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Before I continue, please note this is a rather lengthy infosec notice about the Windows command prompt as I have found a bug that might be exploitable using simple batch files. This bug is prevalent in all versions of Windows from 2000 up and works on 64 and 32-bit machines, and being that it's a batch file parsing bug, it requires no additional software to install (cmd.exe is a default part of Windows) and can be initiated by any user with any level of privilege (assuming they can run cmd.exe and thus parse batch files). Included in this summary is the assembly of where the bug happens (with breakdown of code flow to show why). This isn't an RCE level bug (not that I've been able to find yet), just a DoS type and would require that a user run it (or have it as a startup item), but given the simplicity of it and ubiquity of Windows systems, I figured it deserved a second look. Please note that I'm not responsible if you run any of these bug enabling batch files and crash your system (task manager and kill the PID works on a runaway script in case you do run them).

tldr: a batch file with only this line ^ nul<^ will cause a massive memory leak, while a batch file with only this line ^|^ causes the command prompt to crash due to 'infinite recursion'. These behaviors can lead to interesting batch 'hacks' on any Windows system (Win2k+) and the reason is a logic error in the cmd.exe batch file processing (see assembly and pseudo-C code below for more).

Background

While answering a question on SuperUser (link) I came across an interesting anomaly with how the command interpreter parses batch files. If the caret character (^) is the last character of the file, a memory leak/cmd.exe crash can happen. The caret has to be the last character of the file and cannot be followed by a \n (the line feed character), though \r (the carriage return character) is OK as it's stripped before the caret is parsed; nothing can trail it though as it would cause the parser to proceed normally (since ^\r\t would become ^\t thus the \t is "ignored"). This last note about carriage return characters being OK for this bug to still happen actually makes it a little more interesting because it 'fakes' a newline in most text editors, and in notepad you could be fooled into thinking there's a newline at the end ('technically' it's a carriage return or an 'old Mac' new line).

After doing some quick investigations I found that the ^ at the end of a file can lead to a memory leak or can crash the command prompt (more specifically the command.com or cmd.exe program), I also found that specific batch files (and sequences thereof) can lead to some very interesting behavior. Further investigations lead me to other people noting similar issues; a Stack Overflow question where a user noted a memory leak and a message board topic at ss64.com that noted other interesting behaviors with the caret at the EOF. The Stack Overflow question helped to confirm suspensions that it's an infinite loop type situation, but didn't try to dive much deeper than that. The ss64.org topic mostly just discussed various ways to make the command prompt crash, but failed to explain what kind of crash it was or why.

Naturally this lead me to question what was happening and why (and could it be exploited). The answers are mixed and the fix is quite simple (at least it seems 'simple' from the assembly I was inspecting). I found that there a few combinations of batch file trickery that can yield a memory leak, how fast or slow depends on what is put in the batch file (not how many carets, but sequences of pipes and interestingly line length [more later]) and regardless of crash or memory leak, the parser code is in a tight loop on a single thread, so CPU usage increases significantly (single core CPU or pushed to a single affinity, yields an average of 98+% CPU usage).

The Crashing

To crash the command prompt was simple enough, a batch file with no newlines containing only the following characters ^&^ (or ^|^), will cause the command prompt the batch is being processed on to crash with an error code of 0xC00000FD, which is a stack/frame overflow due to infinite recursion. That confirmed the 'infinite loop' scenario, but didn't quite explain the memory leak (or why for that matter it was crashing due to an infinite recursion??). To this extent, I started by examine some of the simplest ways to produce a memory leak; as it turns out, a 2 byte batch file is all that is needed to consume 100% CPU and eat memory (albeit at an insanely slow rate, ~8k/5s on a 2.2GHz i7).

