verilog/rtl/rtc/rtclight.v - third_party/shuttle/sky130/mpw-002/slot-020 - Git at Google

 ///////////////////////////////////////////////////////////////////////////
 //
 // Filename: 	rtclight.v
 //
 // Project:	A Wishbone Controlled Real--time Clock Core
 //
 // Purpose:	Implement a real time clock, including alarm, count--down
 //		timer, stopwatch, variable time frequency, and more.
 //
 //	This is a light-weight version of the RTC found in this directory.
 //	Unlike the full RTC, this version does not support time hacks, seven
 //	segment display outputs, or LED's.  It is an RTC for an internal core
 //	only.  (That's how I was using it on one of my projects anyway ...)
 //
 //
 // Creator:	Dan Gisselquist, Ph.D.
 //		Gisselquist Technology, LLC
 //
 ///////////////////////////////////////////////////////////////////////////
 //
 // Copyright (C) 2015, Gisselquist Technology, LLC
 //
 // This program is free software (firmware): you can redistribute it and/or
 // modify it under the terms of  the GNU General Public License as published
 // by the Free Software Foundation, either version 3 of the License, or (at
 // your option) any later version.
 //
 // This program is distributed in the hope that it will be useful, but WITHOUT
 // ANY WARRANTY; without even the implied warranty of MERCHANTIBILITY or
 // FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
 // for more details.
 //
 // You should have received a copy of the GNU General Public License along
 // with this program.  (It's in the $(ROOT)/doc directory.  Run make with no
 // target there if the PDF file isn't present.)  If not, see
 // <http://www.gnu.org/licenses/> for a copy.
 //
 // License:	GPL, v3, as defined and found on www.gnu.org,
 //		http://www.gnu.org/licenses/gpl.html
 //
 //
 ///////////////////////////////////////////////////////////////////////////
 module	rtclight(i_clk,
 		// Wishbone interface
 		i_wb_cyc, i_wb_stb, i_wb_we, i_wb_addr, i_wb_data,
 		//	o_wb_ack, o_wb_stb, o_wb_data, // no reads here
 		// // Button inputs
 		// i_btn,
 		// Output registers
 		o_data, // multiplexed based upon i_wb_addr
 		// Output controls
 		o_interrupt,
 		// A once-per-day strobe on the last clock of the day
 		o_ppd);
 	parameter	DEFAULT_SPEED = 32'd2814750;	// 100 Mhz
 	input	i_clk;
 	input	i_wb_cyc, i_wb_stb, i_wb_we;
 	input	[2:0]	i_wb_addr;
 	input	[31:0]	i_wb_data;
 	// input		i_btn;
 	output	reg	[31:0]	o_data;
 	output	wire		o_interrupt, o_ppd;

 	reg	[21:0]	clock;
 	reg	[31:0]	stopwatch, ckspeed;
 	reg	[25:0]	timer;

 	wire	ck_sel, tm_sel, sw_sel, sp_sel, al_sel;
 	assign	ck_sel = ((i_wb_cyc)&&(i_wb_stb)&&(i_wb_addr[2:0]==3'b000));
 	assign	tm_sel = ((i_wb_cyc)&&(i_wb_stb)&&(i_wb_addr[2:0]==3'b001));
 	assign	sw_sel = ((i_wb_cyc)&&(i_wb_stb)&&(i_wb_addr[2:0]==3'b010));
 	assign	al_sel = ((i_wb_cyc)&&(i_wb_stb)&&(i_wb_addr[2:0]==3'b011));
 	assign	sp_sel = ((i_wb_cyc)&&(i_wb_stb)&&(i_wb_addr[2:0]==3'b100));

 	reg		ck_carry;
 	reg	[39:0]	ck_counter;
 	initial		ck_carry = 1'b0;
 	initial		ck_counter = 40'h00;
 	always @(posedge i_clk)
 		{ ck_carry, ck_counter } <= ck_counter + { 8'h00, ckspeed };

