Microsoft directwrite / afdko heapbased buffer overflow in opentype font handling in readencoding Vulnerability / Exploit
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Exploits / Vulnerability Discovered : 2019-07-10 |
Type : dos |
Platform : windows
[+] Code ...
-----=====[ Background ]=====-----
AFDKO (Adobe Font Development Kit for OpenType) is a set of tools for examining, modifying and building fonts. The core part of this toolset is a font handling library written in C, which provides interfaces for reading and writing Type 1, OpenType, TrueType (to some extent) and several other font formats. While the library existed as early as 2000, it was open-sourced by Adobe in 2014 on GitHub [1, 2], and is still actively developed. The font parsing code can be generally found under afdko/c/public/lib/source/*read/*.c in the project directory tree.
At the time of this writing, based on the available source code, we conclude that AFDKO was originally developed to only process valid, well-formatted font files. It contains very few to no sanity checks of the input data, which makes it susceptible to memory corruption issues (e.g. buffer overflows) and other memory safety problems, if the input file doesn't conform to the format specification.
We have recently discovered that starting with Windows 10 1709 (Fall Creators Update, released in October 2017), Microsoft's DirectWrite library [3] includes parts of AFDKO, and specifically the modules for reading and writing OpenType/CFF fonts (internally called cfr/cfw). The code is reachable through dwrite!AdobeCFF2Snapshot, called by methods of the FontInstancer class, called by dwrite!DWriteFontFace::CreateInstancedStream and dwrite!DWriteFactory::CreateInstancedStream. This strongly indicates that the code is used for instancing the relatively new variable fonts [4], i.e. building a single instance of a variable font with a specific set of attributes. The CreateInstancedStream method is not a member of a public COM interface, but we have found that it is called by d2d1!dxc::TextConvertor::InstanceFontResources, which led us to find out that it can be reached through the Direct2D printing interface. It is unclear if there are other ways to trigger the font instancing functionality.
One example of a client application which uses Direct2D printing is Microsoft Edge. If a user opens a specially crafted website with an embedded OpenType variable font and decides to print it (to PDF, XPS, or another physical or virtual printer), the AFDKO code will execute with the attacker's font file as input.
In this specific case, the CFR_NO_ENCODING flag must be unset while interacting with AFDKO to trigger the bug. According to our analysis, DirectWrite currently does specify this flag, but it still contains the readEncoding() function including the vulnerable code. In case the code can be reached in a way we haven't considered, or the CFR_NO_ENCODING flag is ever removed in the future, we have opted to report the bug despite its apparent unreachability at this time.
-----=====[ Description ]=====-----
The readEncoding() function in afdko/c/public/lib/source/cffread/cffread.c is designed to read and parse the encoding table of an input OpenType font. It is called by cfrBegFont(), the standard entry point function for the "cfr" (CFF Reader) module of AFDKO, if the CFR_NO_ENCODING flag is not set. The relevant part of the function is shown below:
In both loops in lines 2292-2294 and 2297-2303, the code doesn't consider the size of the h->glyphs array and writes to it solely based on the encoding information. If the values read from the input stream in lines 2292, 2297 and/or 2300 exceed the number of glyphs in the font, the array may be overflown by the encAdd() function, corrupting adjacent objects on the heap. The h->glyphs array is initialized in readCharStringsINDEX() based on the number of CharStrings found in the font:
The three attached proof of concept files were generated by a fuzzer running against the "tx" utility compiled with AddressSanitizer. They are not complete OpenType fonts but rather raw CFF streams, which causes tx to not use the CFR_NO_ENCODING flag, which is necessary to reach the vulnerable readEncoding() function (c/tx/source/tx.c):
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425 case src_OTF:
426 h->cfr.flags |= CFR_NO_ENCODING;
427 /* Fall through */
428 case src_CFF:
429 cfrReadFont(h, rec->offset, rec->iTTC);
430 break;
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-----=====[ Crash logs ]=====-----
A 64-bit "tx" program compiled with ASAN crashes with the following report when started with a ./tx -cff poc.cff command:
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=================================================================
==205898==ERROR: AddressSanitizer: heap-buffer-overflow on address 0x62a00000b220 at pc 0x0000005573aa bp 0x7fff35b2b5c0 sp 0x7fff35b2b5b8
READ of size 8 at 0x62a00000b220 thread T0
#0 0x5573a9 in encAdd afdko/c/public/lib/source/cffread/cffread.c:2203:14
#1 0x540f80 in readEncoding afdko/c/public/lib/source/cffread/cffread.c:2302:29
#2 0x529eb9 in cfrBegFont afdko/c/public/lib/source/cffread/cffread.c:2805:17
#3 0x50928d in cfrReadFont afdko/c/tx/source/tx.c:137:9
#4 0x508cc3 in doFile afdko/c/tx/source/tx.c:429:17
#5 0x506b2e in doSingleFileSet afdko/c/tx/source/tx.c:488:5
#6 0x4fc91e in parseArgs afdko/c/tx/source/tx.c:558:17
#7 0x4f9470 in main afdko/c/tx/source/tx.c:1631:9
#8 0x7f116e1722b0 in __libc_start_main
#9 0x41e5b9 in _start
0x62a00000b220 is located 32 bytes to the right of 20480-byte region [0x62a000006200,0x62a00000b200)
allocated by thread T0 here:
#0 0x4c63f3 in __interceptor_malloc
#1 0x6c9ac2 in mem_manage afdko/c/public/lib/source/tx_shared/tx_shared.c:73:20
#2 0x5474a4 in dna_manage afdko/c/public/lib/source/cffread/cffread.c:271:17
#3 0x7de64e in dnaGrow afdko/c/public/lib/source/dynarr/dynarr.c:86:23
#4 0x7dec75 in dnaSetCnt afdko/c/public/lib/source/dynarr/dynarr.c:119:13
#5 0x53e6fa in readCharStringsINDEX afdko/c/public/lib/source/cffread/cffread.c:1791:5
#6 0x5295be in cfrBegFont afdko/c/public/lib/source/cffread/cffread.c:2769:9
#7 0x50928d in cfrReadFont afdko/c/tx/source/tx.c:137:9
#8 0x508cc3 in doFile afdko/c/tx/source/tx.c:429:17
#9 0x506b2e in doSingleFileSet afdko/c/tx/source/tx.c:488:5
#10 0x4fc91e in parseArgs afdko/c/tx/source/tx.c:558:17
#11 0x4f9470 in main afdko/c/tx/source/tx.c:1631:9
#12 0x7f116e1722b0 in __libc_start_main
SUMMARY: AddressSanitizer: heap-buffer-overflow afdko/c/public/lib/source/cffread/cffread.c:2203:14 in encAdd
Shadow bytes around the buggy address:
0x0c547fff95f0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0x0c547fff9600: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0x0c547fff9610: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0x0c547fff9620: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
0x0c547fff9630: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00
=>0x0c547fff9640: fa fa fa fa[fa]fa fa fa fa fa fa fa fa fa fa fa
0x0c547fff9650: fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa
0x0c547fff9660: fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa
0x0c547fff9670: fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa
0x0c547fff9680: fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa
0x0c547fff9690: fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa
Shadow byte legend (one shadow byte represents 8 application bytes):
Addressable: 00
Partially addressable: 01 02 03 04 05 06 07
Heap left redzone: fa
Freed heap region: fd
Stack left redzone: f1
Stack mid redzone: f2
Stack right redzone: f3
Stack after return: f5
Stack use after scope: f8
Global redzone: f9
Global init order: f6
Poisoned by user: f7
Container overflow: fc
Array cookie: ac
Intra object redzone: bb
ASan internal: fe
Left alloca redzone: ca
Right alloca redzone: cb
Shadow gap: cc
==205898==ABORTING
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