# RISC-V Simple Core Collection
Collection of SystemVerilog RV32I cores and modules

## Table of contents
- [Features](#features)
- [Directory structure](#directory-structure)
- [Requirements](#requirements)
- [Build](#build)
- [Tests](#tests)
- [Benchmark](#benchmark)

## Features
- Single cycle processor
- 5-Stage pipelined processor with hazard detection
- N-Way associative cache memory

## Directory structure
    .
    ├── fw                   # Firmware
    │   ├── sandbox          # C/Assembly sandbox firmware source
    │   └── test             # Assembly programs used for testbenchs
    ├── include              # SystemVerilog include directory
    ├── rtl                  # SystemVerilog RTL modules
    └── test                 # SystemVerilog testbenchs

## Requirements
- Verilator or another SystemVerilog simulator
- CMake
- 32-bit GNU RISC-V toolchain

> If your package manager does not provide the RISC-V GNU toolchain you can either download the binaries from the [xPack GNU RISC-V Embedded GCC](https://github.com/xpack-dev-tools/riscv-none-elf-gcc-xpack/releases) package or it can be compiled from their [main repository](https://github.com/riscv-collab/riscv-gnu-toolchain). Also you can take a look to the [docker enviroment](#docker-enviroment) provided.

### Docker enviroment

There is a docker enviroment image with all the dependencies already pre-installed.
For getting docker check their [installation instruction site](https://docs.docker.com/get-docker/).
> **Tip:** If you run into problems running docker make sure you have:
> - **WSL2** installed in case of Windows
> - **Secure Boot disabled** and **Virtualization enabled** in your BIOS settings

To set up the enviroment you can create a [dev enviroment](https://docs.docker.com/desktop/dev-environments) pointing to this repository or you can pull the image directly from the container registry and then run it:
```
docker pull git.1159.cl/mario1159/rvscc
docker run -it git.1159.cl/mario1159/rvscc
```

## Build
To build the firmware that will be loaded in the instruction memory and the simulation testbenchs execute CMake in the project root directory using your system default toolchain (the [CMake toolchain file](cmake/riscv-toolchain.cmake) will search automatically for a RISC-V toolchain to build the firmware).
```
cmake -Bbuild
cmake --build build
```
This will generate a `sandbox.mem` file in the `/build` folder. For other simualtors than verilator make sure to add the firmware it to your simulator sources and that the memory path matches the path specified in the memory module.
## Tests
After building, test can be runned using CMake CTest.
```
ctest --test-dir build
```