metasploit-framework/lib/metasm
HD Moore 3c924b245a Fix a metasm bug that causes a conflict with rails. Thanks h!
git-svn-id: file:///home/svn/framework3/trunk@6326 4d416f70-5f16-0410-b530-b9f4589650da
2009-03-09 13:35:20 +00:00
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metasm Add new metasm checkout 2009-03-07 23:03:38 +00:00
misc Add new metasm checkout 2009-03-07 23:03:38 +00:00
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CREDITS Add new metasm checkout 2009-03-07 23:03:38 +00:00
LICENCE Add new metasm checkout 2009-03-07 23:03:38 +00:00
README Add new metasm checkout 2009-03-07 23:03:38 +00:00
TODO Add new metasm checkout 2009-03-07 23:03:38 +00:00
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metasm.rb Fix a metasm bug that causes a conflict with rails. Thanks h! 2009-03-09 13:35:20 +00:00

README

Metasm, the Ruby assembly manipulation suite
============================================

* You have some samples in samples/
* LICENCE is LGPL

Author: Yoann Guillot <yoann at ofjj.net>


Basic overview:

Metasm allows you to interact with executables formats (ExeFormat):
PE, ELF, Shellcode, etc
There are three approaches of an ExeFormat:
 - compiling one up, from scratch ( -> source)
 - decompiling an existing format ( -> blocks)
 - manipulating the file structure( -> encoded)


Assembly:

When compiling, you start from a source text (ruby String, consisting
mostly in a sequence of instructions/data/padding directive), then you parse
it.
The string is handed to a Preprocessor (which handles #if, #ifdef, #include,
#define, comments etc, almost 100% compatible with gcc -E), which is
encapsulated in an AsmPreprocessor (which handles asm macro definitions, equ and
asm comments).
This AsmPreprocessor returns tokens to the ExeFormat, which parses them as Data,
Padding, Labels or parser directives. Parser directives always start with a dot.
They can be generic (.pad, .offset...) or ExeFormat-specific (.section,
.import...).
If the ExeFormat does not recognize a word, it hands it to its CPU instance,
which is responsible for parsing Instructions, or raise an exception.
All these tokens are stored in one or more arrays in the @source attribute of
the ExeFormat (Shellcode's @source is an Array, for PE/ELF it is a hash of
section name => Array)
Every immediate value can be an arbitrary Expression (see later).

You can then assemble the source to binary sections.

ExeFormat has a constructor to do that: ExeFormat.assemble(cpu, source)
it parses the source, assemble it, and return the ExeFormat instance.


EncodedData:

In Metasm all binary data is stored as an EncodedData.
EncodedData has 3 main attributes:
 - @data which holds the raw binary data (generally a ruby String, but see
VirtualString)
 - @export which is a hash associating an export name (label name) to an offset
within @data
 - @reloc which is a hash whose keys are offsets within @data, and whose values
are Relocation objects.
A Relocation object has an endianness (:little/:big), a sign (:signed/:unsigned/:any),
a size (in bits) and a target.
The target is an arbitrary arithmetic/logic Expression.

EncodedData also has a @virtualsize (for e.g. .bss sections), and a @ptr (used
when decoding things)

You can fixup an EncodedData, with a Hash variable name => value (value should
be an Expression or a numeric value). When you do that, each relocation's target
is bound using the binding, and if the result is calculable (no external variable
name used in the Expression), the result is encoded using the relocation's
size/sign/endianness information. If it overflows (try to store 128 in an 8bit
signed relocation), an EncodeError exception is raised.
If the relocation's target is not numeric, the target is unchanged if you use 
EncodedData#fixup, or it is replaced with the bound target with #fixup! .


Desassembly: (experimental)

When decompiling, you start from a decoded ExeFormat (you need to be able to
say what data is at which virtual address), you specify a virtual address to
start (virtual address or export name). The ExeFormat starts disassembling
instructions. When it encounters an Opcode marked as :setip, it calls the CPU
to find the jump destination, and backtracks instructions until it finds the
numeric value.
The disassembled code is stored as InstructionBlocks, whichs holds a list of
DecodedInstruction, a list of @from and @to (array of block addresses)
A DecodedInstruction has an Instruction, an Opcode and a bin_length (to allow
printing the hex dump)
(experimental for now, does not handle external calls, does not handle well
subfunctions, should only be used on small shellcodes)

Constructor: Shellcode.disassemble(cpu, binary)


ExeFormat manipulation:

You can encode/decode an ExeFormat (ie decode sections, imports, headers etc)

Constructor: ExeFormat.decode_file(str), ExeFormat.decode_file_header(str)
Methods: ExeFormat#encode_file(filename), ExeFormat#encode_string


VirtualString:

A VirtualString is an object String-like : you can read/maybe write slices of
it. It can be used as @data in an EncodedData, and thus allows virtualization
of most Metasm algorithms.
You cannot change a VirtualString length.
Taking a slice of a VirtualString can return either a String (length smaller
than 4096) or another VirtualString. You can force getting a small VirtualString
using the #dup(from, length) method.
Any unimplemented method called on it is forwarded to frozen String which is
a full copy of the VirtualString (should generally not be used).

There are currently 3 VirtualStrings implemented:
- VirtualFile, whichs loads a file by 4096-bytes chunks, on demand,
- WindowsRemoteString, which maps another process' virtual memory (uses windows
debug api)
- LinuxRemoteString, which maps another process' virtual memory (need ptrace
rights, memory reading is done using /proc/pid/mem)

The Win/Lin version are quite powerful, and allow things like live process
disassembly/patching easily (use LoadedPE/LoadedELF as ExeFormat)


Things planned:

Write a C parser (at least for headers), and adding syntax to support C structs
in assembly.
Write a good disassembler, supporting external calls through C header parsing,
recognize/handle sub functions.
Write an UI for dasm