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

 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //      http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // 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.
 // SPDX-License-Identifier: Apache-2.0

 `default_nettype none
 /*
  *-------------------------------------------------------------
  *
  * user_proj_example
  *
  * This is an example of a (trivially simple) user project,
  * showing how the user project can connect to the logic
  * analyzer, the wishbone bus, and the I/O pads.
  *
  * This project generates an integer count, which is output
  * on the user area GPIO pads (digital output only).  The
  * wishbone connection allows the project to be controlled
  * (start and stop) from the management SoC program.
  *
  * See the testbenches in directory "mprj_counter" for the
  * example programs that drive this user project.  The three
  * testbenches are "io_ports", "la_test1", and "la_test2".
  *
  *-------------------------------------------------------------
  */

 module user_proj_example #(
     parameter BITS = 32
 )(
 `ifdef USE_POWER_PINS
     inout vdda1,	// User area 1 3.3V supply
     inout vdda2,	// User area 2 3.3V supply
     inout vssa1,	// User area 1 analog ground
     inout vssa2,	// User area 2 analog ground
     inout vccd1,	// User area 1 1.8V supply
     inout vccd2,	// User area 2 1.8v supply
     inout vssd1,	// User area 1 digital ground
     inout vssd2,	// User area 2 digital ground
 `endif

     // Wishbone Slave ports (WB MI A)
     input wb_clk_i,
     input wb_rst_i,
     input wbs_stb_i,
     input wbs_cyc_i,
     input wbs_we_i,
     input [3:0] wbs_sel_i,
     input [31:0] wbs_dat_i,
     input [31:0] wbs_adr_i,
     output reg wbs_ack_o,
     output reg [31:0] wbs_dat_o,

     // Logic Analyzer Signals
     input  [127:0] la_data_in,
     output [127:0] la_data_out,
     input  [127:0] la_oenb,

     // IOs
     input  [`MPRJ_IO_PADS-1:0] io_in,
     output [`MPRJ_IO_PADS-1:0] io_out,
     output [`MPRJ_IO_PADS-1:0] io_oeb,

     // IRQ
     output [2:0] irq
 );
     wire clk;
     wire rst;

     wire [`MPRJ_IO_PADS-1:0] io_in;
     wire [`MPRJ_IO_PADS-1:0] io_out;
     wire [`MPRJ_IO_PADS-1:0] io_oeb;

     wire [31:0] rdata;
     wire [31:0] wdata;
     wire [BITS-1:0] count;

     wire valid;
     wire [3:0] wstrb;
     wire [31:0] la_write;

     wire pwm1_select , pwm2_select , i2c_select , rtc_select , pid_select ;
     wire pwm1_wbs_stb_i , pwm2_wbs_stb_i , i2c_wbs_stb_i , rtc_wbs_stb_i , pid_wbs_stb_i ;
     wire pwm1_wbs_ack_o , pwm2_wbs_ack_o , i2c_wbs_ack_o , rtc_wbs_ack_o , pid_wbs_ack_o ;

     reg [15:0] pwm1_wbs_dat_o ;
     reg [15:0] pwm2_wbs_dat_o ;
     reg [7:0] i2c_wbs_dat_o ;
     reg [31:0] rtc_wbs_dat_o ;
     reg [31:0] pid_wbs_dat_o  ;

     wire pwm_out1 , pwm_out2 ;
     wire pwm_out1_oen , pwm_out2_oen ;
     wire ptc1_intr , ptc2_intr , i2c_intr , rtc_intr ;
     reg led1, led2, led3 ;
     wire ptc_clk1,ptc_clk2;
     wire capt_in1,capt_in1;


     assign ptc_clk1 = io_in[0] ;                           // IO[0]
     assign io_oeb[0]= 1'b1;

     assign ptc_clk2 = io_in[1] ;                           // IO[1]
     assign io_oeb[1]= 1'b1;

     assign capt_in1 = io_in[2] ;                           // IO[2]
     assign io_oeb[1]= 1'b1;

     assign capt_in2 = io_in[3] ;                           // IO[3]
     assign io_oeb[1]= 1'b1;


     assign io_out[5:4] = la_data_in[1:0] ;                 // IO[5:4]
     assign io_oeb[5:4] = la_oenb[1:0]    ;

     assign io_out[7:6] = {pwm_out2,pwm_out1} ;             // IO[7:6]
     assign io_oeb[7:6] = {pwm_out2_oen,pwm_out1_oen} ;

     assign io_out[8] = scl_pad_o ;                         // IO[8]
     assign io_oeb[8] = scl_padoen_o ;

     assign i2c_scl_in = io_in[9] ;                         // IO[9]
     assign io_oeb[9]= 1'b1;

     assign io_out[10] = sda_pad_o ;                        // IO[10]
     assign io_oeb[10] = sda_padoen_o;

     assign i2c_sda_in = io_in[11] ;                        // IO[11]
     assign io_oeb[11]= 1'b1;

