Library
Module
Module type
Parameter
Class
Class type
Jump straight to the reference section for documentation on types and functions.
Bitstring adds Erlang-style bitstrings and matching over bitstrings as a syntax extension and library for OCaml. You can use this module to both parse and generate binary formats, for example, communications protocols, disk formats and binary files.
This library used to be called "bitmatch".
A function which can parse IPv4 packets:
let display pkt =
bitmatch pkt with
(* IPv4 packet header
0 1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| 4 | IHL |Type of Service| Total Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Identification |Flags| Fragment Offset |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Time to Live | Protocol | Header Checksum |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Source Address |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Destination Address |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Options | Padding |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
*)
| { 4 : 4; hdrlen : 4; tos : 8; length : 16;
identification : 16; flags : 3; fragoffset : 13;
ttl : 8; protocol : 8; checksum : 16;
source : 32;
dest : 32;
options : (hdrlen-5)*32 : bitstring;
payload : -1 : bitstring } ->
printf "IPv4:\n";
printf " header length: %d * 32 bit words\n" hdrlen;
printf " type of service: %d\n" tos;
printf " packet length: %d bytes\n" length;
printf " identification: %d\n" identification;
printf " flags: %d\n" flags;
printf " fragment offset: %d\n" fragoffset;
printf " ttl: %d\n" ttl;
printf " protocol: %d\n" protocol;
printf " checksum: %d\n" checksum;
printf " source: %lx dest: %lx\n" source dest;
printf " header options + padding:\n";
Bitstring.hexdump_bitstring stdout options;
printf " packet payload:\n";
Bitstring.hexdump_bitstring stdout payload
| { version : 4 } ->
eprintf "unknown IP version %d\n" version;
exit 1
| { _ } as pkt ->
eprintf "data is smaller than one nibble:\n";
Bitstring.hexdump_bitstring stderr pkt;
exit 1
A program which can parse Linux EXT3 filesystem superblocks:
let bits = Bitstring.bitstring_of_file "tests/ext3_sb"
let () =
bitmatch bits with
| { s_inodes_count : 32 : littleendian; (* Inodes count *)
s_blocks_count : 32 : littleendian; (* Blocks count *)
s_r_blocks_count : 32 : littleendian; (* Reserved blocks count *)
s_free_blocks_count : 32 : littleendian; (* Free blocks count *)
s_free_inodes_count : 32 : littleendian; (* Free inodes count *)
s_first_data_block : 32 : littleendian; (* First Data Block *)
s_log_block_size : 32 : littleendian; (* Block size *)
s_log_frag_size : 32 : littleendian; (* Fragment size *)
s_blocks_per_group : 32 : littleendian; (* # Blocks per group *)
s_frags_per_group : 32 : littleendian; (* # Fragments per group *)
s_inodes_per_group : 32 : littleendian; (* # Inodes per group *)
s_mtime : 32 : littleendian; (* Mount time *)
s_wtime : 32 : littleendian; (* Write time *)
s_mnt_count : 16 : littleendian; (* Mount count *)
s_max_mnt_count : 16 : littleendian; (* Maximal mount count *)
0xef53 : 16 : littleendian } -> (* Magic signature *)
printf "ext3 superblock:\n";
printf " s_inodes_count = %ld\n" s_inodes_count;
printf " s_blocks_count = %ld\n" s_blocks_count;
printf " s_free_inodes_count = %ld\n" s_free_inodes_count;
printf " s_free_blocks_count = %ld\n" s_free_blocks_count
| { _ } ->
eprintf "not an ext3 superblock!\n%!";
exit 2
Constructing packets for a simple binary message protocol:
(*
+---------------+---------------+--------------------------+
| type | subtype | parameter |
+---------------+---------------+--------------------------+
<-- 16 bits --> <-- 16 bits --> <------- 32 bits -------->
All fields are in network byte order.
