Nios® V Processor Reference Manual

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ID 683632
Date 7/26/2024
Public
Document Table of Contents
Document Table of Contents x
1. Overview 2. Nios® V/c Processor 3. Nios® V/m Processor 4. Nios® V/g Processor 5. Nios V Processor Reference Manual Archives 6. Document Revision History for the Nios® V Processor Reference Manual
1. Overview x
1.1. Quartus® Prime Software Support
2. Nios® V/c Processor x
2.1. Processor Performance Benchmarks 2.2. Processor Pipeline 2.3. Processor Architecture 2.4. Programming Model 2.5. Core Implementation
2.3. Processor Architecture x
2.3.1. General-Purpose Register File 2.3.2. Arithmetic Logic Unit 2.3.3. Reset and Debug Signals 2.3.4. Memory and I/O Organization 2.3.5. Error Correction Code (ECC)
2.3.4. Memory and I/O Organization x
2.3.4.1. Instruction and Data Buses 2.3.4.2. Address Map
2.3.4.1. Instruction and Data Buses x
2.3.4.1.1. Instruction Manager Port 2.3.4.1.2. Data Manager Port
2.4. Programming Model x
2.4.1. Privilege Levels
2.5. Core Implementation x
2.5.1. Instruction Set Reference
3. Nios® V/m Processor x
3.1. Processor Performance Benchmarks 3.2. Processor Pipeline 3.3. Processor Architecture 3.4. Programming Model 3.5. Core Implementation
3.1. Processor Performance Benchmarks x
3.1.1. Pipelined 3.1.2. Non-pipelined
3.2. Processor Pipeline x
3.2.1. Pipelined Architecture 3.2.2. Non-pipelined Architecture
3.3. Processor Architecture x
3.3.1. General-Purpose Register File 3.3.2. Arithmetic Logic Unit 3.3.3. Reset and Debug Signals 3.3.4. Control and Status Registers 3.3.5. Trap Controller 3.3.6. Memory and I/O Organization 3.3.7. RISC-V based Debug Module 3.3.8. Error Correction Code (ECC)
3.3.5. Trap Controller x
3.3.5.1. Exception Handling 3.3.5.2. Interrupt Handling
3.3.5.2. Interrupt Handling x
3.3.5.2.1. Timer and Software Interrupt Module
3.3.6. Memory and I/O Organization x
3.3.6.1. Instruction and Data Buses 3.3.6.2. Address Map
3.3.6.1. Instruction and Data Buses x
3.3.6.1.1. Instruction Manager Port 3.3.6.1.2. Data Manager Port
3.3.7. RISC-V based Debug Module x
3.3.7.1. Debug Mode 3.3.7.2. Halt from Debug Module 3.3.7.3. Trigger 3.3.7.4. Abstract Commands in Debug Mode 3.3.7.5. Hardware/Software Interface
3.4. Programming Model x
3.4.1. Privilege Levels 3.4.2. Control and Status Registers (CSR) Mapping
3.4.1. Privilege Levels x
3.4.1.1. Machine Mode (M-mode) 3.4.1.2. Debug Mode (D-mode)
3.4.2. Control and Status Registers (CSR) Mapping x
3.4.2.1. Control and Status Register Field
3.5. Core Implementation x
3.5.1. Instruction Set Reference
4. Nios® V/g Processor x
4.1. Processor Performance Benchmarks 4.2. Processor Pipeline 4.3. Processor Architecture 4.4. Programming Model 4.5. Core Implementation
4.3. Processor Architecture x
4.3.1. General-Purpose Register File 4.3.2. Arithmetic Logic Unit 4.3.3. Multipy and Divide Units 4.3.4. Floating-Point Unit 4.3.5. Custom Instruction 4.3.6. Reset and Debug Signals 4.3.7. Control and Status Registers 4.3.8. Trap Controller 4.3.9. Memory and I/O Organization 4.3.10. RISC-V based Debug Module 4.3.11. Error Correction Code (ECC)
4.3.4. Floating-Point Unit x
4.3.4.1. IEEE 754 Exception Conditions 4.3.4.2. Floating Point Operations
4.3.4.2. Floating Point Operations x
4.3.4.2.1. Floating Point Classification
4.3.8. Trap Controller x
4.3.8.1. Exception Controller 4.3.8.2. Interrupt Controller
4.3.8.2. Interrupt Controller x
4.3.8.2.1. Timer and Software Interrupt Module
4.3.9. Memory and I/O Organization x
4.3.9.1. Instruction and Data Buses 4.3.9.2. Address Map 4.3.9.3. Cache Memory 4.3.9.4. Tightly Coupled Memory
4.3.9.1. Instruction and Data Buses x
4.3.9.1.1. Instruction Manager Port 4.3.9.1.2. Data Manager Port
4.3.9.3. Cache Memory x
4.3.9.3.1. Instruction Cache 4.3.9.3.2. Data Cache 4.3.9.3.3. Configurable Cache Memory 4.3.9.3.4. Bypassing Cache (Peripheral Region) 4.3.9.3.5. Using Cache Memory Effectively
4.3.9.4. Tightly Coupled Memory x
4.3.9.4.1. Instruction and Data Tightly Coupled Memory 4.3.9.4.2. Accessing Tightly Coupled Memory 4.3.9.4.3. Using Tightly Coupled Memory Effectively
4.3.10. RISC-V based Debug Module x
4.3.10.1. Debug Mode 4.3.10.2. Halt from Debug Module 4.3.10.3. Trigger 4.3.10.4. Abstract Commands in Debug Mode 4.3.10.5. Hardware/Software Interface
4.4. Programming Model x
4.4.1. Privilege Levels 4.4.2. Control and Status Registers (CSR) Mapping
4.4.1. Privilege Levels x
4.4.1.1. Machine Mode (M-mode) 4.4.1.2. Debug Mode (D-mode)
4.4.2. Control and Status Registers (CSR) Mapping x
4.4.2.1. Control and Status Register Field
4.5. Core Implementation x
4.5.1. Instruction Set Reference
1. Overview
2. Nios® V/c Processor
3. Nios® V/m Processor
4. Nios® V/g Processor
5. Nios V Processor Reference Manual Archives
6. Document Revision History for the Nios® V Processor Reference Manual

