessagesBlastDoorService...

Based on analysis by iVerify, as well as analysis of earlier exploit chains published by Citizen Lab, my current working theory is that the large amount of HomeKit traffic seen in those cases is likely a separate ASLR/memory disclosure exploit.

Caveat III: Pointer Authentication

In the years since PAC was introduced we've seen a whole spectrum of interesting ways to either defeat, or just avoid, PAC. So what did these attackers do? To understand that let's follow the CFReadStream destruction code closely. (All these code snippets are from the most recently available version of CF from 2015, but the code doesn't seem to have changed much.)

Here's the definition of the CFReadStream:

static const CFRuntimeClass __CFReadStreamClass = {

    0,

    "CFReadStream",

    NULL,      // init

    NULL,      // copy

    __CFStreamDeallocate,

    NULL,

    NULL,

    NULL,      // copyHumanDesc

    __CFStreamCopyDescription

};

When a CFReadStream is passed to CFRelease, it will call __CFStreamDeallocate:

static void __CFStreamDeallocate(CFTypeRef cf) {

  struct _CFStream *stream = (struct _CFStream *)cf;

  const struct _CFStreamCallBacks *cb =

    _CFStreamGetCallBackPtr(stream);

  CFAllocatorRef alloc = CFGetAllocator(stream);

  _CFStreamClose(stream);

_CFStreamGetCallBackPtr just returns the CFStream's callBacks field:

CF_INLINE const struct _CFStreamCallBacks *_CFStreamGetCallBackPtr(struct _CFStream *stream) {

    return stream->callBacks;

}

Here's _CFStreamClose:

CF_PRIVATE void _CFStreamClose(struct _CFStream *stream) {

  CFStreamStatus status = _CFStreamGetStatus(stream);

  const struct _CFStreamCallBacks *cb =

    _CFStreamGetCallBackPtr(stream);

  if (status == kCFStreamStatusNotOpen || 

      status == kCFStreamStatusClosed ||

       (status == kCFStreamStatusError &&

        __CFBitIsSet(stream->flags, HAVE_CLOSED)

      ))

  {

    // Stream is not open from the client's perspective;

    // do not callout and do not update our status to "closed"

    return;

  }

  if (! __CFBitIsSet(stream->flags, HAVE_CLOSED)) {

        __CFBitSet(stream->flags, HAVE_CLOSED);

        __CFBitSet(stream->flags, CALLING_CLIENT);

    if (cb->close) {

      cb->close(stream, _CFStreamGetInfoPointer(stream));

    }

_CFStreamGetStatus extracts the status bitfield from the flags field:

#define __CFStreamGetStatus(x) __CFBitfieldGetValue((x)->flags, MAX_STATUS_CODE_BIT, MIN_STATUS_CODE_BIT)

Looking at the 1MB object again the flags field is the first non-base field:

00000000  00 00 00 00 00 00 00 00  00 00 00 00 00 00 00 00  |................|

00000010  00 00 00 00 00 00 00 00  80 26 00 00 01 00 00 00  |.........&......|

00000020  1f 00 00 00 00 00 00 00  10 00 8b 56 02 00 00 00  |...........V....|

00000030  b0 c3 31 16 02 00 00 00  48 e3 01 00 00 00 00 00  |..1.....H.......|

00000040  20 ec 46 58 02 00 00 00  00 00 00 00 00 00 00 00  | .FX............|

00000050  00 00 00 00 00 00 00 00  00 00 00 00 00 00 00 00  |................|

00000060  00 00 00 00 00 00 00 00  60 bf 31 16 02 00 00 00  |........`.1.....|

00000070  00 00 00 00 00 00 00 00  00 00 00 00 00 00 00 00  |................|

That gives a status code of 0x1f with all the other flags bits clear. This gets through the two conditional branches to reach this close callback call:

  if (cb->close) {

    cb->close(stream, _CFStreamGetInfoPointer(stream));

  }

At this point we need to switch to looking at the assembly to see what's really happening:

__CFStreamClose

var_30= -0x30

var_20= -0x20

var_10= -0x10

var_s0=  0

PACIBSP

STP             X24, X23, [SP,#-0x10+var_30]!