     // Inputs

     // IRQ
     assign irq = {rtc_intr , i2c_intr , {ptc2_intr || ptc1_intr} };

     // LA
    assign la_data_out = 128'b0;
    assign clk = wb_clk_i ;
    assign rst = wb_rst_i ;

    // Module Address Select Logic
    assign pwm1_select = (wbs_adr_i[31:12] == 20'h30001) ;
    assign pwm2_select = (wbs_adr_i[31:12] == 20'h30002) ;
    assign i2c_select  = (wbs_adr_i[31:12] == 20'h30003) ;
    assign rtc_select  = (wbs_adr_i[31:12] == 20'h30004) ;
    assign pid_select  = (wbs_adr_i[31:12] == 20'h30005) ;

    // Module STROBE Select based on Address Range
    assign pwm1_wbs_stb_i = (wbs_stb_i && pwm1_select) ;
    assign pwm2_wbs_stb_i = (wbs_stb_i && pwm2_select) ;
    assign i2c_wbs_stb_i  = (wbs_stb_i && i2c_select)  ;
    assign rtc_wbs_stb_i  = (wbs_stb_i && rtc_select)  ;
    assign pid_wbs_stb_i  = (wbs_stb_i && pid_select)  ;


    // Slave Acknowledge Response
    always @(posedge clk)
 	   wbs_ack_o <= (pwm1_wbs_ack_o || pwm2_wbs_ack_o || i2c_wbs_ack_o || rtc_wbs_ack_o || pid_wbs_ack_o) ;

    // Slave Return Data
    always @(posedge clk)
 	   if (pwm1_wbs_ack_o)
 		   wbs_dat_o <= pwm1_wbs_dat_o ;
 	   else if (pwm2_wbs_ack_o)
 		   wbs_dat_o <= pwm2_wbs_dat_o ;
 	   else if (i2c_wbs_ack_o)
 		   wbs_dat_o <= {24'b0,i2c_wbs_dat_o} ;
 	   else if (rtc_wbs_ack_o)
 		   wbs_dat_o <= rtc_wbs_dat_o ;
 	   else if (pid_wbs_ack_o)
 		   wbs_dat_o <= pid_wbs_dat_o ;
 	   else
 		   wbs_dat_o <= 32'h0 ;


    // PTC1 Module instantiations
    ptc_top ptc1_i (
 	   .wb_clk_i (clk),
 	   .wb_rst_i (rst),
 	   .wb_cyc_i (wbs_cyc_i),
 	   .wb_adr_i ({8'h0,wbs_adr_i[7:0]}), // 16-bit address
 	   .wb_dat_i (wbs_dat_i),
 	   .wb_sel_i (wbs_sel_i),
 	   .wb_we_i  (wbs_we_i),
 	   .wb_stb_i (pwm1_wbs_stb_i),
 	   .wb_dat_o (pwm1_wbs_dat_o),
 	   .wb_ack_o (pwm1_wbs_ack_o),
 	   .wb_err_o ( ),
 	   .wb_inta_o (ptc1_intr),
 	   .gate_clk_pad_i (ptc_clk1),
 	   .capt_pad_i (capt_in1),
 	   .pwm_pad_o (pwm_out1),
 	   .oen_padoen_o (pwm_out1_oen)
    );

    // PTC2 Module instantiations

  ptc_top ptc2_i (
 	   .wb_clk_i (clk),
 	   .wb_rst_i (rst),
 	   .wb_cyc_i (wbs_cyc_i),
 	   .wb_adr_i ({8'h0,wbs_adr_i[7:0]}), // 16-bit address
 	   .wb_dat_i (wbs_dat_i),
 	   .wb_sel_i (wbs_sel_i),
 	   .wb_we_i  (wbs_we_i),
 	   .wb_stb_i (pwm2_wbs_stb_i),
 	   .wb_dat_o (pwm2_wbs_dat_o),
 	   .wb_ack_o (pwm2_wbs_ack_o),
 	   .wb_err_o ( ),
 	   .wb_inta_o (ptc1_intr),
 	   .gate_clk_pad_i (ptc_clk2),
 	   .capt_pad_i (capt_in2),
 	   .pwm_pad_o (pwm_out2),
 	   .oen_padoen_o (pwm_out2_oen)
    );

