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[/] [openrisc/] [trunk/] [or1200/] [rtl/] [verilog/] [or1200_wb_biu.v] - Rev 639
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////////////////////////////////////////////////////////////////////// //// //// //// OR1200's WISHBONE BIU //// //// //// //// This file is part of the OpenRISC 1200 project //// //// http://opencores.org/project,or1k //// //// //// //// Description //// //// Implements WISHBONE interface //// //// //// //// To Do: //// //// - if biu_cyc/stb are deasserted and wb_ack_i is asserted //// //// and this happens even before aborted_r is asssrted, //// //// wb_ack_i will be delivered even though transfer is //// //// internally considered already aborted. However most //// //// wb_ack_i are externally registered and delayed. Normally //// //// this shouldn't cause any problems. //// //// //// //// 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 //// //// //// ////////////////////////////////////////////////////////////////////// // // // $Log: or1200_wb_biu.v,v $ // Revision 2.0 2010/06/30 11:00:00 ORSoC // Major update: // Structure reordered and bugs fixed. // // synopsys translate_off `include "timescale.v" // synopsys translate_on `include "or1200_defines.v" module or1200_wb_biu( // RISC clock, reset and clock control clk, rst, clmode, // WISHBONE interface wb_clk_i, wb_rst_i, wb_ack_i, wb_err_i, wb_rty_i, wb_dat_i, wb_cyc_o, wb_adr_o, wb_stb_o, wb_we_o, wb_sel_o, wb_dat_o, `ifdef OR1200_WB_CAB wb_cab_o, `endif `ifdef OR1200_WB_B3 wb_cti_o, wb_bte_o, `endif // Internal RISC bus biu_dat_i, biu_adr_i, biu_cyc_i, biu_stb_i, biu_we_i, biu_sel_i, biu_cab_i, biu_dat_o, biu_ack_o, biu_err_o ); parameter dw = `OR1200_OPERAND_WIDTH; parameter aw = `OR1200_OPERAND_WIDTH; parameter bl = 4; /* Can currently be either 4 or 8 - the two optional line sizes for the OR1200. */ // // RISC clock, reset and clock control // input clk; // RISC clock input rst; // RISC reset input [1:0] clmode; // 00 WB=RISC, 01 WB=RISC/2, 10 N/A, 11 WB=RISC/4 // // WISHBONE interface // input wb_clk_i; // clock input input wb_rst_i; // reset input input wb_ack_i; // normal termination input wb_err_i; // termination w/ error input wb_rty_i; // termination w/ retry input [dw-1:0] wb_dat_i; // input data bus output wb_cyc_o; // cycle valid output output [aw-1:0] wb_adr_o; // address bus outputs output wb_stb_o; // strobe output output wb_we_o; // indicates write transfer output [3:0] wb_sel_o; // byte select outputs output [dw-1:0] wb_dat_o; // output data bus `ifdef OR1200_WB_CAB output wb_cab_o; // consecutive address burst `endif `ifdef OR1200_WB_B3 output [2:0] wb_cti_o; // cycle type identifier output [1:0] wb_bte_o; // burst type extension `endif // // Internal RISC interface // input [dw-1:0] biu_dat_i; // input data bus input [aw-1:0] biu_adr_i; // address bus input biu_cyc_i; // WB cycle input biu_stb_i; // WB strobe input biu_we_i; // WB write enable input biu_cab_i; // CAB input input [3:0] biu_sel_i; // byte selects output [31:0] biu_dat_o; // output data bus output biu_ack_o; // ack output output biu_err_o; // err output // // Registers // wire wb_ack; // normal termination reg [aw-1:0] wb_adr_o; // address bus outputs reg wb_cyc_o; // cycle output reg wb_stb_o; // strobe output reg wb_we_o; // indicates write transfer reg [3:0] wb_sel_o; // byte select outputs `ifdef OR1200_WB_CAB reg wb_cab_o; // CAB output `endif `ifdef OR1200_WB_B3 reg [2:0] wb_cti_o; // cycle type identifier reg [1:0] wb_bte_o; // burst type