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3.2. System Design with Platform Designer
Platform Designer simplifies the task of building complex hardware systems on an FPGA. Platform Designer allows you to describe the topology of your system using a graphical user interface (GUI) and then generate the hardware description language (HDL) files for that system. The Intel® Quartus® Prime software compiles the HDL files to create an SRAM Object File (.sof). For additional information about Platform Designer, refer to the Intel® Quartus® Prime Handbook.
Platform Designer allows you to choose the processor core type and the level of cache, debugging, and custom functionality for each Nios® II processor. Your design can use on-chip resources such as memory, PLLs, DSP functions, and high-speed transceivers. You can construct the optimal processor for your design using Platform Designer.
After you construct your system using Platform Designer, and after you add any required custom logic to complete your top-level design, you must create pin assignments using the Intel® Quartus® Prime software. The FPGA’s external pins have flexible functionality, and a range of pins are available to connect to clocks, control signals, and I/O signals.
For information about how to create pin assignments, refer to Intel® Quartus® Prime Help and to the I/O Management chapter in Volume 2: Design Implementation and Optimization of the Intel® Quartus® Prime Handbook.
Intel recommends that you start your design from a small pretested project and build it incrementally. Start with one of the many Platform Designer example designs available from the All Design Examples web page of the Intel website, or with an example design from the Nios® II Hardware Development Tutorial.
Platform Designer allows you to create your own custom components using the component editor. In the component editor you can import your own source files, assign signals to various interfaces, and set various component and parameter properties.
Before designing a custom component, you should become familiar with the interface and signal types that are available in Platform Designer.
You should use dynamic addressing for slave interfaces on all new components. Dynamically addressable slave ports include byte enables to qualify which byte lanes are accessed during read and write cycles. Dynamically addressable slave interfaces have the added benefit of being accessible by masters of any data width without data truncation or side effects.
To learn about the interface and signal types that you can use in Platform Designer, refer to Avalon Interface Specifications. To learn about using the component editor, refer to the Component Editor chapter in the Intel® Quartus® Prime Handbook.
As you add each hardware component to the system, test it with software. If you do not know how to develop software to test new hardware components, Intel recommends that you work with a software engineer to test the components.
The Nios® II EDS includes several software examples, located in your Nios® II EDS installation directory (nios2eds), at < Nios® II EDS install dir>\examples\software. After you run a simple software design—such as the simplest example, Hello World Small—build individual systems based on this design to test the additional interfaces or custom options that your system requires. Intel recommends that you start with a simple system that includes a processor with a JTAG debug module, an on-chip memory component, and a JTAG UART component, and create a new system for each new untested component, rather than adding in new untested components incrementally.
After you verify that each new hardware component functions correctly in its own separate system, you can combine the new components incrementally in a single Platform Designer system. Platform Designer supports this design methodology well, by allowing you to add components and regenerate the project easily.
For detailed information about how to implement the recommended incremental design process, refer to the Verification and Board Bring-Up chapter of the Embedded Design Handbook.