    // I2C Module Instanciation
  i2c_master_top i2c_i (
 	   .wb_clk_i (clk),
 	   .wb_rst_i (rst),
 	   .arst_i   (1'b1),
 	   .wb_adr_i (wbs_adr_i[2:0]), // 3-bit address
 	   .wb_dat_i (wbs_dat_i[7:0]), // 8-bit data
 	   .wb_dat_o (i2c_wbs_dat_o),  // 8-bit data
 	   .wb_we_i  (wbs_we_i),
 	   .wb_stb_i (rtc_wbs_stb_i),
 	   .wb_cyc_i (wbs_cyc_i),
 	   .wb_ack_o (i2c_wbs_ack_o),
 	   .wb_inta_o (i2c_intr),
 	   .scl_pad_i (i2c_scl_in),
 	   .scl_pad_o (scl_pad_o),
 	   .scl_padoen_o (scl_padoen_o),
 	   .sda_pad_i (i2c_sda_in),
 	   .sda_pad_o (sda_pad_o),
 	   .sda_padoen_o (sda_padoen_o)
    );

    // RTC Module Instanciation

   rtcclock rtc_i (
 	  .i_clk (clk),
 	  .i_wb_cyc (wbs_cyc_i),
 	  .i_wb_stb (rtc_wbs_stb_i),
 	  .i_wb_we (wbs_we_i),
 	  .i_wb_addr (wbs_adr_i[2:0]),
 	  .i_wb_data (wbs_dat_i),
 	  .o_data (rtc_wbs_dat_o),
 	  .o_sseg (),
 	  .o_led (),
 	  .o_interrupt (rtc_intr),
 	  .o_ppd (),
 	  .i_hack (la_data_in[2])
   );

    // PID Module Instantiation
   PID pid (
 	  .i_clk (clk),
 	  .i_rst (rst),
 	  .i_wb_cyc (wbs_cyc_i),
 	  .i_wb_stb (pid_wbs_stb_i),
 	  .i_wb_we (wbs_we_i),
 	  .i_wb_adr ({8'h0,wbs_adr_i[7:0]}), // 16-bit address
 	  .i_wb_data (wbs_dat_i),
 	  .o_wb_ack (pid_wbs_ack_o),
 	  .o_wb_data (pid_wbs_dat_o),
 	  .o_un (),
 	  .o_valid ()
   );

 endmodule
 `default_nettype wire
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// 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.
	// SPDX-License-Identifier: Apache-2.0

	`default_nettype none
	/*
	*-------------------------------------------------------------
	*
	* user_proj_example
	*
	* This is an example of a (trivially simple) user project,
	* showing how the user project can connect to the logic
	* analyzer, the wishbone bus, and the I/O pads.
	*
	* This project generates an integer count, which is output
	* on the user area GPIO pads (digital output only). The
	* wishbone connection allows the project to be controlled
	* (start and stop) from the management SoC program.
	*
	* See the testbenches in directory "mprj_counter" for the
	* example programs that drive this user project. The three
	* testbenches are "io_ports", "la_test1", and "la_test2".
	*
	*-------------------------------------------------------------
	*/

	module user_proj_example #(
	parameter BITS = 32
	)(
	`ifdef USE_POWER_PINS
	inout vdda1, // User area 1 3.3V supply
	inout vdda2, // User area 2 3.3V supply
	inout vssa1, // User area 1 analog ground
	inout vssa2, // User area 2 analog ground
	inout vccd1, // User area 1 1.8V supply
	inout vccd2, // User area 2 1.8v supply
	inout vssd1, // User area 1 digital ground
	inout vssd2, // User area 2 digital ground
	`endif

	// Wishbone Slave ports (WB MI A)
	input wb_clk_i,
	input wb_rst_i,
	input wbs_stb_i,
	input wbs_cyc_i,
	input wbs_we_i,
	input [3:0] wbs_sel_i,
	input [31:0] wbs_dat_i,
	input [31:0] wbs_adr_i,
	output reg wbs_ack_o,
	output reg [31:0] wbs_dat_o,

	// Logic Analyzer Signals
	input [127:0] la_data_in,
	output [127:0] la_data_out,
	input [127:0] la_oenb,

	// IOs
	input [`MPRJ_IO_PADS-1:0] io_in,
	output [`MPRJ_IO_PADS-1:0] io_out,
	output [`MPRJ_IO_PADS-1:0] io_oeb,

