A powerful and easy-to-use fuzzing framework in Nim for C/C++/Obj-C targets

Go to file

Antonis Geralis 554206d44c minor		2022-08-28 19:19:57 +03:00
benchmarks	minor	2022-08-27 14:07:48 +03:00
drchaos	v0.1.2	2022-08-28 12:43:58 +03:00
examples	added warnings in everything that broke, minor additions	2022-08-26 08:15:17 +03:00
experiments	fixes #7 , minor cleanups	2022-08-27 12:46:19 +03:00
tests	added warnings in everything that broke, minor additions	2022-08-26 08:15:17 +03:00
README.md	minor	2022-08-28 19:19:57 +03:00
drchaos.nim	Initial commit	2022-08-25 23:18:38 +03:00
drchaos.nimble	v0.1.2	2022-08-28 12:43:58 +03:00

README.md

Dr. Chaos

A powerful and easy-to-use fuzzing framework in Nim for C/C++/Obj-C targets.

Fuzzing is an automated bug finding technique, where randomized inputs are fed to a target program in order to get it to crash. With fuzzing, you can increase your test coverage to find edge cases and trigger bugs more effectively.

Dr. Chaos extends the Nim interface to LLVM/Clang libFuzzer, an in-process, coverage-guided, evolutionary fuzzing engine. And adds support for structured fuzzing. The user should define the input type, as a parameter to the target function and the fuzzer is responsible for providing valid inputs. Behind the scenes it uses value profiling to guide the fuzzer past these comparisons much more efficiently than simply hoping to stumble on the exact sequence of bytes by chance.

Usage

For most cases, it is fairly trivial to define a data type and a target function that performs some operations and checks if the invariants expressed as assert conditions still hold. Then call defaultMutator with that function as parameter. That can be as basic as defining a range type and ensuring your library doesn't crash or complex as shown bellow.

Example

A simple but somewhat contrived example looks like this:

import drchaos

type
  ContentNodeKind = enum
    P, Br, Text
  ContentNode = object
    case kind: ContentNodeKind
    of P: pChildren: seq[ContentNode]
    of Br: discard
    of Text: textStr: string

func `==`(a, b: ContentNode): bool =
  if a.kind != b.kind: return false
  case a.kind
  of P: return a.pChildren == b.pChildren
  of Br: return true
  of Text: return a.textStr == b.textStr

func fuzzTarget(x: ContentNode) =
  # Convert or translate `x` to any format (JSON, HMTL, binary, etc...)
  # and feed it to the API you are testing.

defaultMutator(fuzzTarget)

Dr. Chaos will generate millions of inputs and run fuzzTarget under a few seconds. More articulate examples, such as fuzzing a graph library are in the examples/ directory.

Defining a == proc for your input type is necessary.

Post-processors

Sometimes it is necessary to adjust the random input in order to add magic values or dependencies between some fields. This is supported with a post-processing step, which for performance and clarity reasons only runs on compound types such as object/tuple/ref/seq/string/array/set and by exception distinct types.

proc postProcess(x: var ContentNode; r: var Rand) =
  if x.kind == Text:
    x.textStr = "The man the professor the student has studies Rome."

Custom mutator

Besides defaultMutator there is also customMutator which allows more fine-grained control of the mutation procedure, like uncompressing a seq[byte] then calling runMutator on the raw data and compressing the output again.

func myTarget(x: seq[byte]) =
  var data = uncompress(x)
  ...

proc myMutator(x: var seq[byte]; sizeIncreaseHint: Natural; r: var Rand) =
  var data = uncompress(x)
  runMutator(data, sizeIncreaseHint, r)
  x = compress(data)

customMutator(myTarget, myMutator)

User-defined mutate procs

It's possible to use distinct types to provide a mutate overload for fields that have interesting values, like file signatures or to limit the search space.

# Fuzzed library
when defined(runFuzzTests):
  type
    ClientId = distinct int
else:
  type
    ClientId = int

# In a test file
import drchaos/mutator

const
  idA = 0.ClientId
  idB = 2.ClientId
  idC = 4.ClientId

proc mutate(value: var ClientId; sizeIncreaseHint: int; enforceChanges: bool; r: var Rand) =
  # use `rand()` to return a new value.
  repeatMutate(r.sample([idA, idB, idC]))

For aiding the creation of mutate functions, mutators for every supported type are exported by drchaos/mutator.

What's not supported

Polymorphic types, missing serialization support.
References with cycles. A .noFuzz custom pragma will be added soon for cursors.

License

Licensed and distributed under either of

MIT license: LICENSE-MIT or http://opensource.org/licenses/MIT

Apache License, Version 2.0, (LICENSE-APACHEv2 or http://www.apache.org/licenses/LICENSE-2.0)

at your option. These files may not be copied, modified, or distributed except according to those terms.