Table of Contents
Foreword
I’ve been gone for a little long this time, mainly because I took the time to finish the entire book of “The C Programming Language” by Brian Kernighan and Dennis Ritchie. It was a rather quick read (I guess C was not a very complex language after all), but it helped me immensely. Adobe Acrobat and Adobe Reader had changed a lot since the article I was following in the last article was written, and JP2KLib.dll also had a bit of a minor change, so I ended up having to change some things and do a bit of debugging by myself to fix the harness, and I will be covering all of that here.
Introduction
The last time I touched this, I was simply following suit along with the article “50 CVEs in 50 Days”. I stopped last time at JP2KDecOptCreate, where my function did not return the correct return value for the function. This time, with much better knowledge and more experience in debugging as well as reverse engineering the JP2K library, I decided that there were many things that I had to confirm myself to ensure that the harness would not break. I will be using windbg and IDA a lot through this post so please bear with me.
Implementing the NOP Functions
I first needed to figure out what nop4 and nop7 could possibly be, as they were both called by JP2KDecOptCreate. The article mentioned that they were wrappers around malloc and memset, but I had to make sure for myself. I fired up windbg and set a breakpoint at nop4 and nop7 respectively, then stepped forward one execution step at a time until eventually I arrived at the following:
nop4:
eax=0ebc3db6 ebx=00000000 ecx=75e1edb0 edx=01400200 esi=75e1edb0 edi=222d65c8
eip=79c576d7 esp=00b8cf70 ebp=00b8cf78 iopl=0 nv up ei pl zr na pe cy
cs=0023 ss=002b ds=002b es=002b fs=0053 gs=002b efl=00000247
Acrobat!AcroWinMainSandbox+0x33b7:
79c576d7 ffd6 call esi {ucrtbase!malloc (75e1edb0)}
nop7:
eax=00000000 ebx=240ee4f0 ecx=240ee4f0 edx=11010100 esi=7a3f37c0 edi=00000058
eip=79c4d3e0 esp=00b8cf44 ebp=00b8cf70 iopl=0 nv up ei pl nz na pe nc
cs=0023 ss=002b ds=002b es=002b fs=0053 gs=002b efl=00000206
Acrobat+0x4d3e0:
79c4d3e0 ff25f0413a7b jmp dword ptr [Acrobat!CTJPEGThrowException+0x2851f0 (7b3a41f0)] ds:002b:7b3a41f0={VCRUNTIME140!memset (72183c30)}
There, now we know for sure that at least these 2 wrappers had not changed so I went ahead and implemented them. The malloc wrapper was pretty straightforward to implement, it just took in an argument for size to pass to malloc and returned the address that malloc returned. The memset wrapper was also pretty straightforward as it took in 3 args in the same order that memset accepted: void* dest, int val, int size in this exact order. After implementing them, I ran the harness again to make sure it was not crashing, and it worked.
...
pointer address of JP2KDecOptCreate: 79A16690
==> nop4 (malloc wrapper) called, with args size:58
==> nop7 (memset wrapper) called with args val:0, size:58, dest:001A1C48
JP2KDecOptCreate: ret = 001A1C48
The article also mentioned that nop5 and nop6 were wrappers around free and memcpy respectively, but I also had to make sure for myself:
nop5:
eax=7bc6c51c ebx=00000000 ecx=79c735d0 edx=04000000 esi=79c735d0 edi=00000000
eip=79c5820c esp=00b8cd50 ebp=00b8cd58 iopl=0 nv up ei pl nz na po nc
cs=0023 ss=002b ds=002b es=002b fs=0053 gs=002b efl=00000202
Acrobat!AcroWinMainSandbox+0x3eec:
79c5820c 8b7018 mov esi,dword ptr [eax+18h] ds:002b:7bc6c534={ucrtbase!free (75e228c0)}
nop6:
eax=0f47e6f0 ebx=0000005c ecx=7a3f3780 edx=11010100 esi=7a3f3780 edi=2410e510
eip=79a1600f esp=00b8cd20 ebp=00b8cd30 iopl=0 nv up ei pl zr na pe cy
cs=0023 ss=002b ds=002b es=002b fs=0053 gs=002b efl=00000247
JP2KLib!JP2KTileGeometryRegionIsTile+0x3bf:
79a1600f ffd6 call esi {Acrobat!AX_PDXlateToHostEx+0x418530 (7a3f3780)}
nop5 was straightforward but nop6 wasn’t quite so, so I fired up IDA and looked into the function it was calling and sure enough, it was a memcpy wrapper:
I implemented nop4, nop5, nop6 and nop7 and then moved onwards to the next functions.