	// IRQ
	output [2:0] irq
	);
	wire clk;
	wire rst;

	wire [`MPRJ_IO_PADS-1:0] io_in;
	wire [`MPRJ_IO_PADS-1:0] io_out;
	wire [`MPRJ_IO_PADS-1:0] io_oeb;

	wire [31:0] rdata;
	wire [31:0] wdata;
	wire [BITS-1:0] count;

	wire valid;
	wire [3:0] wstrb;
	wire [31:0] la_write;

	wire pwm1_select , pwm2_select , i2c_select , rtc_select , pid_select ;
	wire pwm1_wbs_stb_i , pwm2_wbs_stb_i , i2c_wbs_stb_i , rtc_wbs_stb_i , pid_wbs_stb_i ;
	wire pwm1_wbs_ack_o , pwm2_wbs_ack_o , i2c_wbs_ack_o , rtc_wbs_ack_o , pid_wbs_ack_o ;

	reg [15:0] pwm1_wbs_dat_o ;
	reg [15:0] pwm2_wbs_dat_o ;
	reg [7:0] i2c_wbs_dat_o ;
	reg [31:0] rtc_wbs_dat_o ;
	reg [31:0] pid_wbs_dat_o ;

	wire pwm_out1 , pwm_out2 ;
	wire pwm_out1_oen , pwm_out2_oen ;
	wire ptc1_intr , ptc2_intr , i2c_intr , rtc_intr ;
	reg led1, led2, led3 ;
	wire ptc_clk1,ptc_clk2;
	wire capt_in1,capt_in1;


	assign ptc_clk1 = io_in[0] ; // IO[0]
	assign io_oeb[0]= 1'b1;

	assign ptc_clk2 = io_in[1] ; // IO[1]
	assign io_oeb[1]= 1'b1;

	assign capt_in1 = io_in[2] ; // IO[2]
	assign io_oeb[1]= 1'b1;

	assign capt_in2 = io_in[3] ; // IO[3]
	assign io_oeb[1]= 1'b1;


	assign io_out[5:4] = la_data_in[1:0] ; // IO[5:4]
	assign io_oeb[5:4] = la_oenb[1:0] ;

	assign io_out[7:6] = {pwm_out2,pwm_out1} ; // IO[7:6]
	assign io_oeb[7:6] = {pwm_out2_oen,pwm_out1_oen} ;

	assign io_out[8] = scl_pad_o ; // IO[8]
	assign io_oeb[8] = scl_padoen_o ;

	assign i2c_scl_in = io_in[9] ; // IO[9]
	assign io_oeb[9]= 1'b1;

	assign io_out[10] = sda_pad_o ; // IO[10]
	assign io_oeb[10] = sda_padoen_o;

	assign i2c_sda_in = io_in[11] ; // IO[11]
	assign io_oeb[11]= 1'b1;

	// Inputs

	// IRQ
	assign irq = {rtc_intr , i2c_intr , {ptc2_intr \|\| ptc1_intr} };

	// LA
	assign la_data_out = 128'b0;
	assign clk = wb_clk_i ;
	assign rst = wb_rst_i ;

	// Module Address Select Logic
	assign pwm1_select = (wbs_adr_i[31:12] == 20'h30001) ;
	assign pwm2_select = (wbs_adr_i[31:12] == 20'h30002) ;
	assign i2c_select = (wbs_adr_i[31:12] == 20'h30003) ;
	assign rtc_select = (wbs_adr_i[31:12] == 20'h30004) ;
	assign pid_select = (wbs_adr_i[31:12] == 20'h30005) ;

	// Module STROBE Select based on Address Range
	assign pwm1_wbs_stb_i = (wbs_stb_i && pwm1_select) ;
	assign pwm2_wbs_stb_i = (wbs_stb_i && pwm2_select) ;
	assign i2c_wbs_stb_i = (wbs_stb_i && i2c_select) ;
	assign rtc_wbs_stb_i = (wbs_stb_i && rtc_select) ;
	assign pid_wbs_stb_i = (wbs_stb_i && pid_select) ;


	// Slave Acknowledge Response
	always @(posedge clk)
	wbs_ack_o <= (pwm1_wbs_ack_o \|\| pwm2_wbs_ack_o \|\| i2c_wbs_ack_o \|\| rtc_wbs_ack_o \|\| pid_wbs_ack_o) ;

