69 MIPS-Lite 8-bit Processor

69 : MIPS-Lite 8-bit Processor

Design render

MIPS-Lite 8-bit Processor

How it works

This is an 8-bit MIPS-inspired single-cycle processor designed for Tiny Tapeout. It preserves the core architectural concepts of a full 32-bit MIPS processor, scaled down to fit in a single tile:

Architecture
  • 8 general-purpose registers (R0 hardwired to 0, R1-R7 writable)
  • 8-bit ALU with ADD, SUB, AND, OR, SLT operations
  • 16-bit instruction format supporting R-type, I-type, and J-type instructions
  • 5-bit Program Counter addressing 32 instruction ROM entries
  • Single-cycle execution — one instruction per clock cycle
Instruction Set
Opcode Name Format Operation
0000 R-type R ADD, SUB, AND, OR, SLT (based on funct field)
0001 ADDI I R[rt] ← R[rs] + sign_ext(imm)
0010 ANDI I R[rt] ← R[rs] & zero_ext(imm)
0011 ORI I R[rt] ← R[rs] | zero_ext(imm)
0100 BEQ I if R[rs]==R[rt]: PC ← PC+1+imm
0101 BNE I if R[rs]!=R[rt]: PC ← PC+1+imm
0110 J J PC ← addr
0111 LUI I R[rt] ← imm << 2
1111 HALT - Stop execution
Demo Program

The hardcoded ROM contains a Fibonacci + ALU test program that:

  1. Computes Fibonacci numbers (1, 1, 2, 3, 5)
  2. Tests AND, OR, SUB, SLT operations
  3. Tests BEQ (not taken) and BNE (taken) branches
  4. Tests Jump instruction
  5. Halts

How to test

  1. Apply reset (rst_n = 0) for at least one clock cycle, then release (rst_n = 1)
  2. The CPU will execute the hardcoded program automatically
  3. Use ui_in[2:0] to select which register (R0-R7) to observe on uo_out[7:0]
  4. Monitor uio_out[4:0] for the current Program Counter value
  5. Check uio_out[5] for the halt flag (goes high when HALT is reached)
Expected results after execution:
Register Value Description
R0 0x00 Hardwired zero
R1 0x03 Fibonacci intermediate
R2 0x05 Fibonacci result
R3 0x05 Fibonacci result
R4 0x15 ADDI result (21)
R5 0x0F ORI result (15)
R6 0xFE SUB result (-2 signed)
R7 0x01 SLT result (3 < 5 = true)

External hardware

No external hardware required. Connect LEDs to outputs for visual observation:

  • 8 LEDs on uo_out to display the selected register value
  • 5 LEDs on uio_out[4:0] to show PC
  • 1 LED on uio_out[5] for halt indicator
  • 3 switches on ui_in[2:0] for register selection

IO

#InputOutputBidirectional
0reg_sel[0]reg_data[0]pc[0]
1reg_sel[1]reg_data[1]pc[1]
2reg_sel[2]reg_data[2]pc[2]
3reg_data[3]pc[3]
4reg_data[4]pc[4]
5reg_data[5]halt
6reg_data[6]alu_zero
7reg_data[7]

Chip location

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