*)
let make_message typ subtype param =
(BITSTRING {
typ : 16;
subtype : 16;
param : 32
}) ;;
The basic data type is the bitstring
, a string of bits of arbitrary length. Bitstrings can be any length in bits and operations do not need to be byte-aligned (although they will generally be more efficient if they are byte-aligned).
Internally a bitstring is stored as a normal OCaml string
together with an offset and length, where the offset and length are measured in bits. Thus one can efficiently form substrings of bitstrings, overlay a bitstring on existing data, and load and save bitstrings from files or other external sources.
To load a bitstring from a file use bitstring_of_file
or bitstring_of_chan
.
There are also functions to create bitstrings from arbitrary data. See the reference below.
Use the bitmatch
operator (part of the syntax extension) to break apart a bitstring into its fields. bitmatch
works a lot like the OCaml match
operator.
The general form of bitmatch
is:
bitmatch
bitstring-expression with
| {
pattern } ->
code
| {
pattern } ->
code
|
...
As with normal match, the statement attempts to match the bitstring against each pattern in turn. If none of the patterns match then the standard library Match_failure
exception is thrown.
Patterns look a bit different from normal match patterns. They consist of a list of bitfields separated by ;
where each bitfield contains a bind variable, the width (in bits) of the field, and other information. Some example patterns:
bitmatch bits with
| { version : 8; name : 8; param : 8 } -> ...
(* Bitstring of at least 3 bytes. First byte is the version
number, second byte is a field called name, third byte is
a field called parameter. *)
| { flag : 1 } ->
printf "flag is %b\n" flag
(* A single flag bit (mapped into an OCaml boolean). *)
| { len : 4; data : 1+len } ->
printf "len = %d, data = 0x%Lx\n" len data
(* A 4-bit length, followed by 1-16 bits of data, where the
length of the data is computed from len. *)
| { ipv6_source : 128 : bitstring;
ipv6_dest : 128 : bitstring } -> ...
(* IPv6 source and destination addresses. Each is 128 bits
and is mapped into a bitstring type which will be a substring
of the main bitstring expression. *)
You can also add conditional when-clauses:
| { version : 4 }
when version = 4 || version = 6 -> ...
(* Only match and run the code when version is 4 or 6. If
it isn't we will drop through to the next case. *)
Note that the pattern is only compared against the first part of the bitstring (there may be more data in the bitstring following the pattern, which is not matched). In terms of regular expressions you might say that the pattern matches ^pattern
, not ^pattern$
. To ensure that the bitstring contains only the pattern, add a length -1 bitstring to the end and test that its length is zero in the when-clause:
| { n : 4;
rest : -1 : bitstring }
when Bitstring.bitstring_length rest = 0 -> ...
(* Only matches exactly 4 bits. *)
Normally the first part of each field is a binding variable, but you can also match a constant, as in:
| { (4|6) : 4 } -> ...
(* Only matches if the first 4 bits contain either
the integer 4 or the integer 6. *)
One may also match on strings:
| { "MAGIC" : 5*8 : string } -> ...
(* Only matches if the string "MAGIC" appears at the start
of the input. *)
The exact format of each pattern field is:
pattern : length [: qualifier [,qualifier ...]]
pattern
is the pattern, binding variable name, or constant to match. length
is the length in bits which may be either a constant or an expression. The length expression is just an OCaml expression and can use any values defined in the program, and refer back to earlier fields (but not to later fields).
Integers can only have lengths in the range [1..64] bits. See the integer types section below for how these are mapped to the OCaml int/int32/int64 types. This is checked at compile time if the length expression is constant, otherwise it is checked at runtime and you will get a runtime exception eg. in the case of a computed length expression.
A bitstring field of length -1 matches all the rest of the bitstring (thus this is only useful as the last field in a pattern).
A bitstring field of length 0 matches an empty bitstring (occasionally useful when matching optional subfields).
