Crates.io | bendy |
lib.rs | bendy |
version | 0.4.0-beta.2 |
source | src |
created_at | 2018-07-05 15:59:40.958545 |
updated_at | 2022-08-01 11:12:49.580661 |
description | A rust library for encoding and decoding bencode with enforced canonicalization rules. |
homepage | |
repository | https://github.com/P3KI/bendy |
max_upload_size | |
id | 72995 |
size | 254,086 |
A Rust library for encoding and decoding bencode with enforced canonicalization rules. Bencode is a simple but very effective encoding scheme, originating with the BitTorrent peer-to-peer system.
You may be looking for:
This is not the first library to implement Bencode. In fact there's several implementations already:
So why the extra work adding yet-another-version of a thing that already exists, you might ask?
Implementing a canonical encoding form is straight forward. It comes down to defining a proper way of handling unordered data. The next step is that bendy's sorting data before encoding it using the regular Bencode rules. If your data is already sorted bendy will of course skip the extra sorting step to gain efficiency. But bendy goes a step further to ensure correctness: If you hand the library data that you say is already sorted, bendy still does an in-place verification to ensure that your data actually is sorted and complains if it isn't. In the end, once bendy serialized your data, it's Bencode through and through. So it's perfectly compatible with every other Bencode library.
Just remember: At this point only bendy enforces the correctness of the canonical format if you read it back in.
Bendy ensures that any de-serialize / serialize round trip produces the exact same and correct binary representation. This is relevant if you're dealing with unordered sets or map-structured data where theoretically the order is not relevant, but in practice it is, especially if you want to ensure that cryptographic signatures related to the data structure do not get invalidated accidentally.
Data Structure | Default Impl | Comment |
---|---|---|
Vec | ✔ | Defines own ordering |
VecDeque | ✔ | Defines own ordering |
LinkedList | ✔ | Defines own ordering |
HashMap | ✔ | Ordering missing but content is ordered by key byte representation. |
BTreeMap | ✔ | Defines own ordering |
HashSet | ✘ | (Unordered) Set handling not yet defined |
BTreeSet | ✘ | (Unordered) Set handling not yet defined |
BinaryHeap | ✘ | Ordering missing |
Iterator | ~ | emit_unchecked_list() allows to emit any iterable but user needs to ensure the ordering. |
Attention:
Since most list types already define their inner ordering, data structures
like Vec
, VecDeque
, and LinkedList
will not get sorted during encoding!
There is no default implementation for handling generic iterators.
This is by design. Bendy
cannot tell from an iterator whether the underlying
structure requires sorting or not and would have to take data as-is.
First you need to add bendy as a project dependency:
[dependencies]
bendy = "^0.3"
ToBencode
To encode an object of a type which already implements the ToBencode
trait
it is enough to import the trait and call the to_bencode()
function on the object.
use bendy::encoding::{ToBencode, Error};
let my_data = vec!["hello", "world"];
let encoded = my_data.to_bencode()?;
assert_eq!(b"l5:hello5:worlde", encoded.as_slice());
Ok::<(), Error>(())
ToBencode
In most cases it should be enough to overwrite the associated encode
function
and keep the default implementation of to_bencode
.
The function will provide you with a SingleItemEncoder
which must be used to
emit any relevant components of the current object. As long as these implement
ToBencode
themselves it is enough to pass them into the emit
function of
the encoder as this will serialize any type implementing the trait.
Next to emit
the encoder also provides a list of functions to encode specific
bencode primitives (i.e. emit_int
and emit_str
) and nested bencode elements
(i.e. emit_dict
and emit_list
). These methods should be used if its necessary
to output a specific non default data type.
