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Eclipser Artifact

Eclipser is a binary-based fuzz testing tool, which will be presented in ICSE 2019 conference. This repository maintains a Docker image to run the experiments in our paper. The Docker image and running scripts were tested on Ubuntu 18.04 host machine.

Installation

  1. Install Docker

To install Docker CE, please follow the instructions in this link.

  1. Prepare to run Docker without root privilege (i.e. sudo)

Since we wanted our scripts not to ask you for sudo password, we assumed that you run Docker commands as a non-root user. Please follow the instructions in this link for the configuration.

  1. Prepare Docker image for experiment

You may choose either (1) to build a Docker image from the scratch by running build.sh, or (2) to download an already-built image from Docker Hub by running pull.sh. Since building an image from the scratch takes a long time, we recommend the latter choice if you want to save your time.

If you want to investigate the image setup process in detail, please refer to Dockerfile and setup scripts.

Note: If you chose to run build.sh script, you would want to fix the first command in Dockerfile and replace the apt-get repository to the fastest one from your region.

Note: When you run pull.sh, it will first pull the image from Docker Hub, and then build an image on top of that, by running a command to adjust UID within the container. This is to avoid creating files on your system with root privilege.

  1. Testing the image

Once the Docker image is prepared, you can run launch.sh to run a Docker container. Also, you can use the following commands to run Eclipser on some simple example programs. Each testing script in Eclipser/examples directory contains a comment about the test cases expected to be found by Eclipser.

$ ./launch.sh
artifact@fb7350adf920:~$ cd Eclipser/examples/
artifact@fb7350adf920:~/Eclipser/examples$ ./test_cmp_gcc.sh
Fuzz target: /home/artifact/Eclipser/examples/cmp.bin
...

Note: In launch.sh, resource limitations of Docker container is specified with --cpuset-cpus and --memory options. Memory resource limitation may print the following warning message, depending on the kernel environment. We believe this warning can be ignored.

WARNING: Your kernel does not support swap limit capabilities or the cgroup is not mounted. Memory limited without swap.

Running experiments

Pre-requisites

Although we provide a Docker image to minimize the effect on your system, running AFLFast and LAF-intel requires to change some of your system configuration.

  • Configuring core dump file pattern

AFL-based fuzzers request to disable the use of external crash report utilities like 'apport', by running the following command.

echo core | sudo tee /proc/sys/kernel/core_pattern'"
  • Configuring CPU governor

AFL-based fuzzers request to configure your CPU scaling algorithm, by running the following command.

[ -f /sys/devices/system/cpu/cpu0/cpufreq/scaling_governor ] && \
echo performance | sudo tee /sys/devices/system/cpu/cpu*/cpufreq/scaling_governor

Top-level script

We provide a single top-level script scripts/run_experiment.py to run our experiments. You can specify which experiment to run, by providing proper arguments to this script. Its basic usage is as follow, and more detailed usage for each experiment is described below.

run_experiment.py <testset> <tool> <timelimit> <# proc> <# iteration (optional)>

Note: You can adjust the memory resource limitation for each Docker container, by fixing MEM_PER_CONTAINER variable at the top of run_experiment.py file.

Running coreutils experiment

To run coreutils experiment with Eclipser and KLEE, you can use the following commands respectively.

$ ./scripts/run_experiment.py coreutils eclipser 3600 4
$ ./scripts/run_experiment.py coreutils klee 3600 4

This command will run each program in coreutils for one hour, as in our experiment setting in the paper. The last argument specifies to run four worker processes in parallel. You should modify these parameters considering your machine spec and available resource. When deciding the number of worker processes, please take a look at threats section, too.

Also, you can run each program in the test set iteratively. For this, you simply have to append an optional argument (N) at the end of the command. If no optional argument is provided, each program in the test set will be ran only once.

When run_experiment.py script finishes, the testing outputs will be stored in output-* directory. The directory name is automatically suffixed with a unique number, starting from zero. You can parse the coverage result of the experiment with scripts/parse_coreutils_coverage.py as below. The last argument specifies how many time each program was ran iteratively.

$./scripts/parse_coreutils_coverage.py ./output-0 1

Note : FYI, coreutils test set is composed of 95 programs.

Running LAVA experiment

To run LAVA experiment with Eclipser, AFLFast, and LAF-intel, you can use the following commands respectively. Each program in LAVA test set will be ran for 5 hours, as in our experiment setting in the paper. You should modify these parameters considering your machine spec and available resource.

$ ./scripts/run_experiment.py lava eclipser 18000 4
$ ./scripts/run_experiment.py lava aflfast 18000 4
$ ./scripts/run_experiment.py lava lafintel 18000 4

We recommend you to carefully choose the number of worker process to spawn, because if you run too many Docker containers simultaneously, AFLFast may fail to initialize its 'fork server' for fuzzing, and exit immediately.

You can count the number of bugs found from the experiment with scripts/count_lava_crash.py as below.

$./scripts/count_lava_crash.py ./output-0

Note : FYI, LAVA test set is composed of 4 programs.

Running Debian package experiment

To run Debian package experiment with Eclipser, AFLFast, and LAF-intel, you can use the following commands respectively. Each program in Debian package test set will be ran for 24 hours, as in our experiment setting in the paper. You should modify these parameters considering your machine spec and available resource.

$ ./scripts/run_experiment.py package eclipser 86400 4
$ ./scripts/run_experiment.py package aflfast 86400 4
$ ./scripts/run_experiment.py package lafintel 86400 4

You can parse the coverage result of the experiment with scripts/parse_package_coverage.py, and triage found crashes with scripts/triage_package_crash.py as below. However, note that triage_package_crash.py conservatively de-duplicates crashes, so its result should be further investigated manually, in order to correctly identify unique bugs.

$./scripts/parse_package_coverage.py ./output-0 1
$./scripts/triage_package_crash.py ./output-0 1

Note : FYI, Debian package test set is composed of 20 programs.

Threats to reproducing experiments

There are several obstacles to precisely reproduce the experiment results of the paper. First, the difference between Docker and KVM (which was used in our paper experiment) seems to substantially affect the experiment result.

Especially, running AFLFast and LAF-intel within Docker seems not to scale up well as we increase the number of worker processes (i.e. Docker container) that runs in parallel. Therefore, we recommend to avoid choosing a large number as the number of worker process to spawn, when running run_experiment.py script.

Also, even if we give each experiment the same amount of time as in the paper, experiment results can vary according to machine specs.

Despite such threats, in our several testing environments we could consistently confirm the overall tendency that Eclipser outperforms other tools as in the paper.