Qualifiers are a list of identifiers/expressions which control the type, signedness and endianness of the field. Permissible qualifiers are:
int
: field has an integer typestring
: field is a string typebitstring
: field is a bitstring typesigned
: field is signedunsigned
: field is unsignedbigendian
: field is big endian - a.k.a network byte orderlittleendian
: field is little endian - a.k.a Intel byte ordernativeendian
: field is same endianness as the machineendian (expr)
: expr
should be an expression which evaluates to a endian
type, ie. LittleEndian
, BigEndian
or NativeEndian
. The expression is an arbitrary OCaml expression and can use the value of earlier fields in the bitmatch.offset (expr)
: see computed offsets below.The default settings are int
, unsigned
, bigendian
, no offset.
Note that many of these qualifiers cannot be used together, eg. bitstrings do not have endianness. The syntax extension should give you a compile-time error if you use incompatible qualifiers.
As well as a list of fields, it is possible to name the bitstring and/or have a default match case:
| { _ } -> ...
(* Default match case. *)
| { _ } as pkt -> ...
(* Default match case, with 'pkt' bound to the whole bitstring. *)
Bitstrings may be constructed using the BITSTRING
operator (as an expression). The BITSTRING
operator takes a list of fields, similar to the list of fields for matching:
let version = 1 ;;
let data = 10 ;;
let bits =
BITSTRING {
version : 4;
data : 12
} ;;
(* Constructs a 16-bit bitstring with the first four bits containing
the integer 1, and the following 12 bits containing the integer 10,
arranged in network byte order. *)
Bitstring.hexdump_bitstring stdout bits ;;
(* Prints:
00000000 10 0a |.. |
*)
The format of each field is the same as for pattern fields (see Pattern field reference section), and things like computed length fields, fixed value fields, insertion of bitstrings within bitstrings, etc. are all supported.
The BITSTRING
operator may throw a Construct_failure
exception at runtime.
Runtime errors include:
Integer types are mapped to OCaml types bool
, int
, int32
or int64
using a system which tries to ensure that (a) the types are reasonably predictable and (b) the most efficient type is preferred.
The rules are slightly different depending on whether the bit length expression in the field is a compile-time constant or a computed expression.
Detection of compile-time constants is quite simplistic so only simple integer literals and simple expressions (eg. 5*8
) are recognized as constants.
In any case the bit size of an integer is limited to the range [1..64]. This is detected as a compile-time error if that is possible, otherwise a runtime check is added which can throw an Invalid_argument
exception.
The mapping is thus:
Bit size ---- OCaml type ---- Constant Computed expression 1 bool int64 2..31 int int64 32 int32 int64 33..64 int64 int64
A possible future extension may allow people with 64 bit computers to specify a more optimal int
type for bit sizes in the range 32..63
. If this was implemented then such code could not even be compiled on 32 bit platforms, so it would limit portability.
Another future extension may be to allow computed expressions to assert min/max range for the bit size, allowing a more efficient data type than int64 to be used. (Of course under such circumstances there would still need to be a runtime check to enforce the size).
You can add an offset(..)
qualifier to bitmatch patterns in order to move the current offset within the bitstring forwards.
For example:
bitmatch bits with
| { field1 : 8;
field2 : 8 : offset(160) } -> ...
matches field1
at the start of the bitstring and field2
at 160 bits into the bitstring. The middle 152 bits go unmatched (ie. can be anything).
The generated code is efficient. If field lengths and offsets are known to be constant at compile time, then almost all runtime checks are avoided. Non-constant field lengths and/or non-constant offsets can result in more runtime checks being added.
Note that moving the offset backwards, and moving the offset in BITSTRING
constructors, are both not supported at present.
You can add a check(expr)
qualifier to bitmatch patterns. If the expression evaluates to false then the current match case fails to match (in other words, we fall through to the next match case - there is no error).
For example:
bitmatch bits with
| { field : 16 : check (field > 100) } -> ...
Note the difference between a check expression and a when-clause is that the when-clause is evaluated after all the fields have been matched. On the other hand a check expression is evaluated after the individual field has been matched, which means it is potentially more efficient (if the check expression fails then we don't waste any time matching later fields).