2.1. Processor Performance Benchmarks

Table 2.   Nios® V/c Processor Performance Benchmarks in Intel FPGA Devices for Quartus® Prime Software
Quartus® Prime Edition FPGA Used fMAX (MHz) Logic Size (ALM) Architecture Performance
DMIPS/MHz Ratio CoreMark/MHz Ratio
Quartus® Prime Pro Edition Cyclone® 10 299 405 ALM 0.227 0.17
Arria® 10 323 408 ALM
Stratix® 10 370 429 ALM
Agilex™ 7 442 421 ALM
Agilex™ 5 382 414 ALM
Quartus® Prime Standard Edition Cyclone® IV E 118 1022 LE 0.268 0.201
Cyclone® V 155 423 ALM
Arria® V 175 414 ALM
Arria® V GZ 289 372 ALM
Stratix® V 332 372 ALM
Cyclone® 10 LP 137 1025 LE
Arria® 10 325 355 ALM
MAX® 10 137 1022 LE
Table 3.  Benchmark Parameters for Quartus® Prime Software
Parameter Settings/Description
Quartus® Prime Pro Edition Quartus® Prime Standard Edition
Quartus® Prime seed Maximum performance result are based on 10 seed sweep from Quartus® Prime Pro Edition software version 24.2. Maximum performance result are based on 10 seed sweep from Quartus® Prime Standard Edition software version 23.1.
Device speed grade Fastest speed grade from each Intel FPGA device family.
Defined peripherals
  • Nios® V/c processor core (without debug module and internal timer).
  • 128 KB on-chip memory for the instruction and data bus.
  • JTAG UART Intel® FPGA IP.
  • Interval Timer Core.
Toolchain Version
  • riscv32-unknown-elf-gcc (GCC) version 13.2.0
  • CMake Version: 3.28.3
  • riscv32-unknown-elf-gcc (GCC) version 12.1.0
  • CMake Version: 3.27.1
Compiler configuration
  • Compiler flags: -03
  • Assembler options: -Wa -gdwarf2
  • Compile options: -Wall -Wformat-security -march=rv32i -mabi=ilp32

Altera® uses the same Quartus® Prime design example for maximum performance benchmark(fMAX) and logic size benchmarks. The compiler settings are:

  • Superior Performance with Maximum Placement Effort in Quartus® Prime Pro Edition software.
  • High Performance Effort in Quartus® Prime Standard Edition software.
Note: Results may vary depending on the version of the Quartus® Prime software, the version of the Nios® V processor, compiler version, target device and the configuration of the processor. Additionally, any changes to the system logic design can change the performance and LE usage. All results are generated from design built with Platform Designer.
Level Two Title