 	wire		ck_pps;
 	reg		ck_prepps, ck_ppm, ck_pph, ck_ppd;
 	reg	[7:0]	ck_sub;
 	initial	clock = 22'h00000;
 	assign	ck_pps = (ck_carry)&&(ck_prepps);
 	always @(posedge i_clk)
 	begin
 		if (ck_carry)
 			ck_sub <= ck_sub + 8'h1;
 		ck_prepps <= (ck_sub == 8'hff);

 		if (ck_pps)
 		begin // advance the seconds
 			if (clock[3:0] >= 4'h9)
 				clock[3:0] <= 4'h0;
 			else
 				clock[3:0] <= clock[3:0] + 4'h1;
 			if (clock[7:0] >= 8'h59)
 				clock[7:4] <= 4'h0;
 			else if (clock[3:0] >= 4'h9)
 				clock[7:4] <= clock[7:4] + 4'h1;
 		end
 		ck_ppm <= (clock[7:0] == 8'h59);

 		if ((ck_pps)&&(ck_ppm))
 		begin // advance the minutes
 			if (clock[11:8] >= 4'h9)
 				clock[11:8] <= 4'h0;
 			else
 				clock[11:8] <= clock[11:8] + 4'h1;
 			if (clock[15:8] >= 8'h59)
 				clock[15:12] <= 4'h0;
 			else if (clock[11:8] >= 4'h9)
 				clock[15:12] <= clock[15:12] + 4'h1;
 		end
 		ck_pph <= (clock[15:0] == 16'h5959);

 		if ((ck_pps)&&(ck_pph))
 		begin // advance the hours
 			if (clock[21:16] >= 6'h23)
 			begin
 				clock[19:16] <= 4'h0;
 				clock[21:20] <= 2'h0;
 			end else if (clock[19:16] >= 4'h9)
 			begin
 				clock[19:16] <= 4'h0;
 				clock[21:20] <= clock[21:20] + 2'h1;
 			end else begin
 				clock[19:16] <= clock[19:16] + 4'h1;
 			end
 		end
 		ck_ppd <= (clock[21:0] == 22'h235959);


 		if ((ck_sel)&&(i_wb_we))
 		begin
 			if (8'hff != i_wb_data[7:0])
 			begin
 				clock[7:0] <= i_wb_data[7:0];
 				ck_ppm <= (i_wb_data[7:0] == 8'h59);
 			end
 			if (8'hff != i_wb_data[15:8])
 			begin
 				clock[15:8] <= i_wb_data[15:8];
 				ck_pph <= (i_wb_data[15:8] == 8'h59);
 			end
 			if (6'h3f != i_wb_data[21:16])
 				clock[21:16] <= i_wb_data[21:16];
 			if (8'h00 == i_wb_data[7:0])
 				ck_sub <= 8'h00;
 		end
 	end

 	// Clock updates take several clocks, so let's make sure we
 	// are only looking at a valid clock value before testing it.
 	reg	[21:0]		ck_last_clock;
 	always @(posedge i_clk)
 		ck_last_clock <= clock[21:0];


 	reg	tm_pps, tm_ppm, tm_int;
 	wire	tm_stopped, tm_running, tm_alarm;
 	assign	tm_stopped = ~timer[24];
 	assign	tm_running =  timer[24];
 	assign	tm_alarm   =  timer[25];
 	reg	[23:0]		tm_start;
 	reg	[7:0]		tm_sub;
 	initial	tm_start = 24'h00;
 	initial	timer    = 26'h00;
 	initial	tm_int   = 1'b0;
 	initial	tm_pps   = 1'b0;
 	always @(posedge i_clk)
 	begin
 		if (ck_carry)
 		begin
 			tm_sub <= tm_sub + 8'h1;
 			tm_pps <= (tm_sub == 8'hff);
 		end else
 			tm_pps <= 1'b0;

