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////////////////////////////////////////////////////////////////////// //// //// //// WISHBONE General-Purpose I/O //// //// //// //// This file is part of the GPIO project //// //// http://www.opencores.org/cores/gpio/ //// //// //// //// Description //// //// Implementation of GPIO IP core according to //// //// GPIO IP core specification document. //// //// //// //// To Do: //// //// Nothing //// //// //// //// Author(s): //// //// - Damjan Lampret, lampret@opencores.org //// //// //// ////////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2000 Authors and OPENCORES.ORG //// //// //// //// This source file may be used and distributed without //// //// restriction provided that this copyright statement is not //// //// removed from the file and that any derivative work contains //// //// the original copyright notice and the associated disclaimer. //// //// //// //// This source file is free software; you can redistribute it //// //// and/or modify it under the terms of the GNU Lesser General //// //// Public License as published by the Free Software Foundation; //// //// either version 2.1 of the License, or (at your option) any //// //// later version. //// //// //// //// This source is distributed in the hope that it will be //// //// useful, but WITHOUT ANY WARRANTY; without even the implied //// //// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR //// //// PURPOSE. See the GNU Lesser General Public License for more //// //// details. //// //// //// //// You should have received a copy of the GNU Lesser General //// //// Public License along with this source; if not, download it //// //// from http://www.opencores.org/lgpl.shtml //// //// //// ////////////////////////////////////////////////////////////////////// // // CVS Revision History // // $Log: not supported by cvs2svn $ // Revision 1.17 2004/05/05 08:21:00 andreje // Bugfixes when GPIO_RGPIO_ECLK/GPIO_RGPIO_NEC disabled, gpio oe name change and set to active-high according to spec // // Revision 1.16 2003/12/17 13:00:52 gorand // added ECLK and NEC registers, all tests passed. // // Revision 1.15 2003/11/10 23:21:22 gorand // bug fixed. all tests passed. // // Revision 1.14 2003/11/06 13:59:07 gorand // added support for 8-bit access to registers. // // Revision 1.13 2002/11/18 22:35:18 lampret // Bug fix. Interrupts were also asserted when condition was not met. // // Revision 1.12 2002/11/11 21:36:28 lampret // Added ifdef to remove mux from clk_pad_i if mux is not allowed. This also removes RGPIO_CTRL[NEC]. // // Revision 1.11 2002/03/13 20:56:28 lampret // Removed zero padding as per Avi Shamli suggestion. // // Revision 1.10 2002/03/13 20:47:57 lampret // Ports changed per Ran Aviram suggestions. // // Revision 1.9 2002/03/09 03:43:27 lampret // Interrupt is asserted only when an input changes (code patch by Jacob Gorban) // // Revision 1.8 2002/01/14 19:06:28 lampret // Changed registered WISHBONE outputs wb_ack_o/wb_err_o to follow WB specification. // // Revision 1.7 2001/12/25 17:21:21 lampret // Fixed two typos. // // Revision 1.6 2001/12/25 17:12:35 lampret // Added RGPIO_INTS. // // Revision 1.5 2001/12/12 20:35:53 lampret // Fixing style. // // Revision 1.4 2001/12/12 07:12:58 lampret // Fixed bug when wb_inta_o is registered (GPIO_WB_REGISTERED_OUTPUTS) // // Revision 1.3 2001/11/15 02:24:37 lampret // Added