Intel® Quartus® Prime Pro Edition User Guide: Getting Started

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ID 683463
Date 3/28/2022
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Document Table of Contents
Document Table of Contents x
1. Introduction to Intel® Quartus® Prime Pro Edition 2. Managing Intel® Quartus® Prime Projects 3. Design Planning 4. Introduction to Intel® FPGA IP Cores 5. Migrating to Intel® Quartus® Prime Pro Edition A. Intel® Quartus® Prime Pro Edition User Guides 6. Document Archives
1. Introduction to Intel® Quartus® Prime Pro Edition x
1.1. Selecting an Intel® Quartus® Prime Software Edition 1.2. Introduction to Intel® Quartus® Prime Pro Edition Revision History
2. Managing Intel® Quartus® Prime Projects x
2.1. Viewing Basic Project Information 2.2. Intel® Quartus® Prime Project Contents 2.3. Managing Project Settings 2.4. Managing Logic Design Files 2.5. Managing Timing Constraints 2.6. Integrating Other EDA Tools 2.7. Exporting Compilation Results 2.8. Migrating Projects Across Operating Systems 2.9. Archiving Projects 2.10. Command-Line Interface 2.11. Managing Projects Revision History
2.1. Viewing Basic Project Information x
2.1.1. Using the Compilation Dashboard 2.1.2. Viewing Project Reports 2.1.3. Viewing Project Messages
2.1.3. Viewing Project Messages x
2.1.3.1. Viewing Synthesis Warning Messages 2.1.3.2. Suppressing Message Display 2.1.3.3. Promoting Critical Warnings to Errors
2.2. Intel® Quartus® Prime Project Contents x
2.2.1. Project File Best Practices
2.3. Managing Project Settings x
2.3.1. Specifying the Target Device or Board 2.3.2. Optimizing Project Settings
2.3.2. Optimizing Project Settings x
2.3.2.1. Optimize Settings with Design Space Explorer II 2.3.2.2. Optimize Settings with Project Revisions 2.3.2.3. Back-Annotate Optimized Assignments
2.4. Managing Logic Design Files x
2.4.1. Including Design Libraries 2.4.2. Creating a Project Copy
2.7. Exporting Compilation Results x
2.7.1. Exporting a Version-Compatible Compilation Database 2.7.2. Importing a Version-Compatible Compilation Database 2.7.3. Creating a Design Partition 2.7.4. Exporting a Design Partition 2.7.5. Reusing a Design Partition 2.7.6. Viewing Quartus Database File Information 2.7.7. Clearing Compilation Results
2.7.6. Viewing Quartus Database File Information x
2.7.6.1. QDB File Attribute Types
2.8. Migrating Projects Across Operating Systems x
2.8.1. Migrating Design Files and Libraries 2.8.2. Design Library Migration Guidelines
2.8.1. Migrating Design Files and Libraries x
2.8.1.1. Use Relative Paths
2.9. Archiving Projects x
2.9.1. Manually Adding Files To Archives 2.9.2. Archiving Projects for Service Requests 2.9.3. Archiving Projects for External Revision Control 2.9.4. Creating Database-Only Archives
2.9.3. Archiving Projects for External Revision Control x
2.9.3.1. Project Files to Include In External Revision Control
2.10. Command-Line Interface x
2.10.1. Project Revision Commands 2.10.2. Project Archive Commands 2.10.3. Project Database Commands
2.10.3. Project Database Commands x
2.10.3.1. quartus_cdb Executables to Manage Version-Compatible Databases
3. Design Planning x
3.1. Design Planning 3.2. Create a Design Specification and Test Plan 3.3. Plan for the Target Device 3.4. Plan for Intellectual Property Cores 3.5. Plan for Standard Interfaces 3.6. Plan for Device Programming 3.7. Plan for Device Power Consumption 3.8. Plan for Interface I/O Pins 3.9. Plan for other EDA Tools 3.10. Plan for On-Chip Debugging Tools 3.11. Plan HDL Coding Styles 3.12. Plan for Hierarchical and Team-Based Designs 3.13. Design Planning Revision History
3.3. Plan for the Target Device x
3.3.1. Device Migration Planning
3.8. Plan for Interface I/O Pins x
3.8.1. Simultaneous Switching Noise Analysis
3.9. Plan for other EDA Tools x
3.9.1. Third-Party Synthesis Tools 3.9.2. Third-Party Simulation Tools
3.11. Plan HDL Coding Styles x
3.11.1. Design Recommendations 3.11.2. Recommended HDL Coding Styles 3.11.3. Managing Metastability
3.12. Plan for Hierarchical and Team-Based Designs x
3.12.1. Flat Compilation without Design Partitions
4. Introduction to Intel® FPGA IP Cores x
4.1. IP Catalog and Parameter Editor 4.2. Installing and Licensing Intel® FPGA IP Cores 4.3. IP General Settings 4.4. Adding IP to IP Catalog 4.5. Best Practices for Intel® FPGA IP 4.6. Specifying the IP Core Parameters and Options ( Intel® Quartus® Prime Pro Edition) 4.7. Modifying an IP Variation 4.8. Upgrading IP Cores 4.9. Simulating Intel® FPGA IP Cores 4.10. Simulating Platform Designer Systems 4.11. Synthesizing IP Cores in Other EDA Tools 4.12. Instantiating IP Cores in HDL 4.13. Support for the IEEE 1735 Encryption Standard 4.14. Introduction to Intel FPGA IP Cores Revision History
4.1. IP Catalog and Parameter Editor x
4.1.1. The Parameter Editor
4.2. Installing and Licensing Intel® FPGA IP Cores x
4.2.1. Intel® FPGA IP Evaluation Mode
4.2.1. Intel® FPGA IP Evaluation Mode x
4.2.1.1. Intel FPGA IP Versioning 4.2.1.2. Checking the IP License Status
4.6. Specifying the IP Core Parameters and Options ( Intel® Quartus® Prime Pro Edition) x
4.6.1. IP Core Generation Output ( Intel® Quartus® Prime Pro Edition) 4.6.2. Scripting IP Core Generation
4.8. Upgrading IP Cores x
4.8.1. Upgrading IP Cores at Command-Line 4.8.2. Migrating IP Cores to a Different Device 4.8.3. Troubleshooting IP or Platform Designer System Upgrade
4.9. Simulating Intel® FPGA IP Cores x
4.9.1. Generating IP Simulation Files 4.9.2. Scripting IP Simulation
4.9.2. Scripting IP Simulation x
4.9.2.1. Generating a Combined Simulator Setup Script ( Intel® Quartus® Prime Pro Edition)
4.12. Instantiating IP Cores in HDL x
4.12.1. Example Top-Level Verilog HDL Module 4.12.2. Example Top-Level VHDL Module
5. Migrating to Intel® Quartus® Prime Pro Edition x
5.1. Keep Pro Edition Project Files Separate 5.2. Upgrade Project Assignments and Constraints 5.3. Upgrade IP Cores and Platform Designer Systems 5.4. Upgrade Non-Compliant Design RTL 5.5. Migrating to Intel® Quartus® Prime Pro Edition Revision History
5.2. Upgrade Project Assignments and Constraints x
5.2.1. Modify Entity Name Assignments 5.2.2. Resolve Timing Constraint Entity Names 5.2.3. Verify Generated Node Name Assignments 5.2.4. Replace Logic Lock (Standard) Regions 5.2.5. Modify Signal Tap Logic Analyzer Files 5.2.6. Remove References to .qip Files 5.2.7. Remove Unsupported Feature Assignments
5.2.4. Replace Logic Lock (Standard) Regions x
5.2.4.1. Logic Lock Region Assignment Examples
5.4. Upgrade Non-Compliant Design RTL x
5.4.1. Verify Verilog Compilation Unit 5.4.2. Update Entity Auto-Discovery 5.4.3. Ensure Distinct VHDL Namespace for Each Library 5.4.4. Remove Unsupported Parameter Passing 5.4.5. Remove Unsized Constant from WYSIWYG Instantiation 5.4.6. Remove Non-Standard Pragmas 5.4.7. Declare Objects Before Initial Values 5.4.8. Confine SystemVerilog Features to SystemVerilog Files 5.4.9. Avoid Assignment Mixing in Always Blocks 5.4.10. Avoid Unconnected, Non-Existent Ports 5.4.11. Avoid Illegal Parameter Ranges 5.4.12. Update Verilog HDL and VHDL Type Mapping
5.4.1. Verify Verilog Compilation Unit x
5.4.1.1. Verilog HDL Configuration Instantiation
1. Introduction to Intel® Quartus® Prime Pro Edition
2. Managing Intel® Quartus® Prime Projects
3. Design Planning
4. Introduction to Intel® FPGA IP Cores
5. Migrating to Intel® Quartus® Prime Pro Edition
A. Intel® Quartus® Prime Pro Edition User Guides
6. Document Archives