Eat Memory

The batch file I used to test contained the following hex bytes:

0x01 0x5E

0x5E is the caret character (^) and 0x01 is the ASCII character code for 'start of header'. The first HEX code is only half significant in the bug, it can't be null (0x00), \r, |, or the & as these characters cause the batch file to exit via a normal termination (i.e. 'invalid command detected'). I used the 0x01 to demonstrate that it didn't have to be a valid command (or printable character for that matter) to induce the bug, a 2 byte batch file containing simply a^ will suffice too.

Doing some other testing, I found the quickest way to eat memory (and simplest) with a batch file is the following line: ^ nul<^

... Having inadvertently run this myself a couple of times, please be aware this will cripple a 64-bit system rather quickly; it took roughly 20 seconds to eat all of my remaining 14GB of RAM (16GB total) on my quad core (HTT, so 8 effective cores) i7, which then rendered my machine useless while everything was trying to page (I had to restart my machine). Running this 'quick' version on a 32-bit system ended the command parser with an out of memory error as it quickly exhausts its 32-bit 2GB limit. It doesn't crash the command prompt, instead it seems like there's a check to ensure memory can be properly mallocd, and when it can't it just aborts the batch processing.

Chained bug fun

Note though that all of these 'batch exploits' can be 'chained' together, so on a 32-bit system (assuming it only had 4GB of RAM with no PAE), one could run the following command to preform a DoS on it: cmd eat_mem.bat | eat_mem.bat (this will launch 2 command parsers and exhaust 2GB each).

Another interesting variation is to chain the 'crash' batch files together; for example, assuming there's a file called crash.bat and it contained our 'crash exploit' from above (^&^), you could do the following: cmd crash.bat | crash.bat and note some interesting behavior. This particular one causes the output of cmd crash.bat to be written to a pipe that has crashed (due to the parser bug) and thus gives wrote to a non-existent pipe errors when you attempt to CTRL+C out of it; interestingly enough though it still allows you to execute commands, like typing notepad and hitting enter will launch notepad. I have explored this more for possible pipe hijacking but don't have anything fruitful just yet (more on 'exploits' below).

8K buffer

As the Stack Overflow question/answer had alluded to, the more ^ you had on a line, the faster it would eat memory (aside from the 'quick' version I found). Through some more experiments, I found that 'line length' can actually have some interesting effects on this bug as well. If the last line of the batch file has a ^ at the end of it and is exactly 8192 bytes long (including the caret), the bug fails...Yet anything below and above multiples of 8192 cause the bug. The more bytes in a string, the faster memory is consumed (up to a multiple of 8192). This 8192 number is interesting as our memory leak is 8k (or in larger chunks thereof).

It should be noted that the file size is irrelevant to the bug and because of this can be put in just about any innocuous batch file. As a test I put the 'quick' version (^ nul<^) at the end of a batch file I use to compile a lot of legacy code. This compiler script is just under 21KB with recursive calls and multiple functions (to allow me to compile certain things) and putting the 'buggy' line at the end of the file allowed me to run the compile script as normal and complete as normal, but when it hit the 'bug' it spun up my CPU and quickly ate my memory.

If I was an unassuming software engineer given a 'simple' compiler script (with a call to :eof randomly in there 'forcing' the bug), I wouldn't think twice if the script suddenly kicked up my CPU, and if I wasn't paying attention to my task manager I would not see how quickly my RAM was eaten and then have to restart (not fun).

Dig Deeper

From here I decided to do some higher level inspections to see what was happening with the command prompt while this leak was happening. I opened up the Process Explorer and Procmon tools to inspect what was happening in the processes (on the stack with PE) and with the system (via Procmon). Procmon confirmed the 8k (more specifically 8191 bytes) leak with a call to ReadFile with an 8191 byte buffer and PE confirmed the calls to the kernel for ReadFile, though I wasn't too sure why the batch file was being read?

Interestingly, this bug also allows batch files to be modified while running and re-parsed (up to 8k of 'parsing', line feeds and all). It should be noted that the contents can be modified and certain commands will be processed, but I've noticed that unless there's a lot of other commands (more specifically line feeds before the final ^), timing can also play a part in success of a modified batch 'hack' though it happens more often than not (i.e. it works most of the time).