GPIO_REGISTERED_WB_OUTPUTS, GPIO_REGISTERED_IO_OUTPUTS and GPIO_NO_NEGEDGE_FLOPS. // // Revision 1.2 2001/10/31 02:26:51 lampret // Fixed wb_err_o. // // Revision 1.1 2001/09/18 18:49:07 lampret // Changed top level ptc into gpio_top. Changed defines.v into gpio_defines.v. // // Revision 1.1 2001/08/21 21:39:28 lampret // Changed directory structure, port names and drfines. // // Revision 1.2 2001/07/14 20:39:26 lampret // Better configurability. // // Revision 1.1 2001/06/05 07:45:26 lampret // Added initial RTL and test benches. There are still some issues with these files. // // // synopsys translate_off `include "timescale.v" // synopsys translate_on `include "gpio_defines.v" module gpio_top( // WISHBONE Interface wb_clk_i, wb_rst_i, wb_cyc_i, wb_adr_i, wb_dat_i, wb_sel_i, wb_we_i, wb_stb_i, wb_dat_o, wb_ack_o, wb_err_o, wb_inta_o, `ifdef GPIO_AUX_IMPLEMENT // Auxiliary inputs interface aux_i, `endif // GPIO_AUX_IMPLEMENT // External GPIO Interface ext_pad_i, ext_pad_o, ext_padoe_o `ifdef GPIO_CLKPAD , clk_pad_i `endif ); parameter dw = 32; parameter aw = `GPIO_ADDRHH+1; parameter gw = `GPIO_IOS; // // WISHBONE Interface // input wb_clk_i; // Clock input wb_rst_i; // Reset input wb_cyc_i; // cycle valid input input [aw-1:0] wb_adr_i; // address bus inputs input [dw-1:0] wb_dat_i; // input data bus input [3:0] wb_sel_i; // byte select inputs input wb_we_i; // indicates write transfer input wb_stb_i; // strobe input output [dw-1:0] wb_dat_o; // output data bus output wb_ack_o; // normal termination output wb_err_o; // termination w/ error output wb_inta_o; // Interrupt request output `ifdef GPIO_AUX_IMPLEMENT // Auxiliary Inputs Interface input [gw-1:0] aux_i; // Auxiliary inputs `endif // GPIO_AUX_IMPLEMENT // // External GPIO Interface // input [gw-1:0] ext_pad_i; // GPIO Inputs `ifdef GPIO_CLKPAD input clk_pad_i; // GPIO Eclk `endif // GPIO_CLKPAD output [gw-1:0] ext_pad_o; // GPIO Outputs output [gw-1:0] ext_padoe_o; // GPIO output drivers enables `ifdef GPIO_IMPLEMENTED // // GPIO Input Register (or no register) // `ifdef GPIO_RGPIO_IN reg [gw-1:0] rgpio_in; // RGPIO_IN register `else wire [gw-1:0] rgpio_in; // No register `endif // // GPIO Output Register (or no register) // `ifdef GPIO_RGPIO_OUT reg [gw-1:0] rgpio_out; // RGPIO_OUT register `else wire [gw-1:0] rgpio_out; // No register `endif // // GPIO Output Driver Enable Register (or no register) // `ifdef GPIO_RGPIO_OE reg [gw-1:0] rgpio_oe; // RGPIO_OE register `else wire [gw-1:0] rgpio_oe; // No register `endif // // GPIO Interrupt Enable Register (or no register) // `ifdef GPIO_RGPIO_INTE reg [gw-1:0] rgpio_inte; // RGPIO_INTE register `else wire [gw-1:0] rgpio_inte; // No register `endif // // GPIO Positive edge Triggered Register (or no register) // `ifdef GPIO_RGPIO_PTRIG reg [gw-1:0] rgpio_ptrig; // RGPIO_PTRIG register `else wire [gw-1:0] rgpio_ptrig; // No register `endif // // GPIO Auxiliary select Register (or no register) // `ifdef GPIO_RGPIO_AUX reg [gw-1:0] rgpio_aux; // RGPIO_AUX register `else wire [gw-1:0] rgpio_aux; // No register `endif // // GPIO Control Register (or no register) // `ifdef GPIO_RGPIO_CTRL reg [1:0] rgpio_ctrl; // RGPIO_CTRL register `else wire [1:0] rgpio_ctrl; // No register `endif // // GPIO Interrupt Status Register (or no register) // `ifdef GPIO_RGPIO_INTS reg [gw-1:0] rgpio_ints; // RGPIO_INTS register `else wire [gw-1:0] rgpio_ints; // No register `endif // // GPIO