Implementing a Custom File Stream Class
Following the article, I added JP2KDecOptInitToDefaults and passed to it the return value from JP2KDecOptCreate. This was definitely still the case as a quick run in windbg showed that:
eax=240ee4f0 ebx=00000000 ecx=00000001 edx=00000058 esi=79fffb30 edi=240d3e88
eip=79a1669b esp=00b8cf80 ebp=00b8d03c iopl=0 nv up ei pl nz ac po nc
cs=0023 ss=002b ds=002b es=002b fs=0053 gs=002b efl=00000212
JP2KLib!JP2KDecOptCreate+0xb:
79a1669b c3 ret
and
eax=79a166c0 ebx=00000000 ecx=00000001 edx=00000058 esi=240ee4f0 edi=240d3e88
eip=79a166c0 esp=00b8cf7c ebp=00b8d03c iopl=0 nv up ei pl nz ac po nc
cs=0023 ss=002b ds=002b es=002b fs=0053 gs=002b efl=00000212
JP2KLib!JP2KDecOptInitToDefaults:
79a166c0 55 push ebp
0:000> dd esp
00b8cf7c 7a3f3d5e 240ee4f0 42bb8065 222d65c8
00b8cf8c 2410a4c4 00000000 00000000 00000000
00b8cf9c 00b8cfcc 00000003 42bb9fe5 0000040c
00b8cfac 00b8d024 240d4114 00000008 00002054
00b8cfbc 7759a180 1e71d298 154a0000 1e71d298
00b8cfcc 00b8d0cc 79e71800 154ff8a4 00000000
00b8cfdc 775af94e 00000008 00000000 00002054
00b8cfec 00002054 00000000 00b8d00c 75e20647
From here, we move on to JP2KImageInitDecoderEx, which still took in 5 arguments, and with windbg we can easily see that it took in 2 of the return values that we got earlier:
eax=79a150b0 ebx=240eda10 ecx=240a3948 edx=00000000 esi=7a3d8da0 edi=2410a4c4
eip=79a150b0 esp=00b8cf54 ebp=00b8d040 iopl=0 nv up ei pl nz ac po nc
cs=0023 ss=002b ds=002b es=002b fs=0053 gs=002b efl=00000212
JP2KLib!JP2KImageInitDecoderEx:
79a150b0 6a24 push 24h
0:000> dd esp
00b8cf54 7a3f56a9 240ea4b8 240a3948 240d3e88
00b8cf64 240ee4f0 223d14f0 240eda10 7a3dc3a0
00b8cf74 2410a4c4 240eda10 00000000 00000054
00b8cf84 42bb8065 222d65c8 2410a4c4 00000000
00b8cf94 00000000 00000000 00b8cfcc 00000003
00b8cfa4 42bb9fe5 0000040c 00b8d024 240d4114
00b8cfb4 00000008 00002054 7759a180 1e71d298
00b8cfc4 154a0000 1e71d298 00b8d0cc 79e71800
In order on the stack, 240ea4b8 was the return value from JP2KImageCreate, followed by 2 unknown structs, 240ee4f0 was the return value from JP2KDecOptCreate, followed by a last unknown struct. That’s right, this function had changed since the article I was referring to was written, so it no longer took in the return value of JP2KGetMemObjEx as its last argument, even though JP2KGetMemObjEx was still called in the correct order (and a lot of times too). Weird, but we could still move on. For now, I used a placeholder for the last argument and followed what the article did to also arrive at the same conclusion: the second argument was a pointer to a file stream object and the third argument was a struct of functions that would be carried out on the second argument. Hence, I also had to create my own file object and file stream functions to pass into this function:
typedef struct {
FILE *fileptr;
} file_obj_t;
It was just a simple struct that took in FILE* as its only variable. To save space and clutter, I will not be showing every single function that I created, but the filestream functions were something like these:
is_readable:
int file_obj_is_readable(const file_obj_t *file) {