Implementing Integer Encoding
As bencode has native integer support bendy provides default implementations for
all of rusts native integer types. This allows to call to_bencode
on any integer
object and to pass these objects into the encoder's emit_int
function.
use bendy::encoding::{ToBencode, SingleItemEncoder, Error};
struct IntegerWrapper(i64);
impl ToBencode for IntegerWrapper {
const MAX_DEPTH: usize = 0;
fn encode(&self, encoder: SingleItemEncoder) -> Result<(), Error> {
encoder.emit_int(self.0)
}
}
let example = IntegerWrapper(21);
let encoded = example.to_bencode()?;
assert_eq!(b"i21e", encoded.as_slice());
let encoded = 21.to_bencode()?;
assert_eq!(b"i21e", encoded.as_slice());
Ok::<(), Error>(())
Encode a byte string
Another data type bencode natively supports are byte strings. Therefore bendy
provides default implementations for String
and &str
.
use bendy::encoding::{ToBencode, SingleItemEncoder, Error};
struct StringWrapper(String);
impl ToBencode for StringWrapper {
const MAX_DEPTH: usize = 0;
fn encode(&self, encoder: SingleItemEncoder) -> Result<(), Error> {
encoder.emit_str(&self.0)
}
}
let example = StringWrapper("content".to_string());
let encoded = example.to_bencode()?;
assert_eq!(b"7:content", encoded.as_slice());
let encoded = "content".to_bencode()?;
assert_eq!(b"7:content", encoded.as_slice());
Ok::<(), Error>(())
As its a very common pattern to represent a byte string as Vec<u8>
bendy
exposes the AsString
wrapper. This can be used to encapsulate any element
implementing AsRef<[u8]>
to output itself as a bencode string instead of a
list.
use bendy::encoding::{ToBencode, SingleItemEncoder, Error, AsString};
struct ByteStringWrapper(Vec<u8>);
impl ToBencode for ByteStringWrapper {
const MAX_DEPTH: usize = 0;
fn encode(&self, encoder: SingleItemEncoder) -> Result<(), Error> {
let content = AsString(&self.0);
encoder.emit(&content)
}
}
let example = ByteStringWrapper(b"content".to_vec());
let encoded = example.to_bencode()?;
assert_eq!(b"7:content", encoded.as_slice());
let encoded = AsString(b"content").to_bencode()?;
assert_eq!(b"7:content", encoded.as_slice());
Ok::<(), Error>(())
Encode a dictionary
If a data structure contains key-value pairs its most likely a good idea to encode it as a bencode dictionary. This is also true for most structs with more then one member as it might be helpful to represent their names to ensure the existence of specific (optional) member.
Attention: To ensure a canonical representation bendy requires that the keys
of a dictionary emitted via emit_dict
are sorted in ascending order or the
encoding will fail with an error of kind UnsortedKeys
. In case of an unsorted
dictionary it might be useful to use emit_and_sort_dict
instead.
use bendy::encoding::{ToBencode, SingleItemEncoder, Error};
struct Example {
label: String,
counter: u64,
}
impl ToBencode for Example {
const MAX_DEPTH: usize = 1;
fn encode(&self, encoder: SingleItemEncoder) -> Result<(), Error> {
encoder.emit_dict(|mut e| {
e.emit_pair(b"counter", &self.counter)?;
e.emit_pair(b"label", &self.label)?;
Ok(())
})
}
}
let example = Example { label: "Example".to_string(), counter: 0 };
let encoded = example.to_bencode()?;
assert_eq!(b"d7:counteri0e5:label7:Examplee", encoded.as_slice());
Ok::<(), Error>(())
Encode a list
While encoding a list bendy assumes the elements inside this list are inherently sorted through their position inside the list. The implementation is therefore free to choose its own sorting.
use bendy::encoding::{ToBencode, SingleItemEncoder, Error};
struct Location(i64, i64);
impl ToBencode for Location {
const MAX_DEPTH: usize = 1;
fn encode(&self, encoder: SingleItemEncoder) -> Result<(), Error> {
encoder.emit_list(|e| {
e.emit_int(self.0)?;
e.emit_int(self.1)
})
}
}
let example = Location(2, 3);
let encoded = example.to_bencode()?;
assert_eq!(b"li2ei3ee", encoded.as_slice());
Ok::<(), Error>(())
FromBencode
To decode an object of a type which already implements the FromBencode
trait
it is enough to import the trait and call the from_bencode()
function on the object.
use bendy::decoding::{FromBencode, Error};
let encoded = b"l5:hello5:worlde".to_vec();
let decoded = Vec::<String>::from_bencode(&encoded)?;
assert_eq!(vec!["hello", "world"], decoded);
Ok::<(), Error>(())
FromBencode
In most cases it should be enough to overwrite the associated
decode_bencode_object
function and keep the default implementation of
from_bencode
.