STP             X22, X21, [SP,#0x30+var_20]

STP             X20, X19, [SP,#0x30+var_10]

STP             X29, X30, [SP,#0x30+var_s0]

ADD             X29, SP, #0x30

MOV             X19, X0

BL              __CFStreamGetStatus

CBZ             X0, loc_187076958

The fake CFReadStream is the first argument to this function, so passed in the X0 register. It's then stored into X19 so it survives the call to __CFStreamGetStatus.

Skipping ahead past the flag checks we reach the callback callsite (this is also the crash site seen earlier):

LDR             X8, [X19,#0x30]

...

LDR             X8, [X8,#0x58]

CBZ             X8, loc_187076758

LDR             X1, [X19,#0x28]

MOV             X0, X19

BLRAAZ          X8

Let's walk through each instruction in turn there:

First it loads the 64-bit value from X19+0x30 into X8:

LDR             X8, [X19,#0x30]

Looking at the hexdump of the 1MB object above this will load the value 0x25846ec20.

From the crash reports we know the runtime ASLR slide of the MessagesBlastDoorService when this exploit was thrown was 0x3A8D0000, so subtracting that we can figure out where in the shared cache this pointer should point:

0x25846ec20-0x3A8D0000=0x21DB9EC20

It points into the __const segment of the TextToSpeechMauiSupport library in the shared cache:

The next instruction adds 0x58 to that TextToSpeechMauiSupport pointer and reads a 64-bit value from there:

LDR             X8, [X8,#0x58] // x8 := [0x21DB9EC20+0x58]

This loads the pointer to the function _DataSectionWriter_CommitDataBlock from 0x21DB9EC78.

IDA is simplifying something for us here: the function pointer loaded there is actually signed with the A-family instruction key with a zero context. This signing happens transparently (either during load or when the page is faulted in).

The remaining four instructions then check that the pointer wasn't NULL, load X1 from offset +0x28 in the fake 1MB object, move the pointer to the fake object back into X0 and call the PAC'ed _DataSectionWriter_CommitDataBlock function pointer via BLRAAZ:

CBZ             X8, loc_187076758

LDR             X1, [X19,#0x28]

MOV             X0, X19

BLRAAZ          X8

Callback-Oriented Programming

A well-known attack against PAC is to swap two valid, PAC'ed pointers which are signed in the same way but point to different places (e.g. swapping two function pointers with different semantics, allowing you to exploit those semantic differences).

Since a large number of PAC-protected pointers are signed with the A-family instruction key with a zero-context value, there are a large number of pointers to choose from. "Just" having an ASLR defeat shouldn't be enough to achieve this though; surely you'd need to disclose the actual PAC'ed pointer value? But that's not what happened above.

Notice that the CFStream objects don't directly contain the callback function pointers — there's an extra level of indirection. The CFStream object contains a pointer to a callback structure, and that structure has the PAC'd function pointers. And crucially: that first pointer, the one to the callbacks structure, isn't protected by PAC. This means that the attackers can freely swap pointers to callback structures, operating one-level removed from the function pointers.

This might seem like a severe constraint, but the dyld_shared_cache is vast and there are easily enough pre-existing callback structures to build a "callback-oriented JOP" chain, chaining together unsigned pointers to signed function pointers.

The initial portion of the payload is a large callback-oriented JOP chain which is used to bootstrap the evaluation of the next payload stage, a large NSExpression.

Similarities

There are a number of similarities between this exploit chain and PWNYOURHOME, an earlier exploit also attributed by CitizenLab to NSO, described in this blog post in April 2023.

That chain also had an initial stage targeting HomeKit, followed by a stage targeting MessagesBlastDoorService and also involving a MakerNote object — the Citizen Lab post claims that at the time the MakerNote was inside a PNG file. My guess would be that that PNG was being used as the delivery mechanism for the MakerNote bplist heap grooming primitives discussed in this post.

Based on Citizen Lab's description it also seems like PWNYOURHOME was leveraging a similar callback-oriented JOP technique, and it seems likely that there was also a HomeKit-based ASLR disclosure. The PWNYOURHOME post has a couple of extra details around a minor fix which Apple made, preventing parsing of "certain HomeKit messages unless they arrive from a plausible source." But there still aren't enough details to figure out the underlying vulnerability or primitive. It seems likely to me that the same issue, or a variant thereof was still in use in BLASTPASS.