printf("file_obj_is_readable called\n");
return (feof(file->fileptr)) ? 0:1;
}
write:
int file_obj_write(void* fileptr, unsigned char *data, int param2) {
printf("file_obj_write called with params fileptr=%p, data=%p, param2=%d\n", fileptr, data, param2);
return fwrite(data, 1, param2, fileptr);
}
The article mentioned at one point that they realized that the SEEK constants were different in Adobe compared to in libc, so I had to swap them too (SEEK_SET and SEEK_CUR were swapped, same as mentioned in the article), leading me to do some sort of a mini-workaround in my seek function:
int file_obj_seek(void* fileptr, int offset, uint64_t whence) {
printf("file_obj_seek called with fileptr=%p, offset=%d, whence=%d\n", fileptr, offset, whence);
uint64_t actual;
switch (whence) {
case 0:
actual = SEEK_CUR;
break;
case 1:
actual = SEEK_SET;
break;
case 2:
actual = SEEK_END;
break;
}
return fseek(fileptr, offset, actual);
}
Not the prettiest workaround, but it works. After this, I simply initialized a file_obj_t and created a struct that contained all my custom file stream functions and passed it into JP2KImageInitDecoderEx with the last argument still being an unknown placeholder struct. Similarly to the article, my JP2KImageInitDecoderEx would also return 0 only if it succeeded, so I added in a check to make sure I wasn’t continuing execution with a failed image decode. I ended up with something like this:
//create vtable
vtable_t procs;
//assign relevant func pointers
procs.funcs[0] = (void*)nop_ret_0;
procs.funcs[1] = (void*)file_obj_die;
procs.funcs[2] = (void*)file_obj_read;
procs.funcs[3] = (void*)file_obj_write;
procs.funcs[4] = (void*)file_obj_seek;
procs.funcs[5] = (void*)file_obj_tellpos;
procs.funcs[6] = (void*)file_obj_is_seekable;
procs.funcs[7] = (void*)file_obj_is_readable;
procs.funcs[8] = (void*)file_obj_is_writeable;
procs.funcs[9] = (void*)&procs;
//read file and store in file obj
file_obj_t fobj;
init_file(&fobj, argv[1]);
if(!(fobj.fileptr)) {
printf("failed to load file object\n");
return 1;
}
printf("f_obj is at address: %p\n with fobj->fileptr at: %p\n", fobj, fobj.fileptr);
unknown* u = malloc(sizeof(unknown));
u->p1 = malloc(16);
printf("struct u has address: %p with p1=%p\n",u,u->p1);
ret = JP2KImageInitDecoderEx_func(image, &fobj, &procs, dec_opt, u);
printf("JP2KImageInitDecoderEx: ret = %d\n", ret);
//if failed to decode we want to just exit so there's no bogus crashes
if(ret != 0)
printf("failed to decode.\n");
I also made sure to add in the relevant destroy functions to destroy all data if JP2KImageInitDecoderEx failed to decode to prevent memory leaks. After running the new harness, we could confirm that it was working:
pointer address of JP2KImageInitDecoderEx: 684D50B0
file "sample1.jp2" initiated
initial fileptr is 95E11CFF
f_obj is at address: 75D74660
with fobj->fileptr at: 75D74660
struct u has address: 058DCFF8 with p1=058DEFF0
==> nop4 (malloc wrapper) called, with args size:40 pointer: 684D5DA4
==> nop7 (memset wrapper) called with args val:0, size:40, dest:058E0FC0, pointer: 684D5DE5
file_obj_is_seekable called
file_obj_is_readable called
file_obj_is_writeable called
...