extension `endif `ifdef OR1200_NO_DC reg [dw-1:0] wb_dat_o; // output data bus `else assign wb_dat_o = biu_dat_i; // No register on this - straight from DCRAM `endif `ifdef OR1200_WB_RETRY reg [`OR1200_WB_RETRY-1:0] retry_cnt; // Retry counter `else wire retry_cnt; assign retry_cnt = 1'b0; `endif `ifdef OR1200_WB_B3 reg [3:0] burst_len; // burst counter `endif reg biu_stb_reg; // WB strobe wire biu_stb; // WB strobe reg wb_cyc_nxt; // next WB cycle value reg wb_stb_nxt; // next WB strobe value reg [2:0] wb_cti_nxt; // next cycle type identifier value reg wb_ack_cnt; // WB ack toggle counter reg wb_err_cnt; // WB err toggle counter reg wb_rty_cnt; // WB rty toggle counter reg biu_ack_cnt; // BIU ack toggle counter reg biu_err_cnt; // BIU err toggle counter reg biu_rty_cnt; // BIU rty toggle counter wire biu_rty; // BIU rty indicator reg [1:0] wb_fsm_state_cur; // WB FSM - surrent state reg [1:0] wb_fsm_state_nxt; // WB FSM - next state wire [1:0] wb_fsm_idle = 2'h0; // WB FSM state - IDLE wire [1:0] wb_fsm_trans = 2'h1; // WB FSM state - normal TRANSFER wire [1:0] wb_fsm_last = 2'h2; // EB FSM state - LAST transfer // // WISHBONE I/F <-> Internal RISC I/F conversion // //assign wb_ack = wb_ack_i; assign wb_ack = wb_ack_i & !wb_err_i & !wb_rty_i; // // WB FSM - register part // always @(posedge wb_clk_i or `OR1200_RST_EVENT wb_rst_i) begin if (wb_rst_i == `OR1200_RST_VALUE) wb_fsm_state_cur <= wb_fsm_idle; else wb_fsm_state_cur <= wb_fsm_state_nxt; end // // WB burst tength counter // always @(posedge wb_clk_i or `OR1200_RST_EVENT wb_rst_i) begin if (wb_rst_i == `OR1200_RST_VALUE) begin burst_len <= 0; end else begin // burst counter if (wb_fsm_state_cur == wb_fsm_idle) burst_len <= bl[3:0] - 2; else if (wb_stb_o & wb_ack) burst_len <= burst_len - 1; end end // // WB FSM - combinatorial part // always @(wb_fsm_state_cur or burst_len or wb_err_i or wb_rty_i or wb_ack or wb_cti_o or wb_sel_o or wb_stb_o or wb_we_o or biu_cyc_i or biu_stb or biu_cab_i or biu_sel_i or biu_we_i) begin // States of WISHBONE Finite State Machine case(wb_fsm_state_cur) // IDLE wb_fsm_idle : begin wb_cyc_nxt = biu_cyc_i & biu_stb; wb_stb_nxt = biu_cyc_i & biu_stb; wb_cti_nxt = {!biu_cab_i, 1'b1, !biu_cab_i}; if (biu_cyc_i & biu_stb) wb_fsm_state_nxt = wb_fsm_trans; else wb_fsm_state_nxt = wb_fsm_idle; end // normal TRANSFER wb_fsm_trans : begin wb_cyc_nxt = !wb_stb_o | !wb_err_i & !wb_rty_i & !(wb_ack & wb_cti_o == 3'b111); wb_stb_nxt = !wb_stb_o | !wb_err_i & !wb_rty_i & !wb_ack | !wb_err_i & !wb_rty_i & wb_cti_o == 3'b010 ; wb_cti_nxt[2] = wb_stb_o & wb_ack & burst_len == 'h0 | wb_cti_o[2]; wb_cti_nxt[1] = 1'b1 ; wb_cti_nxt[0] = wb_stb_o & wb_ack & burst_len == 'h0 | wb_cti_o[0]; if ((!biu_cyc_i | !biu_stb | !biu_cab_i | biu_sel_i != wb_sel_o | biu_we_i != wb_we_o) & wb_cti_o == 3'b010) wb_fsm_state_nxt = wb_fsm_last; else if ((wb_err_i | wb_rty_i | wb_ack & wb_cti_o==3'b111) & wb_stb_o) wb_fsm_state_nxt = wb_fsm_idle; else wb_fsm_state_nxt = wb_fsm_trans; end // LAST transfer wb_fsm_last : begin wb_cyc_nxt = !wb_stb_o | !wb_err_i & !wb_rty_i & !(wb_ack & wb_cti_o == 3'b111); wb_stb_nxt = !wb_stb_o | !wb_err_i & !wb_rty_i & !(wb_ack & wb_cti_o == 3'b111); wb_cti_nxt[2] = wb_ack & wb_stb_o | wb_cti_o[2]; wb_cti_nxt[1] = 1'b1 ; wb_cti_nxt[0] = wb_ack & wb_stb_o | wb_cti_o[0]; if ((wb_err_i | wb_rty_i | wb_ack & wb_cti_o == 3'b111) & wb_stb_o) wb_fsm_state_nxt = wb_fsm_idle; else wb_fsm_state_nxt = wb_fsm_last; end // default state default:begin wb_cyc_nxt = 1'bx; wb_stb_nxt = 1'bx; wb_cti_nxt = 3'bxxx; wb_fsm_state_nxt = 2'bxx; end endcase end // // WB FSM - output signals // always @(posedge wb_clk_i or `OR1200_RST_EVENT wb_rst_i) begin if (wb_rst_i == `OR1200_RST_VALUE) begin wb_cyc_o <= 1'b0; wb_stb_o <= 1'b0; wb_cti_o <= 3'b111; wb_bte_o <= (bl==8) ? 