 		if ((~tm_alarm)&&(tm_running)&&(tm_pps))
 		begin // If we are running ...
 			timer[25] <= 1'b0;
 			if (timer[23:0] == 24'h00)
 				timer[25] <= 1'b1;
 			else if (timer[3:0] != 4'h0)
 				timer[3:0] <= timer[3:0]-4'h1;
 			else begin // last digit is a zero
 				timer[3:0] <= 4'h9;
 				if (timer[7:4] != 4'h0)
 					timer[7:4] <= timer[7:4]-4'h1;
 				else begin // last two digits are zero
 					timer[7:4] <= 4'h5;
 					if (timer[11:8] != 4'h0)
 						timer[11:8] <= timer[11:8]-4'h1;
 					else begin // last three digits are zero
 						timer[11:8] <= 4'h9;
 						if (timer[15:12] != 4'h0)
 							timer[15:12] <= timer[15:12]-4'h1;
 						else begin
 							timer[15:12] <= 4'h5;
 							if (timer[19:16] != 4'h0)
 								timer[19:16] <= timer[19:16]-4'h1;
 							else begin
 							//
 								timer[19:16] <= 4'h9;
 								timer[23:20] <= timer[23:20]-4'h1;
 							end
 						end
 					end
 				end
 			end
 		end

 		if((~tm_alarm)&&(tm_running))
 		begin
 			timer[25] <= (timer[23:0] == 24'h00);
 			tm_int <= (timer[23:0] == 24'h00);
 		end else tm_int <= 1'b0;
 		if (tm_alarm)
 			timer[24] <= 1'b0;

 		if ((tm_sel)&&(i_wb_we)&&(tm_running)) // Writes while running
 			// Only allowed to stop the timer, nothing more
 			timer[24] <= i_wb_data[24];
 		else if ((tm_sel)&&(i_wb_we)&&(tm_stopped)) // Writes while off
 		begin
 			timer[24] <= i_wb_data[24];
 			if ((timer[24])||(i_wb_data[24]))
 				timer[25] <= 1'b0;
 			if (i_wb_data[23:0] != 24'h0000)
 			begin
 				timer[23:0] <= i_wb_data[23:0];
 				tm_start <= i_wb_data[23:0];
 				tm_sub <= 8'h00;
 			end else if (timer[23:0] == 24'h00)
 			begin // Resetting timer to last valid timer start val
 				timer[23:0] <= tm_start;
 				tm_sub <= 8'h00;
 			end
 			// Any write clears the alarm
 			timer[25] <= 1'b0;
 		end
 	end

 	//
 	// Stopwatch functionality
 	//
 	// Setting bit '0' starts the stop watch, clearing it stops it.
 	// Writing to the register with bit '1' high will clear the stopwatch,
 	// and return it to zero provided that the stopwatch is stopped either
 	// before or after the write.  Hence, writing a '2' to the device
 	// will always stop and clear it, whereas writing a '3' to the device
 	// will only clear it if it was already stopped.
 	reg		sw_pps, sw_ppm, sw_pph;
 	reg	[7:0]	sw_sub;
 	wire	sw_running;
 	assign	sw_running = stopwatch[0];
 	initial	stopwatch = 32'h00000;
 	always @(posedge i_clk)
 	begin
 		sw_pps <= 1'b0;
 		if (sw_running)
 		begin
 			if (ck_carry)
 			begin
 				sw_sub <= sw_sub + 8'h1;
 				sw_pps <= (sw_sub == 8'hff);
 			end
 		end

 		stopwatch[7:1] <= sw_sub[7:1];

 		if (sw_pps)
 		begin // Second hand
 			if (stopwatch[11:8] >= 4'h9)
 				stopwatch[11:8] <= 4'h0;
 			else
 				stopwatch[11:8] <= stopwatch[11:8] + 4'h1;

 			if (stopwatch[15:8] >= 8'h59)
 				stopwatch[15:12] <= 4'h0;
 			else if (stopwatch[11:8] >= 4'h9)
 				stopwatch[15:12] <= stopwatch[15:12] + 4'h1;
 			sw_ppm <= (stopwatch[15:8] == 8'h59);
 		end else sw_ppm <= 1'b0;

 		if (sw_ppm)
 		begin // Minutes
 			if (stopwatch[19:16] >= 4'h9)
 				stopwatch[19:16] <= 4'h0;
 			else
 				stopwatch[19:16] <= stopwatch[19:16]+4'h1;

 			if (stopwatch[23:16] >= 8'h59)
 				stopwatch[23:20] <= 4'h0;
 			else if (stopwatch[19:16] >= 4'h9)
 				stopwatch[23:20] <= stopwatch[23:20]+4'h1;
 			sw_pph <= (stopwatch[23:16] == 8'h59);
 		end else sw_pph <= 1'b0;