The function will provide you with an representation of a bencode Object
which must be processed to receive any relevant components of the expected data
type. As long as these implement FromBencode
themselves it is enough to call
decode_bencode_object
on the expected data type of the element as this will
deserialize any type implementing the trait.
Next to from_bencode
the bencode Object
representation also provides a list
of helper functions to itself into specific bencode primitives and container
(i.e. bytes_or
, integer_or_else
or try_into_list
). Which than can be used
to restore the actual element.
Decode an integer
As bencode has native integer support bendy provides default implementations
for all of rusts native integer types. This allows to call from_bencode
on
any type of integer.
Attention: If it's necessary to handle a big integer which has no representation through one of the default data types it's always possible to access the string version of the number during decoding.
use bendy::decoding::{FromBencode, Object, Error};
#[derive(Debug, Eq, PartialEq)]
struct IntegerWrapper(i64);
impl FromBencode for IntegerWrapper {
const EXPECTED_RECURSION_DEPTH: usize = 0;
fn decode_bencode_object(object: Object) -> Result<Self, Error> {
// This is an example for content handling. It would also be possible
// to call `i64::decode_bencode_object(object)` directly.
let content = object.try_into_integer()?;
let number = content.parse::<i64>()?;
Ok(IntegerWrapper(number))
}
}
let encoded = b"i21e".to_vec();
let example = IntegerWrapper::from_bencode(&encoded)?;
assert_eq!(IntegerWrapper(21), example);
let example = i64::from_bencode(&encoded)?;
assert_eq!(21, example);
Ok::<(), Error>(())
Decode a byte string
In most cases it is possible to restore a string from its bencode
representation as a byte sequence via the String::from_utf8
and
str::from_utf8
.
use bendy::decoding::{FromBencode, Object, Error};
#[derive(Debug, Eq, PartialEq)]
struct StringWrapper(String);
impl FromBencode for StringWrapper {
const EXPECTED_RECURSION_DEPTH: usize = 0;
fn decode_bencode_object(object: Object) -> Result<Self, Error> {
// This is an example for content handling. It would also be possible
// to call `String::decode_bencode_object(object)` directly.
let content = object.try_into_bytes()?;
let content = String::from_utf8(content.to_vec())?;
Ok(StringWrapper(content))
}
}
let encoded = b"7:content".to_vec();
let example = StringWrapper::from_bencode(&encoded)?;
assert_eq!(StringWrapper("content".to_string()), example);
let example = String::from_bencode(&encoded)?;
assert_eq!("content".to_string(), example);
Ok::<(), Error>(())
If the content is a non utf8 encoded string or an actual byte sequence the
AsString
wrapper might be useful to restore the bencode string object as
a sequence of bytes through an object of type Vec<u8>
.
use bendy::{
decoding::{FromBencode, Object, Error},
encoding::AsString,
};
#[derive(Debug, Eq, PartialEq)]
struct ByteStringWrapper(Vec<u8>);
impl FromBencode for ByteStringWrapper {
const EXPECTED_RECURSION_DEPTH: usize = 0;
fn decode_bencode_object(object: Object) -> Result<Self, Error> {
let content = AsString::decode_bencode_object(object)?;
Ok(ByteStringWrapper(content.0))
}
}
let encoded = b"7:content".to_vec();
let example = ByteStringWrapper::from_bencode(&encoded)?;
assert_eq!(ByteStringWrapper(b"content".to_vec()), example);
let example = AsString::from_bencode(&encoded)?;
assert_eq!(b"content".to_vec(), example.0);
Ok::<(), Error>(())
Decode a dictionary
Unwrapping the bencode object into a dictionary will provide a dictionary decoder which can be used to access the included key-value pairs.