These batch exploits lead me to wonder if the same could be done programmatically; my first try was a simple C program that simply had system("crash.bat"); which called the batch file containing ^&^ in it. This launched a separate cmd.exe process which subsequently crashed returning control to my program (this was all expected). I then switched to the simple memory leak file (contained just a^) and ran the program again, this time the cmd.exe ran and started to spin up (as expected), but when I pressed CTRL+C, the cmd.exe process was orphaned and control returned to my program leaving me to have to end the rogue cmd.exe process through the task manager. I also tried using the lines from the file directly in my program (i.e. calling something to the effect of system("^ nul<^");) but got valid results back (valid in this case meaning the command was deemed 'invalid' by the command parser). I tried variations of how to hook into the process or take advantage of the stack/frame overflow error, but due to the cmd.exe being the parser itself, some of the more obvious exploits won't be as easy. To this extent, I decided to break open the cmd.exe process and inspect the assembly to verify what was leaking and to better understand what was happening and how it could be exploited (if at all).

The Code (cmd.exe)

I used Visual Studio 2010 and attached to a running cmd.exe process, then using the 'simple' memory leak batch file (a^) paused the process to step through the assembly while the parser was in the error state. After inspecting the assembly and using Process Explorer to verify what module I was in during debug, I was able to trace a lot of the code flow and found where the parser looked for the ^ character (hex 0x5E). The following is the assembly flow as I can see where the issue lie.

Note that a lot of the 'main' and 'parsing' function assembly has been removed for brevities sake (relevant code posted but the full dump of what I've found is available upon request [1.2 MB ASM dump with comments]):

; start cmd.exe asm code flow 

000000004A161D50 ; { start main  (more init frame/code here)
; { start loop
000000004A161FC1 3B F5                cmp         esi,ebp  
; mem leak here?? esi == #bytes, ebp == our 8191 buffer size number
000000004A161FC3 7D 29                jge         000000004A161FEE  
000000004A161FC5 0F B7 44 24 20       movzx       eax,word ptr [rsp+20h]  
000000004A161FCA 48 8D 54 24 70       lea         rdx,[rsp+70h]  
000000004A161FCF 48 8D 4C 24 20       lea         rcx,[rsp+20h]  
000000004A161FD4 66 89 03             mov         word ptr [rbx],ax  
000000004A161FD7 48 83 C3 02          add         rbx,2  
000000004A161FDB FF C6                inc         esi 
000000004A161FDD 48 89 5C 24 60       mov         qword ptr [rsp+60h],rbx  
000000004A161FE2 E8 99 04 00 00       call        000000004A162480  ; main_parser_fn
000000004A161FE7 3D 00 01 00 00       cmp         eax,100h  
000000004A161FEC 75 D3                jne         000000004A161FC1
; } end loop
000000004A162058 ; } end main?? function here