	// Slave Return Data
	always @(posedge clk)
	if (pwm1_wbs_ack_o)
	wbs_dat_o <= pwm1_wbs_dat_o ;
	else if (pwm2_wbs_ack_o)
	wbs_dat_o <= pwm2_wbs_dat_o ;
	else if (i2c_wbs_ack_o)
	wbs_dat_o <= {24'b0,i2c_wbs_dat_o} ;
	else if (rtc_wbs_ack_o)
	wbs_dat_o <= rtc_wbs_dat_o ;
	else if (pid_wbs_ack_o)
	wbs_dat_o <= pid_wbs_dat_o ;
	else
	wbs_dat_o <= 32'h0 ;



	// PTC1 Module instantiations
	ptc_top ptc1_i (
	.wb_clk_i (clk),
	.wb_rst_i (rst),
	.wb_cyc_i (wbs_cyc_i),
	.wb_adr_i ({8'h0,wbs_adr_i[7:0]}), // 16-bit address
	.wb_dat_i (wbs_dat_i),
	.wb_sel_i (wbs_sel_i),
	.wb_we_i (wbs_we_i),
	.wb_stb_i (pwm1_wbs_stb_i),
	.wb_dat_o (pwm1_wbs_dat_o),
	.wb_ack_o (pwm1_wbs_ack_o),
	.wb_err_o ( ),
	.wb_inta_o (ptc1_intr),
	.gate_clk_pad_i (ptc_clk1),
	.capt_pad_i (capt_in1),
	.pwm_pad_o (pwm_out1),
	.oen_padoen_o (pwm_out1_oen)
	);

	// PTC2 Module instantiations

	ptc_top ptc2_i (
	.wb_clk_i (clk),
	.wb_rst_i (rst),
	.wb_cyc_i (wbs_cyc_i),
	.wb_adr_i ({8'h0,wbs_adr_i[7:0]}), // 16-bit address
	.wb_dat_i (wbs_dat_i),
	.wb_sel_i (wbs_sel_i),
	.wb_we_i (wbs_we_i),
	.wb_stb_i (pwm2_wbs_stb_i),
	.wb_dat_o (pwm2_wbs_dat_o),
	.wb_ack_o (pwm2_wbs_ack_o),
	.wb_err_o ( ),
	.wb_inta_o (ptc1_intr),
	.gate_clk_pad_i (ptc_clk2),
	.capt_pad_i (capt_in2),
	.pwm_pad_o (pwm_out2),
	.oen_padoen_o (pwm_out2_oen)
	);

	// I2C Module Instanciation
	i2c_master_top i2c_i (
	.wb_clk_i (clk),
	.wb_rst_i (rst),
	.arst_i (1'b1),
	.wb_adr_i (wbs_adr_i[2:0]), // 3-bit address
	.wb_dat_i (wbs_dat_i[7:0]), // 8-bit data
	.wb_dat_o (i2c_wbs_dat_o), // 8-bit data
	.wb_we_i (wbs_we_i),
	.wb_stb_i (rtc_wbs_stb_i),
	.wb_cyc_i (wbs_cyc_i),
	.wb_ack_o (i2c_wbs_ack_o),
	.wb_inta_o (i2c_intr),
	.scl_pad_i (i2c_scl_in),
	.scl_pad_o (scl_pad_o),
	.scl_padoen_o (scl_padoen_o),
	.sda_pad_i (i2c_sda_in),
	.sda_pad_o (sda_pad_o),
	.sda_padoen_o (sda_padoen_o)
	);

	// RTC Module Instanciation

	rtcclock rtc_i (
	.i_clk (clk),
	.i_wb_cyc (wbs_cyc_i),
	.i_wb_stb (rtc_wbs_stb_i),
	.i_wb_we (wbs_we_i),
	.i_wb_addr (wbs_adr_i[2:0]),
	.i_wb_data (wbs_dat_i),
	.o_data (rtc_wbs_dat_o),
	.o_sseg (),
	.o_led (),
	.o_interrupt (rtc_intr),
	.o_ppd (),
	.i_hack (la_data_in[2])
	);

	// PID Module Instantiation
	PID pid (
	.i_clk (clk),
	.i_rst (rst),
	.i_wb_cyc (wbs_cyc_i),
	.i_wb_stb (pid_wbs_stb_i),
	.i_wb_we (wbs_we_i),
	.i_wb_adr ({8'h0,wbs_adr_i[7:0]}), // 16-bit address
	.i_wb_data (wbs_dat_i),
	.o_wb_ack (pid_wbs_ack_o),
	.o_wb_data (pid_wbs_dat_o),
	.o_un (),
	.o_valid ()
	);

	endmodule
	`default_nettype wire