Key material

Matthias from iVerify presented an initial analysis of the NSExpression payload at BlackHat Asia in April 2024. In early July 2024, Matthias and I took a closer look at the final stages of the NSExpression payload which decrypts an AES-encrypted NSExpression and executes it.

It seems very likely that the encrypted payload contains a BlastDoor sandbox escape. Although the BlastDoor sandbox profile is fairly restrictive it still allows access to a number of system services like notifyd, logd and mobilegestalt. In addition to the syscall attack surface there's also a non-trivial IOKit driver attack surface:

...

(allow iokit-open-user-client

        (iokit-user-client-class "IOSurfaceRootUserClient")

        (iokit-user-client-class "IOSurfaceAcceleratorClient")

        (iokit-user-client-class "AGXDevice"))

(allow iokit-open-service)

(allow mach-derive-port)

(allow mach-kernel-endpoint)

(allow mach-lookup

        (require-all

                (require-not (global-name "com.apple.diagnosticd"))

                (require-any

                        (global-name "com.apple.logd")

                        (global-name "com.apple.system.notification_center")

                        (global-name "com.apple.mobilegestalt.xpc"))))

...

(This profile snippet was generated using the Cellebrite labs' fork of SandBlaster)

In FORCEDENTRY the sandbox escape was contained directly in the NSExpression payload (though that was an escape from the less-restrictive IMTranscoderAgent sandbox). This time around it seems extra care has been taken to prevent analysis of the sandbox escape.

The question is: where does the key come from? We had a few theories:

• Perhaps the key is just obfuscated, and by completely reversing the NSExpression payload we can find it?
• Perhaps the key is derived from some target-specific information?
• Perhaps the key was somehow delivered in some other way and can be read from inside BlastDoor?

We spent a day analysing the NSExpression payload and concluded that the third theory appeared to be the correct one. The NSExpression walks up the native stack looking for the communication ports back to imagent. It then hijacks that communication, effectively taking over responsibility for parsing all subsequent incoming requests from imagent for "defusing" of iMessage payloads. The NSExpression loops 100 times, parsing incoming requests as XPC messages, reading the request xpc dictionary then the data xpc data object to get access to the raw, binary iMessage format. It waits until the device receives another iMessage with a specific format, and from that message extracts an AES key which is then used to decrypt the next NSExpression stage and evaluate it.

We were unable to recover any messages with the matching format and therefore unable to analyse the next stage of the exploit.

Conclusion

In contrast to FORCEDENTRY, BLASTPASS's separation of the ASLR disclosure and RCE phases mitigated the need for a novel weird machine. Whilst the heap groom was impressively complicated and precise, the exploit still relied on well-known exploitation techniques. Furthermore, the MakerNote bplist groom and callback-JOP PAC defeat techniques appear to have been in use for multiple years, based on similarities with Citizenlab's blogpost in 2023, which looked at devices compromised in 2022.

Enforcing much stricter requirements on the format of the bplist inside the MakerNote (for example: a size limit or a strict-parser mode which rejects duplicate keys) would seem prudent. The callback-JOP issue is likely harder to mitigate.

The HomeKit aspect of the exploit chain remains mostly a mystery, but it seems very likely that it was somehow involved in the ASLR disclosure. Samuel Groß's post "A Look at iMessage in iOS 14" in 2021, mentioned that Apple added support for re-randomizing the shared cache slide of certain services. Ensuring that BlastDoor has a unique ASLR slide could be a way to mitigate this.

This is the second in-the-wild NSO exploit which relied on simply renaming a file extension to access a parser in an unexpected context which shouldn't have been allowed.

FORCEDENTRY had a .gif which was really a .pdf.

BLASTPASS had a .png which was really a .webp.

A basic principle of sandboxing is treating all incoming attacker-controlled data as untrusted, and not simply trusting a file extension.

This speaks to a broader challenge in sandboxing: that current approaches based on process isolation can only take you so far. They increase the length of an exploit chain, but don't necessarily reduce the size of the initial remote attack surface. Accurately mapping, then truly reducing the scope of that initial remote attack surface should be a top priority.