We wanted to use the notation when(expr)
here, but because when
is a reserved word we could not do this.
A bind expression is used to change the value of a matched field. For example:
bitmatch bits with
| { len : 16 : bind (len * 8);
field : len : bitstring } -> ...
In the example, after 'len' has been matched, its value would be multiplied by 8, so the width of 'field' is the matched value multiplied by 8.
In the general case:
| { field : ... : bind (expr) } -> ...
evaluates the following after the field has been matched:
let field = expr in
(* remaining fields *)
The choice is arbitrary, but we have chosen that check expressions are evaluated first, and bind expressions are evaluated after.
This means that the result of bind() is not available in the check expression.
Note that this rule applies regardless of the order of check() and bind() in the source code.
Use save_offset_to(variable)
to save the current bit offset within the match to a variable (strictly speaking, to a pattern). This variable is then made available in any check()
and bind()
clauses in the current field, and to any later fields, and to the code after the ->
.
For example:
bitmatch bits with
| { len : 16;
_ : len : bitstring;
field : 16 : save_offset_to (field_offset) } ->
printf "field is at bit offset %d in the match\n" field_offset
(In that example, field_offset
should always have the value len+16
).
Please see Bitstring_persistent
for documentation on this subject.
Using the compiler directly you can do:
ocamlc -I +bitstring \ -pp "camlp4of bitstring.cma bitstring_persistent.cma \ `ocamlc -where`/bitstring/pa_bitstring.cmo" \ unix.cma bitstring.cma test.ml -o test
Simpler method using findlib:
ocamlfind ocamlc \ -package bitstring,bitstring.syntax -syntax bitstring.syntax \ -linkpkg test.ml -o test
The main concerns for input are buffer overflows and denial of service.
It is believed that this library is robust against attempted buffer overflows. In addition to OCaml's normal bounds checks, we check that field lengths are >= 0, and many additional checks.
Denial of service attacks are more problematic. We only work forwards through the bitstring, thus computation will eventually terminate. As for computed lengths, code such as this is thought to be secure:
bitmatch bits with
| { len : 64;
buffer : Int64.to_int len : bitstring } ->
The len
field can be set arbitrarily large by an attacker, but when pattern-matching against the buffer
field this merely causes a test such as if len <= remaining_size
to fail. Even if the length is chosen so that buffer
bitstring is allocated, the allocation of sub-bitstrings is efficient and doesn't involve an arbitary-sized allocation or any copying.
However the above does not necessarily apply to strings used in matching, since they may cause the library to use the Bitstring.string_of_bitstring
function, which allocates a string. So you should take care if you use the string
type particularly with a computed length that is derived from external input.
The main protection against attackers should be to ensure that the main program will only read input bitstrings up to a certain length, which is outside the scope of this library.
As with the input side, computed lengths are believed to be safe. For example:
let len = read_untrusted_source () in
let buffer = allocate_bitstring () in
BITSTRING {
buffer : len : bitstring
}
This code merely causes a check that buffer's length is the same as len
. However the program function allocate_bitstring
must refuse to allocate an oversized buffer (but that is outside the scope of this library).
In bitmatch
statements, fields are evaluated left to right.
Note that the when-clause is evaluated last, so if you are relying on the when-clause to filter cases then your code may do a lot of extra and unncessary pattern-matching work on fields which may never be needed just to evaluate the when-clause. Either rearrange the code to do only the first part of the match, followed by the when-clause, followed by a second inner bitmatch, or use a check()
qualifier within fields.
The current implementation is believed to be fully type-safe, and makes compile and run-time checks where appropriate. If you find a case where a check is missing please submit a bug report or a patch.
These are thought to be the current limits:
Integers: [1..64] bits.
Bitstrings (32 bit platforms): maximum length is limited by the string size, ie. 16 MBytes.
