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[/] [openmsp430/] [trunk/] [fpga/] [xilinx_diligent_s3board/] [rtl/] [verilog/] [openmsp430/] [periph/] [omsp_gpio.v] - Rev 204
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//---------------------------------------------------------------------------- // Copyright (C) 2009 , Olivier Girard // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions // are met: // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above copyright // notice, this list of conditions and the following disclaimer in the // documentation and/or other materials provided with the distribution. // * Neither the name of the authors nor the names of its contributors // may be used to endorse or promote products derived from this software // without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" // AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE // IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE // ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE // LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, // OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF // SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS // INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN // CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) // ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF // THE POSSIBILITY OF SUCH DAMAGE // //---------------------------------------------------------------------------- // // *File Name: omsp_gpio.v // // *Module Description: // Digital I/O interface // // *Author(s): // - Olivier Girard, olgirard@gmail.com // //---------------------------------------------------------------------------- // $Rev: 136 $ // $LastChangedBy: olivier.girard $ // $LastChangedDate: 2012-03-22 22:14:16 +0100 (Thu, 22 Mar 2012) $ //---------------------------------------------------------------------------- module omsp_gpio ( // OUTPUTs irq_port1, // Port 1 interrupt irq_port2, // Port 2 interrupt p1_dout, // Port 1 data output p1_dout_en, // Port 1 data output enable p1_sel, // Port 1 function select p2_dout, // Port 2 data output p2_dout_en, // Port 2 data output enable p2_sel, // Port 2 function select p3_dout, // Port 3 data output p3_dout_en, // Port 3 data output enable p3_sel, // Port 3 function select p4_dout, // Port 4 data output p4_dout_en, // Port 4 data output enable p4_sel, // Port 4 function select p5_dout, // Port 5 data output p5_dout_en, // Port 5 data output enable p5_sel, // Port 5 function select p6_dout, // Port 6 data output p6_dout_en, // Port 6 data output enable p6_sel, // Port 6 function select per_dout, // Peripheral data output // INPUTs mclk, // Main system clock p1_din, // Port 1 data input p2_din, // Port 2 data input p3_din, // Port 3 data input p4_din, // Port 4 data input p5_din, // Port 5 data input p6_din, // Port 6 data input per_addr, // Peripheral address per_din, // Peripheral data input per_en, // Peripheral enable (high active) per_we, // Peripheral write enable (high active) puc_rst // Main system reset ); // PARAMETERs //============ parameter P1_EN = 1'b1; // Enable Port 1 parameter P2_EN = 1'b1; // Enable Port 2 parameter P3_EN = 1'b0; // Enable Port 3 parameter P4_EN = 1'b0; // Enable Port 4 parameter P5_EN = 1'b0; // Enable Port 5 parameter P6_EN = 1'b0; // Enable Port 6 // OUTPUTs //========= output