Google is beating the drum for Gemini 2.5, a new AI model that reportedly offers better performance than similar reasoning models from competitors such as OpenAI, Anthropic and Deepseek. Google calls it its “most intelligent AI model yet.”

According to a post on The Keyword blog, Gemini 2.5 can, among other things, analyze information, draw logical conclusions, take context into account, and make informed decisions. It can also interpret text, audio, images, video and code, which means it can be used to create apps and games, for example.

In the video below, a game is being created from a simple text prompt.

Gemini 2.5 can be tested using the Google AI Studio. The AI model is also available through the Gemini Advanced subscription service.

Posted by Christiaan Brand, Group Product Manager

We’re excited to announce that starting today, Titan Security Keys are available for purchase in more than 10 new countries:

• Ireland

• Portugal

• The Netherlands

• Denmark

• Norway

• Sweden

• Finland

• Australia

• New Zealand

• Singapore

• Puerto Rico

This expansion means Titan Security Keys are now available in 22 markets, including previously announced countries like Austria, Belgium, Canada, France, Germany, Italy, Japan, Spain, Switzerland, the UK, and the US.

What is a Titan Security Key?

A Titan Security Key is a small, physical device that you can use to verify your identity when you sign in to your Google Account. It’s like a second password that’s much harder for cybercriminals to steal.

Titan Security Keys allow you to store your passkeys on a strong, purpose-built device that can help protect you against phishing and other online attacks. They’re easy to use and work with a wide range of devices and services as they’re compatible with the FIDO2 standard.

How do I use a Titan Security Key?

To use a Titan Security Key, you simply plug it into your computer’s USB port or tap it to your device using NFC. When you’re asked to verify your identity, you’ll just need to tap the button on the key.

Where can I buy a Titan Security Key?

You can buy Titan Security Keys on the Google Store.

We’re committed to making our products available to as many people as possible and we hope this expansion will help more people stay safe online.

The Chinese threat actor known as FamousSparrow has been linked to a cyber attack targeting a trade group in the United States and a research institute in Mexico to deliver its flagship backdoor SparrowDoor and ShadowPad. The activity, observed in July 2024, marks the first time the hacking crew has deployed ShadowPad, a malware widely shared by Chinese state-sponsored actors. "FamousSparrow Ravie Lakshmananhttp://www.blogger.com/profile/09767675513435997467noreply@blogger.com

You know how IT admins are always warning employees about best practices for security? They’re always mandating which apps to use, which to avoid and which devices can safely connect to corporate networks.

You know why they do that? To keep idiot workers from going rogue and endangering corporate data and secrets.

Case in point: Secretary of Defense Pete Hegseth, who’s under fire this week for — and it’s almost too stupid to be true, but it is — setting up a high-level chat using Signal for top National Security officials to discuss a military attack. And then somehow, some way, a journalist — Jeffrey Goldberg, editor-in-chief of the liberal publication The Atlantic — was invited to join the secretaries of State and Treasury, the director of the CIA, and the Vice President of the United States, JD Vance, for the discussion.

Now, I like serious spy shows. Give me Gary Oldman as George Smiley in Tinker Tailor Solider Spy to keep me on the edge of my seat.  But I can’t watch those now, because the real world has gotten so stupid I can no longer suspend my disbelief. 

I still have trouble believing what Hegseth and company did. So does Goldberg: “I could not believe that the national-security leadership of the United States would communicate on Signal, [the popular, secure messaging service] about imminent war plans. I also could not believe that the national security adviser to the president would be so reckless as to include the editor-in-chief of The Atlanticin such discussions with senior U.S. officials, up to and including the vice president.”

Believe it. Goldberg was added to the Houthi PC small group. The virtual group’s purpose was to talk about planning a military strike on Houthi rebels in Yemen. Goldberg wasn’t asked if he wanted to be involved; he was just added. If there was a group administrator, he or she paid no attention whatsoever to what they were doing. 

At first, Goldberg thought this might be some kind of elaborate joke. Who would add him, of all people, to such a group? Then the bombs, as discussed in the group, started falling on rebels in Yemen.

Goldberg asked, essentially, what in the world these officials thought they were doing. 