Enable Clock Register (or no register) // `ifdef GPIO_RGPIO_ECLK reg [gw-1:0] rgpio_eclk; // RGPIO_ECLK register `else wire [gw-1:0] rgpio_eclk; // No register `endif // // GPIO Active Negative Edge Register (or no register) // `ifdef GPIO_RGPIO_NEC reg [gw-1:0] rgpio_nec; // RGPIO_NEC register `else wire [gw-1:0] rgpio_nec; // No register `endif // // Synchronization flops for input signals // `ifdef GPIO_SYNC_IN_WB reg [gw-1:0] sync , ext_pad_s ; `else wire [gw-1:0] ext_pad_s ; `endif // // Internal wires & regs // wire rgpio_out_sel; // RGPIO_OUT select wire rgpio_oe_sel; // RGPIO_OE select wire rgpio_inte_sel; // RGPIO_INTE select wire rgpio_ptrig_sel;// RGPIO_PTRIG select wire rgpio_aux_sel; // RGPIO_AUX select wire rgpio_ctrl_sel; // RGPIO_CTRL select wire rgpio_ints_sel; // RGPIO_INTS select wire rgpio_eclk_sel ; wire rgpio_nec_sel ; wire full_decoding; // Full address decoding qualification wire [gw-1:0] in_muxed; // Muxed inputs wire wb_ack; // WB Acknowledge wire wb_err; // WB Error wire wb_inta; // WB Interrupt reg [dw-1:0] wb_dat; // WB Data out `ifdef GPIO_REGISTERED_WB_OUTPUTS reg wb_ack_o; // WB Acknowledge reg wb_err_o; // WB Error reg wb_inta_o; // WB Interrupt reg [dw-1:0] wb_dat_o; // WB Data out `endif wire [gw-1:0] out_pad; // GPIO Outputs `ifdef GPIO_REGISTERED_IO_OUTPUTS reg [gw-1:0] ext_pad_o; // GPIO Outputs `endif `ifdef GPIO_CLKPAD wire [gw-1:0] extc_in; // Muxed inputs sampled by external clock wire [gw-1:0] pext_clk; // External clock for posedge flops reg [gw-1:0] pextc_sampled; // Posedge external clock sampled inputs `ifdef GPIO_NO_NEGEDGE_FLOPS `ifdef GPIO_NO_CLKPAD_LOGIC `else reg [gw-1:0] nextc_sampled; // Negedge external clock sampled inputs `endif // GPIO_NO_CLKPAD_LOGIC `else reg [gw-1:0] nextc_sampled; // Negedge external clock sampled inputs `endif `endif // GPIO_CLKPAD // // All WISHBONE transfer terminations are successful except when: // a) full address decoding is enabled and address doesn't match // any of the GPIO registers // b) wb_sel_i evaluation is enabled and one of the wb_sel_i inputs is zero // // // WB Acknowledge // assign wb_ack = wb_cyc_i & wb_stb_i & !wb_err_o; // // Optional registration of WB Ack // `ifdef GPIO_REGISTERED_WB_OUTPUTS always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) wb_ack_o <= #1 1'b0; else wb_ack_o <= #1 wb_ack & ~wb_ack_o & (!wb_err) ; `else assign wb_ack_o = wb_ack; `endif // // WB Error // `ifdef GPIO_FULL_DECODE `ifdef GPIO_STRICT_32BIT_ACCESS assign wb_err = wb_cyc_i & wb_stb_i & (!full_decoding | (wb_sel_i != 4'b1111)); `else assign wb_err = wb_cyc_i & wb_stb_i & !full_decoding; `endif `else `ifdef GPIO_STRICT_32BIT_ACCESS assign wb_err = wb_cyc_i & wb_stb_i & (wb_sel_i != 4'b1111); `else assign wb_err = 1'b0; `endif `endif // // Optional registration of WB error // `ifdef GPIO_REGISTERED_WB_OUTPUTS always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) wb_err_o <= #1 1'b0; else wb_err_o <= #1 wb_err & ~wb_err_o; `else assign wb_err_o = wb_err; `endif // // Full address decoder // `ifdef GPIO_FULL_DECODE assign full_decoding = (wb_adr_i[`GPIO_ADDRHH:`GPIO_ADDRHL] == {`GPIO_ADDRHH-`GPIO_ADDRHL+1{1'b0}}) & (wb_adr_i[`GPIO_ADDRLH:`GPIO_ADDRLL] == {`GPIO_ADDRLH-`GPIO_ADDRLL+1{1'b0}}); `else assign full_decoding = 1'b1; `endif // // GPIO registers address decoder // `ifdef GPIO_RGPIO_OUT assign rgpio_out_sel = wb_cyc_i & wb_stb_i & (wb_adr_i[`GPIO_OFS_BITS] == `GPIO_RGPIO_OUT) & full_decoding; `endif `ifdef GPIO_RGPIO_OE assign rgpio_oe_sel = wb_cyc_i & wb_stb_i & (wb_adr_i[`GPIO_OFS_BITS] == `GPIO_RGPIO_OE) & full_decoding; `endif `ifdef GPIO_RGPIO_INTE assign rgpio_inte_sel = wb_cyc_i & wb_stb_i & (wb_adr_i[`GPIO_OFS_BITS] == `GPIO_RGPIO_INTE) & full_decoding; `endif `ifdef GPIO_RGPIO_PTRIG assign rgpio_ptrig_sel = wb_cyc_i & wb_stb_i & (wb_adr_i[`GPIO_OFS_BITS] == `GPIO_RGPIO_PTRIG) & full_decoding; `endif `ifdef GPIO_RGPIO_AUX assign rgpio_aux_sel = wb_cyc_i & wb_stb_i & (wb_adr_i[`GPIO_OFS_BITS] == `GPIO_RGPIO_AUX) & full_decoding; `endif `ifdef GPIO_RGPIO_CTRL assign rgpio_ctrl_sel = wb_cyc_i & wb_stb_i & (wb_adr_i[`GPIO_OFS_BITS] == `GPIO_RGPIO_CTRL) & full_decoding; `endif `ifdef GPIO_RGPIO_INTS assign rgpio_ints_sel = wb_cyc_i & wb_stb_i & (wb_adr_i[`GPIO_OFS_BITS] == `GPIO_RGPIO_INTS) & full_decoding; `endif `ifdef GPIO_RGPIO_ECLK assign rgpio_eclk_sel = wb_cyc_i & wb_stb_i & (wb_adr_i[`GPIO_OFS_BITS] == `GPIO_RGPIO_ECLK) & full_decoding; `endif `ifdef GPIO_RGPIO_NEC assign rgpio_nec_sel = wb_cyc_i & wb_stb_i & (wb_adr_i[`GPIO_OFS_BITS] == `GPIO_RGPIO_NEC) & full_decoding; `endif // // Write to RGPIO_CTRL or update of RGPIO_CTRL[INT] bit // `ifdef GPIO_RGPIO_CTRL always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) rgpio_ctrl <= #1 2'b0; else if (rgpio_ctrl_sel && wb_we_i) rgpio_ctrl <= #1 wb_dat_i[1:0]; else if (rgpio_ctrl[`GPIO_RGPIO_CTRL_INTE]) rgpio_ctrl[`GPIO_RGPIO_CTRL_INTS] <= #1 rgpio_ctrl[`GPIO_RGPIO_CTRL_INTS] | wb_inta_o; `else assign rgpio_ctrl = 2'h01; // RGPIO_CTRL[EN] = 1 `endif // // Write to RGPIO_OUT // `ifdef GPIO_RGPIO_OUT always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) rgpio_out <= #1 {gw{1'b0}}; else if (rgpio_out_sel && wb_we_i) begin `ifdef GPIO_STRICT_32BIT_ACCESS rgpio_out <= #1 wb_dat_i[gw-1:0]; `endif `ifdef GPIO_WB_BYTES4 if ( wb_sel_i [3] == 1'b1 ) rgpio_out [gw-1:24] <= #1 wb_dat_i [gw-1:24] ; if ( wb_sel_i [2] == 1'b1 ) rgpio_out [23:16] <= #1 wb_dat_i [23:16] ; if ( wb_sel_i [1] == 1'b1 ) rgpio_out [15:8] <= #1 wb_dat_i [15:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_out [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES3 if ( wb_sel_i [2] == 1'b1 ) rgpio_out [gw-1:16] <= #1 wb_dat_i [gw-1:16] ; if ( wb_sel_i [1] == 1'b1 ) rgpio_out [15:8] <= #1 wb_dat_i [15:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_out [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES2 if ( wb_sel_i [1] == 1'b1 ) rgpio_out [gw-1:8] <= #1 wb_dat_i [gw-1:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_out [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES1 if ( wb_sel_i [0] == 1'b1 ) rgpio_out [gw-1:0] <= #1 wb_dat_i [gw-1:0] ; `endif end `else assign rgpio_out = `GPIO_DEF_RGPIO_OUT; // RGPIO_OUT = 0x0 `endif // // Write to RGPIO_OE. // `ifdef GPIO_RGPIO_OE always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) rgpio_oe <= #1 {gw{1'b0}}; else if (rgpio_oe_sel && wb_we_i) begin `ifdef GPIO_STRICT_32BIT_ACCESS rgpio_oe <= #1 wb_dat_i[gw-1:0]; `endif `ifdef GPIO_WB_BYTES4 if ( wb_sel_i [3] == 1'b1 ) rgpio_oe [gw-1:24] <= #1 wb_dat_i [gw-1:24] ; if ( wb_sel_i [2] == 1'b1 ) rgpio_oe [23:16] <= #1 wb_dat_i [23:16] ; if ( wb_sel_i [1] == 1'b1 ) rgpio_oe [15:8] <= #1 wb_dat_i [15:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_oe [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES3 if ( wb_sel_i [2] == 1'b1 ) rgpio_oe [gw-1:16] <= #1 