% vim: ft=tex \section{Introduction} Quantum computing has been a rapidly growing field over the last years with many companies and institutions working on building and using quantum computers \cite{ibmq}\cite{intelqc}\cite{microsoftqc}\cite{dwavesys}\cite{lrzqc}\cite{heise25_18}. One important topic in this research is quantum error correction \cite{nielsen_chuang_2010}\cite{gottesman2009}\cite{gottesman1997}\cite{shor1995} that will allow the execution of arbitrarily long quantum circuits \cite{nielsen_chuang_2010}. One important class of quantum error correction strategies are stabilizer codes \cite{gottesman2009}\cite{gottesman1997} that can be simulated exponentially faster than general quantum circuits \cite{gottesman_aaronson2008}\cite{CHP}\cite{andersbriegel2005}. One particularly efficient way to simulate stabilizer states is the graphical representation \cite{andersbriegel2005} that has been studied extensively in the context of both quantum error correction and quantum information theory \cite{schlingenmann2001}\cite{dahlberg_ea2019}\cite{vandennest_ea2004}\cite{hein_eisert_briegel2008}. This paper describes the development of a quantum computing simulator using both the usual dense state vector representation for a general state and a graphical representation for stabilizer states. After giving some introduction to quantum computing some basic properties of stabilizer states and their dynamics are elucidated. Using this the graphical representation is introduced and some operations on the graphical states are explained. Following is a chapter describing the implementation of these techniques and some performance analysis.