Brian Hughes, spokesman for the National Security Council, replied: “This appears to be an authentic message chain, and we are reviewing how an inadvertent number was added to the chain.”

He went on: “The thread is a demonstration of the deep and thoughtful policy coordination between senior officials. The ongoing success of the Houthi operation demonstrates that there were no threats to troops or national security.”

Oh, really? 

What if, say, a spy were in the group instead of an editor and told the Houthi to aim what anti-air missiles they had in X direction at Y time? Or maybe move some school kids or hospital patients into the targeted areas so they could claim that the real terrorists were the Americans for killing helpless civilians. 

For that matter, we know from Goldberg that some things were let slip in the conversation that could have compromised American intelligence agents (read, spies) in the Middle East. Do you know what happens to spies in the Middle East? They get a date with a 7.62mm bullet, if they’re lucky. 

As Rep. Seth Moulton (D-MA), a Marine veteran, tweeted:  “Hegseth is in so far over his head that he is a danger to this country and our men and women in uniform. Incompetence so severe that it could have gotten Americans killed.”

President Donald J. Trump said he knew nothing about what happened and downplayed it. Of course, The Atlantic then published more details of the chat, undermining Trump and what national security officials told Congress just yesterday. Oops.

Sure, Signal is a relatively secure, open-source encrypted messaging service, but it’s not approved for government use. It encrypts messages from end to end. That means only you and the people you’re sending messages to see decrypted messages. That is, of course, when it works perfectly. 

But, you see, there’s this little problem. It doesn’t always work perfectly. Indeed, the National Security Agency (NSA) alerted its employees in February that Signal has vulnerabilities. The NSA also warned its employees not to send “anything compromising over any social media or Internet-based tool or application” and to not “establish connections with people you do not know.” 

Someone should tell the people who are, theoretically, in charge of defending the United States about this. 

On top of that, Google researchers have found that Russians have recently been attempting to compromise Signal accounts. I wonder who they might be targeting? 

I use Signal myself. But, in no way, shape, or form should it ever be used for covert government work. 

There is so much wrong with this, it’s impossible to underestimate how bad the whole incident looks. By sheer dumb luck, no Americans were hurt by this exercise in total operations security incompetence. We can’t count on always being so lucky.

But I bet we can count on certain government officials to ignore the experts on security and do whatever they want.

WWDC event marketing intensifies, and as we head toward that event in a little over two months, it looks as if we’re being told to expect a new paint job (aka user interface change)s for iOS.

But will those tweaks really be enough to move the needle on flatlining iPhone sales?

Is Apple concerned in case these changes don’t impress? Is there any reason the big names in Apple rumor all jumped into this freshwater pool of speculation at more or less the same time, like synchronized swimmers?

Somewhere in the Apple Universe there must now be a place where all rumors go to die. There must also be at least one place where they all get created in the first place.

Across the universe

If you’ve been watching Apple over the last few years, you will have seen that the vast majority of its news announcements all seem to get leaked in advance, with a tiny minority of tales that never get officially teased but could still happen. I’ve not added it up, but I now think that the number of times any given Apple speculations are shown to be false can probably be measured on one hand. Even the rumors that don’t happen in one time frame turn true later. 

The connection between speculation and fact seems so strong it’s hard not to think Apple is planting at least some of these rumors to seed speculation. Well, it’s that, or at some high-level point within Apple there is a civil war going on and rumor has become a weapon to undermine company leadership. Apple is made up of some of the most talented and competitive people on the planet.

Perhaps controlling click bait is just another string to the company bow?

It is also quite amusing that Apple has managed to carve out a global reputation for secrecy at the same time as leaking just about every step it takes. Can both things be true?

Words like rain

Speculation is such fun; however, this is what we’re currently being told to expect in iOS 19  – and, no, it’s not about AI. 

Changes across the interface might include:

• A more rounded aesthetic (no, I don’t know what that really means, either).
• Glassy reflective surfaces.
• An interface similar to visionOS for apps, buttons, and more.
• A new interface for the Camera app — again, more in tune with visionOS.
• A sense of what it looks like in existing tools, including the new Apple Sports and Invites apps.

Bloomberg’s Mark Gurman has previously promised iOS 19 will be the “most significant upgrade” in years, and now says the latest crop of speculation misses key details and Apple has even more planned.