; { start main_parser_fn
000000004A162480 48 8B C4             mov         rax,rsp  
000000004A162483 48 89 58 08          mov         qword ptr [rax+8],rbx  
000000004A162487 48 89 70 10          mov         qword ptr [rax+10h],rsi  
000000004A16248B 48 89 78 18          mov         qword ptr [rax+18h],rdi  
000000004A16248F 4C 89 60 20          mov         qword ptr [rax+20h],r12  
000000004A162493 41 55                push        r13  
000000004A162495 48 83 EC 20          sub         rsp,20h  
000000004A162499 48 8B DA             mov         rbx,rdx  
000000004A16249C 48 8B F9             mov         rdi,rcx  
000000004A16249F E8 BC FB FF FF       call        000000004A162060  ; get_next_char
000000004A1624A4 33 F6                xor         esi,esi  
000000004A1624A6 66 89 07             mov         word ptr [rdi],ax  
000000004A1624A9 39 35 D1 98 03 00    cmp         dword ptr [4A19BD80h],esi  
000000004A1624AF 0F 85 F1 75 01 00    jne         000000004A179AA6  
000000004A1624B5 0F B7 17             movzx       edx,word ptr [rdi]  
000000004A1624B8 41 BD 3C 00 00 00    mov         r13d,3Ch  
000000004A1624BE 8B CA                mov         ecx,edx  
000000004A1624C0 45 8D 65 CE          lea         r12d,[r13-32h]  
000000004A1624C4 3B D6                cmp         edx,esi  
000000004A1624C6 74 98                je          000000004A162460  
000000004A1624C8 41 2B CC             sub         ecx,r12d  
000000004A1624CB 74 93                je          000000004A162460  
000000004A1624CD 83 E9 1C             sub         ecx,1Ch  
000000004A1624D0 74 91                je          000000004A162463  
000000004A1624D2 83 E9 02             sub         ecx,2  
000000004A1624D5 0F 84 61 FF FF FF    je          000000004A16243C  
000000004A1624DB 83 E9 01             sub         ecx,1  
000000004A1624DE 0F 84 6A FF FF FF    je          000000004A16244E  
000000004A1624E4 83 E9 13             sub         ecx,13h  
000000004A1624E7 0F 84 76 FF FF FF    je          000000004A162463  
000000004A1624ED 83 E9 02             sub         ecx,2  
000000004A1624F0 0F 84 6D FF FF FF    je          000000004A162463  
000000004A1624F6 83 E9 02             sub         ecx,2  
000000004A1624F9 0F 84 28 FF FF FF    je          000000004A162427  ; quote_parse_fn
000000004A1624FF 41 3B CD             cmp         ecx,r13d  ; check if it's the '<'
000000004A162502 0F 84 5B FF FF FF    je          000000004A162463  
000000004A162508 83 FA 5E             cmp         edx,5Eh  ; start the '^' parse
000000004A16250B 0F 84 86 DC 00 00    je          000000004A170197  ; caret_parse
000000004A162511 83 FA 22             cmp         edx,22h  
000000004A162514 0F 84 5E 2F 00 00    je          000000004A165478  
000000004A16251A F6 03 23             test        byte ptr [rbx],23h  
000000004A16251D 0F 84 E5 00 00 00    je          000000004A162608  
000000004A162523 0F B7 0F             movzx       ecx,word ptr [rdi]  
000000004A162526 FF 15 54 6C 02 00    call        qword ptr [4A189180h]  
000000004A16252C 3B C6                cmp         eax,esi  
000000004A16252E 0F 85 C0 10 00 00    jne         000000004A1635F4  
000000004A162534 33 C0                xor         eax,eax  
000000004A162536 48 8B 5C 24 30       mov         rbx,qword ptr [rsp+30h]  
000000004A16253B 48 8B 74 24 38       mov         rsi,qword ptr [rsp+38h]  
000000004A162540 48 8B 7C 24 40       mov         rdi,qword ptr [rsp+40h]  
000000004A162545 4C 8B 64 24 48       mov         r12,qword ptr [rsp+48h]  
000000004A16254A 48 83 C4 20          add         rsp,20h  
000000004A16254E 41 5D                pop         r13  
000000004A162550 C3                   ret  
; } end main_parser_fn

