Shoddy minsize-oriented linker
PoC and maintenance by Shiz, bugfixing, 64-bit version and maintenance by PoroCYon, enhancements and bugfixes by blackle.
- GCC (not clang, as the latter doesn't support
nolto-reloutput), GNU ld, binutils, GNU make, ...
- nasm 2.13 or newer
- Python 3
NOTE: Your entrypoint (
_start) must be in a section called
.text.startup._start! Otherwise, the linker script will fail silently, and
the smol startup/symbol resolving code will jump to an undefined location.
NOTE: C++ exceptions, RTTI, global external variables, thread-local
storage, global constructors and destructors (the ELF
attribute((con-/destructor)) things, not the C++ language constructs), ...
aren't supported yet, and probably won't be anytime soon.
# example: ./smold.py -fuse-dnload-loader [--opts...] -lfoo -lbar input.o... output.elf
usage: smold.py [-h] [-m TARGET] [-l LIB] [-L DIR] [-s | -c] [-n] [-d] [-g] [-fuse-interp] [-falign-stack] [-fskip-zero-value] [-fifunc-support] [-fuse-dnload-loader] [-fuse-nx] [-fuse-dt-debug] [-fuse-dl-fini] [-fskip-entries] [-fno-start-arg] [-funsafe-dynamic] [-fifunc-strict-cconv] [--nasm NASM] [--cc CC] [--readelf READELF] [-Wc CFLAGS] [-Wa ASFLAGS] [-Wl LDFLAGS] [--smolrt SMOLRT] [--smolld SMOLLD] [--gen-rt-only] [--verbose] [--keeptmp] [--debugout DEBUGOUT] input [input ...] output positional arguments: input input object file output output binary optional arguments: -h, --help show this help message and exit -m TARGET, --target TARGET architecture to generate asm code for (default: auto) -l LIB, --library LIB libraries to link against -L DIR, --libdir DIR directories to search libraries in -s, --hash16 Use 16-bit (BSD2) hashes instead of 32-bit djb2 hashes. Implies -fuse-dnload-loader. Only usable for 32-bit output. -c, --crc32c Use Intel's crc32 intrinsic for hashing. Implies -fuse-dnload-loader. Conflicts with `--hash16'. -n, --nx Use NX (i.e. don't use RWE pages). Costs the size of one phdr, plus some extra bytes on i386. -d, --det Make the order of imports deterministic (default: just use whatever binutils throws at us) -g, --debug Pass `-g' to the C compiler, assembler and linker. Only useful when `--debugout' is specified. -fuse-interp [Default ON] Include a program interpreter header (PT_INTERP). If not enabled, ld.so has to be invoked manually by the end user. Disable with `-fno-use-interp'. -falign-stack [Default ON] Align the stack before running user code (_start). If not enabled, this has to be done manually. Costs 1 byte. Disable with `-fno-align-stack'. -fskip-zero-value [Default: ON if `-fuse-dnload-loader' supplied, OFF otherwise] Skip an ELF symbol with a zero address (a weak symbol) when parsing libraries at runtime. Try enabling this if you're experiencing sudden breakage. However, many libraries don't use weak symbols, so this doesn't often pose a problem. Costs ~5 bytes.Disable with `-fno-skip-zero-value'. -fifunc-support [Default ON] Support linking to IFUNCs. Probably needed on x86_64, but costs ~16 bytes. Ignored on platforms without IFUNC support. Disable with `-fno-fifunc-support'. -fuse-dnload-loader Use a dnload-style loader for resolving symbols, which doesn't depend on nonstandard/undocumented ELF and ld.so features, but is slightly larger. If not enabled, a smaller custom loader is used which assumes glibc. `-fskip-zero-value' defaults to ON if this flag is supplied. -fuse-nx Don't use one big RWE segment, but use separate RW and RE ones. Use this to keep strict kernels (PaX/grsec) happy. Costs at least the size of one program header entry. -fuse-dt-debug Use the DT_DEBUG Dyn header to access the link_map, which doesn't depend on nonstandard/undocumented ELF and ld.so features. If not enabled, the link_map is accessed using data leaked to the entrypoint by ld.so, which assumes glibc. Costs ~10 bytes. -fuse-dl-fini Pass _dl_fini to the user entrypoint, which should be done to properly comply with all standards, but is very often not needed at all. Costs 2 bytes. -fskip-entries Skip the first two entries in the link map (resp. ld.so and the vDSO). Speeds up symbol resolving, but costs ~5 bytes. -fno-start-arg Don't pass a pointer to argc/argv/envp