I certainly hope so. I imagine one surprise might be the addition of more Accessibility options, potentially including gesture and movement-based controls bought over to iOS from visionOS. We know these work on Apple’s headsets; can some also logically work on iPhones? Accessibility isn’t just about doing the right thing at Apple; again and again, the tools Apple provides there end up feeding into its products, too.

Change my world

It is also interesting how much of the work Apple did on visionOS is now feeding outwards across the company — Apple Intelligence is, after all, now run by the former leaders of Vision Pro development, and if the ideas they had around user interfaces are now to be deployed across the rest of the company’s products then this reflects the importance of spatial computing to Apple’s future.

However, if all Apple is promising does turn out to be some slight user interface changes, then 2025 may yet go down as a slightly fallow year. That’s going to hurt Apple financially, though it’s big enough to take a little headwind; it may still benefit it in the long term with more time to bring Apple Intelligence up to speed. A few months in calmer waters could also give Apple’s teams a little breathing space as they prepare the biggest iPhone redesign yet.

But no doubt we’ll know all about all of these announcements well before they are officially announced, thanks to the Apple speculation machine.

You can follow me on social media! Join me on BlueSky,  LinkedIn, and Mastodon.

Claude could be getting a ChatGPT-like Deep Research feature called Compass. You can tell Claude's Compass what you need, and the AI agent will take care of everything. [...]

230M stolen passwords met complexity requirements—and were still compromised. Passwords aren't going away for now, but there are new technologies that may increasingly replace them. Learn more from Specops Software about how to protect your passwords. [...]

When the editor-in-chief of The Atlantic, Jeff Goldberg, was accidentally added to a Signal conversation, things took a surprising turn. The journalist could not initially believe the authenticity of the invitation, but the chat apparently involving high-ranking US politicians and government officials discussed specific targets for attacking Huti forces in Yemen — and a few hours later, airstrikes did indeed take place.

Due to the nature of the information exchanged, his doubts were raised both by the fact that top-secret plans were discussed using an app that is not designed to transmit classified data, and by the free-form statements of the politicians, including Vice President J.D. Vance. The messages even included emoticons, symbolizing the celebration of the operation carried out.

The editor-in-chief of The Atlantic reacted

Goldberg refrained from publishing details about specific targets and weaponry in his article about the chat, fearing that the safety of those involved would be compromised.

His description of the leaked news shows that Vice President JD Vance, one of the participants in the conversation, was critical of President Donald Trump’s decision to carry out the attacks, stressing that their effects could benefit Europe more than the United States.

The event instantly sparked a wave of discussion about security rules and possible violations of laws protecting classified information. Legal experts pointed out that transmitting secret data in this way could violate at least the Espionage Act, especially if the app’s configuration provides for automatic deletion of messages.

Trump, however, defended the use of Signal, explaining that access to secure devices and premises is not always possible at short notice.

Meredith Whittaker defends Signal app

Signal’s CEO, Meredith Whittaker, defended the app in an interview with Polish media, stressing that Signal maintains full end-to-end encryption and prioritizes user privacy.

She pointed out that while WhatsApp also uses encryption technologies designed by Signal, it does not protect metadata to the same extent and does not guarantee such a strict policy against collecting or sharing user information.

Whittaker at the same time pointed out that no application can eliminate human error. The accidental invitation of a journalist to a government chat room is precisely one example of a risk that cannot be excluded by technological measures alone.

(This story was originally published by Computerworld Poland.)

Microsoft has fixed a known issue causing some USB printers to start printing random text after installing Windows updates released since late January 2025. [...]

A threat actor named 'RedCurl,' known for stealthy corporate espionage operations since 2018, is now using a ransomware encryptor designed to target Hyper-V virtual machines. [...]