; { start get_next_char
000000004A162060 FF F3                push        rbx  
000000004A162062 48 83 EC 20          sub         rsp,20h  
000000004A162066 48 8B 05 0B C2 02 00 mov         rax,qword ptr [4A18E278h]  
000000004A16206D 8B 0D ED 9B 03 00    mov         ecx,dword ptr [4A19BC60h]  
000000004A162073 33 DB                xor         ebx,ebx  
000000004A162075 66 39 18             cmp         word ptr [rax],bx 
000000004A162078 74 29                je          000000004A1620A3  ; when bx=0 
000000004A16207A 66 83 38 0D          cmp         word ptr [rax],0Dh ; 0d = \r
000000004A16207E 0F 84 69 0E 00 00    je          000000004A162EED  
000000004A162084 3B CB                cmp         ecx,ebx  
000000004A162086 0F 85 46 7A 01 00    jne         000000004A179AD2  
000000004A16208C 0F B7 08             movzx       ecx,word ptr [rax]  
000000004A16208F 48 83 C0 02          add         rax,2  
000000004A162093 48 89 05 DE C1 02 00 mov         qword ptr [4A18E278h],rax  
000000004A16209A 66 8B C1             mov         ax,cx  
000000004A16209D 48 83 C4 20          add         rsp,20h  
000000004A1620A1 5B                   pop         rbx  
000000004A1620A2 C3                   ret  
; } end get_next_char
000000004A1620A3 E8 18 00 00 00       call        000000004A1620C0  
000000004A1620A8 48 8B 05 C9 C1 02 00 mov         rax,qword ptr [4A18E278h]  
000000004A1620AF 8B 0D AB 9B 03 00    mov         ecx,dword ptr [4A19BC60h]  
000000004A1620B5 EB C3                jmp         000000004A16207A  

000000004A1620C0  ; this starts a large chunk of code that does more parsing (as well as calls
; some CriticalSection code) it's omitted from this because the issues that are prevalent in the
; rest of the code are pertaining to the 'caret_parser' not returning properly. The 'memory leak'
; is in this section code (an 8k buffer read that's also checked in main loop).


; { start quote_parse
000000004A162463 F6 03 22             test        byte ptr [rbx],22h  
000000004A162466 0F 85 9C 00 00 00    jne         000000004A162508  
000000004A16246C B8 00 01 00 00       mov         eax,100h  
000000004A162471 E9 C0 00 00 00       jmp         000000004A162536  
; } end quote_parse

; { start caret_parse
000000004A170197 F6 03 22             test        byte ptr [rbx],22h ; check if '"' 
000000004A17019A 0F 85 71 23 FF FF    jne         000000004A162511  ; if char == '"'
000000004A1701A0 E8 BB 1E FF FF       call        000000004A162060  ; get_next_char
000000004A1701A5 66 89 07             mov         word ptr [rdi],ax  ; ax will be 0 if EOF
000000004A1701A8 66 41 3B C4          cmp         ax,r12w  ; r12w is 0x0A ('\n') here, so this is a EOL check (fail in EOF case)
000000004A1701AC 0F 85 82 23 FF FF    jne         000000004A162534  ; this is the jump back to the 'main_parser_fn' <--error
000000004A1701B2 E9 0B 99 00 00       jmp         000000004A179AC2  ; == call 000000004A162060 (get_next_char)
000000004A1701B7 33 C9                xor         ecx,ecx  
000000004A1701B9 E8 22 1B FF FF       call        000000004A161CE0  
; } end caret_parse

; end cmd.exe asm code flow 

Based on this assembly, I was able to ascertain that the cmd.exe parsing code is doing something like this (psuedo-C code):

void main_parser_fn() { 
    /* the 'some_read_condition' is based on a lot of things but
       interestingly one of them is an 8k buffer size; the ASM
       shows an 8191 byte buffer for reading/parsing, but I
       couldn't ascertain why having a buffer divisible by exactly
       8192 bytes in the line buffer was 'ok' but anything more or
       less causes the continuation (mem leak)?? */
    while (some_read_condition) {
        // allocate 8k buffer appropriately
        x = get_next_char();
        if (x == '|' || x == '&') {
            main_parser_fn();
        }
        if (x == '^') {
            get_next_char(); // error here
            // POSSIBLE FIX:
            // if (get_next_char() == 0) { abort_batch(); }
            continue;
        }
        // free buffer (never get here due to EOF error)
    }
}

This is (of course) a rough approximation based on the input/output and assembly, but it seems that the code to get the next character after the caret is where the issue resides.