...
=> nop4 (malloc wrapper) called, with args size:c pointer: 684D5F6E
==> nop4 (malloc wrapper) called, with args size:c pointer: 684D5F6E
==> nop5 (free wrapper) called at location:0593CFF0, pointer: 684D5E80
==> nop5 (free wrapper) called at location:0593EFF0, pointer: 684D5E80
==> nop5 (free wrapper) called at location:05940FF0, pointer: 684D5E80
==> nop5 (free wrapper) called at location:058E7FC0, pointer: 684D5E80
JP2KImageInitDecoderEx: ret = 0
It returned 0! We can now move on. This took waaaaay longer than I would’ve hoped.
Common error return values that I got:
17 - This meant that the input image was not a valid jp2 image, or was not a jp2 image at all.
26 - This meant that something went wrong in the process of decoding the image. Something went wrong with one or more of the file stream functions.
Anecdote: I was tearing my hair out because JP2KImageInitDecoderEx kept failing for me even though I felt I had already implemented everything correctly, but it turned out that for certain file stream functions, the file stream pointer itself was passed directly into them instead of just the custom file stream object.
Implementing the Last Functions
According to the article, they only had to implement JP2KImageDataCreate, JP2KImageGetMaxRes and JP2KImageDecodeTileInterleaved. After going through windbg and consulting some people, I believed that this still held true as a lot of the other functions that were called were likely unrelated to the parsing of JP2 images and thus were not needed in the harness.
JP2KImageDataCreate and JP2KImageGetMaxRes were similar to in the article, I just had to call the former and pass its return value to the latter and save both return values before moving on.
Now began the nightmare (again, after JP2KImageInitDecoderEx). This function took in a massive amount of 7 arguments (hadn’t changed since the article was written) and through windbg I could double confirm that it took in the return values of JP2KImageCreate, JP2KImageGetMaxRes and JP2KImageDataCreate. The 2nd and 6th parameters were also found to be null and the 4th and 5th arguments often were 8 and 0xff respectively so I took the article’s word that it did depend on the colour depth so I also decided to leave it as 8 and 0xff, which left me with:
int max_res = JP2KImageGetMaxRes_func(image);
printf("JP2KImageGetMaxRes: ret = %d\n", max_res);
void* image_data = JP2KImageDataCreate_func();
printf("JP2KImageDataCreate: ret = %p\n", image_data);
ret = JP2KImageDecodeTileInterleaved_func(image, 0, max_res, 8, 0xff, 0, image_data);
printf("JP2KImageDecodeTileInterleaved called with params max_res=%d: ret = %d\n", max_res, ret);
After running it once, it ran successfully, so I also called JP2KImageDataDestroy, JP2KImageDestroy, and JP2KDecOptDestroy at the end to prevent memory leaks. However…
The Work was Not Done
Because the library had changed over the years, when I tried running my harness in winafl I had a suspiciously low stability (<80%) and also suspiciously low amount of paths (it never reached >300). This meant that I was likely not hitting all the correct parsing functions, so I had to go through slowly to find out what was wrong. I realized 2 main things:
- When running through windbg,
JP2KImageDecodeTileInterleavedALWAYS returned 0, but mine would always return 8. - nop0 was called at the end of
JP2KImageDecodeTileInterleaved, and even though the article mentioned nothing about implementing that, after setting a breakpoint in windbg it turned out that nop0 was likely an important parsing function as it eventually lead to multiple calls ofCopyRectand it seemed to call many important subroutines in IDA as well.
Final Words
In the end, I still have to figure out what nop0 was exactly and implement it, as well as make sure that all my other functions were correctly harnessed. I had learnt a lot and gotten a lot more familiar with the rev-debugging process and this was definitely fun, albeit stressful and frustrating. I’m still in the process of reverse engineering the missing link in my harness, so hopefully another writeup could come soon, after I figure some things out. But I guess that’s it for now.
Thanks for reading.