 		if (sw_pph)
 		begin // And hours
 			if (stopwatch[27:24] >= 4'h9)
 				stopwatch[27:24] <= 4'h0;
 			else
 				stopwatch[27:24] <= stopwatch[27:24]+4'h1;

 			if((stopwatch[27:24] >= 4'h9)&&(stopwatch[31:28] < 4'hf))
 				stopwatch[31:28] <= stopwatch[27:24]+4'h1;
 		end

 		if ((sw_sel)&&(i_wb_we))
 		begin
 			stopwatch[0] <= i_wb_data[0];
 			if((i_wb_data[1])&&((~stopwatch[0])||(~i_wb_data[0])))
 			begin
 				stopwatch[31:1] <= 31'h00;
 				sw_sub <= 8'h00;
 				sw_pps <= 1'b0;
 				sw_ppm <= 1'b0;
 				sw_pph <= 1'b0;
 			end
 		end
 	end

 	//
 	// The alarm code
 	//
 	// Set the alarm register to the time you wish the board to "alarm".
 	// The "alarm" will take place once per day at that time.  At that
 	// time, the RTC code will generate a clock interrupt, and the CPU/host
 	// can come and see that the alarm tripped.
 	//
 	//
 	reg	[21:0]		alarm_time;
 	reg			al_int,		// The alarm interrupt line
 				al_enabled,	// Whether the alarm is enabled
 				al_tripped;	// Whether the alarm has tripped
 	initial	al_enabled= 1'b0;
 	initial	al_tripped= 1'b0;
 	always @(posedge i_clk)
 	begin
 		if ((al_sel)&&(i_wb_we))
 		begin
 			// Only adjust the alarm hours if the requested hours
 			// are valid.  This allows writes to the register,
 			// without a prior read, to leave these configuration
 			// bits alone.
 			if (i_wb_data[21:16] != 6'h3f)
 				alarm_time[21:16] <= i_wb_data[21:16];
 			// Here's the same thing for the minutes: only adjust
 			// the alarm minutes if the new bits are not all 1's.
 			if (i_wb_data[15:8] != 8'hff)
 				alarm_time[15:8] <= i_wb_data[15:8];
 			// Here's the same thing for the seconds: only adjust
 			// the alarm minutes if the new bits are not all 1's.
 			if (i_wb_data[7:0] != 8'hff)
 				alarm_time[7:0] <= i_wb_data[7:0];
 			al_enabled <= i_wb_data[24];
 			// Reset the alarm if a '1' is written to the tripped
 			// register, or if the alarm is disabled.
 			if ((i_wb_data[25])||(~i_wb_data[24]))
 				al_tripped <= 1'b0;
 		end

 		al_int <= 1'b0;
 		if ((ck_last_clock != alarm_time)&&(clock[21:0] == alarm_time)
 			&&(al_enabled))
 		begin
 			al_tripped <= 1'b1;
 			al_int <= 1'b1;
 		end
 	end

 	//
 	// The ckspeed register is equal to 2^48 divded by the number of
 	// clock ticks you expect per second.  Adjust high for a slower
 	// clock, lower for a faster clock.  In this fashion, a single
 	// real time clock RTL file can handle tracking the clock in any
 	// device.  Further, because this is only the lower 32 bits of a
 	// 48 bit counter per seconds, the clock jitter is kept below
 	// 1 part in 65 thousand.
 	//
 	initial	ckspeed = DEFAULT_SPEED; // 2af31e = 2^48 / 100e6 MHz
 	// In the case of verilator, comment the above and uncomment the line
 	// below.  The clock constant below is "close" to simulation time,
 	// meaning that my verilator simulation is running about 300x slower
 	// than board time.
 	// initial	ckspeed = 32'd786432000;
 	always @(posedge i_clk)
 		if ((sp_sel)&&(i_wb_we))
 			ckspeed <= i_wb_data;

 	assign	o_interrupt = tm_int || al_int;

