This simulation is written in Java. We took this decision as it is an Object-Oriented language and we thought that it would be perfect to model the algorithm. Indeed, using this fact, we can model the ROB, Reservation Station, Load Buffer, Memory, Register File and the Instruction Queue all as Objects. This simplifies greatly the design of the algorithm.

The entry point of our program is obviously the Main class. You can find there a timer. This timer represents our Clock Cycles for the simulation. Every specified interval of time, this clock cycle is incremented by 1 and an interface function called “didUpdate()” is called. This last represents “always @ (posedge clk)” in Verilog and is implemented by the Controller class. This is where all the Tomasulo’s Algorithm lives. The algorithm begins by first of all, at each cycle fetching 2 instructions at a time from the Instruction Queue by first checking if both the ROB & the Reservation Stations have empty slots, then if this is true, it issues the 2 fetched instructions to them. After this is done, we execute the 2 instructions at the next CC. And while the ROB is not empty, we try to commit if the instruction on its turn is ready to commit. We finally predict the next PC: If the branch offset is positive we predict that it is not taken and If it is negative we predict that it is negative (based on the usual behavior of a branch instruction). If a misprediction occurred, at the next CC, we flush and search for the instruction to be fetched (by either dequeuing if the instruction has not been executed or by enqueuing the instructions again until we find the matching PC). Finally, if the ROB and the Instruction Queue are empty, we stop the Timer and send the ROB and RS as a response to the website to be viewed.

We offered the user the option to choose either to see the output of the algorithm cycle by cycle or just see the algorithm running till it stops. This is done by entering 1 if you run it on console when asked to or by pressing on “” if you were on our website. The program then shows the user what happens in the processor at each Clock Cycle.

We implemented a GUI: a website made in React.js where you can type your code manually or just upload the txt file containing your code. In both cases, your code will be previewed to you and highlighted before you click on start simulation. When you click on this last button, a request will be sent to our Back-End with all the assembly instructions then simulated in the backend then sent back to the front-end as a response. This response can then be displayed in the front-end and see even what happens at each clock cycle in the CPU. The Back-End is made in Spring Framework as it is the most known server framework where you can code in JAVA.

Please visit our website to have a lot nicer GUI to deal with.

Finally, have a look at our repositories on Github: Tomasulo’s Algorithm repository: https://github.com/djzenma/Tomasolo Front-End Repository: https://github.com/djzenma/Tomasolo-s-Simulation Back-End Spring Repositoy: https://github.com/KhaledSoliman/TomasuloSimSpring