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NetSquid simulator for quantum networks running NetQASM applications

Project description

Installation

SquidASM uses the NetSquid Python package. To install and use NetSquid, you need to first create an account for the netsquid forum. The username and password for this account are needed to install SquidASM.

Because NetSquid only supports Linux and MacOS, SquidASM also requires a Linux or MacOS system. For Windows users it is recommended to either use a virtual machine or use Windows Subsystem for Linux (WSL).

Next the SquidASM repository needs to be cloned using git. If git is not installed, instructions on installing it can be found on this website. Afterward, go to your desired directory and execute:

git clone https://github.com/QuTech-Delft/squidasm.git

This will create a new folder with the name squidasm and download the squidasm package to that folder.

The SquidASM install script requires the NetSquid user name and password to be set into environment variables. This can be done by executing the following code, but with your own user name and password:

export NETSQUIDPYPI_USER=user1234
export NETSQUIDPYPI_PWD=password1234

For a more permanent solution, if SquidASM is installed more than once, these lines can be added to ~\.bashrc.

Then, to install squidasm execute the following command inside the newly created squidasm folder:

make install

To verify the installation, do:

make verify

If this commands completes without errors, it means that SquidASM has been successfully installed and should work properly.

Getting started

A tutorial introducing SquidASM and API documentation can be found on https://squidasm.readthedocs.io/en/latest/index.html.

Simulator variants

SquidASM currently has 3 ways of simulating applications: multithread, singlethread and stack. Each of these can run applications written using the NetQASM SDK, but the way they must be written, and what kind of results they can give, is slightly different.

Multithread

Multithreaded simulation uses multiple threads: one thread for each application layer of each node, plus one thread for the NetSquid simulation of all quantum memories and links of all nodes combined.

Since application layer code is in a separate thread, it can do blocking operations, e.g. waiting for user input or receiving a message over TCP, without blocking the reset of the simulation. The way applications are written for the multithread simulator is hence closest to how they would be written when running on real hardware.

Since the quantum simulator (i.e. NetSquid) uses simulated time and does not work well with real-time interaction (like waiting for events outside the simulator process), the multithreaded simulator uses busy loops in some cases, which slows down overall execution.

Singlethread

Singlethreaded simulation uses a single thread that runs all application layer code of all nodes as well as all quantum simulation. All communication and classical events are also simulated in NetSquid, in contrast to the multithread simulator. This leads to faster simulation but poses some constraints to how applications are written.

The singlethread simulator is being deprecated in favor of the stack simulator.

Stack

The stack simulator is also singlethreaded, but does more accurate simulation of the components of the software stack that is intended to be run on physical quantum networks.

Usage

Multithread simulator

The multithread simulator is used as one of the backends of the netqasm package. See the netqasm package for more documentation on how to write NetQASM applications and run them using SquidASM.

Stack simulator

The main interface for the stack simulator is the run function in squidasm.run.stack.run. See examples/stack for examples of using the stack simulator.

Implementation

The code is divided into the following modules:

  • nqasm: implementations of interfaces defined in the netqasm package

  • run: code for setting up and starting simulations

  • sim: internal simulation code

  • util: various utility functions

License and patent

A patent application (NL 2029673) has been filed which covers parts of the software in this repository. We allow for non-commercial and academic use but if you want to explore a commercial market, please contact us for a license agreement.

Development

For code formatting, black and isort are used. Type hints should be added as much as possible.

Before code is pushed, make sure that the make lint command succeeds, which runs black, isort and flake8.

Contributors

In alphabetical order:

  • Axel Dahlberg

  • Bart van der Vecht (b.vandervecht[at]tudelft.nl)

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