Difference between revisions of "3DS System Flaws"
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==Stale / Rejected Efforts== | ==Stale / Rejected Efforts== | ||
− | * Neimod has been working on a RAM dumping setup for a little while now. He's de-soldered the 3DS's RAM chip and hooked it and the RAM pinouts on the 3DS' PCB up to a custom RAM dumping setup. | + | * Neimod has been working on a RAM dumping setup for a little while now. He's de-soldered the 3DS's RAM chip and hooked it and the RAM pinouts on the 3DS' PCB up to a custom RAM dumping setup. A while ago he published photos showing his setup to be working quite well, with the 3DS successfully booting up. However, his flickr stream is now private along with most of his work. |
− | + | * Someone (who will remain unnamed) has released CFW and CIA installers, most of which are presumably copied from the work of others and include copyrighted material. | |
− | |||
− | * | ||
==Failed attempts== | ==Failed attempts== |
Revision as of 20:52, 21 January 2015
Exploits are used to execute unofficial code (homebrew) on the Nintendo 3DS. This page is a list of known 3DS-mode exploits.
List of 3DS exploits
Current Efforts
There are people working on finding exploits and documenting the 3DS. Here's a list of some current efforts being made to make homebrew on the 3DS possible:
- See here regarding Ninjhax.
Stale / Rejected Efforts
- Neimod has been working on a RAM dumping setup for a little while now. He's de-soldered the 3DS's RAM chip and hooked it and the RAM pinouts on the 3DS' PCB up to a custom RAM dumping setup. A while ago he published photos showing his setup to be working quite well, with the 3DS successfully booting up. However, his flickr stream is now private along with most of his work.
- Someone (who will remain unnamed) has released CFW and CIA installers, most of which are presumably copied from the work of others and include copyrighted material.
Failed attempts
Here are listed all attempts at exploiting 3DS software that have failed so far.
- Pushmo (3DSWare), QR codes: level name is properly limited to 16 characters, game doesn't crash with a longer name. The only possible crashes are triggered by out-of-bounds array index values, these crashes are not exploitable.
- Pyramids (3DSWare), QR codes: no strings. Only crashes are from out-of-bounds values (like background ID) and are not exploitable.
- 3DS browser, 2^32 characters long string: this is similar to the vulnerability fixed here, concat-large-strings-crash2.html triggers a crash which is about the same as the one triggered by a 2^32 string. Most of the time this vulnerability will cause a memory page permissions fault, since the WebKit code attempts to copy the string text data to the output buffer located in read-only CRO heap memory. The only difference between a crash triggered by a 2^32 string and the concat-large-strings-crash2.html crash is at the former copies the string data using the original string length(like 1 text character for "x", 4 for "xxxx") while the latter attempts to copy >12MB. In some very rare cases a thread separate from the string data-copy thread will crash, this might be exploitable. However, this is mostly useless since it rarely crashes this way.
Tips and info
The 3DS uses the XN feature of the ARM processor, and only apps that have the necessary permissions in their headers can set memory to be executable. This means that although a usable buffer overflow exploit would still be useful, it would not go the entire way towards allowing code to be run in an easy or practical fashion (like an actual homebrew launcher). For that, an exploit in the system is required. A buffer overflow exploit does, however, provide enough wiggle room through the use of return-oriented programming to potentially trigger a system exploit.
SD card extdata and SD savegames can be attacked, for consoles where the console-unique movable.sed was dumped.
Note that the publicly-available <v5.0 total-control exploits are Process9 exploits, not "kernel exploits".
System flaws
FIRM Process9
Summary | Description | Successful exploitation result | Fixed in FIRM system version | Last FIRM system version this flaw was checked for | Timeframe this was discovered | Discovered by |
---|---|---|---|---|---|---|
firmlaunch-haxx: FIRM header ToCToU | This can't be exploited from ARM11 userland.
During FIRM launch, the only FIRM header the ARM9 uses at all is stored in FCRAM, this is 0x200-bytes(the actual used FIRM RSA signature is read to the Process9 stack however). The ARM9 doesn't expect "anything" besides the ARM9 to access this data. |
ARM9 code execution | None | 9.3.0-X | 2012, 3 days after Yellows8 started Process9 code RE. | Yellows8 |
Uninitialized data output for PXI command replies | Various (stubbed?) PXI commands(including some here) just write uninitialized data (like from ARM registers) to the command reply. | None | 9.3.0-X | ? | Yellows8 | |
FSPXI OpenArchive SD permissions | Process9 does not use the exheader ARM9 access-mount permission flag for SD at all.
This would mean ARM11-kernelmode code / fs-module itself could directly use FSPXI to access SD card without ARM9 checking for SD access, but this is rather useless since a process is usually running with SD access(Home Menu for example) anyway. |
None | 9.3.0-X | 2012 | Yellows8 | |
PXIAM command 0x003D0108(See also this) | When handling this command, Process9 allocates a 0x2800-byte heap buffer, then copies the 4 FCRAM input buffers to this heap buffer without checking the sizes at all(only the buffers with non-zero sizes are copied). Starting with 5.0.0-X, the total combined size of the input data must be <=0x2800. | ARM9 code execution | 5.0.0-X | May 2013 | Yellows8 | |
PS RSA commands buffer overflows | pxips9 cmd1(not accessible via ps:ps) and VerifyRsaSha256: unchecked copy to a buffer in Process9's .bss, from the input FCRAM buffer. The buffer is located before the pxi cmdhandler threads' stacks. SignRsaSha256 also has a buf overflow, but this isn't exploitable.
