Vulnerabilities

WebKit 531 (Vita FW BEFORE 2.00)
There are two exploits used for WebKit prior to 2.00. One is a data leakage exploit CVE-2010-4577 using type confusion to treat a double as a string memory address and length. The other is a type confusion exploit CVE-2010-1807 on the parseFloat function using a Nan as the arg.

WebKit 536 (Vita FW 2.00 thru 3.18) (CVE-2012-3748) (2013-09-03-1)
The heap memory buffer overflow vulnerability exists within the WebKit's JavaScriptCore JSArray::sort(...) method. This method accepts the user-defined JavaScript function and calls it from the native code to compare array items. If this compare function reduces array length, then the trailing array items will be written outside the "m_storage->m_vector[]" buffer, which leads to the heap memory corruption.

WebKit 537.73 (as used in Vita FW 3.30-3.36) (CVE-2014-1303)
The CSSSelectorList can be mutated after it's allocated. If the mutated list contains less entries than the original one, a restrictive 1-bit OOB write can be achieved.

WebKit 537.73 (as used in Vita FW 3.50-3.60) (unknown or no CVE)
The JSArray::sort method has a heap use-after-free vulnerability. If an array containing an object with a custom toString method is sorted, and the toString method causes the array to be reallocated, then the sorted elements will be written to the old freed address.

https://blog.xyz.is/2016/webkit-360.html

PSM Mono privilege escalation
https://yifan.lu/2015/06/21/hacking-the-ps-vita/

PSM Unity privilege escalation
UnityEngine.dll is a trusted assembly (SecurityCritical) and is not signed (can be modified). However, the actual file at  is PFS signed and encrypted, making this (and any) resource based hacks just as difficult as unsigned code execution hacks (which is the original goal).

PSM NetworkRequest privilege escalation
NetworkRequest.BeginGetResponse(AsyncCallback callback) invokes callback with  allowing for a privilege escalation. Unfortunately, Sony closed down the scoreboards feature which means that Network.AuthGetTicket fails and Network.CreateRequest cannot be invoked. There is no other way of creating a NetworkRequest object.

Stack buffer overflow in sceSblDmac5EncDec
(2014-09-16) might have found one SceSblDmac5Mgr_sceSblDmac5EncDec reads in 0x18 bytes from first arg processes a little then ROM:005F711A                MOV             R1, R11 ROM:005F711C                ADD             R0, SP, #0x88+var_70 ROM:005F711E                MOV.W           R2, R10,LSR#3 ROM:005F7122                BLX             _import_SceSblSsMgr_SceSysmemForDriver_sceKernelMemcpyUserToKernel R10 comes from orginal read in buffer+0x10 bad news is it got patched in 1.80 they also added a isShell check

Consensus: Confirmed exploitable before 1.80. YEAH!

sceIoDevctl does not clear stack buffer
(2014-11-24) Call some interesting functions that interest you in a kernel context (call some damn syscalls) Then call devctl and get upto 0x3FF bytes of that stack!

Fixed in 3.61.

Syscall handler doesn't check syscall number
(2015-07-03) A large syscall number passed in R12 can overflow syscall table and cause an arbitrary function pointer to be dereferenced and executed.

This was patched in 1.61.

Heap use-after-free in sceNetSyscallIoctl
(2016-04-05) sceNetSyscallIoctl is declared as. When  is in range (0x80; 0x1000], it will use SceNetPs custom malloc to allocate a buffer of that size on the heap. However, the second argument to malloc is 0, meaning that when not enough memory is available instead of returning NULL, it unlocks the global SceNetPs mutex and waits on a semaphore. Then, while malloc is waiting, another thread can free the socket sceNetSyscallIoctl is operating on, causing a use-after-free condition.

When passed proper arguments, sceNetSyscallIoctl will execute a function from the socket's vtable at the end:

v13 = (*(int (__fastcall **)(int, signed int, unsigned int, char *))(*(_DWORD *)(socket + 24) + 28))(             socket,              11,              flags_,              mem_);

Fixed in 3.63.

Ensō
(2017-04-30) A logic flaw related to error code propagation in NSBL allows for a buffer overflow in the data section and early code execution on ARM in non-secure privileged mode.

It was patched in 3.67.

yifan's write-up

enso source code

SMC 0x12F does not validate arguments -> TrustZone level arbitrary code execution
(2017-01-01) SMC 0x12F (sceSblSmSchedGetStatusMonitorCall) takes two unchecked arguments:   and.

is a pointer to TrustZone memory in the form of  and   is an integer value calculated as.

By passing the right value as, SMC 0x12F will read 0x08 bytes from   and return them at   which translates to a TrustZone arbitrary memory leak (0x08 bytes only).

By passing the right value as  it is also possible to write the leaked data into an arbitrary TrustZone memory region. The Non-secure Kernel sees the shared memory region at  (size is 0x5000 bytes) and the Secure Kernel sees the exact same memory region at , thus making it possible to plant data inside the Non-secure Kernel's region and having the SMC copy this data somewhere into TrustZone memory (e.g.: SMC table).

This results in TrustZone level arbitrary code execution.

It was patched somewhere around after 1.80 before 2.10.

A 1.80 TrustZone modules imports/exports list is available there.

Example code exploiting this vulnerability:

Crypto engine allows partial AES key overwrite
(2017-02-01) The Dmac5 crypto engine, accessible from the kernel, allows writing 4 bytes of key material at a time. This makes it possible to recover plaintext AES keys via bruteforce.

octopus exploit
(2017-02-18) To be disclosed.

https://twitter.com/pomfpomfpomf3/status/832806488221446145

octopus exploit

.---.        ,,                 ,,        /     \       ;,,'                ;, ;      (  o  o )      ; ; ;,';,,, \  \/ /      ,; ;               ,,,  ;,,,,;;,`   '-,;',,,'              ;,, ;,, ,,,,   ,;  ,,,;;,,;;                 ;,,,;    '  ;,,,,;'

(I copied the octopus from an ASCII art page: http://ascii.co.uk/art/octopus)

To be disclosed
(2017-02-23) To be disclosed.