blob: 57d4a230e2a458e24cd42370abccc8f6b5599c46 [file] [log] [blame]
`default_nettype none
/*
* SPDX-FileCopyrightText: 2015 Clifford Wolf
* PicoSoC - A simple example SoC using PicoRV32
*
* Copyright (C) 2017 Clifford Wolf <clifford@clifford.at>
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*
* SPDX-License-Identifier: ISC
*/
module simpleuartA_wb # (
parameter BASE_ADR = 32'h 2000_0000,
parameter CLK_DIV = 8'h00,
parameter DATA = 8'h04,
parameter CONFIG = 8'h08
) (
input wb_clk_i,
input wb_rst_i,
input [31:0] wb_adr_i,
input [31:0] wb_dat_i,
input [3:0] wb_sel_i,
input wb_we_i,
input wb_cyc_i,
input wb_stb_i,
output wb_ack_o,
output [31:0] wb_dat_o,
output uart_enabled,
output ser_tx,
input ser_rx
);
wire [31:0] simpleuartA_reg_div_do;
wire [31:0] simpleuartA_reg_dat_do;
wire [31:0] simpleuartA_reg_cfg_do;
wire reg_dat_wait;
wire resetn = ~wb_rst_i;
wire valid = wb_stb_i && wb_cyc_i;
wire simpleuartA_reg_div_sel = valid && (wb_adr_i == (BASE_ADR | CLK_DIV));
wire simpleuartA_reg_dat_sel = valid && (wb_adr_i == (BASE_ADR | DATA));
wire simpleuartA_reg_cfg_sel = valid && (wb_adr_i == (BASE_ADR | CONFIG));
wire [3:0] reg_div_we = simpleuartA_reg_div_sel ? (wb_sel_i & {4{wb_we_i}}): 4'b 0000;
wire reg_dat_we = simpleuartA_reg_dat_sel ? (wb_sel_i[0] & wb_we_i): 1'b 0; // simpleuartA_reg_dat_sel ? mem_wstrb[0] : 1'b 0
wire reg_cfg_we = simpleuartA_reg_cfg_sel ? (wb_sel_i[0] & wb_we_i): 1'b 0;
wire [31:0] mem_wdata = wb_dat_i;
wire reg_dat_re = simpleuartA_reg_dat_sel && !wb_sel_i && ~wb_we_i; // read_enable
assign wb_dat_o = simpleuartA_reg_div_sel ? simpleuartA_reg_div_do:
simpleuartA_reg_cfg_sel ? simpleuartA_reg_cfg_do:
simpleuartA_reg_dat_do;
assign wb_ack_o = (simpleuartA_reg_div_sel || simpleuartA_reg_dat_sel
|| simpleuartA_reg_cfg_sel) && (!reg_dat_wait);
simpleuartA simpleuartA (
.clk (wb_clk_i),
.resetn (resetn),
.ser_tx (ser_tx),
.ser_rx (ser_rx),
.enabled (uart_enabled),
.reg_div_we (reg_div_we),
.reg_div_di (mem_wdata),
.reg_div_do (simpleuartA_reg_div_do),
.reg_cfg_we (reg_cfg_we),
.reg_cfg_di (mem_wdata),
.reg_cfg_do (simpleuartA_reg_cfg_do),
.reg_dat_we (reg_dat_we),
.reg_dat_re (reg_dat_re),
.reg_dat_di (mem_wdata),
.reg_dat_do (simpleuartA_reg_dat_do),
.reg_dat_wait(reg_dat_wait)
);
endmodule
module simpleuartA (
input clk,
input resetn,
output enabled,
output ser_tx,
input ser_rx,
input [3:0] reg_div_we,
input [31:0] reg_div_di,
output [31:0] reg_div_do,
input reg_cfg_we,
input [31:0] reg_cfg_di,
output [31:0] reg_cfg_do,
input reg_dat_we,
input reg_dat_re,
input [31:0] reg_dat_di,
output [31:0] reg_dat_do,
output reg_dat_wait
);
reg [31:0] cfg_divider;
reg enabled;
reg [3:0] recv_state;
reg [31:0] recv_divcnt;
reg [7:0] recv_pattern;
reg [7:0] recv_buf_data;
reg recv_buf_valid;
reg [9:0] send_pattern;
reg [3:0] send_bitcnt;
reg [31:0] send_divcnt;
reg send_dummy;
assign reg_div_do = cfg_divider;
assign reg_cfg_do = {31'd0, enabled};
assign reg_dat_wait = reg_dat_we && (send_bitcnt || send_dummy);
assign reg_dat_do = recv_buf_valid ? recv_buf_data : ~0;
always @(posedge clk) begin
if (!resetn) begin
cfg_divider <= 1;
enabled <= 1'b0;
end else begin
if (reg_div_we[0]) cfg_divider[ 7: 0] <= reg_div_di[ 7: 0];
if (reg_div_we[1]) cfg_divider[15: 8] <= reg_div_di[15: 8];
if (reg_div_we[2]) cfg_divider[23:16] <= reg_div_di[23:16];
if (reg_div_we[3]) cfg_divider[31:24] <= reg_div_di[31:24];
if (reg_cfg_we) enabled <= reg_div_di[0];
end
end
always @(posedge clk) begin
if (!resetn) begin
recv_state <= 0;
recv_divcnt <= 0;
recv_pattern <= 0;
recv_buf_data <= 0;
recv_buf_valid <= 0;
end else begin
recv_divcnt <= recv_divcnt + 1;
if (reg_dat_re)
recv_buf_valid <= 0;
case (recv_state)
0: begin
if (!ser_rx && enabled)
recv_state <= 1;
recv_divcnt <= 0;
end
1: begin
if (2*recv_divcnt > cfg_divider) begin
recv_state <= 2;
recv_divcnt <= 0;
end
end
10: begin
if (recv_divcnt > cfg_divider) begin
recv_buf_data <= recv_pattern;
recv_buf_valid <= 1;
recv_state <= 0;
end
end
default: begin
if (recv_divcnt > cfg_divider) begin
recv_pattern <= {ser_rx, recv_pattern[7:1]};
recv_state <= recv_state + 1;
recv_divcnt <= 0;
end
end
endcase
end
end
assign ser_tx = send_pattern[0];
always @(posedge clk) begin
if (reg_div_we && enabled)
send_dummy <= 1;
send_divcnt <= send_divcnt + 1;
if (!resetn) begin
send_pattern <= ~0;
send_bitcnt <= 0;
send_divcnt <= 0;
send_dummy <= 1;
end else begin
if (send_dummy && !send_bitcnt) begin
send_pattern <= ~0;
send_bitcnt <= 15;
send_divcnt <= 0;
send_dummy <= 0;
end else
if (reg_dat_we && !send_bitcnt) begin
send_pattern <= {1'b1, reg_dat_di[7:0], 1'b0};
send_bitcnt <= 10;
send_divcnt <= 0;
end else
if (send_divcnt > cfg_divider && send_bitcnt) begin
send_pattern <= {1'b1, send_pattern[9:1]};
send_bitcnt <= send_bitcnt - 1;
send_divcnt <= 0;
end
end
end
endmodule
`default_nettype wire