To improve the error handling in case of huge or multiple nested dictionaries
the decoding module provides a ResultExt
trait which allows to add a context
description in case of an error. If multiple context calls are nested they will
concatenated in a dot notation like style.
use bendy::decoding::{FromBencode, Object, Error, ResultExt};
#[derive(Debug, Eq, PartialEq)]
struct Example {
label: String,
counter: u64,
}
impl FromBencode for Example {
const EXPECTED_RECURSION_DEPTH: usize = 1;
fn decode_bencode_object(object: Object) -> Result<Self, Error> {
let mut counter = None;
let mut label = None;
let mut dict = object.try_into_dictionary()?;
while let Some(pair) = dict.next_pair()? {
match pair {
(b"counter", value) => {
counter = u64::decode_bencode_object(value)
.context("counter")
.map(Some)?;
},
(b"label", value) => {
label = String::decode_bencode_object(value)
.context("label")
.map(Some)?;
},
(unknown_field, _) => {
return Err(Error::unexpected_field(String::from_utf8_lossy(
unknown_field,
)));
},
}
}
let counter = counter.ok_or_else(|| Error::missing_field("counter"))?;
let label= label.ok_or_else(|| Error::missing_field("label"))?;
Ok(Example { counter, label })
}
}
let encoded = b"d7:counteri0e5:label7:Examplee".to_vec();
let expected = Example { label: "Example".to_string(), counter: 0 };
let example = Example::from_bencode(&encoded)?;
assert_eq!(expected, example);
Ok::<(), Error>(())
Decode a list
Unwrapping the bencode object into a list will provide a list decoder which can be used to access the contained elements.
use bendy::decoding::{FromBencode, Object, Error};
#[derive(Debug, PartialEq, Eq)]
struct Location(i64, i64);
impl FromBencode for Location {
const EXPECTED_RECURSION_DEPTH: usize = 1;
fn decode_bencode_object(object: Object) -> Result<Self, Error> {
let mut list = object.try_into_list()?;
let x = list.next_object()?.ok_or(Error::missing_field("x"))?;
let x = i64::decode_bencode_object(x)?;
let y = list.next_object()?.ok_or(Error::missing_field("y"))?;
let y = i64::decode_bencode_object(y)?;
Ok(Location(x, y))
}
}
let encoded = b"li2ei3ee".to_vec();
let expected = Location(2, 3);
let example = Location::from_bencode(&encoded)?;
assert_eq!(expected, example);
Ok::<(), Error>(())
What?
The library allows to set an expected recursion depth limit for de- and encoding. If set, the parser will use this value as an upper limit for the validation of any nested data structure and abort with an error if an additional level of nesting is detected.
While the encoding limit itself is primarily there to increase the confidence of bendy users in their own validation code, the decoding limit should be used to avoid parsing of malformed or malicious external data.
MAX_DEPTH
constant in any implementation
of the ToBencode
trait.EXPECTED_RECURSION_DEPTH
constant in any
implementation of the FromBencode
trait.How?
The nesting level calculation always starts on level zero, is incremented by one when the parser enters a nested bencode element (i.e. list, dictionary) and decrement as soon as the related element ends. Therefore any values decoded as bencode strings or integers do not affect the nesting limit.
Bendy supports serde when the serde
feature is enabled:
[dependencies]
bendy = { version = "^0.3", features = ["std", "serde"] }
serde = { version = "1.0", features = ["derive"] }
With the feature enabled, values can be serialized to and deserialized from
bencode with bendy::serde::from_bytes
and bendy::serde::to_bytes
respectively:
# #[cfg(not(feature = "serde"))]
# fn main() {}
# #[cfg(feature = "serde")]
# fn main() -> Result<(), bendy::serde::Error> {
use serde_derive::{Deserialize, Serialize};
#[serde(crate = "serde_")]
#[derive(Serialize, Deserialize, PartialEq, Debug)]
struct Foo {
bar: String,
}
let value = Foo {
bar: "hello".into(),
};
let bencode = bendy::serde::to_bytes(&value)?;
assert_eq!(bencode, b"d3:bar5:helloe");
let deserialized = bendy::serde::from_bytes::<Foo>(&bencode)?;
assert_eq!(deserialized, value);
Ok(())
# }
Information on how Rust types are represented in bencode is available in the serde module documentation.
The parser would not require any unsafe code to work but it still contains a single unsafe call
to str::from_utf8_unchecked
. This call is used to avoid a duplicated UTF-8 check when the
parser converts the bytes representing an incoming integer into a &str
after its successful
validation.
Disclaimer: Further unsafe code may be introduced through the dependency on the snafu
crate.
We welcome everyone to ask questions, open issues or provide merge requests. Each merge request will be reviewed and either landed in the main tree or given feedback for changes that would be required.
All code in this repository is under the BSD-3-Clause license.