wb_dat_i [gw-1:16] ; if ( wb_sel_i [1] == 1'b1 ) rgpio_oe [15:8] <= #1 wb_dat_i [15:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_oe [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES2 if ( wb_sel_i [1] == 1'b1 ) rgpio_oe [gw-1:8] <= #1 wb_dat_i [gw-1:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_oe [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES1 if ( wb_sel_i [0] == 1'b1 ) rgpio_oe [gw-1:0] <= #1 wb_dat_i [gw-1:0] ; `endif end `else assign rgpio_oe = `GPIO_DEF_RGPIO_OE; // RGPIO_OE = 0x0 `endif // // Write to RGPIO_INTE // `ifdef GPIO_RGPIO_INTE always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) rgpio_inte <= #1 {gw{1'b0}}; else if (rgpio_inte_sel && wb_we_i) begin `ifdef GPIO_STRICT_32BIT_ACCESS rgpio_inte <= #1 wb_dat_i[gw-1:0]; `endif `ifdef GPIO_WB_BYTES4 if ( wb_sel_i [3] == 1'b1 ) rgpio_inte [gw-1:24] <= #1 wb_dat_i [gw-1:24] ; if ( wb_sel_i [2] == 1'b1 ) rgpio_inte [23:16] <= #1 wb_dat_i [23:16] ; if ( wb_sel_i [1] == 1'b1 ) rgpio_inte [15:8] <= #1 wb_dat_i [15:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_inte [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES3 if ( wb_sel_i [2] == 1'b1 ) rgpio_inte [gw-1:16] <= #1 wb_dat_i [gw-1:16] ; if ( wb_sel_i [1] == 1'b1 ) rgpio_inte [15:8] <= #1 wb_dat_i [15:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_inte [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES2 if ( wb_sel_i [1] == 1'b1 ) rgpio_inte [gw-1:8] <= #1 wb_dat_i [gw-1:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_inte [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES1 if ( wb_sel_i [0] == 1'b1 ) rgpio_inte [gw-1:0] <= #1 wb_dat_i [gw-1:0] ; `endif end `else assign rgpio_inte = `GPIO_DEF_RGPIO_INTE; // RGPIO_INTE = 0x0 `endif // // Write to RGPIO_PTRIG // `ifdef GPIO_RGPIO_PTRIG always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) rgpio_ptrig <= #1 {gw{1'b0}}; else if (rgpio_ptrig_sel && wb_we_i) begin `ifdef GPIO_STRICT_32BIT_ACCESS rgpio_ptrig <= #1 wb_dat_i[gw-1:0]; `endif `ifdef GPIO_WB_BYTES4 if ( wb_sel_i [3] == 1'b1 ) rgpio_ptrig [gw-1:24] <= #1 wb_dat_i [gw-1:24] ; if ( wb_sel_i [2] == 1'b1 ) rgpio_ptrig [23:16] <= #1 wb_dat_i [23:16] ; if ( wb_sel_i [1] == 1'b1 ) rgpio_ptrig [15:8] <= #1 wb_dat_i [15:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_ptrig [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES3 if ( wb_sel_i [2] == 1'b1 ) rgpio_ptrig [gw-1:16] <= #1 wb_dat_i [gw-1:16] ; if ( wb_sel_i [1] == 1'b1 ) rgpio_ptrig [15:8] <= #1 wb_dat_i [15:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_ptrig [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES2 if ( wb_sel_i [1] == 1'b1 ) rgpio_ptrig [gw-1:8] <= #1 wb_dat_i [gw-1:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_ptrig [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES1 if ( wb_sel_i [0] == 1'b1 ) rgpio_ptrig [gw-1:0] <= #1 wb_dat_i [gw-1:0] ; `endif end `else assign rgpio_ptrig = `GPIO_DEF_RGPIO_PTRIG; // RGPIO_PTRIG = 0x0 `endif // // Write to RGPIO_AUX // `ifdef GPIO_RGPIO_AUX always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) rgpio_aux <= #1 {gw{1'b0}}; else if (rgpio_aux_sel && wb_we_i) begin `ifdef GPIO_STRICT_32BIT_ACCESS rgpio_aux <= #1 wb_dat_i[gw-1:0]; `endif `ifdef GPIO_WB_BYTES4 if ( wb_sel_i [3] == 1'b1 ) rgpio_aux [gw-1:24] <= #1 wb_dat_i [gw-1:24] ; if ( wb_sel_i [2] == 1'b1 ) rgpio_aux [23:16] <= #1 wb_dat_i [23:16] ; if ( wb_sel_i [1] == 1'b1 ) rgpio_aux [15:8] <= #1 wb_dat_i [15:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_aux [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES3 if ( wb_sel_i [2] == 1'b1 ) rgpio_aux [gw-1:16] <= #1 wb_dat_i [gw-1:16] ; if ( wb_sel_i [1] == 1'b1 ) rgpio_aux [15:8] <= #1 wb_dat_i [15:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_aux [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES2 if ( wb_sel_i [1] == 1'b1 ) rgpio_aux [gw-1:8] <= #1 wb_dat_i [gw-1:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_aux [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES1 if ( wb_sel_i [0] == 1'b1 ) rgpio_aux [gw-1:0] <= #1 wb_dat_i [gw-1:0] ; `endif end `else assign rgpio_aux = `GPIO_DEF_RGPIO_AUX; // RGPIO_AUX = 0x0 `endif // // Write to RGPIO_ECLK // `ifdef GPIO_RGPIO_ECLK always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) rgpio_eclk <= #1 {gw{1'b0}}; else if (rgpio_eclk_sel && wb_we_i) begin `ifdef GPIO_STRICT_32BIT_ACCESS rgpio_eclk <= #1 wb_dat_i[gw-1:0]; `endif `ifdef GPIO_WB_BYTES4 if ( wb_sel_i [3] == 1'b1 ) rgpio_eclk [gw-1:24] <= #1 wb_dat_i [gw-1:24] ; if ( wb_sel_i [2] == 1'b1 ) rgpio_eclk [23:16] <= #1 wb_dat_i [23:16] ; if ( wb_sel_i [1] == 1'b1 ) rgpio_eclk [15:8] <= #1 wb_dat_i [15:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_eclk [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES3 if ( wb_sel_i [2] == 1'b1 ) rgpio_eclk [gw-1:16] <= #1 wb_dat_i [gw-1:16] ; if ( wb_sel_i [1] == 1'b1 ) rgpio_eclk [15:8] <= #1 wb_dat_i [15:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_eclk [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES2 if ( wb_sel_i [1] == 1'b1 ) rgpio_eclk [gw-1:8] <= #1 wb_dat_i [gw-1:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_eclk [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES1 if ( wb_sel_i [0] == 1'b1 ) rgpio_eclk [gw-1:0] <= #1 wb_dat_i [gw-1:0] ; `endif end `else assign rgpio_eclk = `GPIO_DEF_RGPIO_ECLK; // RGPIO_ECLK = 0x0 `endif // // Write to RGPIO_NEC // `ifdef GPIO_RGPIO_NEC always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) rgpio_nec <= #1 {gw{1'b0}}; else if (rgpio_nec_sel && wb_we_i) begin `ifdef GPIO_STRICT_32BIT_ACCESS rgpio_nec <= #1 wb_dat_i[gw-1:0]; `endif `ifdef GPIO_WB_BYTES4 if ( wb_sel_i [3] == 1'b1 ) rgpio_nec [gw-1:24] <= #1 wb_dat_i [gw-1:24] ; if ( wb_sel_i [2] == 1'b1 ) rgpio_nec [23:16] <= #1 wb_dat_i [23:16] ; if ( wb_sel_i [1] == 1'b1 ) rgpio_nec [15:8] <= #1 wb_dat_i [15:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_nec [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES3 if ( wb_sel_i [2] == 1'b1 ) rgpio_nec [gw-1:16] <= #1 wb_dat_i [gw-1:16] ; if ( wb_sel_i [1] == 1'b1 ) rgpio_nec [15:8] <= #1 wb_dat_i [15:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_nec [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES2 if ( wb_sel_i [1] == 1'b1 ) rgpio_nec [gw-1:8] <= #1 wb_dat_i [gw-1:8] ; if ( wb_sel_i [0] == 1'b1 ) rgpio_nec [7:0] <= #1 wb_dat_i [7:0] ; `endif `ifdef GPIO_WB_BYTES1 if ( wb_sel_i [0] == 1'b1 ) rgpio_nec [gw-1:0] <= #1 wb_dat_i [gw-1:0] ; `endif end `else assign rgpio_nec = `GPIO_DEF_RGPIO_NEC; // RGPIO_NEC = 0x0 `endif // // synchronize inputs to systam clock // `ifdef GPIO_SYNC_IN_WB always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) begin sync <= #1 {gw{1'b0}} ; ext_pad_s <= #1 {gw{1'b0}} ; end else begin sync <= #1 ext_pad_i ; ext_pad_s <= #1 sync ; end `else assign ext_pad_s = ext_pad_i; `endif // GPIO_SYNC_IN_WB // // Latch into RGPIO_IN // `ifdef GPIO_RGPIO_IN always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) rgpio_in <= #1 {gw{1'b0}}; else rgpio_in <= #1 in_muxed; `else assign rgpio_in = in_muxed; `endif `ifdef GPIO_CLKPAD `ifdef GPIO_SYNC_CLK_WB // // external clock enabled // synchronized to system clock // (one clock domain) // reg sync_clk, clk_s , clk_r ; wire pedge , nedge ; wire [gw-1:0] pedge_vec , nedge_vec ; wire [gw-1:0] in_lach ; assign pedge = clk_s & !clk_r ; assign nedge = !clk_s & clk_r ; assign pedge_vec = {gw{pedge}} ; assign nedge_vec = {gw{nedge}} ; assign in_lach = (~rgpio_nec & pedge_vec) | (rgpio_nec & nedge_vec) ; assign extc_in = (in_lach & ext_pad_s) | (~in_lach & pextc_sampled) ; always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) begin sync_clk <= #1 1'b0 ; clk_s <= #1 1'b0 ; clk_r <= #1 1'b0 ; end else begin sync_clk <= #1 clk_pad_i ; clk_s <= #1 sync_clk ; clk_r <= #1 clk_s ; end always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) begin pextc_sampled <= #1 {gw{1'b0}}; end else begin pextc_sampled <= #1 extc_in ; end assign in_muxed = (rgpio_eclk & pextc_sampled) | (~rgpio_eclk & ext_pad_s) ; `else // // external clock enabled // not synchronized to system clock // (two clock domains) // `ifdef GPIO_SYNC_IN_CLK_WB reg [gw-1:0] syn_extc , extc_s ; always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) begin syn_extc <= #1 {gw{1'b0}}; extc_s <= #1 {gw{1'b0}}; end else begin syn_extc <= #1 extc_in ; extc_s <= #1 syn_extc; end `else wire [gw-1:0] extc_s ; assign extc_s = syn_extc ; `endif // GPIO_SYNC_IN_CLK_WB `ifdef GPIO_SYNC_IN_CLK reg [gw-1:0] syn_pclk , ext_pad_spc ; always @(posedge clk_pad_i or posedge wb_rst_i) if (wb_rst_i) begin syn_pclk <= #1 {gw{1'b0}} ; ext_pad_spc <= #1 {gw{1'b0}} ; end else begin syn_pclk <= #1 ext_pad_i ; ext_pad_spc <= #1 syn_pclk ; end `else wire [gw-1:0] ext_pad_spc ; assign ext_pad_spc = ext_pad_i ; `endif // GPIO_SYNC_IN_CLK always @(posedge clk_pad_i or posedge wb_rst_i) if (wb_rst_i) begin pextc_sampled <= #1 {gw{1'b0}}; end else begin pextc_sampled <= #1 ext_pad_spc ; end `ifdef GPIO_NO_NEGEDGE_FLOPS `ifdef GPIO_NO_CLKPAD_LOGIC assign extc_in = pextc_sampled; `else wire clk_n; assign clk_n = !clk_pad_i; `ifdef GPIO_SYNC_IN_CLK reg [gw-1:0] syn_nclk , ext_pad_snc ; always @(posedge clk_n or posedge wb_rst_i) if (wb_rst_i) begin syn_nclk <= #1 {gw{1'b0}} ; ext_pad_snc <= #1 {gw{1'b0}} ; end else begin syn_nclk <= #1 ext_pad_i ; ext_pad_snc <= #1 syn_nclk ; end `else wire [gw-1:0] ext_pad_snc ; assign ext_pad_snc = ext_pad_i ; `endif // GPIO_SYNC_IN_CLK always @(posedge clk_n or posedge wb_rst_i) if (wb_rst_i) begin nextc_sampled <= #1 {gw{1'b0}}; end else begin nextc_sampled <= #1 ext_pad_snc ; end assign extc_in = (~rgpio_nec & pextc_sampled) | (rgpio_nec & nextc_sampled) ; `endif // GPIO_NO_CLKPAD_LOGIC `else `ifdef GPIO_SYNC_IN_CLK reg [gw-1:0] syn_nclk , ext_pad_snc ; always @(negedge clk_n or posedge wb_rst_i) if (wb_rst_i) begin syn_nclk <= #1 {gw{1'b0}} ; ext_pad_snc <= #1 {gw{1'b0}} ; end else begin syn_nclk <= #1 ext_pad_i ; ext_pad_snc <= #1 syn_nclk ; end `else wire [gw-1:0] ext_pad_snc ; assign ext_pad_snc = ext_pad_i ; `endif // GPIO_SYNC_IN_CLK always @(negedge clk_pad_i or posedge wb_rst_i) if (wb_rst_i) begin nextc_sampled <= #1 {gw{1'b0}}; end else begin nextc_sampled <= #1 ext_pad_snc ; end assign extc_in = (~rgpio_nec & pextc_sampled) | (rgpio_nec & nextc_sampled) ; `endif // GPIO_NO_NEGEDGE_FLOPS assign in_muxed = (rgpio_eclk & extc_s) | (~rgpio_eclk & ext_pad_s) ; `endif // GPIO_SYNC_CLK_WB `else assign in_muxed = ext_pad_s ; `endif // GPIO_CLKPAD // // Mux all registers when doing a read of GPIO registers // always @(wb_adr_i or rgpio_in or rgpio_out or rgpio_oe or rgpio_inte or rgpio_ptrig or rgpio_aux or rgpio_ctrl or rgpio_ints or rgpio_eclk or rgpio_nec) case (wb_adr_i[`GPIO_OFS_BITS]) // synopsys full_case parallel_case `ifdef GPIO_READREGS `ifdef GPIO_RGPIO_OUT `GPIO_RGPIO_OUT: begin wb_dat[dw-1:0] = rgpio_out; end `endif `ifdef GPIO_RGPIO_OE `GPIO_RGPIO_OE: begin wb_dat[dw-1:0] = rgpio_oe; end `endif `ifdef GPIO_RGPIO_INTE `GPIO_RGPIO_INTE: begin wb_dat[dw-1:0] = rgpio_inte; end `endif `ifdef GPIO_RGPIO_PTRIG `GPIO_RGPIO_PTRIG: begin wb_dat[dw-1:0] = rgpio_ptrig; end `endif `ifdef GPIO_RGPIO_NEC `GPIO_RGPIO_NEC: begin wb_dat[dw-1:0] = rgpio_nec; end `endif `ifdef GPIO_RGPIO_ECLK `GPIO_RGPIO_ECLK: begin wb_dat[dw-1:0] = rgpio_eclk; end `endif `ifdef GPIO_RGPIO_AUX `GPIO_RGPIO_AUX: begin wb_dat[dw-1:0] = rgpio_aux; end `endif `ifdef GPIO_RGPIO_CTRL `GPIO_RGPIO_CTRL: begin wb_dat[1:0] = rgpio_ctrl; wb_dat[dw-1:2] = {dw-2{1'b0}}; end `endif `endif `ifdef GPIO_RGPIO_INTS `GPIO_RGPIO_INTS: begin wb_dat[dw-1:0] = rgpio_ints; end `endif default: begin wb_dat[dw-1:0] = rgpio_in; end endcase // // WB data output // `ifdef GPIO_REGISTERED_WB_OUTPUTS always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) wb_dat_o <= #1 {dw{1'b0}}; else wb_dat_o <= #1 wb_dat; `else assign wb_dat_o = wb_dat; `endif // // RGPIO_INTS // `ifdef GPIO_RGPIO_INTS always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) rgpio_ints <= #1 {gw{1'b0}}; else if (rgpio_ints_sel && wb_we_i) rgpio_ints <= #1 wb_dat_i[gw-1:0]; else if (rgpio_ctrl[`GPIO_RGPIO_CTRL_INTE]) rgpio_ints <= #1 (rgpio_ints | ((in_muxed ^ rgpio_in) & ~(in_muxed ^ rgpio_ptrig)) & rgpio_inte); `else assign rgpio_ints = (rgpio_ints | ((in_muxed ^ rgpio_in) & ~(in_muxed ^ rgpio_ptrig)) & rgpio_inte); `endif // // Generate interrupt request // assign wb_inta = |rgpio_ints ? rgpio_ctrl[`GPIO_RGPIO_CTRL_INTE] : 1'b0; // // Optional registration of WB interrupt // `ifdef GPIO_REGISTERED_WB_OUTPUTS always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) wb_inta_o <= #1 1'b0; else wb_inta_o <= #1 wb_inta; `else assign wb_inta_o = wb_inta; `endif // GPIO_REGISTERED_WB_OUTPUTS // // Output enables are RGPIO_OE bits // assign ext_padoe_o = rgpio_oe; // // Generate GPIO outputs // `ifdef GPIO_AUX_IMPLEMENT assign out_pad = rgpio_out & ~rgpio_aux | aux_i & rgpio_aux; `else assign out_pad = rgpio_out ; `endif // GPIO_AUX_IMPLEMENT // // Optional registration of GPIO outputs // `ifdef GPIO_REGISTERED_IO_OUTPUTS always @(posedge wb_clk_i or posedge wb_rst_i) if (wb_rst_i) ext_pad_o <= #1 {gw{1'b0}}; else ext_pad_o <= #1 out_pad; `else assign ext_pad_o = out_pad; `endif // GPIO_REGISTERED_IO_OUTPUTS `else // // When GPIO is not implemented, drive all outputs as would when RGPIO_CTRL // is cleared and WISHBONE transfers complete with errors // assign wb_inta_o = 1'b0; assign wb_ack_o = 1'b0; assign wb_err_o = wb_cyc_i & wb_stb_i; assign ext_padoe_o = {gw{1'b1}}; assign ext_pad_o = {gw{1'b0}}; // // Read GPIO registers // assign wb_dat_o = {dw{1'b0}}; `endif // GPIO_IMPLEMENTED endmodule
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