SEm-Labos/Libs/RiscV/NEORV32/setups/quartus/de0-nano-test-setup-qsys/README.md

# NEORV32 Test Setup using the NEORV32 as a Nios II drop-in replacement

This setup provides a very simple "demo setup" that uses the NEORV32 Qsys/Platform Designer component
so that the NEORV32 can be used as a drop-in replacement of the Nios II soft CPU from Intel.
The demo is running on the Terasic DE0-Nano FPGA Board.

The design is based on the de0-nano-test-setup, but the NEORV32 cpu is added as a QSys/Platform Designer
component. As an example the DMEM is "external" and uses an Platform Designer SRAM block.

![NEORV32 in Platform Designer](figures/neorv32_platform_designer.png)

For details about the design and use of the NEORV32 as a Qsys/Platform Designer component please
look at the Qsys component files and documentation here [`NEORV32 Qsys Component`](../neorv32_qsys_component)

It uses the simplified simple example top entity that provides a minimalistic interface (clock, reset, UART and 8 LEDs).

* FPGA Board: :books: [Terasic DE0-Nano FPGA Board](https://www.terasic.com.tw/cgi-bin/page/archive.pl?Language=English&CategoryNo=139&No=593)
* FPGA: Intel Cyclone-IV `EP4CE22F17C6N`
* Toolchain: Intel Quartus Prime (tested with Quartus Prime 18.1.1 - Lite Edition)


### NEORV32 Configuration

For NEORV32 configuration the default values of the neorv32_top in version 1.6.0 are used
with a few exceptions:

* Memory: 16kB instruction memory (internal IMEM), 8kB data memory (external DMEM), No bootloader
* Tested with version [`1.6.0`](https://github.com/stnolting/neorv32/blob/master/CHANGELOG.md)
* Clock: 50MHz from on-board oscillator
* Reset: via on-board button "KEY0"
* GPIO output port `gpio_o` (8-bit) connected to the 8 green user LEDs ("LED7" - "LED0")
* UART0 signals `uart0_txd_o` and `uart0_rxd_i` are connected to the 40-pin **GPIO_0** header
  * `uart0_txd_o:` output, connected to FPGA pin `C3` - header pin `GPIO_01` (pin number "4")
  * `uart0_rxd_i:` input, connected to FPGA pin `A3` - header pin `GPIO_03` (pin number "6")

### FPGA Utilization

```
Total logic elements 4,064 / 22,320 ( 18 % )
Total registers      1932
Total pins           12 / 154 ( 8 % )
Total virtual pins   0
Total memory bits    230,400 / 608,256 ( 38 % )
Embedded Multiplier  9-bit elements	0 / 132 ( 0 % )
Total PLLs           0 / 4 ( 0 % )
```


## How To Run

Open the Quartus project file, compile and upload to FPGA.
Initial commit 2024-02-23 13:01:05 +00:00			`# NEORV32 Test Setup using the NEORV32 as a Nios II drop-in replacement`

			`This setup provides a very simple "demo setup" that uses the NEORV32 Qsys/Platform Designer component`
			`so that the NEORV32 can be used as a drop-in replacement of the Nios II soft CPU from Intel.`
			`The demo is running on the Terasic DE0-Nano FPGA Board.`

			`The design is based on the de0-nano-test-setup, but the NEORV32 cpu is added as a QSys/Platform Designer`
			`component. As an example the DMEM is "external" and uses an Platform Designer SRAM block.`

			`![NEORV32 in Platform Designer](figures/neorv32_platform_designer.png)`

			`For details about the design and use of the NEORV32 as a Qsys/Platform Designer component please`
			look at the Qsys component files and documentation here [`NEORV32 Qsys Component`](../neorv32_qsys_component)

			`It uses the simplified simple example top entity that provides a minimalistic interface (clock, reset, UART and 8 LEDs).`

			`* FPGA Board: :books: [Terasic DE0-Nano FPGA Board](https://www.terasic.com.tw/cgi-bin/page/archive.pl?Language=English&CategoryNo=139&No=593)`
			* FPGA: Intel Cyclone-IV `EP4CE22F17C6N`
			`* Toolchain: Intel Quartus Prime (tested with Quartus Prime 18.1.1 - Lite Edition)`


			`### NEORV32 Configuration`

			`For NEORV32 configuration the default values of the neorv32_top in version 1.6.0 are used`
			`with a few exceptions:`

			`* Memory: 16kB instruction memory (internal IMEM), 8kB data memory (external DMEM), No bootloader`
			* Tested with version [`1.6.0`](https://github.com/stnolting/neorv32/blob/master/CHANGELOG.md)
			`* Clock: 50MHz from on-board oscillator`
			`* Reset: via on-board button "KEY0"`
			* GPIO output port `gpio_o` (8-bit) connected to the 8 green user LEDs ("LED7" - "LED0")
			* UART0 signals `uart0_txd_o` and `uart0_rxd_i` are connected to the 40-pin GPIO_0 header
			* `uart0_txd_o:` output, connected to FPGA pin `C3` - header pin `GPIO_01` (pin number "4")
			* `uart0_rxd_i:` input, connected to FPGA pin `A3` - header pin `GPIO_03` (pin number "6")

			`### FPGA Utilization`

			```
			`Total logic elements 4,064 / 22,320 ( 18 % )`
			`Total registers 1932`
			`Total pins 12 / 154 ( 8 % )`
			`Total virtual pins 0`
			`Total memory bits 230,400 / 608,256 ( 38 % )`
			`Embedded Multiplier 9-bit elements 0 / 132 ( 0 % )`
			`Total PLLs 0 / 4 ( 0 % )`
			```


			`## How To Run`

			`Open the Quartus project file, compile and upload to FPGA.`