The buffer for this is the buffer for the signature data. With v5.0, the signature buffer was moved to stack, with a check for the signature data size. When the signature data size is too large, Process9 uses svcBreak. |
ARM9 code execution | 5.0.0-X | 2012 | Yellows8 |
ARM11 kernel
Summary | Description | Successful exploitation result | Fixed in FIRM system version | Last FIRM system version this flaw was checked for | Timeframe this was discovered | Discovered by |
---|---|---|---|---|---|---|
SVC table too small | The table of function pointers for SVC's only contains entries up to 0x7D, but the biggest allowed SVC for the table is 0x7F. Thus, executing SVC7E or SVC7F would make the SVC-handler read after the buffer, and interpret some ARM instructions as function pointers.
However, this would require patching the kernel .text or modifying SVC-access-control. Even if you could get these to execute, they would still jump to memory that isn't mapped as executable. |
None | 9.3.0-21 | 2012 | ||
svcBackdoor (0x7B) | This backdoor allows executing SVC-mode code at the user-specified code-address. This is used by Process9, using this on the ARM11(with NATIVE_FIRM) requires patching the kernel .text or modifying SVC-access-control. | See description | None | 9.3.0-21 | ||
0xEFF00000 / 0xDFF00000 ARM11 kernel virtual-memory | The ARM11 kernel-mode 0xEFF00000/0xDFF00000 virtual-memory(size 0x100000) is mapped to phys-mem 0x1FF00000(entire DSP-mem + entire AXIWRAM), with permissions RW-. This is used during ARM11 kernel startup, this never seems to be used after that, however. | None | 9.3.0-X | |||
memchunkhax | The kernel originally did not validate the data stored in the FCRAM kernel heap memchunk-headers for free-memory at all. Exploiting this requires raw R/W access to these memchunk-headers, like physical-memory access with gspwn.
There are multiple ways to exploit this, but the end-result for most of these is the same: overwrite code in AXIWRAM via the 0xEFF00000/0xDFF00000 kernel virtual-memory mapping. This was fixed in 9.3.0-X by checking that the memchunk(including size, next, and prev ptrs) is located within the currently used heap memory. The kernel may also check that the next/prev ptrs are valid compared to other memchunk-headers basically. When any of these checks fail, kernelpanic() is called. |
When combined with other flaws: ARM11-kernelmode code execution | 9.3.0-21 | February 2014 | Yellows8 | |
PXI Command input/output buffer permissions | Originally the ARM11-kernel didn't check permissions for PXI input/output buffers for commands. Starting with 6.0.0 PXI input/output buffers must have RW permissions, otherwise kernelpanic is triggered. | 6.0.0-11 | 2012 | Yellows8 | ||
svcStartInterProcessDma | For svcStartInterProcessDma, the kernel code had the following flaws:
|
6.0.0-11 | DmaConfig issue: unknown. The rest: 2014 | |||
svcControlMemory Parameter checks | For svcControlMemory the parameter check had these two flaws:
|
5.0.0-11 | ||||
Command request/response buffer overflow | Originally the kernel did not check the word-values from the command-header. Starting with 5.0.0-11, the kernel will trigger a kernelpanic() when the total word-size of the entire command(including the cmd-header) is larger than 0x40-words (0x100-bytes). This allows overwriting threadlocalstorage+0x180 in the destination thread. However, since the data written there would be translate parameters (such as header-words + buffer addresses), exploiting this would likely be very difficult, if possible at all.
If the two words at threadlocalstorage+0x180 could be overwritten with controlled data this way, one could then use a command with a buffer-header of ((size<<14) | 2) to write arbitrary memory to any RW userland memory in the destination process. |
5.0.0-11 | v4.1 FIRM -> v5.0 code diff | |||
SVC stack allocation overflows |
This might allow for ARM11 kernel code-execution. (Applies to svcSetResourceLimitValues, svcGetThreadList, svcGetProcessList, svcReplyAndReceive, svcWaitSynchronizationN.) |
5.0.0-11 | v4.1 FIRM -> v5.0 code diff | |||
svcControlMemory MemoryOperation MAP memory-permissions | svcControlMemory with MemoryOperation=MAP allows mapping the already-mapped process virtual-mem at addr1, to addr0. The lowest address permitted for addr1 is 0x00100000. Originally the ARM11 kernel didn't check memory permissions for addr1. Therefore .text as addr1 could be mapped elsewhere as RW- memory, which allowed ARM11 userland code-execution. | 4.1.0-8 | 2012 | Yellows8 | ||
Command input/output buffer permissions | Originally the ARM11 kernel didn't check memory permissions for the input/output buffers for commands. Starting with 4.0.0-7 the ARM11 kernel will trigger a kernelpanic() if the input/output buffers don't have the required memory permissions. For example, this allowed a FSUSER file-read to .text, which therefore allowed ARM11-userland code execution. | 4.0.0-7 | 2012 | Yellows8 | ||
svcReadProcessMemory/svcWriteProcessMemory memory permissions | Originally the kernel only checked the first page(0x1000-bytes) of the src/dst buffers, for svcReadProcessMemory and svcWriteProcessMemory. There is no known retail processes which have access to these SVCs. | 4.0.0-7 | 2012? | Yellows8 |
FIRM ARM11 modules
Summary | Description | Successful exploitation result | Fixed in FIRM system version | Last FIRM system version this flaw was checked for | Timeframe this was discovered | Discovered by |
---|---|---|---|---|---|---|
"srv:pm" process registration | Originally any process had access to the port "srv:pm". The PID's used for the (un)registration commands are not checked either. This allowed any process to re-register itself with "srv:pm", and therefore allowed the process to give itself access to any service, bypassing the exheader service-access-control list.