The Bug Explained

The bug is that when a caret is detected, the next character is read from the file (to be 'escaped'). If the caret is the last character of the file, this results in a logic error, as when a call to get_next_char is made, the file pointer is incremented by one; in this case that puts it passed the EOF. Since the EOF is effectively ignored when the command parser continues to read the next input, it essentially 'resets' its file pointer due to the EOF+1 error. In this case, putting the file pointer to EOF+1 causes the pointer to be at some large negative number, and since file's can't go below 0, it's file pointer is basically reset to 0 and the parsing continues from the beginning of the file.

This explains the memory leaks and why it's 8k (an 8k 'read buffer' being filled), and can also explain the recursion issue. When a | or & is detected in the batch file, it's recursively parsed out, and since there's an EOF bug the recursion then becomes infinite as no return paths can be had.

Edit: As some comments have pointed out, and further research has shown, the caret doesn't have to be at the end of the file for this bug to happen, I'm currently investigating (and breaking down more of the ASM) to see if there are other scenario's and why/how it's happening.

The Fix

It seems that a simple fix would be to check for EOF on a read of the next character when parsing the caret. This check (and subsequent 'proper batch abort' functionality) would fix the memory leak issue as well as the infinite recursion.

Exploits?

After inspecting the process more and thinking about possible exploits, I don't see this being anywhere as serious as MS14-019, but given the ease of its use/implementation (and relative ease of fixing it), I would consider this 'medium' level alert as most 'exploits' would require the user to run the batch file, and 'obvious' avenues like trying to exploit the stack/frame overflow error or launch shell code through a batch file would prove more difficult over the many other exploits that would yield a more 'fruitful' outcome vs this innocuous batch bug. Though I can see it being used in a DoS attack as it's easy to write one given that it's 7 bytes (^ nul<^) and could potentially be distributed and 'setup' rather easy.

Here's a simple vbscript that could be used to write and launch the 'killer' batch file (and do it all silently)

CreateObject("Scripting.FileSystemObject").CreateTextFile("killer.bat", True).Write("^ nul<^") & VbCr
CreateObject("WScript.Shell").Run "killer.bat", 0, False

That will create a batch file named killer.bat with a ^ nul<^\r in it and then run it, this could be put in a .vbs file and run at startup, or put in an Excel macro and run.

echo|set /p="^ nul<^" > killer.bat

That line is the command line equivalent to create the 'killer' batch file (doing a normal echo to a file would result in a \r\n at the end of the file and thus the bug won't be present).

As a proof of concept, I created this vbscript (as well as some other batch file tests), and put them in my Startup folder and registry as well. When I logged in, I was greeted with a command prompt when using the batch files and nothing when using the vbscript, and in a few seconds my system came to a halt and was unusable because the script had consumed all my RAM. The scripts can be ended via killing the running cmd.exe process, but because they work so fast, you might not even have enough time to launch the task manager before it consumes all of the RAM. Removal through Safe Mode was the 'cure' for this, but not the 'fix'.

I could also envision a scenario where an unsuspecting admin is going to run a backup.bat script with this unfortunate bug in it and inadvertently bringing down their server. Or the fun that might be had with the at/schtasks.exe commands on an unsecured system.

Granted I don't see these 'exploits' leaving the realm of a DoS or prank.

I'm still inspecting various avenues with piping and redirection of the 'broken' scripts that could possibly lead to an RCE, as it stands the simplest attack vector is a DoS attack with the 'quick' file. I've tested this bug on Windows 98, 2000, XP, Vista, 7, 8, and the server variations (to include 32 and 64 bit flavors). Windows 98 command prompt is not affected by this, but every version above it is (to include command.com since it uses cmd.exe to parse batch files). Out of curiosity I also tested this on ReactOS and Wine (neither of which had the issue).

Questions (edited after more research)

As stated, I don't see this bug being "exploitable" more than a denial of service "attack" (or prank on co-worker/friend), but it got me thinking in general about frame overflow's and memory leaks, more specifically if they are exploitable (just in general).