to the entrypoint using the standard calling convention. This means you need to read these yourself in assembly if you want to use them! (envp is a preprequisite for X11, because it needs $DISPLAY.) Frees 3 bytes. -funsafe-dynamic Don't end the ELF Dyn table with a DT_NULL entry. This might cause ld.so to interpret the entire binary as the Dyn table, so only enable this if you're sure this won't break things! -fifunc-strict-cconv On i386, if -fifunc-support is specified, strictly follow the calling convention rules. Probably not needed, but you never know. --nasm NASM which nasm binary to use --cc CC which cc binary to use (MUST BE GCC!) --readelf READELF which readelf binary to use -Wc CFLAGS, --cflags CFLAGS Flags to pass to the C compiler for the relinking step -Wa ASFLAGS, --asflags ASFLAGS Flags to pass to the assembler when creating the ELF header and runtime startup code -Wl LDFLAGS, --ldflags LDFLAGS Flags to pass to the linker for the final linking step --smolrt SMOLRT Directory containing the smol runtime sources --smolld SMOLLD Directory containing the smol linker scripts --gen-rt-only Only generate the headers/runtime assembly source file, instead of doing a full link. (I.e. fall back to pre-release behavior.) --verbose Be verbose about what happens and which subcommands are invoked --keeptmp Keep temp files (only useful for debugging) --debugout DEBUGOUT Write out an additional, unrunnable debug ELF file with symbol information. (Useful for debugging with gdb, cannot be ran due to broken relocations.) --hang-on-startup Hang on startup until a debugger breaks the code out of the loop. Only useful for debugging.
A minimal crt (and
_start funcion) are provided in case you want to use
smoldd.py is a script that tries to resolve all symbols from the hashes when
imported by a
smol-ified binary. This can thus be used to detect user mistakes
during dynamic linking. (Think of it as an equivalent of
ldd, except that it
also checks whether the imported functions are present as well.)
usage: smoldd.py [-h] [--cc CC] [--readelf READELF] [--map MAP] [-s | -c] input positional arguments: input input file optional arguments: -h, --help show this help message and exit --cc CC C compiler binary --readelf READELF readelf binary --map MAP Get the address of the symbol hash table from the linker map output instead of attempting to parse the binary. -s, --hash16 Use 16-bit (BSD2) hashes instead of 32-bit djb2 hashes. Only usable for 32-bit output. -c, --crc32c Use Intel's crc32 intrinsic for hashing. Conflicts with `--hash16'.
Debugging your smol-ified executable
So suddenly the output binaries are crashing, while non-smol-ified executables run just fine. What could've happened?
First of all, it could be PEBCAK: are you compiling with the exact same set of compiler flags for the optimized and the regular builds? There could always be a broken codepath in the former.
Secondly, did you enable any of the "evil" flags that can possibly break
compatiblity, such as
-funsafe-dynamic, etc.? Try disabling these first, or try specifying
-fuse-dnload-loader (or remove the last one if you already
were using it). If you had to enable
-fuse-dt-debug or mess with
-fuse-dnload-loader, please file an issue. If you had to specify
please don't use PaX/grsec for democoding.
But let's assume smol is the cause of the issue here. The first thing you
should do, is to check whether the crash happens in smol's runtime linking
code, or your actual executable code. This can be done by adding an
bkpt (ARM) instruction or
__builtin_trap() intrinsic (GCC/clang)
at the very beginning of your
_start function. If the binary is now exiting
Trace/breakpoint trap or
Undefined instruction error (or something
similar) instead of a
Segmentation fault, it means the segfault is happening
after smol's runtime linker code has ran.
The error is happening in the smol runtime linking/startup code
A common source of crashes here is that a symbol actually might not have been
resolved correctly. Try checking the output of
If that isn't the cause, it's time to dig out GDB (see a later section), find out what roughly is going wrong, and send in an issue ticket.