 	// A once-per day strobe, on the last second of the day so that the
 	// the next clock is the first clock of the day.  This is useful for
 	// connecting this module to a year/month/date date/calendar module.
 	assign	o_ppd = (ck_ppd)&&(ck_pps);

 	always @(posedge i_clk)
 		case(i_wb_addr[2:0])
 		3'b000: o_data <= { 10'h0, ck_last_clock };
 		3'b001: o_data <= { 6'h00, timer };
 		3'b010: o_data <= stopwatch;
 		3'b011: o_data <= { 6'h00, al_tripped, al_enabled, 2'b00, alarm_time };
 		3'b100: o_data <= ckspeed;
 		default: o_data <= 32'h000;
 		endcase

 endmodule
	///////////////////////////////////////////////////////////////////////////
	//
	// Filename: rtclight.v
	//
	// Project: A Wishbone Controlled Real--time Clock Core
	//
	// Purpose: Implement a real time clock, including alarm, count--down
	// timer, stopwatch, variable time frequency, and more.
	//
	// This is a light-weight version of the RTC found in this directory.
	// Unlike the full RTC, this version does not support time hacks, seven
	// segment display outputs, or LED's. It is an RTC for an internal core
	// only. (That's how I was using it on one of my projects anyway ...)
	//
	//
	// Creator: Dan Gisselquist, Ph.D.
	// Gisselquist Technology, LLC
	//
	///////////////////////////////////////////////////////////////////////////
	//
	// Copyright (C) 2015, Gisselquist Technology, LLC
	//
	// This program is free software (firmware): you can redistribute it and/or
	// modify it under the terms of the GNU General Public License as published
	// by the Free Software Foundation, either version 3 of the License, or (at
	// your option) any later version.
	//
	// This program is distributed in the hope that it will be useful, but WITHOUT
	// ANY WARRANTY; without even the implied warranty of MERCHANTIBILITY or
	// FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
	// for more details.
	//
	// You should have received a copy of the GNU General Public License along
	// with this program. (It's in the $(ROOT)/doc directory. Run make with no
	// target there if the PDF file isn't present.) If not, see
	// <http://www.gnu.org/licenses/> for a copy.
	//
	// License: GPL, v3, as defined and found on www.gnu.org,
	// http://www.gnu.org/licenses/gpl.html
	//
	//
	///////////////////////////////////////////////////////////////////////////
	module rtclight(i_clk,
	// Wishbone interface
	i_wb_cyc, i_wb_stb, i_wb_we, i_wb_addr, i_wb_data,
	// o_wb_ack, o_wb_stb, o_wb_data, // no reads here
	// // Button inputs
	// i_btn,
	// Output registers
	o_data, // multiplexed based upon i_wb_addr
	// Output controls
	o_interrupt,
	// A once-per-day strobe on the last clock of the day
	o_ppd);
	parameter DEFAULT_SPEED = 32'd2814750; // 100 Mhz
	input i_clk;
	input i_wb_cyc, i_wb_stb, i_wb_we;
	input [2:0] i_wb_addr;
	input [31:0] i_wb_data;
	// input i_btn;
	output reg [31:0] o_data;
	output wire o_interrupt, o_ppd;

	reg [21:0] clock;
	reg [31:0] stopwatch, ckspeed;
	reg [25:0] timer;

	wire ck_sel, tm_sel, sw_sel, sp_sel, al_sel;
	assign ck_sel = ((i_wb_cyc)&&(i_wb_stb)&&(i_wb_addr[2:0]==3'b000));
	assign tm_sel = ((i_wb_cyc)&&(i_wb_stb)&&(i_wb_addr[2:0]==3'b001));
	assign sw_sel = ((i_wb_cyc)&&(i_wb_stb)&&(i_wb_addr[2:0]==3'b010));
	assign al_sel = ((i_wb_cyc)&&(i_wb_stb)&&(i_wb_addr[2:0]==3'b011));
	assign sp_sel = ((i_wb_cyc)&&(i_wb_stb)&&(i_wb_addr[2:0]==3'b100));

	reg ck_carry;
	reg [39:0] ck_counter;
	initial ck_carry = 1'b0;
	initial ck_counter = 40'h00;
	always @(posedge i_clk)
	{ ck_carry, ck_counter } <= ck_counter + { 8'h00, ckspeed };

