I've got an fpga design that utilizes synchronous resets (I prefer synchronous resets to asynchronous for reasons discussed elsewhere). I have four different clock domains in the design and I utilize a single button to generate my reset signal, which is of course totally asynchronous to everything (save my finger). I debounce the button signal in each of the four clock domains to generate synchronous resets for the four domains from a single source. My debounce module basically counts N clock cycles of the reset button being asserted. If more than N cycles have passed with reset asserted then I generate my reset signal (code for this module pasted below).

First question -- are there better ways of generating the reset(s) than this method?

Second (more interesting question): when I look at the timing reports (using xilinx tools) I see that consistently the limiting signals are all reset related. For example the limiting path is from the reset generator (debouncer) to some state machine's state register. The reset signals are very high fan out (they touch everything in their respective clock domains). I'm a little surprised though that my speed is limited by the reset. I'm finding that I'm limited to something like 8.5 nS where ~50% is routing and ~50% of that is logic. Any suggestions on how to do this a little better? How do you go about dealing with synchronous reset generation in fpga designs?

Here's the code for reset generation. Note that the signal reset signal is akin to the debounced output (e.g. when I instantiate the module the debounced output is the reset for that particular clock domain).

module button_debouncer(/*AUTOARG*/
   // Outputs
   // Inputs
   clk, button
   /* Parameters */
   parameter WIDTH = 1;
   parameter NUM_CLKS_HIGH = 12000000;
   parameter log2_NUM_CLKS = 24;

   /* Inputs */
   input clk;
   input [WIDTH-1:0] button;

   /* Outputs */
   output [WIDTH-1:0] debounced;

   /* Regs and Wires */
   reg [WIDTH-1:0]    b1, b2;
   reg [log2_NUM_CLKS-1:0] counter;

   /* Synched to clock domain */
   always @(posedge clk) begin
      b1 <= button;
      b2 <= b1;

   /* Debounce the button */
   always @(posedge clk) begin
    counter <= 0;
      else if(counter < {log2_NUM_CLKS{1'b1}})
    counter <= counter + 1;

   /* Assign the output */
   //wire [WIDTH-1:0] debounced = counter > NUM_CLKS_HIGH;
   reg [WIDTH-1:0] debounced;

   always @(posedge clk) begin
      debounced <= counter > NUM_CLKS_HIGH;

endmodule //button_debouncer
  • It appears as though my original debouncer didn't have a registered output (original version commented out). By registering the output I was (unsurprisingly) able to improve performance such that the reset signals are no longer the limiting path. That stated the general question of reset strategy remains. Thanks! – Doov May 31 '13 at 19:39
  • Does your fpga really need a reset? FPGAs can be programmed with an initial state, so if you just need a clean starting point you can just use initial and then save yourself the area/timing expense of a reset network. – Tim May 31 '13 at 20:47
  • Thanks for the comment @Tim. Yes, I do indeed need the reset. Thanks. – Doov May 31 '13 at 22:27

A very good way to improve timing scores while working with resets is to cap the max fanout. the tools will then buffer the signal so that there is not one lut trying to be routed and used to drive every register. This can be accomplished in this way:

(* max_fanout = <arbitrary_value> *) 
wire reset; 

so what we have here is a constraint used by the vivado synth tool (or if you are still using ISE, then that tool). Also, if should be noted that this only affects the next declaration of a net, so other nets (wires, regs, ext) declared before or after this are unaffected.

There is a good constraint user guide on xilinx's website. There are a few other ones that you may want to look into as well and they are: IBUF or BUFG.

  • Thanks for the info. That seems like a reasonable approach. I've already enabled register duplication (which I think should in effect do exactly what you suggest in order to meet timing requirements). I wonder if architecturally there's something more intelligent to do than what I've done. Just to clarify -- using your scheme does a module lower in the hierarchy get the reset from a module higher than it? E.g. should every module utilize such a fanout constraint or just a few higher level ones? – Doov Jun 4 '13 at 20:42
  • the reset comes from a top level module and then fans out to all other modules and others at lower levels. The max fanout restriction carries through because it is driven by the same reg or input. – alex_milhouse Jun 4 '13 at 20:52

You don't need four instances of the debouncer. Put in one debouncer off your main clock and then use three metastable filters to sync its output to the other three domains.

Also when you distribute your reset you should use what Cliff Cummings calls a "synchronous reset distribution tree". Check his website for some papers on that.

  • is this intended as a comment or an answer? – Mgetz Aug 2 '13 at 20:04
  • 1
    He said that he was debouncing the button signal in four different clock domains and asked if there was a better way to do it. I assumed that he had instantiated a debouncer in each domain. That would be rather wastefull since you could debounce it in any domain and then resync the signal to the other domains for a lot less than a 24 bit counter/comparator. – John Eaton Aug 2 '13 at 22:09

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