This is a fork of ns-3 with experimental updates to enable L4S support in Wi-Fi.
The "master" branch is stock ns-3, and the "l4s-wifi" branch contains the updated modules, a simulation program, and some experiment scripts. The "l4s-wifi" branch is set as the default branch.
The simulation program can be found in: scratch/l4s-wifi.cc
The experiment scripts can be found in: experiments
Once you've cloned this repo to your local machine, you can build ns3 by following the steps in Building ns-3 below, and then run the initial experiment by doing:
cd experiments/initial
./run-l4s-wifi.py
What follows below is the README for ns-3 itself
- Overview
- Building ns-3
- Testing ns-3
- Running ns-3
- ns-3 Documentation
- Working with the Development Version of ns-3
- Contributing to ns-3
- Reporting Issues
- ns-3 App Store
NOTE: Much more substantial information about ns-3 can be found at https://www.nsnam.org
ns-3 is a free open source project aiming to build a discrete-event network simulator targeted for simulation research and education. This is a collaborative project; we hope that the missing pieces of the models we have not yet implemented will be contributed by the community in an open collaboration process. If you would like to contribute to ns-3, please check the Contributing to ns-3 section below.
This README excerpts some details from a more extensive tutorial that is maintained at: https://www.nsnam.org/documentation/latest/
The code for the framework and the default models provided by ns-3 is built as a set of libraries. User simulations are expected to be written as simple programs that make use of these ns-3 libraries.
To build the set of default libraries and the example
programs included in this package, you need to use the
ns3
tool. This tool provides a Waf-like API to the
underlying CMake build manager.
Detailed information on how to use ns3
is included in the
quick start guide.
Before building ns-3, you must configure it. This step allows the configuration of the build options, such as whether to enable the examples, tests and more.
To configure ns-3 with examples and tests enabled, run the following command on the ns-3 main directory:
./ns3 configure --enable-examples --enable-tests
Then, build ns-3 by running the following command:
./ns3 build
By default, the build artifacts will be stored in the build/
directory.
The current codebase is expected to build and run on the set of platforms listed in the release notes file.
Other platforms may or may not work: we welcome patches to improve the portability of the code to these other platforms.
ns-3 contains test suites to validate the models and detect regressions. To run the test suite, run the following command on the ns-3 main directory:
./test.py
More information about ns-3 tests is available in the test framework section of the manual.
On recent Linux systems, once you have built ns-3 (with examples enabled), it should be easy to run the sample programs with the following command, such as:
./ns3 run simple-global-routing
That program should generate a simple-global-routing.tr
text
trace file and a set of simple-global-routing-xx-xx.pcap
binary
PCAP trace files, which can be read by tcpdump -n -tt -r filename.pcap
.
The program source can be found in the examples/routing
directory.
If you do not plan to modify ns-3 upstream modules, you can get a pre-built version of the ns-3 python bindings.
pip install --user ns3
If you do not have pip
, check their documents
on how to install it.
After installing the ns3
package, you can then create your simulation python script.
Below is a trivial demo script to get you started.
from ns import ns
ns.LogComponentEnable("Simulator", ns.LOG_LEVEL_ALL)
ns.Simulator.Stop(ns.Seconds(10))
ns.Simulator.Run()
ns.Simulator.Destroy()
The simulation will take a while to start, while the bindings are loaded. The script above will print the logging messages for the called commands.
Use help(ns)
to check the prototypes for all functions defined in the
ns3 namespace. To get more useful results, query specific classes of
interest and their functions e.g., help(ns.Simulator)
.
Smart pointers Ptr<>
can be differentiated from objects by checking if
__deref__
is listed in dir(variable)
. To dereference the pointer,
use variable.__deref__()
.
Most ns-3 simulations are written in C++ and the documentation is
oriented towards C++ users. The ns-3 tutorial programs (first.cc
,
second.cc
, etc.) have Python equivalents, if you are looking for
some initial guidance on how to use the Python API. The Python
API may not be as full-featured as the C++ API, and an API guide
for what C++ APIs are supported or not from Python do not currently exist.
The project is looking for additional Python maintainers to improve
the support for future Python users.
Once you have verified that your build of ns-3 works by running
the simple-global-routing
example as outlined in the running ns-3
section, it is quite likely that you will want to get started on reading
some ns-3 documentation.
All of that documentation should always be available from the ns-3 website: https://www.nsnam.org/documentation/.
This documentation includes:
- a tutorial
- a reference manual
- models in the ns-3 model library
- a wiki for user-contributed tips: https://www.nsnam.org/wiki/
- API documentation generated using doxygen: this is a reference manual, most likely not very well suited as introductory text: https://www.nsnam.org/doxygen/index.html
If you want to download and use the development version of ns-3, you
need to use the tool git
. A quick and dirty cheat sheet is included
in the manual, but reading through the Git
tutorials found in the Internet is usually a good idea if you are not
familiar with it.
If you have successfully installed Git, you can get a copy of the development version with the following command:
git clone https://gitlab.com/nsnam/ns-3-dev.git
However, we recommend to follow the GitLab guidelines for starters, that includes creating a GitLab account, forking the ns-3-dev project under the new account's name, and then cloning the forked repository. You can find more information in the manual.
The process of contributing to the ns-3 project varies with the people involved, the amount of time they can invest and the type of model they want to work on, but the current process that the project tries to follow is described in the contributing code website and in the CONTRIBUTING.md file.
If you would like to report an issue, you can open a new issue in the GitLab issue tracker. Before creating a new issue, please check if the problem that you are facing was already reported and contribute to the discussion, if necessary.
The official ns-3 App Store is a centralized directory listing third-party modules for ns-3 available on the Internet.
More information on how to submit an ns-3 module to the ns-3 App Store is available in the ns-3 App Store documentation.