	wire ck_pps;
	reg ck_prepps, ck_ppm, ck_pph, ck_ppd;
	reg [7:0] ck_sub;
	initial clock = 22'h00000;
	assign ck_pps = (ck_carry)&&(ck_prepps);
	always @(posedge i_clk)
	begin
	if (ck_carry)
	ck_sub <= ck_sub + 8'h1;
	ck_prepps <= (ck_sub == 8'hff);

	if (ck_pps)
	begin // advance the seconds
	if (clock[3:0] >= 4'h9)
	clock[3:0] <= 4'h0;
	else
	clock[3:0] <= clock[3:0] + 4'h1;
	if (clock[7:0] >= 8'h59)
	clock[7:4] <= 4'h0;
	else if (clock[3:0] >= 4'h9)
	clock[7:4] <= clock[7:4] + 4'h1;
	end
	ck_ppm <= (clock[7:0] == 8'h59);

	if ((ck_pps)&&(ck_ppm))
	begin // advance the minutes
	if (clock[11:8] >= 4'h9)
	clock[11:8] <= 4'h0;
	else
	clock[11:8] <= clock[11:8] + 4'h1;
	if (clock[15:8] >= 8'h59)
	clock[15:12] <= 4'h0;
	else if (clock[11:8] >= 4'h9)
	clock[15:12] <= clock[15:12] + 4'h1;
	end
	ck_pph <= (clock[15:0] == 16'h5959);

	if ((ck_pps)&&(ck_pph))
	begin // advance the hours
	if (clock[21:16] >= 6'h23)
	begin
	clock[19:16] <= 4'h0;
	clock[21:20] <= 2'h0;
	end else if (clock[19:16] >= 4'h9)
	begin
	clock[19:16] <= 4'h0;
	clock[21:20] <= clock[21:20] + 2'h1;
	end else begin
	clock[19:16] <= clock[19:16] + 4'h1;
	end
	end
	ck_ppd <= (clock[21:0] == 22'h235959);


	if ((ck_sel)&&(i_wb_we))
	begin
	if (8'hff != i_wb_data[7:0])
	begin
	clock[7:0] <= i_wb_data[7:0];
	ck_ppm <= (i_wb_data[7:0] == 8'h59);
	end
	if (8'hff != i_wb_data[15:8])
	begin
	clock[15:8] <= i_wb_data[15:8];
	ck_pph <= (i_wb_data[15:8] == 8'h59);
	end
	if (6'h3f != i_wb_data[21:16])
	clock[21:16] <= i_wb_data[21:16];
	if (8'h00 == i_wb_data[7:0])
	ck_sub <= 8'h00;
	end
	end

	// Clock updates take several clocks, so let's make sure we
	// are only looking at a valid clock value before testing it.
	reg [21:0] ck_last_clock;
	always @(posedge i_clk)
	ck_last_clock <= clock[21:0];


	reg tm_pps, tm_ppm, tm_int;
	wire tm_stopped, tm_running, tm_alarm;
	assign tm_stopped = ~timer[24];
	assign tm_running = timer[24];
	assign tm_alarm = timer[25];
	reg [23:0] tm_start;
	reg [7:0] tm_sub;
	initial tm_start = 24'h00;
	initial timer = 26'h00;
	initial tm_int = 1'b0;
	initial tm_pps = 1'b0;
	always @(posedge i_clk)
	begin
	if (ck_carry)
	begin
	tm_sub <= tm_sub + 8'h1;
	tm_pps <= (tm_sub == 8'hff);
	end else
	tm_pps <= 1'b0;

