cvw/src/uncore/gpio_apb.sv

///////////////////////////////////////////
// gpio_apb.sv
//
// Written: David_Harris@hmc.edu 14 January 2021
// Modified: bbracker@hmc.edu 15 Apr. 2021
//
// Purpose: General Purpose I/O peripheral
//   See FE310-G002-Manual-v19p05 for specifications
//   No interrupts, drive strength, or pull-ups supported
// 
// Documentation: RISC-V System on Chip Design Chapter 15
//
// A component of the CORE-V-WALLY configurable RISC-V project.
// 
// Copyright (C) 2021-23 Harvey Mudd College & Oklahoma State University
//
// SPDX-License-Identifier: Apache-2.0 WITH SHL-2.1
//
// Licensed under the Solderpad Hardware License v 2.1 (the “License”); you may not use this file 
// except in compliance with the License, or, at your option, the Apache License version 2.0. You 
// may obtain a copy of the License at
//
// https://solderpad.org/licenses/SHL-2.1/
//
// Unless required by applicable law or agreed to in writing, any work distributed under the 
// License is distributed on an “AS IS” BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, 
// either express or implied. See the License for the specific language governing permissions 
// and limitations under the License.
////////////////////////////////////////////////////////////////////////////////////////////////

`include "wally-config.vh"

module gpio_apb (
  input  logic              PCLK, PRESETn,
  input  logic              PSEL,
  input  logic [7:0]        PADDR, 
  input  logic [`XLEN-1:0]  PWDATA,
  input  logic [`XLEN/8-1:0] PSTRB,
  input  logic              PWRITE,
  input  logic              PENABLE,
  output logic [`XLEN-1:0]  PRDATA,
  output logic              PREADY,
  input  logic [31:0]       iof0, iof1,
  input  logic [31:0]       GPIOIN,
  output logic [31:0]       GPIOOUT, GPIOEN,
  output logic              GPIOIntr
);

  logic [31:0]              input0d, input1d, input2d, input3d;
  logic [31:0]              input_val, input_en, output_en, output_val;
  logic [31:0]              rise_ie, rise_ip, fall_ie, fall_ip, high_ie, high_ip, low_ie, low_ip; 
  logic [31:0]              out_xor, iof_en, iof_sel, iof_out, gpio_out;
  logic [7:0]               entry;
  logic [31:0]              Din, Dout;
  logic                     memwrite;
  
  // APB I/O
  assign entry = {PADDR[7:2],2'b00};  // 32-bit word-aligned accesses
  assign memwrite = PWRITE & PENABLE & PSEL;  // only write in access phase
  assign PREADY = 1'b1; // GPIO never takes >1 cycle to respond

  // account for subword read/write circuitry
  // -- Note GPIO registers are 32 bits no matter what; access them with LW SW.
  //    (At least that's what I think when FE310 spec says "only naturally aligned 32-bit accesses are supported")
  if (`XLEN == 64) begin
    assign Din =    entry[2] ? PWDATA[63:32] : PWDATA[31:0];
    assign PRDATA = entry[2] ? {Dout,32'b0}  : {32'b0,Dout};
  end else begin // 32-bit
    assign Din = PWDATA[31:0];
    assign PRDATA = Dout;
  end

  // register access
  always_ff @(posedge PCLK, negedge PRESETn)
    if (~PRESETn) begin // asynch reset
      input_en <= 0;
      output_en <= 0;
      // *** synch reset not yet implemented [DH: can we delete this comment?  Check if a sync reset is required]
      output_val <= #1 0;
      rise_ie <= #1 0;
      rise_ip <= #1 0;
      fall_ie <= #1 0;
      fall_ip <= #1 0;
      high_ie <= #1 0;
      high_ip <= #1 0;
      low_ie <= #1 0;
      low_ip <= #1 0;
      iof_en <= #1 0;
      iof_sel <= #1 0;
      out_xor <= #1 0;
    end else begin     // writes
        // According to FE310 spec: Once the interrupt is pending, it will remain set until a 1 is written to the *_ip register at that bit.
        /* verilator lint_off CASEINCOMPLETE */
      if (memwrite) 
        case(entry)
          8'h04: input_en <= #1 Din;
          8'h08: output_en <= #1 Din;
          8'h0C: output_val <= #1 Din;
          8'h18: rise_ie <= #1 Din;
          8'h20: fall_ie <= #1 Din;
          8'h28: high_ie <= #1 Din;
          8'h30: low_ie  <= #1 Din;
          8'h38: iof_en  <= #1 Din;
          8'h3C: iof_sel <= #1 Din;
          8'h40: out_xor <= #1 Din;
        endcase
        /* verilator lint_on CASEINCOMPLETE */