Bitstrings (64 bit platforms): maximum length is thought to be limited by the string size, ie. effectively unlimited.
Bitstrings must be loaded into memory before we can match against them. Thus available memory may be considered a limit for some applications.
val string_of_endian : endian -> string
Endianness.
bitstring
is the basic type used to store bitstrings.
The type contains the underlying data (a bytes), the current bit offset within the string and the current bit length of the string (counting from the bit offset). Note that the offset and length are in bits, not bytes.
Normally you don't need to use the bitstring type directly, since there are functions and syntax extensions which hide the details.
See also bitstring_of_string
, bitstring_of_file
, hexdump_bitstring
, bitstring_length
.
type t = bitstring
t
is a synonym for the bitstring
type.
This allows you to use this module with functors like Set
and Map
from the stdlib.
Construct_failure (message, file, line, char)
may be raised by the BITSTRING
constructor.
Common reasons are that values are out of range of the fields that contain them, or that computed lengths are impossible (eg. negative length bitfields).
message
is the error message.
file
, line
and char
point to the original source location of the BITSTRING
constructor that failed.
compare bs1 bs2
compares two bitstrings and returns zero if they are equal, a negative number if bs1 < bs2
, or a positive number if bs1 > bs2
.
This tests "semantic equality" which is not affected by the offset or alignment of the underlying representation (see bitstring
).
The ordering is total and lexicographic.
equals
returns true if and only if the two bitstrings are semantically equal. It is the same as calling compare
and testing if the result is 0
, but usually more efficient.
val is_zeroes_bitstring : bitstring -> bool
Tests if the bitstring is all zero bits (cf. zeroes_bitstring
)
val is_ones_bitstring : bitstring -> bool
Tests if the bitstring is all one bits (cf. ones_bitstring
).
is_prefix bs1 bs2
returns true if bs2 is a prefix of bs1
val bitstring_length : bitstring -> int
bitstring_length bitstring
returns the length of the bitstring in bits.
Note this just returns the third field in the bitstring
tuple.
subbitstring bits off len
returns a sub-bitstring of the bitstring, starting at offset off
bits and with length len
bits.
If the original bitstring is not long enough to do this then the function raises Invalid_argument "subbitstring"
.
Note that this function just changes the offset and length fields of the bitstring
tuple, so is very efficient.
Drop the first n bits of the bitstring and return a new bitstring which is shorter by n bits.
If the length of the original bitstring is less than n bits, this raises Invalid_argument "dropbits"
.
Note that this function just changes the offset and length fields of the bitstring
tuple, so is very efficient.
Take the first n bits of the bitstring and return a new bitstring which is exactly n bits long.
If the length of the original bitstring is less than n bits, this raises Invalid_argument "takebits"
.
Note that this function just changes the offset and length fields of the bitstring
tuple, so is very efficient.
Concatenate a list of bitstrings together into a single bitstring.
val empty_bitstring : bitstring
empty_bitstring
is the empty, zero-length bitstring.
val create_bitstring : int -> bitstring
create_bitstring n
creates an n
bit bitstring containing all zeroes.
val make_bitstring : int -> char -> bitstring
make_bitstring n c
creates an n
bit bitstring containing the repeated 8 bit pattern in c
.
For example, make_bitstring 16 '\x5a'
will create the bitstring 0x5a5a
or in binary 0101 1010 0101 1010
.
Note that the length is in bits, not bytes. The length does NOT need to be a multiple of 8.
val zeroes_bitstring : int -> bitstring
zeroes_bitstring
creates an n
bit bitstring of all 0's.
Actually this is the same as create_bitstring
.
val ones_bitstring : int -> bitstring
ones_bitstring
creates an n
bit bitstring of all 1's.
val bitstring_of_string : string -> bitstring
bitstring_of_string str
creates a bitstring of length String.length str * 8
(bits) containing the bits in str
.