irq_port1; // Port 1 interrupt output irq_port2; // Port 2 interrupt output [7:0] p1_dout; // Port 1 data output output [7:0] p1_dout_en; // Port 1 data output enable output [7:0] p1_sel; // Port 1 function select output [7:0] p2_dout; // Port 2 data output output [7:0] p2_dout_en; // Port 2 data output enable output [7:0] p2_sel; // Port 2 function select output [7:0] p3_dout; // Port 3 data output output [7:0] p3_dout_en; // Port 3 data output enable output [7:0] p3_sel; // Port 3 function select output [7:0] p4_dout; // Port 4 data output output [7:0] p4_dout_en; // Port 4 data output enable output [7:0] p4_sel; // Port 4 function select output [7:0] p5_dout; // Port 5 data output output [7:0] p5_dout_en; // Port 5 data output enable output [7:0] p5_sel; // Port 5 function select output [7:0] p6_dout; // Port 6 data output output [7:0] p6_dout_en; // Port 6 data output enable output [7:0] p6_sel; // Port 6 function select output [15:0] per_dout; // Peripheral data output // INPUTs //========= input mclk; // Main system clock input [7:0] p1_din; // Port 1 data input input [7:0] p2_din; // Port 2 data input input [7:0] p3_din; // Port 3 data input input [7:0] p4_din; // Port 4 data input input [7:0] p5_din; // Port 5 data input input [7:0] p6_din; // Port 6 data input input [13:0] per_addr; // Peripheral address input [15:0] per_din; // Peripheral data input input per_en; // Peripheral enable (high active) input [1:0] per_we; // Peripheral write enable (high active) input puc_rst; // Main system reset //============================================================================= // 1) PARAMETER DECLARATION //============================================================================= // Masks parameter P1_EN_MSK = {8{P1_EN[0]}}; parameter P2_EN_MSK = {8{P2_EN[0]}}; parameter P3_EN_MSK = {8{P3_EN[0]}}; parameter P4_EN_MSK = {8{P4_EN[0]}}; parameter P5_EN_MSK = {8{P5_EN[0]}}; parameter P6_EN_MSK = {8{P6_EN[0]}}; // Register base address (must be aligned to decoder bit width) parameter [14:0] BASE_ADDR = 15'h0000; // Decoder bit width (defines how many bits are considered for address decoding) parameter DEC_WD = 6; // Register addresses offset parameter [DEC_WD-1:0] P1IN = 'h20, // Port 1 P1OUT = 'h21, P1DIR = 'h22, P1IFG = 'h23, P1IES = 'h24, P1IE = 'h25, P1SEL = 'h26, P2IN = 'h28, // Port 2 P2OUT = 'h29, P2DIR = 'h2A, P2IFG = 'h2B, P2IES = 'h2C, P2IE = 'h2D, P2SEL = 'h2E, P3IN = 'h18, // Port 3 P3OUT = 'h19, P3DIR = 'h1A, P3SEL = 'h1B, P4IN = 'h1C, // Port 4 P4OUT = 'h1D, P4DIR = 'h1E, P4SEL = 'h1F, P5IN = 'h30, // Port 5 P5OUT = 'h31, P5DIR = 'h32, P5SEL = 'h33, P6IN = 'h34, // Port 6 P6OUT = 'h35, P6DIR = 'h36, P6SEL = 'h37; // Register one-hot decoder utilities parameter DEC_SZ = (1 << DEC_WD); parameter [DEC_SZ-1:0] BASE_REG = {{DEC_SZ-1{1'b0}}, 1'b1}; // Register one-hot decoder parameter [DEC_SZ-1:0] P1IN_D = (BASE_REG << P1IN), // Port 1 P1OUT_D = (BASE_REG << P1OUT), P1DIR_D = (BASE_REG << P1DIR), P1IFG_D = (BASE_REG << P1IFG), P1IES_D = (BASE_REG << P1IES), P1IE_D = (BASE_REG << P1IE), P1SEL_D = (BASE_REG << P1SEL), P2IN_D = (BASE_REG << P2IN), // Port 2 P2OUT_D = (BASE_REG << P2OUT), P2DIR_D = (BASE_REG << P2DIR), P2IFG_D = (BASE_REG << P2IFG), P2IES_D = (BASE_REG << P2IES), P2IE_D = (BASE_REG << P2IE), P2SEL_D = (BASE_REG << P2SEL), P3IN_D = (BASE_REG << P3IN), // Port 3 P3OUT_D = (BASE_REG << P3OUT), P3DIR_D = (BASE_REG << P3DIR), P3SEL_D = (BASE_REG << P3SEL), P4IN_D = (BASE_REG << P4IN), // Port 4 P4OUT_D = (BASE_REG << P4OUT), P4DIR_D = (BASE_REG << P4DIR), P4SEL_D = (BASE_REG << P4SEL), P5IN_D = (BASE_REG << P5IN), // Port 5 P5OUT_D = (BASE_REG << P5OUT), P5DIR_D = (BASE_REG << P5DIR), P5SEL_D = (BASE_REG << P5SEL), P6IN_D = (BASE_REG << P6IN), // Port 6 P6OUT_D = (BASE_REG << P6OUT), P6DIR_D = (BASE_REG << P6DIR), P6SEL_D = (BASE_REG << P6SEL); //============================================================================ // 2) REGISTER DECODER //============================================================================ // Local register selection wire reg_sel = per_en & (per_addr[13:DEC_WD-1]==BASE_ADDR[14:DEC_WD]); // Register local address wire [DEC_WD-1:0] reg_addr = {1'b0, per_addr[DEC_WD-2:0]}; // Register address decode wire [DEC_SZ-1:0] reg_dec = (P1IN_D & {DEC_SZ{(reg_addr==(P1IN >>1)) & P1_EN[0]}}) | (P1OUT_D & {DEC_SZ{(reg_addr==(P1OUT >>1)) & P1_EN[0]}}) | (P1DIR_D & {DEC_SZ{(reg_addr==(P1DIR >>1)) & P1_EN[0]}}) | (P1IFG_D & {DEC_SZ{(reg_addr==(P1IFG >>1)) & P1_EN[0]}}) | (P1IES_D & {DEC_SZ{(reg_addr==(P1IES >>1)) & P1_EN[0]}}) | (P1IE_D & {DEC_SZ{(reg_addr==(P1IE >>1)) & P1_EN[0]}}) | (P1SEL_D & {DEC_SZ{(reg_addr==(P1SEL >>1)) & P1_EN[0]}}) | (P2IN_D & {DEC_SZ{(reg_addr==(P2IN >>1)) & P2_EN[0]}}) | (P2OUT_D & {DEC_SZ{(reg_addr==(P2OUT >>1)) & P2_EN[0]}}) | (P2DIR_D & {DEC_SZ{(reg_addr==(P2DIR >>1)) & P2_EN[0]}}) | (P2IFG_D & {DEC_SZ{(reg_addr==(P2IFG >>1)) & P2_EN[0]}}) | (P2IES_D & {DEC_SZ{(reg_addr==(P2IES >>1)) & P2_EN[0]}}) | (P2IE_D & {DEC_SZ{(reg_addr==(P2IE >>1)) & P2_EN[0]}}) | (P2SEL_D & {DEC_SZ{(reg_addr==(P2SEL >>1)) & P2_EN[0]}}) | (P3IN_D & {DEC_SZ{(reg_addr==(P3IN >>1)) & P3_EN[0]}}) | (P3OUT_D & {DEC_SZ{(reg_addr==(P3OUT >>1)) & P3_EN[0]}}) | (P3DIR_D & {DEC_SZ{(reg_addr==(P3DIR >>1)) & P3_EN[0]}}) | (P3SEL_D & {DEC_SZ{(reg_addr==(P3SEL >>1)) & P3_EN[0]}}) | (P4IN_D & {DEC_SZ{(reg_addr==(P4IN >>1)) & P4_EN[0]}}) | (P4OUT_D & {DEC_SZ{(reg_addr==(P4OUT >>1)) & P4_EN[0]}}) | (P4DIR_D & {DEC_SZ{(reg_addr==(P4DIR >>1)) & P4_EN[0]}}) | (P4SEL_D & {DEC_SZ{(reg_addr==(P4SEL >>1)) & P4_EN[0]}}) | (P5IN_D & {DEC_SZ{(reg_addr==(P5IN >>1)) & P5_EN[0]}}) | (P5OUT_D & {DEC_SZ{(reg_addr==(P5OUT >>1)) & P5_EN[0]}}) | (P5DIR_D & {DEC_SZ{(reg_addr==(P5DIR >>1)) & P5_EN[0]}}) | (P5SEL_D & {DEC_SZ{(reg_addr==(P5SEL >>1)) & P5_EN[0]}}) | (P6IN_D & {DEC_SZ{(reg_addr==(P6IN >>1)) & P6_EN[0]}}) | (P6OUT_D & {DEC_SZ{(reg_addr==(P6OUT >>1)) & P6_EN[0]}}) | (P6DIR_D & {DEC_SZ{(reg_addr==(P6DIR >>1)) & P6_EN[0]}}) | (P6SEL_D & {DEC_SZ{(reg_addr==(P6SEL >>1)) & P6_EN[0]}}); // Read/Write probes wire reg_lo_write = per_we[0] & reg_sel; wire reg_hi_write = per_we[1] & reg_sel; wire reg_read = ~|per_we & reg_sel; // Read/Write vectors wire [DEC_SZ-1:0] reg_hi_wr = reg_dec & {DEC_SZ{reg_hi_write}}; wire [DEC_SZ-1:0] reg_lo_wr = reg_dec & {DEC_SZ{reg_lo_write}}; wire [DEC_SZ-1:0] reg_rd = reg_dec & {DEC_SZ{reg_read}}; //============================================================================ // 3) REGISTERS //============================================================================ // P1IN Register //--------------- wire [7:0] p1in; omsp_sync_cell sync_cell_p1in_0 (.data_out(p1in[0]), .data_in(p1_din[0] & P1_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p1in_1 (.data_out(p1in[1]), .data_in(p1_din[1] & P1_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p1in_2 (.data_out(p1in[2]), .data_in(p1_din[2] & P1_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p1in_3 (.data_out(p1in[3]), .data_in(p1_din[3] & P1_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p1in_4 (.data_out(p1in[4]), .data_in(p1_din[4] & P1_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p1in_5 (.data_out(p1in[5]), .data_in(p1_din[5] & P1_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p1in_6 (.data_out(p1in[6]), .data_in(p1_din[6] & P1_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p1in_7 (.data_out(p1in[7]), .data_in(p1_din[7] & P1_EN[0]), .clk(mclk), .rst(puc_rst)); // P1OUT Register //---------------- reg [7:0] p1out; wire p1out_wr = P1OUT[0] ? reg_hi_wr[P1OUT] : reg_lo_wr[P1OUT]; wire [7:0] p1out_nxt = P1OUT[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p1out <= 8'h00; else if (p1out_wr) p1out <= p1out_nxt & P1_EN_MSK; assign p1_dout = p1out; // P1DIR Register //---------------- reg [7:0] p1dir; wire p1dir_wr = P1DIR[0] ? reg_hi_wr[P1DIR] : reg_lo_wr[P1DIR]; wire [7:0] p1dir_nxt = P1DIR[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p1dir <= 8'h00; else if (p1dir_wr) p1dir <= p1dir_nxt & P1_EN_MSK; assign p1_dout_en = p1dir; // P1IFG Register //---------------- reg [7:0] p1ifg; wire p1ifg_wr = P1IFG[0] ? reg_hi_wr[P1IFG] : reg_lo_wr[P1IFG]; wire [7:0] p1ifg_nxt = P1IFG[0] ? per_din[15:8] : per_din[7:0]; wire [7:0] p1ifg_set; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p1ifg <= 8'h00; else if (p1ifg_wr) p1ifg <= (p1ifg_nxt | p1ifg_set) & P1_EN_MSK; else p1ifg <= (p1ifg | p1ifg_set) & P1_EN_MSK; // P1IES Register //---------------- reg [7:0] p1ies; wire p1ies_wr = P1IES[0] ? reg_hi_wr[P1IES] : reg_lo_wr[P1IES]; wire [7:0] p1ies_nxt = P1IES[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p1ies <= 8'h00; else if (p1ies_wr) p1ies <= p1ies_nxt & P1_EN_MSK; // P1IE Register //---------------- reg [7:0] p1ie; wire p1ie_wr = P1IE[0] ? reg_hi_wr[P1IE] : reg_lo_wr[P1IE]; wire [7:0] p1ie_nxt = P1IE[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p1ie <= 8'h00; else if (p1ie_wr) p1ie <= p1ie_nxt & P1_EN_MSK; // P1SEL Register //---------------- reg [7:0] p1sel; wire p1sel_wr = P1SEL[0] ? reg_hi_wr[P1SEL] : reg_lo_wr[P1SEL]; wire [7:0] p1sel_nxt = P1SEL[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p1sel <= 8'h00; else if (p1sel_wr) p1sel <= p1sel_nxt & P1_EN_MSK; assign p1_sel = p1sel; // P2IN Register //--------------- wire [7:0] p2in; omsp_sync_cell sync_cell_p2in_0 (.data_out(p2in[0]), .data_in(p2_din[0] & P2_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p2in_1 (.data_out(p2in[1]), .data_in(p2_din[1] & P2_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p2in_2 (.data_out(p2in[2]), .data_in(p2_din[2] & P2_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p2in_3 (.data_out(p2in[3]), .data_in(p2_din[3] & P2_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p2in_4 (.data_out(p2in[4]), .data_in(p2_din[4] & P2_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p2in_5 (.data_out(p2in[5]), .data_in(p2_din[5] & P2_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p2in_6 (.data_out(p2in[6]), .data_in(p2_din[6] & P2_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p2in_7 (.data_out(p2in[7]), .data_in(p2_din[7] & P2_EN[0]), .clk(mclk), .rst(puc_rst)); // P2OUT Register //---------------- reg [7:0] p2out; wire p2out_wr = P2OUT[0] ? reg_hi_wr[P2OUT] : reg_lo_wr[P2OUT]; wire [7:0] p2out_nxt = P2OUT[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p2out <= 8'h00; else if (p2out_wr) p2out <= p2out_nxt & P2_EN_MSK; assign p2_dout = p2out; // P2DIR Register //---------------- reg [7:0] p2dir; wire p2dir_wr = P2DIR[0] ? reg_hi_wr[P2DIR] : reg_lo_wr[P2DIR]; wire [7:0] p2dir_nxt = P2DIR[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p2dir <= 8'h00; else if (p2dir_wr) p2dir <= p2dir_nxt & P2_EN_MSK; assign p2_dout_en = p2dir; // P2IFG Register //---------------- reg [7:0] p2ifg; wire p2ifg_wr = P2IFG[0] ? reg_hi_wr[P2IFG] : reg_lo_wr[P2IFG]; wire [7:0] p2ifg_nxt = P2IFG[0] ? per_din[15:8] : per_din[7:0]; wire [7:0] p2ifg_set; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p2ifg <= 8'h00; else if (p2ifg_wr) p2ifg <= (p2ifg_nxt | p2ifg_set) & P2_EN_MSK; else p2ifg <= (p2ifg | p2ifg_set) & P2_EN_MSK; // P2IES Register //---------------- reg [7:0] p2ies; wire p2ies_wr = P2IES[0] ? reg_hi_wr[P2IES] : reg_lo_wr[P2IES]; wire [7:0] p2ies_nxt = P2IES[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p2ies <= 8'h00; else if (p2ies_wr) p2ies <= p2ies_nxt & P2_EN_MSK; // P2IE Register //---------------- reg [7:0] p2ie; wire p2ie_wr = P2IE[0] ? reg_hi_wr[P2IE] : reg_lo_wr[P2IE]; wire [7:0] p2ie_nxt = P2IE[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p2ie <= 8'h00; else if (p2ie_wr) p2ie <= p2ie_nxt & P2_EN_MSK; // P2SEL Register //---------------- reg [7:0] p2sel; wire p2sel_wr = P2SEL[0] ? reg_hi_wr[P2SEL] : reg_lo_wr[P2SEL]; wire [7:0] p2sel_nxt = P2SEL[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p2sel <= 8'h00; else if (p2sel_wr) p2sel <= p2sel_nxt & P2_EN_MSK; assign p2_sel = p2sel; // P3IN Register //--------------- wire [7:0] p3in; omsp_sync_cell sync_cell_p3in_0 (.data_out(p3in[0]), .data_in(p3_din[0] & P3_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p3in_1 (.data_out(p3in[1]), .data_in(p3_din[1] & P3_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p3in_2 (.data_out(p3in[2]), .data_in(p3_din[2] & P3_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p3in_3 (.data_out(p3in[3]), .data_in(p3_din[3] & P3_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p3in_4 (.data_out(p3in[4]), .data_in(p3_din[4] & P3_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p3in_5 (.data_out(p3in[5]), .data_in(p3_din[5] & P3_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p3in_6 (.data_out(p3in[6]), .data_in(p3_din[6] & P3_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p3in_7 (.data_out(p3in[7]), .data_in(p3_din[7] & P3_EN[0]), .clk(mclk), .rst(puc_rst)); // P3OUT Register //---------------- reg [7:0] p3out; wire p3out_wr = P3OUT[0] ? reg_hi_wr[P3OUT] : reg_lo_wr[P3OUT]; wire [7:0] p3out_nxt = P3OUT[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p3out <= 8'h00; else if (p3out_wr) p3out <= p3out_nxt & P3_EN_MSK; assign p3_dout = p3out; // P3DIR Register //---------------- reg [7:0] p3dir; wire p3dir_wr = P3DIR[0] ? reg_hi_wr[P3DIR] : reg_lo_wr[P3DIR]; wire [7:0] p3dir_nxt = P3DIR[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p3dir <= 8'h00; else if (p3dir_wr) p3dir <= p3dir_nxt & P3_EN_MSK; assign p3_dout_en = p3dir; // P3SEL Register //---------------- reg [7:0] p3sel; wire p3sel_wr = P3SEL[0] ? reg_hi_wr[P3SEL] : reg_lo_wr[P3SEL]; wire [7:0] p3sel_nxt = P3SEL[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p3sel <= 8'h00; else if (p3sel_wr) p3sel <= p3sel_nxt & P3_EN_MSK; assign p3_sel = p3sel; // P4IN Register //--------------- wire [7:0] p4in; omsp_sync_cell sync_cell_p4in_0 (.data_out(p4in[0]), .data_in(p4_din[0] & P4_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p4in_1 (.data_out(p4in[1]), .data_in(p4_din[1] & P4_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p4in_2 (.data_out(p4in[2]), .data_in(p4_din[2] & P4_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p4in_3 (.data_out(p4in[3]), .data_in(p4_din[3] & P4_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p4in_4 (.data_out(p4in[4]), .data_in(p4_din[4] & P4_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p4in_5 (.data_out(p4in[5]), .data_in(p4_din[5] & P4_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p4in_6 (.data_out(p4in[6]), .data_in(p4_din[6] & P4_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p4in_7 (.data_out(p4in[7]), .data_in(p4_din[7] & P4_EN[0]), .clk(mclk), .rst(puc_rst)); // P4OUT Register //---------------- reg [7:0] p4out; wire p4out_wr = P4OUT[0] ? reg_hi_wr[P4OUT] : reg_lo_wr[P4OUT]; wire [7:0] p4out_nxt = P4OUT[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p4out <= 8'h00; else if (p4out_wr) p4out <= p4out_nxt & P4_EN_MSK; assign p4_dout = p4out; // P4DIR Register //---------------- reg [7:0] p4dir; wire p4dir_wr = P4DIR[0] ? reg_hi_wr[P4DIR] : reg_lo_wr[P4DIR]; wire [7:0] p4dir_nxt = P4DIR[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p4dir <= 8'h00; else if (p4dir_wr) p4dir <= p4dir_nxt & P4_EN_MSK; assign p4_dout_en = p4dir; // P4SEL Register //---------------- reg [7:0] p4sel; wire p4sel_wr = P4SEL[0] ? reg_hi_wr[P4SEL] : reg_lo_wr[P4SEL]; wire [7:0] p4sel_nxt = P4SEL[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p4sel <= 8'h00; else if (p4sel_wr) p4sel <= p4sel_nxt & P4_EN_MSK; assign p4_sel = p4sel; // P5IN Register //--------------- wire [7:0] p5in; omsp_sync_cell sync_cell_p5in_0 (.data_out(p5in[0]), .data_in(p5_din[0] & P5_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p5in_1 (.data_out(p5in[1]), .data_in(p5_din[1] & P5_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p5in_2 (.data_out(p5in[2]), .data_in(p5_din[2] & P5_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p5in_3 (.data_out(p5in[3]), .data_in(p5_din[3] & P5_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p5in_4 (.data_out(p5in[4]), .data_in(p5_din[4] & P5_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p5in_5 (.data_out(p5in[5]), .data_in(p5_din[5] & P5_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p5in_6 (.data_out(p5in[6]), .data_in(p5_din[6] & P5_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p5in_7 (.data_out(p5in[7]), .data_in(p5_din[7] & P5_EN[0]), .clk(mclk), .rst(puc_rst)); // P5OUT Register //---------------- reg [7:0] p5out; wire p5out_wr = P5OUT[0] ? reg_hi_wr[P5OUT] : reg_lo_wr[P5OUT]; wire [7:0] p5out_nxt = P5OUT[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p5out <= 8'h00; else if (p5out_wr) p5out <= p5out_nxt & P5_EN_MSK; assign p5_dout = p5out; // P5DIR Register //---------------- reg [7:0] p5dir; wire p5dir_wr = P5DIR[0] ? reg_hi_wr[P5DIR] : reg_lo_wr[P5DIR]; wire [7:0] p5dir_nxt = P5DIR[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p5dir <= 8'h00; else if (p5dir_wr) p5dir <= p5dir_nxt & P5_EN_MSK; assign p5_dout_en = p5dir; // P5SEL Register //---------------- reg [7:0] p5sel; wire p5sel_wr = P5SEL[0] ? reg_hi_wr[P5SEL] : reg_lo_wr[P5SEL]; wire [7:0] p5sel_nxt = P5SEL[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p5sel <= 8'h00; else if (p5sel_wr) p5sel <= p5sel_nxt & P5_EN_MSK; assign p5_sel = p5sel; // P6IN Register //--------------- wire [7:0] p6in; omsp_sync_cell sync_cell_p6in_0 (.data_out(p6in[0]), .data_in(p6_din[0] & P6_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p6in_1 (.data_out(p6in[1]), .data_in(p6_din[1] & P6_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p6in_2 (.data_out(p6in[2]), .data_in(p6_din[2] & P6_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p6in_3 (.data_out(p6in[3]), .data_in(p6_din[3] & P6_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p6in_4 (.data_out(p6in[4]), .data_in(p6_din[4] & P6_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p6in_5 (.data_out(p6in[5]), .data_in(p6_din[5] & P6_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p6in_6 (.data_out(p6in[6]), .data_in(p6_din[6] & P6_EN[0]), .clk(mclk), .rst(puc_rst)); omsp_sync_cell sync_cell_p6in_7 (.data_out(p6in[7]), .data_in(p6_din[7] & P6_EN[0]), .clk(mclk), .rst(puc_rst)); // P6OUT Register //---------------- reg [7:0] p6out; wire p6out_wr = P6OUT[0] ? reg_hi_wr[P6OUT] : reg_lo_wr[P6OUT]; wire [7:0] p6out_nxt = P6OUT[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p6out <= 8'h00; else if (p6out_wr) p6out <= p6out_nxt & P6_EN_MSK; assign p6_dout = p6out; // P6DIR Register //---------------- reg [7:0] p6dir; wire p6dir_wr = P6DIR[0] ? reg_hi_wr[P6DIR] : reg_lo_wr[P6DIR]; wire [7:0] p6dir_nxt = P6DIR[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p6dir <= 8'h00; else if (p6dir_wr) p6dir <= p6dir_nxt & P6_EN_MSK; assign p6_dout_en = p6dir; // P6SEL Register //---------------- reg [7:0] p6sel; wire p6sel_wr = P6SEL[0] ? reg_hi_wr[P6SEL] : reg_lo_wr[P6SEL]; wire [7:0] p6sel_nxt = P6SEL[0] ? per_din[15:8] : per_din[7:0]; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p6sel <= 8'h00; else if (p6sel_wr) p6sel <= p6sel_nxt & P6_EN_MSK; assign p6_sel = p6sel; //============================================================================ // 4) INTERRUPT GENERATION //============================================================================ // Port 1 interrupt //------------------ // Delay input reg [7:0] p1in_dly; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p1in_dly <= 8'h00; else p1in_dly <= p1in & P1_EN_MSK; // Edge detection wire [7:0] p1in_re = p1in & ~p1in_dly; wire [7:0] p1in_fe = ~p1in & p1in_dly; // Set interrupt flag assign p1ifg_set = {p1ies[7] ? p1in_fe[7] : p1in_re[7], p1ies[6] ? p1in_fe[6] : p1in_re[6], p1ies[5] ? p1in_fe[5] : p1in_re[5], p1ies[4] ? p1in_fe[4] : p1in_re[4], p1ies[3] ? p1in_fe[3] : p1in_re[3], p1ies[2] ? p1in_fe[2] : p1in_re[2], p1ies[1] ? p1in_fe[1] : p1in_re[1], p1ies[0] ? p1in_fe[0] : p1in_re[0]} & P1_EN_MSK; // Generate CPU interrupt assign irq_port1 = |(p1ie & p1ifg) & P1_EN[0]; // Port 1 interrupt //------------------ // Delay input reg [7:0] p2in_dly; always @ (posedge mclk or posedge puc_rst) if (puc_rst) p2in_dly <= 8'h00; else p2in_dly <= p2in & P2_EN_MSK; // Edge detection wire [7:0] p2in_re = p2in & ~p2in_dly; wire [7:0] p2in_fe = ~p2in & p2in_dly; // Set interrupt flag assign p2ifg_set = {p2ies[7] ? p2in_fe[7] : p2in_re[7], p2ies[6] ? p2in_fe[6] : p2in_re[6], p2ies[5] ? p2in_fe[5] : p2in_re[5], p2ies[4] ? p2in_fe[4] : p2in_re[4], p2ies[3] ? p2in_fe[3] : p2in_re[3], p2ies[2] ? p2in_fe[2] : p2in_re[2], p2ies[1] ? p2in_fe[1] : p2in_re[1], p2ies[0] ? p2in_fe[0] : p2in_re[0]} & P2_EN_MSK; // Generate CPU interrupt assign irq_port2 = |(p2ie & p2ifg) & P2_EN[0]; //============================================================================ // 5) DATA OUTPUT GENERATION //============================================================================ // Data output mux wire [15:0] p1in_rd = {8'h00, (p1in & {8{reg_rd[P1IN]}})} << (8 & {4{P1IN[0]}}); wire [15:0] p1out_rd = {8'h00, (p1out & {8{reg_rd[P1OUT]}})} << (8 & {4{P1OUT[0]}}); wire [15:0] p1dir_rd = {8'h00, (p1dir & {8{reg_rd[P1DIR]}})} << (8 & {4{P1DIR[0]}}); wire [15:0] p1ifg_rd = {8'h00, (p1ifg & {8{reg_rd[P1IFG]}})} << (8 & {4{P1IFG[0]}}); wire [15:0] p1ies_rd = {8'h00, (p1ies & {8{reg_rd[P1IES]}})} << (8 & {4{P1IES[0]}}); wire [15:0] p1ie_rd = {8'h00, (p1ie & {8{reg_rd[P1IE]}})} << (8 & {4{P1IE[0]}}); wire [15:0] p1sel_rd = {8'h00, (p1sel & {8{reg_rd[P1SEL]}})} << (8 & {4{P1SEL[0]}}); wire [15:0] p2in_rd = {8'h00, (p2in & {8{reg_rd[P2IN]}})} << (8 & {4{P2IN[0]}}); wire [15:0] p2out_rd = {8'h00, (p2out & {8{reg_rd[P2OUT]}})} << (8 & {4{P2OUT[0]}}); wire [15:0] p2dir_rd = {8'h00, (p2dir & {8{reg_rd[P2DIR]}})} << (8 & {4{P2DIR[0]}}); wire [15:0] p2ifg_rd = {8'h00, (p2ifg & {8{reg_rd[P2IFG]}})} << (8 & {4{P2IFG[0]}}); wire [15:0] p2ies_rd = {8'h00, (p2ies & {8{reg_rd[P2IES]}})} << (8 & {4{P2IES[0]}}); wire [15:0] p2ie_rd = {8'h00, (p2ie & {8{reg_rd[P2IE]}})} << (8 & {4{P2IE[0]}}); wire [15:0] p2sel_rd = {8'h00, (p2sel & {8{reg_rd[P2SEL]}})} << (8 & {4{P2SEL[0]}}); wire [15:0] p3in_rd = {8'h00, (p3in & {8{reg_rd[P3IN]}})} << (8 & {4{P3IN[0]}}); wire [15:0] p3out_rd = {8'h00, (p3out & {8{reg_rd[P3OUT]}})} << (8 & {4{P3OUT[0]}}); wire [15:0] p3dir_rd = {8'h00, (p3dir & {8{reg_rd[P3DIR]}})} << (8 & {4{P3DIR[0]}}); wire [15:0] p3sel_rd = {8'h00, (p3sel & {8{reg_rd[P3SEL]}})} << (8 & {4{P3SEL[0]}}); wire [15:0] p4in_rd = {8'h00, (p4in & {8{reg_rd[P4IN]}})} << (8 & {4{P4IN[0]}}); wire [15:0] p4out_rd = {8'h00, (p4out & {8{reg_rd[P4OUT]}})} << (8 & {4{P4OUT[0]}}); wire [15:0] p4dir_rd = {8'h00, (p4dir & {8{reg_rd[P4DIR]}})} << (8 & {4{P4DIR[0]}}); wire [15:0] p4sel_rd = {8'h00, (p4sel & {8{reg_rd[P4SEL]}})} << (8 & {4{P4SEL[0]}}); wire [15:0] p5in_rd = {8'h00, (p5in & {8{reg_rd[P5IN]}})} << (8 & {4{P5IN[0]}}); wire [15:0] p5out_rd = {8'h00, (p5out & {8{reg_rd[P5OUT]}})} << (8 & {4{P5OUT[0]}}); wire [15:0] p5dir_rd = {8'h00, (p5dir & {8{reg_rd[P5DIR]}})} << (8 & {4{P5DIR[0]}}); wire [15:0] p5sel_rd = {8'h00, (p5sel & {8{reg_rd[P5SEL]}})} << (8 & {4{P5SEL[0]}}); wire [15:0] p6in_rd = {8'h00, (p6in & {8{reg_rd[P6IN]}})} << (8 & {4{P6IN[0]}}); wire [15:0] p6out_rd = {8'h00, (p6out & {8{reg_rd[P6OUT]}})} << (8 & {4{P6OUT[0]}}); wire [15:0] p6dir_rd = {8'h00, (p6dir & {8{reg_rd[P6DIR]}})} << (8 & {4{P6DIR[0]}}); wire [15:0] p6sel_rd = {8'h00, (p6sel & {8{reg_rd[P6SEL]}})} << (8 & {4{P6SEL[0]}}); wire [15:0] per_dout = p1in_rd | p1out_rd | p1dir_rd | p1ifg_rd | p1ies_rd | p1ie_rd | p1sel_rd | p2in_rd | p2out_rd | p2dir_rd | p2ifg_rd | p2ies_rd | p2ie_rd | p2sel_rd | p3in_rd | p3out_rd | p3dir_rd | p3sel_rd | p4in_rd | p4out_rd | p4dir_rd | p4sel_rd | p5in_rd | p5out_rd | p5dir_rd | p5sel_rd | p6in_rd | p6out_rd | p6dir_rd | p6sel_rd; endmodule // omsp_gpio
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