	if ((~tm_alarm)&&(tm_running)&&(tm_pps))
	begin // If we are running ...
	timer[25] <= 1'b0;
	if (timer[23:0] == 24'h00)
	timer[25] <= 1'b1;
	else if (timer[3:0] != 4'h0)
	timer[3:0] <= timer[3:0]-4'h1;
	else begin // last digit is a zero
	timer[3:0] <= 4'h9;
	if (timer[7:4] != 4'h0)
	timer[7:4] <= timer[7:4]-4'h1;
	else begin // last two digits are zero
	timer[7:4] <= 4'h5;
	if (timer[11:8] != 4'h0)
	timer[11:8] <= timer[11:8]-4'h1;
	else begin // last three digits are zero
	timer[11:8] <= 4'h9;
	if (timer[15:12] != 4'h0)
	timer[15:12] <= timer[15:12]-4'h1;
	else begin
	timer[15:12] <= 4'h5;
	if (timer[19:16] != 4'h0)
	timer[19:16] <= timer[19:16]-4'h1;
	else begin
	//
	timer[19:16] <= 4'h9;
	timer[23:20] <= timer[23:20]-4'h1;
	end
	end
	end
	end
	end
	end

	if((~tm_alarm)&&(tm_running))
	begin
	timer[25] <= (timer[23:0] == 24'h00);
	tm_int <= (timer[23:0] == 24'h00);
	end else tm_int <= 1'b0;
	if (tm_alarm)
	timer[24] <= 1'b0;

	if ((tm_sel)&&(i_wb_we)&&(tm_running)) // Writes while running
	// Only allowed to stop the timer, nothing more
	timer[24] <= i_wb_data[24];
	else if ((tm_sel)&&(i_wb_we)&&(tm_stopped)) // Writes while off
	begin
	timer[24] <= i_wb_data[24];
	if ((timer[24])\|\|(i_wb_data[24]))
	timer[25] <= 1'b0;
	if (i_wb_data[23:0] != 24'h0000)
	begin
	timer[23:0] <= i_wb_data[23:0];
	tm_start <= i_wb_data[23:0];
	tm_sub <= 8'h00;
	end else if (timer[23:0] == 24'h00)
	begin // Resetting timer to last valid timer start val
	timer[23:0] <= tm_start;
	tm_sub <= 8'h00;
	end
	// Any write clears the alarm
	timer[25] <= 1'b0;
	end
	end

	//
	// Stopwatch functionality
	//
	// Setting bit '0' starts the stop watch, clearing it stops it.
	// Writing to the register with bit '1' high will clear the stopwatch,
	// and return it to zero provided that the stopwatch is stopped either
	// before or after the write. Hence, writing a '2' to the device
	// will always stop and clear it, whereas writing a '3' to the device
	// will only clear it if it was already stopped.
	reg sw_pps, sw_ppm, sw_pph;
	reg [7:0] sw_sub;
	wire sw_running;
	assign sw_running = stopwatch[0];
	initial stopwatch = 32'h00000;
	always @(posedge i_clk)
	begin
	sw_pps <= 1'b0;
	if (sw_running)
	begin
	if (ck_carry)
	begin
	sw_sub <= sw_sub + 8'h1;
	sw_pps <= (sw_sub == 8'hff);
	end
	end

	stopwatch[7:1] <= sw_sub[7:1];

	if (sw_pps)
	begin // Second hand
	if (stopwatch[11:8] >= 4'h9)
	stopwatch[11:8] <= 4'h0;
	else
	stopwatch[11:8] <= stopwatch[11:8] + 4'h1;

	if (stopwatch[15:8] >= 8'h59)
	stopwatch[15:12] <= 4'h0;
	else if (stopwatch[11:8] >= 4'h9)
	stopwatch[15:12] <= stopwatch[15:12] + 4'h1;
	sw_ppm <= (stopwatch[15:8] == 8'h59);
	end else sw_ppm <= 1'b0;

	if (sw_ppm)
	begin // Minutes
	if (stopwatch[19:16] >= 4'h9)
	stopwatch[19:16] <= 4'h0;
	else
	stopwatch[19:16] <= stopwatch[19:16]+4'h1;

	if (stopwatch[23:16] >= 8'h59)
	stopwatch[23:20] <= 4'h0;
	else if (stopwatch[19:16] >= 4'h9)
	stopwatch[23:20] <= stopwatch[23:20]+4'h1;
	sw_pph <= (stopwatch[23:16] == 8'h59);
	end else sw_pph <= 1'b0;

	if (sw_pph)
	begin // And hours
	if (stopwatch[27:24] >= 4'h9)
	stopwatch[27:24] <= 4'h0;
	else
	stopwatch[27:24] <= stopwatch[27:24]+4'h1;