4.6. Specifying the IP Core Parameters and Options ( Intel® Quartus® Prime Pro Edition)

Quickly configure Intel® FPGA IP cores in the Intel® Quartus® Prime parameter editor. Double-click any component in the IP Catalog to launch the parameter editor. The parameter editor allows you to define a custom variation of the IP core. The parameter editor generates the IP variation synthesis and optional simulation files, and adds the .ip file representing the variation to your project automatically.

Follow these steps to locate, instantiate, and customize an IP core in the parameter editor:

  1. Create or open an Intel® Quartus® Prime project (.qpf) to contain the instantiated IP variation.
  2. In the IP Catalog (Tools > IP Catalog), locate and double-click the name of the IP core to customize. To locate a specific component, type some or all of the component’s name in the IP Catalog search box. The New IP Variation window appears.
  3. Specify a top-level name for your custom IP variation. Do not include spaces in IP variation names or paths. The parameter editor saves the IP variation settings in a file named <your_ip> .ip. Click OK. The parameter editor appears.
    Figure 48. IP Parameter Editor ( Intel® Quartus® Prime Pro Edition)


  4. Set the parameter values in the parameter editor and view the block diagram for the component. The Parameterization Messages tab at the bottom displays any errors in IP parameters:
    • Optionally, select preset parameter values if provided for your IP core. Presets specify initial parameter values for specific applications.
    • Specify parameters defining the IP core functionality, port configurations, and device-specific features.
    • Specify options for processing the IP core files in other EDA tools.
    Note: Refer to your IP core user guide for information about specific IP core parameters.
  5. Click Generate HDL. The Generation dialog box appears.
  6. Specify output file generation options, and then click Generate. The synthesis and simulation files generate according to your specifications.
  7. To generate a simulation testbench, click Generate > Generate Testbench System. Specify testbench generation options, and then click Generate.
  8. To generate an HDL instantiation template that you can copy and paste into your text editor, click Generate > Show Instantiation Template.
  9. Click Finish. Click Yes if prompted to add files representing the IP variation to your project.
  10. After generating and instantiating your IP variation, make appropriate pin assignments to connect ports.
    Note: Some IP cores generate different HDL implementations according to the IP core parameters. The underlying RTL of these IP cores contains a unique hash code that prevents module name collisions between different variations of the IP core. This unique code remains consistent, given the same IP settings and software version during IP generation. This unique code can change if you edit the IP core's parameters or upgrade the IP core version. To avoid dependency on these unique codes in your simulation environment, refer to Generating a Combined Simulator Setup Script.
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