2'b10 : (bl==4) ? 2'b01 : 2'b00; `ifdef OR1200_WB_CAB wb_cab_o <= 1'b0; `endif wb_we_o <= 1'b0; wb_sel_o <= 4'hf; wb_adr_o <= {aw{1'b0}}; `ifdef OR1200_NO_DC wb_dat_o <= {dw{1'b0}}; `endif end else begin wb_cyc_o <= wb_cyc_nxt; if (wb_ack & wb_cti_o == 3'b111) wb_stb_o <= 1'b0; else wb_stb_o <= wb_stb_nxt; `ifndef OR1200_NO_BURSTS wb_cti_o <= wb_cti_nxt; `endif wb_bte_o <= (bl==8) ? 2'b10 : (bl==4) ? 2'b01 : 2'b00; `ifdef OR1200_WB_CAB wb_cab_o <= biu_cab_i; `endif // we and sel - set at beginning of access if (wb_fsm_state_cur == wb_fsm_idle) begin wb_we_o <= biu_we_i; wb_sel_o <= biu_sel_i; end // adr - set at beginning of access and changed at every termination if (wb_fsm_state_cur == wb_fsm_idle) begin wb_adr_o <= biu_adr_i; end else if (wb_stb_o & wb_ack) begin if (bl==4) begin wb_adr_o[3:2] <= wb_adr_o[3:2] + 1; end if (bl==8) begin wb_adr_o[4:2] <= wb_adr_o[4:2] + 1; end end `ifdef OR1200_NO_DC // dat - write data changed after avery subsequent write access if (!wb_stb_o) begin wb_dat_o <= biu_dat_i; end `endif end end // // WB & BIU termination toggle counters // always @(posedge wb_clk_i or `OR1200_RST_EVENT wb_rst_i) begin if (wb_rst_i == `OR1200_RST_VALUE) begin wb_ack_cnt <= 1'b0; wb_err_cnt <= 1'b0; wb_rty_cnt <= 1'b0; end else begin // WB ack toggle counter if (wb_fsm_state_cur == wb_fsm_idle | !(|clmode)) wb_ack_cnt <= 1'b0; else if (wb_stb_o & wb_ack) wb_ack_cnt <= !wb_ack_cnt; // WB err toggle counter if (wb_fsm_state_cur == wb_fsm_idle | !(|clmode)) wb_err_cnt <= 1'b0; else if (wb_stb_o & wb_err_i) wb_err_cnt <= !wb_err_cnt; // WB rty toggle counter if (wb_fsm_state_cur == wb_fsm_idle | !(|clmode)) wb_rty_cnt <= 1'b0; else if (wb_stb_o & wb_rty_i) wb_rty_cnt <= !wb_rty_cnt; end end always @(posedge clk or `OR1200_RST_EVENT rst) begin if (rst == `OR1200_RST_VALUE) begin biu_stb_reg <= 1'b0; biu_ack_cnt <= 1'b0; biu_err_cnt <= 1'b0; biu_rty_cnt <= 1'b0; `ifdef OR1200_WB_RETRY retry_cnt <= {`OR1200_WB_RETRY{1'b0}}; `endif end else begin // BIU strobe if (biu_stb_i & !biu_cab_i & biu_ack_o) biu_stb_reg <= 1'b0; else biu_stb_reg <= biu_stb_i; // BIU ack toggle counter if (wb_fsm_state_cur == wb_fsm_idle | !(|clmode)) biu_ack_cnt <= 1'b0 ; else if (biu_ack_o) biu_ack_cnt <= !biu_ack_cnt ; // BIU err toggle counter if (wb_fsm_state_cur == wb_fsm_idle | !(|clmode)) biu_err_cnt <= 1'b0 ; else if (wb_err_i & biu_err_o) biu_err_cnt <= !biu_err_cnt ; // BIU rty toggle counter if (wb_fsm_state_cur == wb_fsm_idle | !(|clmode)) biu_rty_cnt <= 1'b0 ; else if (biu_rty) biu_rty_cnt <= !biu_rty_cnt ; `ifdef OR1200_WB_RETRY if (biu_ack_o | biu_err_o) retry_cnt <= {`OR1200_WB_RETRY{1'b0}}; else if (biu_rty) retry_cnt <= retry_cnt + 1'b1; `endif end end assign biu_stb = biu_stb_i & biu_stb_reg; // // Input BIU data bus // assign biu_dat_o = wb_dat_i; // // Input BIU termination signals // assign biu_rty = (wb_fsm_state_cur == wb_fsm_trans) & wb_rty_i & wb_stb_o & (wb_rty_cnt ~^ biu_rty_cnt); assign biu_ack_o = (wb_fsm_state_cur == wb_fsm_trans) & wb_ack & wb_stb_o & (wb_ack_cnt ~^ biu_ack_cnt); assign biu_err_o = (wb_fsm_state_cur == wb_fsm_trans) & wb_err_i & wb_stb_o & (wb_err_cnt ~^ biu_err_cnt) `ifdef OR1200_WB_RETRY | biu_rty & retry_cnt[`OR1200_WB_RETRY-1]; `else ; `endif endmodule
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