      // interrupts can be cleared by writing corresponding bits to a register
      if (memwrite & entry == 8'h1C)   rise_ip <= rise_ip & ~Din;
      else                             rise_ip <= rise_ip | (input2d & ~input3d);
      if (memwrite & (entry == 8'h24)) fall_ip <= fall_ip & ~Din;
      else                             fall_ip <= fall_ip | (~input2d & input3d);
      if (memwrite & (entry == 8'h2C)) high_ip <= high_ip & ~Din;
      else                             high_ip <= high_ip | input3d;
      if (memwrite & (entry == 8'h34)) low_ip  <= low_ip  & ~Din;
      else                             low_ip  <= low_ip  | ~input3d;

      case(entry) // flop to sample inputs
        8'h00: Dout <= #1 input_val;
        8'h04: Dout <= #1 input_en;
        8'h08: Dout <= #1 output_en;
        8'h0C: Dout <= #1 output_val;
        8'h18: Dout <= #1 rise_ie;
        8'h1C: Dout <= #1 rise_ip;
        8'h20: Dout <= #1 fall_ie;
        8'h24: Dout <= #1 fall_ip;
        8'h28: Dout <= #1 high_ie;
        8'h2C: Dout <= #1 high_ip;
        8'h30: Dout <= #1 low_ie;
        8'h34: Dout <= #1 low_ip;
        8'h38: Dout <= #1 iof_en;
        8'h3C: Dout <= #1 iof_sel;
        8'h40: Dout <= #1 out_xor; 
        default: Dout <= #1 0;
      endcase
    end

  // chip i/o
  // connect OUT to IN for loopback testing
  if (`GPIO_LOOPBACK_TEST) assign input0d = ((output_en & GPIOOUT) | (~output_en & GPIOIN)) & input_en;
  else                     assign input0d = GPIOIN & input_en;

  // synchroninzer for inputs
  flop #(32) sync1(PCLK,input0d,input1d);
  flop #(32) sync2(PCLK,input1d,input2d);
  flop #(32) sync3(PCLK,input2d,input3d);
  assign input_val = input3d;
  assign iof_out = iof_sel & iof1 | ~iof_sel & iof0;         // per-bit mux between iof1 and iof0
  assign gpio_out = iof_en & iof_out | ~iof_en & output_val; // per-bit mux between IOF and output_val
  assign GPIOOUT = gpio_out ^ out_xor;                   // per-bit flip output polarity
  assign GPIOEN = output_en;

  assign GPIOIntr = |{(rise_ip & rise_ie),(fall_ip & fall_ie),(high_ip & high_ie),(low_ip & low_ie)};
endmodule
Added ahbapbbridge and cleaning RAM 2022-06-08 01:31:34 +00:00			`///////////////////////////////////////////`
			`// gpio_apb.sv`
			`//`
			`// Written: David_Harris@hmc.edu 14 January 2021`
			`// Modified: bbracker@hmc.edu 15 Apr. 2021`
			`//`
			`// Purpose: General Purpose I/O peripheral`
			`// See FE310-G002-Manual-v19p05 for specifications`
			`// No interrupts, drive strength, or pull-ups supported`
			`//`
uncore cleanup 2023-01-14 14:15:35 +00:00			`// Documentation: RISC-V System on Chip Design Chapter 15`
			`//`
changed name to CORE-V-WALLY 2023-01-11 23:15:08 +00:00			`// A component of the CORE-V-WALLY configurable RISC-V project.`
Added ahbapbbridge and cleaning RAM 2022-06-08 01:31:34 +00:00			`//`
Changed MIT license to Solderpad License 2023-01-10 19:35:20 +00:00			`// Copyright (C) 2021-23 Harvey Mudd College & Oklahoma State University`
Added ahbapbbridge and cleaning RAM 2022-06-08 01:31:34 +00:00			`//`
Changed MIT license to Solderpad License 2023-01-10 19:35:20 +00:00			`// SPDX-License-Identifier: Apache-2.0 WITH SHL-2.1`
Added ahbapbbridge and cleaning RAM 2022-06-08 01:31:34 +00:00			`//`
Changed MIT license to Solderpad License 2023-01-10 19:35:20 +00:00			`// Licensed under the Solderpad Hardware License v 2.1 (the “License”); you may not use this file`
			`// except in compliance with the License, or, at your option, the Apache License version 2.0. You`
			`// may obtain a copy of the License at`
Added ahbapbbridge and cleaning RAM 2022-06-08 01:31:34 +00:00			`//`
Changed MIT license to Solderpad License 2023-01-10 19:35:20 +00:00			`// https://solderpad.org/licenses/SHL-2.1/`
			`//`
			`// Unless required by applicable law or agreed to in writing, any work distributed under the`
			`// License is distributed on an “AS IS” BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND,`
			`// either express or implied. See the License for the specific language governing permissions`
			`// and limitations under the License.`
Added ahbapbbridge and cleaning RAM 2022-06-08 01:31:34 +00:00			`////////////////////////////////////////////////////////////////////////////////////////////////`