Note that the bitstring uses str
as the underlying string (see the representation of bitstring
) so you should not change str
after calling this.
val bitstring_of_file : string -> bitstring
bitstring_of_file filename
loads the named file into a bitstring.
val bitstring_of_chan : Pervasives.in_channel -> bitstring
bitstring_of_chan chan
loads the contents of the input channel chan
as a bitstring.
The length of the final bitstring is determined by the remaining input in chan
, but will always be a multiple of 8 bits.
See also bitstring_of_chan_max
.
val bitstring_of_chan_max : Pervasives.in_channel -> int -> bitstring
bitstring_of_chan_max chan max
works like bitstring_of_chan
but will only read up to max
bytes from the channel (or fewer if the end of input occurs before that).
val bitstring_of_file_descr : Unix.file_descr -> bitstring
bitstring_of_file_descr fd
loads the contents of the file descriptor fd
as a bitstring.
See also bitstring_of_chan
, bitstring_of_file_descr_max
.
val bitstring_of_file_descr_max : Unix.file_descr -> int -> bitstring
bitstring_of_file_descr_max fd max
works like bitstring_of_file_descr
but will only read up to max
bytes from the channel (or fewer if the end of input occurs before that).
val string_of_bitstring : bitstring -> string
string_of_bitstring bitstring
converts a bitstring to a string (eg. to allow comparison).
This function is inefficient. In the best case when the bitstring is nicely byte-aligned we do a String.sub
operation. If the bitstring isn't aligned then this involves a lot of bit twiddling and is particularly inefficient.
If the bitstring is not a multiple of 8 bits wide then the final byte of the string contains the high bits set to the remaining bits and the low bits set to 0.
val bitstring_to_file : bitstring -> string -> unit
bitstring_to_file bits filename
writes the bitstring bits
to the file filename
. It overwrites the output file.
Some restrictions apply, see bitstring_to_chan
.
val bitstring_to_chan : bitstring -> Pervasives.out_channel -> unit
bitstring_to_file bits filename
writes the bitstring bits
to the channel chan
.
Channels are made up of bytes, bitstrings can be any bit length including fractions of bytes. So this function only works if the length of the bitstring is an exact multiple of 8 bits (otherwise it raises Invalid_argument "bitstring_to_chan"
).
Furthermore the function is efficient only in the case where the bitstring is stored fully aligned, otherwise it has to do inefficient bit twiddling like string_of_bitstring
.
In the common case where the bitstring was generated by the BITSTRING
operator and is an exact multiple of 8 bits wide, then this function will always work efficiently.
val hexdump_bitstring : Pervasives.out_channel -> bitstring -> unit
hexdump_bitstring chan bitstring
prints the bitstring to the output channel in a format similar to the Unix command hexdump -C
.
module Buffer : sig ... end
Buffers are mainly used by the BITSTRING
constructor, but may also be useful for end users. They work much like the standard library Buffer
module.
These functions let you manipulate individual bits in the bitstring. However they are not particularly efficient and you should generally use the bitmatch
and BITSTRING
operators when building and parsing bitstrings.
These functions all raise Invalid_argument "index out of bounds"
if the index is out of range of the bitstring.
val set : bitstring -> int -> unit
set bits n
sets the n
th bit in the bitstring to 1.
val clear : bitstring -> int -> unit
clear bits n
sets the n
th bit in the bitstring to 0.
val is_set : bitstring -> int -> bool
is_set bits n
is true if the n
th bit is set to 1.
val is_clear : bitstring -> int -> bool
is_clear bits n
is true if the n
th bit is set to 0.
val put : bitstring -> int -> int -> unit
put bits n v
sets the n
th bit in the bitstring to 1 if v
is not zero, or to 0 if v
is zero.
val get : bitstring -> int -> int
get bits n
returns the n
th bit (returns non-zero or 0).
val debug : bool Pervasives.ref
Set this variable to true to enable extended debugging. This only works if debugging was also enabled in the pa_bitstring.ml
file at compile time, otherwise it does nothing.