The threat actor known as EncryptHub exploited a recently-patched security vulnerability in Microsoft Windows as a zero-day to deliver a wide range of malware families, including backdoors and information stealers such as Rhadamanthys and StealC. "In this attack, the threat actor manipulates .msc files and the Multilingual User Interface Path (MUIPath) to download and execute malicious payload, Ravie Lakshmananhttp://www.blogger.com/profile/09767675513435997467noreply@blogger.com

The Russian-speaking hacking group called RedCurl has been linked to a ransomware campaign for the first time, marking a departure in the threat actor's tradecraft. The activity, observed by Romanian cybersecurity company Bitdefender, involves the deployment of a never-before-seen ransomware strain dubbed QWCrypt. RedCurl, also called Earth Kapre and Red Wolf, has a history of orchestrating Unknownnoreply@blogger.com

Microsoft says that some customers might experience Remote Desktop and RDS connection issues after installing recent Windows updates released since January 2025. [...]

If you’re wondering how AI agents work, Microsoft’s new Copilot AI agents provide real-time answers on how data is being analyzed and sourced to reach results.

The Researcher and Analyst agents, announced on Tuesday, take a deeper look at data sources such as email, chat or databases within an organization to produce research reports, analyze strategies, or convert raw information into meaningful data.

In the process, the agents give users a bird’s eye-view on each step of how they’re thinking and analyzing data to formulate answers. The agents are integrated with Microsoft 365 Copilot.

The agents combine Microsoft tools with OpenAI’s newer models, which don’t answer questions right away, but can reason better. The models think deeper by generating additional tokens or drawing more information from outside sources before coming up with an answer.

The Researcher agent takes OpenAI’s reasoning models, checks the efficacy of the model, pokes around by pulling data from sources via Microsoft orchestrators and then builds up the level of confidence in the retrieval and results phases, according to information provided by Microsoft.

A demonstration video provided by Microsoft shows the Copilot chatbot interface publishing its “chain of thought” — for example, the step-by-step process of searching enterprise and domain data, identifying product lines, opportunities and more — with the ultimate output being the final document.

The approach is a major benefit for Microsoft since most models operate as a black box, said Jack Gold, principal analyst at J. Gold Associates.

Accountability and the ability to see how models are getting their results are important to assure users that the technology is safe, effective and not hallucinating, Gold said.

“Much of AI today is a ‘black hole’ when it comes to being able to figure out how it got to its results — most cite references, but not the logic on how they got to the end result,” Gold said. “Any transparency you can offer is about making users feel more comfortable.”

The Copilot Researcher agent can take a deeper look at internal data to develop business strategies or identify unexplored market opportunities — typical tasks by researchers. It provides highly technical research and strategy work that you’d expect to pay a highly skilled consultant, researcher, or analyst, a Microsoft spokeswoman said.

“Its ability to combine a user’s work data and web data means its responses are current, but also contextually relevant to every user’s personal needs,” the spokeswoman said.

For example, within the Researcher agent, a user can query the chatbot on exploring new business opportunities. In the process of analyzing data, the agent shares how the model is approaching the query. It will ask clarifying questions, publish a plan to reach an answer, show the data sources it is drawing information from, and explain how the data is collated, categorized, and analyzed.

The Analyst agent takes raw data and generates insights — typically the job of a data scientist. The tool is designed for workers using data to derive insights and make decisions without knowledge of advanced data analysis like Python coding, the spokeswoman said.

For example, the Analyst agent can take a spreadsheet with charts of unstructured data and share insights. Similar to the Researcher agent, the Analyst agent takes in a question via the Copilot interface, creates a plan to analyze the data, and determines the Python tools to generate insights. The agent shares its step-by-step process of how it is responding to the query and even shares the Python code used to generate the answer.

Microsoft has had a number of documented “misses” related to problematic generative AI (genAI) tools, such as Windows Recall, a Copilot feature that uses snapshots to log the history of activity on a PC, Gold said.

Giving users a sense of security is beneficial to getting users to try CoPilot, Gold said. “Think of it as having the safest car on the road when you go to select a new car for your family,” he said.

Cybersecurity researchers have discovered two malicious packages on the npm registry that are designed to infect another locally installed package, underscoring the continued evolution of software supply chain attacks targeting the open-source ecosystem. The packages in question are ethers-provider2 and ethers-providerz, with the former downloaded 73 times to date since it was published on Ravie Lakshmananhttp://www.blogger.com/profile/09767675513435997467noreply@blogger.com

Two malicious packages were discovered on npm (Node package manager) that covertly patch legitimate, locally installed packages to inject a persistent reverse shell backdoor. [...]