			`include "wally-config.vh"

			`module gpio_apb (`
uncore cleanup 2023-01-15 01:21:07 +00:00			`input logic PCLK, PRESETn,`
			`input logic PSEL,`
			`input logic [7:0] PADDR,`
			input logic [`XLEN-1:0] PWDATA,
AHB bridge for gpio 2022-07-05 05:01:59 +00:00			input logic [`XLEN/8-1:0] PSTRB,
uncore cleanup 2023-01-15 01:21:07 +00:00			`input logic PWRITE,`
			`input logic PENABLE,`
			output logic [`XLEN-1:0] PRDATA,
			`output logic PREADY,`
			`input logic [31:0] iof0, iof1,`
Updated GPIO signal names to reflect book. 2023-03-24 23:55:43 +00:00			`input logic [31:0] GPIOIN,`
			`output logic [31:0] GPIOOUT, GPIOEN,`
uncore cleanup 2023-01-15 01:21:07 +00:00			`output logic GPIOIntr`
			`);`
Added ahbapbbridge and cleaning RAM 2022-06-08 01:31:34 +00:00
uncore cleanup 2023-01-15 01:21:07 +00:00			`logic [31:0] input0d, input1d, input2d, input3d;`
			`logic [31:0] input_val, input_en, output_en, output_val;`
			`logic [31:0] rise_ie, rise_ip, fall_ie, fall_ip, high_ie, high_ip, low_ie, low_ip;`
			`logic [31:0] out_xor, iof_en, iof_sel, iof_out, gpio_out;`
			`logic [7:0] entry;`
			`logic [31:0] Din, Dout;`
			`logic memwrite;`
Added ahbapbbridge and cleaning RAM 2022-06-08 01:31:34 +00:00
			`// APB I/O`
			`assign entry = {PADDR[7:2],2'b00}; // 32-bit word-aligned accesses`
AHB bridge for gpio 2022-07-05 05:01:59 +00:00			`assign memwrite = PWRITE & PENABLE & PSEL; // only write in access phase`
			`assign PREADY = 1'b1; // GPIO never takes >1 cycle to respond`
Added ahbapbbridge and cleaning RAM 2022-06-08 01:31:34 +00:00
			`// account for subword read/write circuitry`
			`// -- Note GPIO registers are 32 bits no matter what; access them with LW SW.`
			`// (At least that's what I think when FE310 spec says "only naturally aligned 32-bit accesses are supported")`
			if (`XLEN == 64) begin
			`assign Din = entry[2] ? PWDATA[63:32] : PWDATA[31:0];`
			`assign PRDATA = entry[2] ? {Dout,32'b0} : {32'b0,Dout};`
			`end else begin // 32-bit`
			`assign Din = PWDATA[31:0];`
			`assign PRDATA = Dout;`
			`end`