The error is happening after the smol runtime linking/startup code
If a segfault is happening here, it's most likely happening when the binary
tries to call an external function. One cause if this can be bad stack
alignment (try messing with
-f[no-]align-stack, or fix your
Another is that a symbol might have a 'value' (relative address) of zero, which
means the function call turned into a jump to the ELF header of the library,
instead of to the actual function. In this case, try specifying the
Of course, it's still entirely possible it's a yet-unknown calling convention, reloction, or other issue. If it isn't one of the above known causes, it's yet again time to dust off your GDB skills and open an issue.
Attaching GDB to a smol-ified executable
As you might have noticed, GDB cannot run smol-ified executables by itself, as
the ELF headers are too messed up. However, the Linux kernel and glibc dynamic
linker are able to parse it just fine. This means you'll have to attach a live
process, ideally before it segfaults. As racing a below-one-millisecond
timeframe is difficult, there is another solution: specify the
flag. Then attach your (currently-stuck) process to GDB, increase the program
counter manually to break out of the infinite loop, then continue debugging as
However, here you don't have any symbols available (let alone DWARF source
info), which makes debugging a bit hard. This can be mitigated by specifying
-g flag, and loading the file specified by the
--debugout flag into gdb,
which will provide you with symbol and (if
-g was specified) debugging info.
A quick overview:
python3 ./smold.py -g --hang-on-startup --debugout=path/to/out.smol.dbg \ [usual args...] input... path/to/out.smol path/to/out.smol # run it (it will hang) ^Z # background the hung process # 1. attach the backgrounded process # 2. break out of the loop (x86_64 example, s/rip/eip/g for i386) # 3. load symbol and debugging info gdb -ex "attach $(jobs sp)" \ -ex 'set $rip=$rip+2' \ path/to/out.smol.dbg
smol.py inspects the input object files for needed library files and symbols.
It then outputs the list of needed libraries, hashes of the needed symbols and
provides stubs for the external functions. This is then combined with a
custom-made, small ELF header and 'runtime linker' which resolves the symbols
(from the hashes) so that the function stubs are usable.
The runtime linker uses an unorthodox way of resolving the symbols (which only
works for glibc): on both i386 and x86_64, the linker startup code
_dl_start_user) leaks the global
struct link_map to the user code:
on i386, a pointer to it is passed directly through
# (eax, edx, ecx, esi) = (_dl_loaded, argc, argv, envp) movl _rtld_local@GOTOFF(%ebx), %eax ## [ boring stuff... ] pushl %eax # Call the function to run the initializers. call _dl_init ## eax still lives thanks to the ABI and calling convention ## [ boring stuff... ] # Jump to the user's entry point. jmp *%edi ## eax contains the pointer to the link_map!
On x86_64, it's a bit more convoluted: the contents of
_rtld_local is loaded
rsi, but because of the x86_64 ABI, the caller isn't required to restore
that register. However, due to the
call instruction, a pointer to the
instruction after the call will be placed on the stack. And thus, at
that pointer will be available at
rsp - 8. Then, the offset to the "load from
_rtld_local"-instruction can be calculated, and the part of the instruction
which contains the offset to
_rtld_local, from the instruction after the load
(of which the address is now also known), can be read, and thus the location
and contents of that global variable are available as well.
DT_DEBUG, a different mechanism is used to take hold of the
struct link_map: on program startup,
ld.so will place a pointer to its
debug data in the value of the
DT_DEBUG key-value-pair. In glibc, this is
r_debug datatype. The second field of that type, is a pointer to the
Now the code continues with walking the "import tables" for the needed
libraries (which already have been automatically parsed by
though their hash tables for the hashes of the imported symbols, gets their
addresses, and replaces the hashes in the table with the function addresses.
However, because the
struct link_map can change between glibc versions,
especially the size of the
l_info field (a fixed-size array, the
constants tend to change every few versions). To remediate this, one can note
l_entry field comes a few bytes after
l_info, that the root
struct link_map is the one of the main executable, and that the contents of
l_entry field is known at compile-time. Thus, the loader scans the struct
for the entry point address, and uses that as an offset for the 'far fields' of
struct link_map. ('Near' fields like
l_addr are resp. 8
and 0, and will thus pretty much never change.)
auld alrj blackle breadbox faemiyah gib3&tix0 las leblane parcelshit unlord