Difference between revisions of "IOP16 16-bit I/O CPU Design"
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* [https://github.com/douggilliland/MultiComp/tree/master/MultiComp_On_RETRO-EP4CE15/M6800_MIKBUG_FrontPanel01 6800 CPU with Front Panel] | * [https://github.com/douggilliland/MultiComp/tree/master/MultiComp_On_RETRO-EP4CE15/M6800_MIKBUG_FrontPanel01 6800 CPU with Front Panel] | ||
+ | * [[Front Panel for 8 Bit Computers V2]] | ||
+ | |||
+ | === Front Panel Loopback === | ||
+ | |||
* [https://github.com/douggilliland/IOP16/tree/main/Higher_Level_Examples/Front%20Panel%20Examples/FrontPanel01_Test_LoopBack Front Panel Loopback FPGA] | * [https://github.com/douggilliland/IOP16/tree/main/Higher_Level_Examples/Front%20Panel%20Examples/FrontPanel01_Test_LoopBack Front Panel Loopback FPGA] | ||
* [https://github.com/douggilliland/Design_A_CPU/tree/main/CPU_Code/Application_Code/FP01_LOOP4 Front Panel Loopback Code] | * [https://github.com/douggilliland/Design_A_CPU/tree/main/CPU_Code/Application_Code/FP01_LOOP4 Front Panel Loopback Code] |
Latest revision as of 17:45, 19 April 2022
Contents
Overview
This CPU is intended to be used as an I/O Processor. The CPU can be used as a Microcontroller replacement in many applications. It can be embedded into an FPGA with a separate Host Computer off-loading tedious I/O programming. It is useful for offloading polled I/O or replacing CPUs in small applications. The majority of these applications deal with 8-bit data and that's where this CPU excels.
Features Set
- 16-bit CPU
- Simple/consistent opcode bit fields
- Instructions are always 16-bits wide
- 4-bit opcode
- Some "sub-instructions" allow more than 16 instructions
- 4-bit register field (shared with address/offset)
- 8-bit constant (shared with address/offset)
- High enough IOP-16 Performance - 12.5 MIPS
- 4 of 50 MHz FPGA clocks
- Register File
- 4, 8, or 13 General Purpose registers
- 3 constant value registers
- Registers are 8-bits
- 12-bit of Program address (up to 4K instructions)
- IOP-16 Stack
- 0 (none)
- 1 deep
- Optionally deeper as build option (uses SRAM)
IOP16 Block Diagram
Instruction Set
Assembler
- Table driven Assembler
- Input comes from a CSV file
- Outputs .MIF and Listing files
- MIF (Memory Initialization File) is Altera ROM initialization File
Hardware Requirements
- Targeted at an FPGA implementation
- The CPU could easily be run on pretty much any FPGA
- Coded in VHDL
Resources
- Very small LUT/Memory footprint in FPGA
- Uses 271 logic cells in an Altera EP4 FPGA
- Uses 76 registers in an Altera EP4 FPGA
- Requires a minimum 1 of 1K SRAM blocks (depends on program size)
- Trade-off - SRAM could be replaced with logic cells (in theory)
Target Hardware
- The initial targeted hardware is the QMTECH EP4CE15 FPGA Starter Kit card
- This FPGA is inexpensive and powerful
- The CPU takes up very little of the resources of the FPGA
- QMTECH CYCLONE IV STARTER KIT GitHub
- QMTECH FPGA Files Reflector
- QMTECH EP4CE15 FPGA card - AliExpress page
Build on Cyclone 10 FPGA
Build into MultiComp in a Box
Peripheral Support
- Extensive Peripheral Support
- 8-bit address (controls up to 256 peripherals)
- 8-bit data
- Read strobe (a couple of clocks wide)
- Write strobe (a couple of clocks wide)
Code Examples
Here are some Code and FPGA build example applications
- Design a CPU Base Code - GitHub
Blink LED
Almost minimal design = CPU + Timer + LED