			`// register access`
			`always_ff @(posedge PCLK, negedge PRESETn)`
			`if (~PRESETn) begin // asynch reset`
			`input_en <= 0;`
			`output_en <= 0;`
			`// *** synch reset not yet implemented [DH: can we delete this comment? Check if a sync reset is required]`
			`output_val <= #1 0;`
			`rise_ie <= #1 0;`
			`rise_ip <= #1 0;`
			`fall_ie <= #1 0;`
			`fall_ip <= #1 0;`
			`high_ie <= #1 0;`
			`high_ip <= #1 0;`
			`low_ie <= #1 0;`
			`low_ip <= #1 0;`
AHB bridge for gpio 2022-07-05 05:01:59 +00:00			`iof_en <= #1 0;`
			`iof_sel <= #1 0;`
			`out_xor <= #1 0;`
Added ahbapbbridge and cleaning RAM 2022-06-08 01:31:34 +00:00			`end else begin // writes`
			`// According to FE310 spec: Once the interrupt is pending, it will remain set until a 1 is written to the *_ip register at that bit.`
			`/* verilator lint_off CASEINCOMPLETE */`
			`if (memwrite)`
			`case(entry)`
			`8'h04: input_en <= #1 Din;`
			`8'h08: output_en <= #1 Din;`
			`8'h0C: output_val <= #1 Din;`
			`8'h18: rise_ie <= #1 Din;`
			`8'h20: fall_ie <= #1 Din;`
			`8'h28: high_ie <= #1 Din;`
			`8'h30: low_ie <= #1 Din;`
AHB bridge for gpio 2022-07-05 05:01:59 +00:00			`8'h38: iof_en <= #1 Din;`
			`8'h3C: iof_sel <= #1 Din;`
			`8'h40: out_xor <= #1 Din;`
Added ahbapbbridge and cleaning RAM 2022-06-08 01:31:34 +00:00			`endcase`
			`/* verilator lint_on CASEINCOMPLETE */`

			`// interrupts can be cleared by writing corresponding bits to a register`
			`if (memwrite & entry == 8'h1C) rise_ip <= rise_ip & ~Din;`
			`else rise_ip <= rise_ip \| (input2d & ~input3d);`
			`if (memwrite & (entry == 8'h24)) fall_ip <= fall_ip & ~Din;`
			`else fall_ip <= fall_ip \| (~input2d & input3d);`
			`if (memwrite & (entry == 8'h2C)) high_ip <= high_ip & ~Din;`
			`else high_ip <= high_ip \| input3d;`
			`if (memwrite & (entry == 8'h34)) low_ip <= low_ip & ~Din;`
			`else low_ip <= low_ip \| ~input3d;`

			`case(entry) // flop to sample inputs`
			`8'h00: Dout <= #1 input_val;`
			`8'h04: Dout <= #1 input_en;`
			`8'h08: Dout <= #1 output_en;`
			`8'h0C: Dout <= #1 output_val;`
			`8'h18: Dout <= #1 rise_ie;`
			`8'h1C: Dout <= #1 rise_ip;`
			`8'h20: Dout <= #1 fall_ie;`
			`8'h24: Dout <= #1 fall_ip;`
			`8'h28: Dout <= #1 high_ie;`
			`8'h2C: Dout <= #1 high_ip;`
			`8'h30: Dout <= #1 low_ie;`
			`8'h34: Dout <= #1 low_ip;`
AHB bridge for gpio 2022-07-05 05:01:59 +00:00			`8'h38: Dout <= #1 iof_en;`
			`8'h3C: Dout <= #1 iof_sel;`
			`8'h40: Dout <= #1 out_xor;`
Added ahbapbbridge and cleaning RAM 2022-06-08 01:31:34 +00:00			`default: Dout <= #1 0;`
			`endcase`
			`end`

			`// chip i/o`
			`// connect OUT to IN for loopback testing`
Updated GPIO signal names to reflect book. 2023-03-24 23:55:43 +00:00			if (`GPIO_LOOPBACK_TEST) assign input0d = ((output_en & GPIOOUT) \| (~output_en & GPIOIN)) & input_en;
			`else assign input0d = GPIOIN & input_en;`
Added ahbapbbridge and cleaning RAM 2022-06-08 01:31:34 +00:00
			`// synchroninzer for inputs`
			`flop #(32) sync1(PCLK,input0d,input1d);`
			`flop #(32) sync2(PCLK,input1d,input2d);`
			`flop #(32) sync3(PCLK,input2d,input3d);`
			`assign input_val = input3d;`
AHB bridge for gpio 2022-07-05 05:01:59 +00:00			`assign iof_out = iof_sel & iof1 \| ~iof_sel & iof0; // per-bit mux between iof1 and iof0`
			`assign gpio_out = iof_en & iof_out \| ~iof_en & output_val; // per-bit mux between IOF and output_val`
Updated GPIO signal names to reflect book. 2023-03-24 23:55:43 +00:00			`assign GPIOOUT = gpio_out ^ out_xor; // per-bit flip output polarity`
			`assign GPIOEN = output_en;`
Added ahbapbbridge and cleaning RAM 2022-06-08 01:31:34 +00:00
			`assign GPIOIntr = \|{(rise_ip & rise_ie),(fall_ip & fall_ie),(high_ip & high_ie),(low_ip & low_ie)};`
			`endmodule`