	if((stopwatch[27:24] >= 4'h9)&&(stopwatch[31:28] < 4'hf))
	stopwatch[31:28] <= stopwatch[27:24]+4'h1;
	end

	if ((sw_sel)&&(i_wb_we))
	begin
	stopwatch[0] <= i_wb_data[0];
	if((i_wb_data[1])&&((~stopwatch[0])\|\|(~i_wb_data[0])))
	begin
	stopwatch[31:1] <= 31'h00;
	sw_sub <= 8'h00;
	sw_pps <= 1'b0;
	sw_ppm <= 1'b0;
	sw_pph <= 1'b0;
	end
	end
	end

	//
	// The alarm code
	//
	// Set the alarm register to the time you wish the board to "alarm".
	// The "alarm" will take place once per day at that time. At that
	// time, the RTC code will generate a clock interrupt, and the CPU/host
	// can come and see that the alarm tripped.
	//
	//
	reg [21:0] alarm_time;
	reg al_int, // The alarm interrupt line
	al_enabled, // Whether the alarm is enabled
	al_tripped; // Whether the alarm has tripped
	initial al_enabled= 1'b0;
	initial al_tripped= 1'b0;
	always @(posedge i_clk)
	begin
	if ((al_sel)&&(i_wb_we))
	begin
	// Only adjust the alarm hours if the requested hours
	// are valid. This allows writes to the register,
	// without a prior read, to leave these configuration
	// bits alone.
	if (i_wb_data[21:16] != 6'h3f)
	alarm_time[21:16] <= i_wb_data[21:16];
	// Here's the same thing for the minutes: only adjust
	// the alarm minutes if the new bits are not all 1's.
	if (i_wb_data[15:8] != 8'hff)
	alarm_time[15:8] <= i_wb_data[15:8];
	// Here's the same thing for the seconds: only adjust
	// the alarm minutes if the new bits are not all 1's.
	if (i_wb_data[7:0] != 8'hff)
	alarm_time[7:0] <= i_wb_data[7:0];
	al_enabled <= i_wb_data[24];
	// Reset the alarm if a '1' is written to the tripped
	// register, or if the alarm is disabled.
	if ((i_wb_data[25])\|\|(~i_wb_data[24]))
	al_tripped <= 1'b0;
	end

	al_int <= 1'b0;
	if ((ck_last_clock != alarm_time)&&(clock[21:0] == alarm_time)
	&&(al_enabled))
	begin
	al_tripped <= 1'b1;
	al_int <= 1'b1;
	end
	end

	//
	// The ckspeed register is equal to 2^48 divded by the number of
	// clock ticks you expect per second. Adjust high for a slower
	// clock, lower for a faster clock. In this fashion, a single
	// real time clock RTL file can handle tracking the clock in any
	// device. Further, because this is only the lower 32 bits of a
	// 48 bit counter per seconds, the clock jitter is kept below
	// 1 part in 65 thousand.
	//
	initial ckspeed = DEFAULT_SPEED; // 2af31e = 2^48 / 100e6 MHz
	// In the case of verilator, comment the above and uncomment the line
	// below. The clock constant below is "close" to simulation time,
	// meaning that my verilator simulation is running about 300x slower
	// than board time.
	// initial ckspeed = 32'd786432000;
	always @(posedge i_clk)
	if ((sp_sel)&&(i_wb_we))
	ckspeed <= i_wb_data;

	assign o_interrupt = tm_int \|\| al_int;

	// A once-per day strobe, on the last second of the day so that the
	// the next clock is the first clock of the day. This is useful for
	// connecting this module to a year/month/date date/calendar module.
	assign o_ppd = (ck_ppd)&&(ck_pps);

	always @(posedge i_clk)
	case(i_wb_addr[2:0])
	3'b000: o_data <= { 10'h0, ck_last_clock };
	3'b001: o_data <= { 6'h00, timer };
	3'b010: o_data <= stopwatch;
	3'b011: o_data <= { 6'h00, al_tripped, al_enabled, 2'b00, alarm_time };
	3'b100: o_data <= ckspeed;
	default: o_data <= 32'h000;
	endcase

	endmodule