My experience and understanding from a software engineering/hacker perspective tells me that memory leaks or frame overflow's could be potentially exploited on an older OS (say Windows 98/2000/XP or older versions of *nix?) that don't have certain protections in place (like use of the NX bit or ASLR) given the right conditions, but I haven't been able to find any research into these areas aside from the 'normal' attack vectors (stack based buffer overflows) or general documentation on what these things 'are' (i.e. the 'white paper' discussions on what a frame overflow or memory leak is and what NX/ASLR are) and not on 'why' you can't.

I've been experimenting with injecting a thread or some other method into the running cmd.exe process to run tests on and analyze the frame overflow and memory leak that occurs within it (as well as just general fun that can be had with this bug, like using CreateProcess and then EmptyWorkingSet for general fun) and I know I won't 'get anywhere' with this particular bug, but it got me thinking (or over thinking rather): has there ever been a frame overflow exploit or memory leak exploit in the wild or is there some documentation I might be able to read that explains why (more specifically/technically) it's not feasible?

I understand the 'why' but more specificity, like 'the EIP register is protected because XYZ...' as opposed to just 'no it's not possible', would be helpful; I know each architecture is different and I might be asking for more details than could be had in an answer, but links or discussion points I could reference are helpful too since I can't seem to find too much in reference to this.

I've been swimming in assembly, a fresh perspective always helps :)

Note: I sent an email (on 04/25/2014) to Microsoft with this bug and they have responded saying they have forward this to the development team and are investigating, no fix in a security bulletin is planned (agree with them on this as nothing yet indicates it's a serious flaw). Will edit should any more updates come.

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closed as unclear what you're asking by Lightness Races in Orbit, ecatmur, BoltClock Jun 6 '14 at 11:32

Please clarify your specific problem or add additional details to highlight exactly what you need. As it's currently written, it’s hard to tell exactly what you're asking. See the How to Ask page for help clarifying this question. If this question can be reworded to fit the rules in the help center, please edit the question.

15  
This question appears to be off-topic because it is not a programming question. –  Andrew Medico Apr 25 '14 at 18:05
34  
Doesn't seem like a particularly interesting bug. If you can get arbitrary batch files or VBScripts running on someone's computer, they have bigger things to worry about than cmd.exe instances crashing or RAM getting used up. –  Andrew Medico Apr 25 '14 at 18:11
17  
While not necessarily a serious issue, this is still a fantastic deep dig and interesting edge case issue! –  adanot Apr 29 '14 at 1:51
10  
This is awesome .. With jus 3 characters you can Hang any Windows system .. I love SO ,, –  spetzz Apr 29 '14 at 13:37
12  
This question appears to be off-topic because it is a book, or a whole website, or something. –  Lightness Races in Orbit Jun 6 '14 at 9:28

1 Answer 1

my question is why a memory leak or more specifically a frame overflow is not 'exploitable'

You need to execute a batch file or a command on the machine to exploit this. If you have that you can perform anything already with a standalone executable rather than trying to exploit cmd.

In fact cmd.exe already contains a vulnerability even without your bug. "It allows arbitrary code execution". :)

Even when you exploit cmd, your "payload" would still be running at cmd.exe's privilege level. You cannot perform privilege escalation by exploiting cmd.exe itself because it's a user mode process.

If cmd.exe was run as "Administrator", that's not an escalation but that's simply a user decision. It's similar for a user running your executable as Administrator. There is no "unwanted escalation" there.

The memory leak itself is useless either because you can, again, allocate as much as memory as you want. And if it was limited by policy, cmd.exe couldn't allocate more memory either. It's no different than running a while(1)malloc(1000000); (which would also hog CPU of course :))

Briefly:

  • You are not gaining more privilege than you have with your exploit
  • You cannot cause code execution with no access to the machine
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+1: Correct. This is not a security vulnerability. It does appear to be a minor code quality issue but this is not the correct place to "report" those. –  Lightness Races in Orbit Jun 6 '14 at 9:49

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