# UHD FPGA Coding Standards ## Preamble To quote R. W. Emerson: "A foolish consistency is the hobgoblin of little minds, adored by little statesmen and philosophers and divines". Ignoring the little statesmen for a minute, these coding standards are here to make our life *easier*, not simply add additional rules. They are meant as additional guidance for developers, and are not meant to be interpreted as law. So, ultimately, it is up to the developer to decide how much these guidelines should be heeded when writing code, and up to reviewers how much they are relevant to new submissions. That said, a consistent codebase is easier to maintain, read, understand, and extend. Choosing personal preferences over these coding guidelines is not a helpful move for the team and future maintainability of the UHD FPGA codebase. ## General Coding Guidelines * Code layout: We use 2 spaces for indentation levels, and never tabs. * Never submit code with trailing whitespace. * Code is read more often than it's written. Code readability is thus something worth optimizing for. * Try and keep line lengths to 79 characters, unless readability suffers. * Comment your code. Especially if your code is tricky or makes unique assumptions. * Provide a detailed description of each module or file in its header. Consider its purpose, how it is intended to be used, assumptions made in its design, limitations of the implementation, etc. * Use the following header at the top of each file: ```verilog // // Copyright Ettus Research, a National Instruments Brand // // SPDX-License-Identifier: LGPL-3.0-or-later // // Module: // // Description: // // // Parameters: // // // Signals: // // ``` ## Verilog Style Guidelines ### General Syntax * Always use `begin`and `end` statements for more complex code blocks even if the enclosing code is only one line. * Indent begin/end as follows: ```verilog if (foo) begin // Do something end else if (bar) begin case(xyz) 1'b0: begin // Handle 0 end default: begin // Handle 1 end endcase end else begin // Do nothing end ``` * Declare and instantiate modules as shown below. Aligning the ports into columns is not required but helps with readability and edibility. A good text editor can make this easy. ```verilog module top_level #( parameter PARAM1 = 0, parameter [7:0] PARAM2 = 0 ) ( input wire clk, input wire rst, input wire [7:0] signal1, output wire [7:0] signal2 ); example_one #( .PARAM1(0), .PARAM2(1) ) example_one_i ( .clk(clk), .rst(rst), .port1(signal1), .port2(signal2) ); example_two #( .PARAM1(0), .PARAM2(1) ) example_two_i ( .clk(clk), .rst(rst), .port1(signal1), .port2(signal2) ); example_three #( .PARAM1 (0), .PARAM2 (1) ) example_three_i ( .clk (clk), .rst (rst), .port1 (signal1), .port2 (signal2) ); endmodule ``` ### Assignments * Sequential blocks should only have non-blocking assignments (`<=`) * Combinational blocks should only have blocking assignments (`=`) * Don't mix blocking and non-blocking assignments ### Modules * Each module should be defined in a separate file * The file name should be the same as the module name * File and module names should be unique. Do not create a new module with the same name as an existing module. * Every module requires a description in the header that gives a synopsis of its function. * Use Verilog 2001 ANSI-C style port declarations: ```verilog ( ... output reg foo, input wire bar ); ``` * Declare inputs and outputs one per line. This makes searching and commenting easier. * Add comments to the header or inline to describe the behavior of input/output ports. * Be explicit about whether an input or output is a wire or reg. * Group signals logically instead of by direction. If a single AXI-Stream bus has multiple inputs and outputs, keep them together. * Instantiate all ports for a module even if they are tied off or unconnected. Don't let the compiler insert values for any signals automatically. ```verilog dummy_module dummy_module_i ( .clk (clk), .rst (1'b0), .status (/* unused */) ); ``` * Don't instantiate modules using positional arguments. Use the dot form illustrated above. * Use default_nettype at the beginning and end of each module file to avoid problems with undeclared signals: ```verilog `default_nettype none module example #( ... endmodule `default_nettype wire ``` ### Clocking and Resets * Name clocks as `clk`. If there are multiple clocks then use a prefix like `bus_clk` and `radio_clk`. * If a module has signals or input/outputs whose clock domain is not obvious, use a clock suffix to be explicit about the domain, for example `axi_tdata_bclk`, `axi_tdata_rclk`. * Try not to encode the frequency of the clock in the name unless the particular clock can *never* take on any other frequency. * Name resets as `rst`. If there are multiple clocks then use a prefix like `bus_rst` and `radio_rst`. * If a reset is asynchronous, call it `arst`. * Try to avoid asynchronous resets as much as possible. * Don't use active low resets unless it is used to drive top-level IO or IP that requires it. ### Generate Statements * Use the ``generate``/``endgenerate`` keywords for backwards compatibility with earlier versions of the Verilog language. * Add labels to the `begin`/`end` blocks of generate statements, so that the labels are used when displaying the hierarchical names in the simulator and other tools, and so that logic can be referenced hierarchically by name in testbenches if needed. For example: ```verilog genvar i; generate for (i = 0; i < NUM_PORTS; i++) begin : gen_loop_example ... end endgenerate ``` ### Parameters, Defines and Constants * Parameterize modules wherever possible, especially if they are designed for reuse. Bus widths, addresses, buffer sizes, etc are good candidates for parametrization. * For modules with parameters, add comments in the header or inline to describe the behavior of each parameter. * Propagate parameters as far up the hierarchy as possible as long as it makes sense. * Place `` `define`` statements in Verilog header files (.vh) and `` `include`` them in modules. * Avoid placing `` `define`` statements in modules. * For local constants, use `localparam` instead on hard-coding things like widths, etc. * Use all uppercase names for constants (``parameter``, ``localparam``, or `` `define``) to distinguish them from signal names. ### AXI Guidelines * Keep the components of an AXI-Stream or AXI-MM bus together in port/wire instantiations. * For module ports, use the master/slave naming convention as shown below. It makes connecting modules easier because a master always connects to a slave. ```verilog input wire [63:0] s_axis_tdata, input wire s_axis_tlast, input wire s_axis_tvalid, output wire s_axis_tready, output reg [63:0] m_axis_tdata, output reg m_axis_tlast, output reg m_axis_tvalid, input wire m_axis_tready, ``` * For connections between a master and slave, *do not* use the master/slave convention. Name the bus based on its function or underlying data. ```verilog wire [63:0] axis_eth2xbar_tdata, wire axis_eth2xbar_tlast, wire axis_eth2xbar_tvalid, wire axis_eth2xbar_tready, // If "axis" is obvious, drop the prefix wire [63:0] samp_tdata, wire samp_tlast, wire samp_tvalid, wire samp_tready, ```