This was fixed in 7.0.0-13: starting with 7.0.0-13 "srv:pm" is now a service instead of a globally accessible port. Only processes with PID's less than 6 (in other words: fs, ldr, sm, pm, pxi modules) have access to it. With 7.0.0-13 there can only be one session for "srv:pm" open at a time(this is used by pm module), svcBreak will be executed if more sessions are opened by the processes which can access this. This flaw was needed for exploiting the <=v4.x Process9 PXI vulnerabilities from ARM11 userland ROP, since most applications don't have access to those service(s). |
Access to arbitrary services | 7.0.0-13 | 2012 | Yellows8 |
ARM11 system modules
Summary | Description | Successful exploitation result | Fixed in system version | Last system version this flaw was checked for | Timeframe this was discovered | Discovered by |
---|---|---|---|---|---|---|
gspwn | GSP module does not validate addresses given to the GPU. This allows a user-mode application/applet to read/write to a large part of physical FCRAM using GPU DMA. From this, you can overwrite the .text segment of the application you're running under, and gain real code-execution from a ROP-chain. Normally applets' .text(Home Menu, Internet Browser, etc) is located beyond the area accessible by the GPU, except for CROs used by applets(Internet Browser for example). | User-mode code execution. | None | 9.4.0-21 | ||
rohax | Using gspwn, it is possible to overwrite a loaded CRO0/CRR0 after its RSA-signature has been validated. Badly validated CRO0 header leads to arbitrary read/write of memory in the ro-process. This gives code-execution in the ro module, who has access to syscalls 0x70-0x72, 0x7D.
This was fixed after ninjhax release by adding checks on CRO0-based pointers before writing to them. |
Memory-mapping syscalls. | 9.3.0-21 | 9.4.0-21 | ||
Region free | Only Home Menu itself checks gamecards' region when launching them. Therefore, any application launch that is done directly with NS without signaling Home Menu to launch the app, will result in region checks being bypassed.
This essentially means launching the gamecard with the "ns:s" service. The main way to exploit this is to trigger a FIRM launch with an application specified, either with a normal FIRM launch or a hardware reboot. |
Launching gamecards from any region + bypassing Home Menu gamecard-sysupdate installation | None | 9.4.0-21 | June(?) 2014 | Yellows8 |
ARM11 system applications and applets
Summary | Description | Successful exploitation result | Fixed in system version | Last system version this flaw was checked for | Timeframe this was discovered | Discovered by |
---|---|---|---|---|---|---|
3DS System Settings DS profile string stack-smash | Too long or corrupted strings (01Ah 2 Nickname length in characters 050h 2 Message length in characters) in the NVRAM DS user settings (System Settings->Other Settings->Profile->Nintendo DS Profile) cause it to crash in 3DS-mode due to a stack-smash. The DSi is not vulnerable to this, DSi launcher(menu) and DSi System Settings will reset the NVRAM user-settings if the length field values are too long(same result as when the CRCs are invalid). TWL_FIRM also resets the NVRAM user-settings when the string-length(s) are too long. | ROP in mset. | 7.0.0-13 | 7.0.0-13 | 2012 | Ichfly |
General/CTRSDK
Summary | Description | Successful exploitation result | Fixed in version | Last version this flaw was checked for | Timeframe this was discovered | Discovered by |
---|---|---|---|---|---|---|
UDS beacon additional-data buffer overflow | Originally CTRSDK did not validate the UDS additional-data size before using that size to copy the additional-data to a networkstruct. This was eventually fixed.
This was discovered while doing code RE with an old dlp-module version. It's unknown in what specific CTRSDK version this was fixed, or even what system-version updated titles with a fixed version. It's unknown if there's any titles using a vulnerable CTRSDK version which are also exploitable with this(dlp module can't be exploited with this). The maximum number of bytes that can be written beyond the end of the outbuf is 0x37-bytes, with additionaldata_size=0xFF. |
Perhaps ROP, very difficult if possible with anything at all | ? | September(?) 2014 | Yellows8 |