SRM is a Turing complete 16-bit RISC CPU based on the Von Neumann architecture. It is inspired by the SAP processor by Albert Paul Malvino and Ben Eater's 8-bit computer. It is created using Logisim.
SRM has a clean and simple architecture. A 16-bit bus runs through the center and connects all the components to each other.
- Registers
- A register - accumulator
- B register - internal register for calculations
- Out - output register connected to a hex display
- Memory Address Register (MAR) - holds the memory location of data that needs to be accessed
- Instruction Register (IR) - holds the current instruction that is being executed
- ALU - capable of doing addition and subtraction
- CU - created using Microcode ROM
| 15 | 14 | 13 | 12 | 11 | 10 | 9 | 8 | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| HLT | MI | RI | RO | IO | II | AI | AO | EO | SU | BI | OI | CE | CO | J | - |
Detailed description is available in the microcodes.py file.
| # | Abbreviation | Description |
|---|---|---|
| 0 | C | Carry Flag |
| 1 | Z | Zero Flag |
The ROM has 9 address lines which map to a data space of 64 bytes. The address lines are:
| Bits | Input |
|---|---|
| A0-A3 | microcode counter |
| A4-A6 | instruction decoder |
| A7 | zero bit |
| A8 | carry bit |
SRM supports three types of instructions:
opcode (4-bit) address (12-bit)opcode (4-bit) data (12-bit)opcode (4-bit)
| Opcode | Instruction | Action |
|---|---|---|
| 0 | NOP | - |
| 1 | LDA address | A <- RAM[address] |
| 2 | ADD address | A <- A + RAM[address] |
| 3 | SUB address | A <- A - RAM[address] |
| 4 | STA address | RAM[address] <- A |
| 5 | LDI data | A <- data |
| 6 | JMP address | PC <- address |
| 7 | JZ address | PC <- address if Z |
| 8 | JC address | PC <- address if C |
| 14 | OUT | OUT <- A |
| 15 | HLT | Halts CPU |
Programs can be written in SRM's assembly and can be assembled using assembler.py. Example, countdown:
; countdown
LDI 1
STA 20
LDI 10
OUT
SUB 20
JZ 7
JMP 3
HLTThe above program counts from 10 to 0 and outputs to the out register.
The assembled code can be then loaded in RAM and executed using the logisim interface.
- Cycle optimisation for instructions