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[/] [openrisc/] [trunk/] [orpsocv2/] [rtl/] [verilog/] [dbg_if/] [dbg_wb.v] - Rev 701
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////////////////////////////////////////////////////////////////////// //// //// //// dbg_wb.v //// //// //// //// //// //// This file is part of the SoC Debug Interface. //// //// http://www.opencores.org/projects/DebugInterface/ //// //// //// //// Author(s): //// //// Igor Mohor (igorm@opencores.org) //// //// //// //// //// //// All additional information is avaliable in the README.txt //// //// file. //// //// //// ////////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2000 - 2004 Authors //// //// //// //// 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 //// //// //// ////////////////////////////////////////////////////////////////////// // synopsys translate_off `include "timescale.v" // synopsys translate_on `include "dbg_wb_defines.v" // Top module module dbg_wb( // JTAG signals tck_i, tdi_i, tdo_o, // TAP states shift_dr_i, pause_dr_i, update_dr_i, wishbone_ce_i, crc_match_i, crc_en_o, shift_crc_o, rst_i, // WISHBONE common signals wb_clk_i, // WISHBONE master interface wb_adr_o, wb_dat_o, wb_dat_i, wb_cyc_o, wb_stb_o, wb_sel_o, wb_we_o, wb_ack_i, wb_cab_o, wb_err_i, wb_cti_o, wb_bte_o ); // JTAG signals input tck_i; input tdi_i; output tdo_o; // TAP states input shift_dr_i; input pause_dr_i; input update_dr_i; input wishbone_ce_i; input crc_match_i; output crc_en_o; output shift_crc_o; input rst_i; // WISHBONE common signals input wb_clk_i; // WISHBONE master interface output [31:0] wb_adr_o; output [31:0] wb_dat_o; input [31:0] wb_dat_i; output wb_cyc_o; output wb_stb_o; output [3:0] wb_sel_o; output wb_we_o; input wb_ack_i; output wb_cab_o; input wb_err_i; output [2:0] wb_cti_o; output [1:0] wb_bte_o; reg wb_cyc_o; reg tdo_o; reg [31:0] wb_dat_tmp, wb_dat_dsff; reg [31:0] wb_adr_dsff; reg [3:0] wb_sel_dsff; reg wb_we_dsff; reg [`DBG_WB_DR_LEN -1 :0] dr; wire enable; wire cmd_cnt_en; reg [`DBG_WB_CMD_CNT_WIDTH -1:0] cmd_cnt; wire cmd_cnt_end; reg cmd_cnt_end_q; reg addr_len_cnt_en; reg [5:0] addr_len_cnt; wire addr_len_cnt_end; reg addr_len_cnt_end_q; reg crc_cnt_en; reg [`DBG_WB_CRC_CNT_WIDTH -1:0] crc_cnt; wire crc_cnt_end; reg crc_cnt_end_q; reg data_cnt_en; reg [`DBG_WB_DATA_CNT_WIDTH:0] data_cnt; reg [`DBG_WB_DATA_CNT_LIM_WIDTH:0] data_cnt_limit; wire data_cnt_end; reg data_cnt_end_q; reg crc_match_reg; reg [`DBG_WB_ACC_TYPE_LEN -1:0] acc_type; reg [`DBG_WB_ADR_LEN -1:0] adr; reg [`DBG_WB_LEN_LEN -1:0] len; reg [`DBG_WB_LEN_LEN:0] len_var; reg start_rd_tck; reg rd_tck_started; reg start_rd_csff; reg start_wb_rd; reg start_wb_rd_q; reg start_wr_tck; reg start_wr_csff; reg start_wb_wr; reg start_wb_wr_q; reg status_cnt_en; wire status_cnt_end; wire byte, half, long; reg byte_q, half_q, long_q; reg [`DBG_WB_STATUS_CNT_WIDTH -1:0] status_cnt; reg [`DBG_WB_STATUS_LEN -1:0] status; reg wb_error, wb_error_csff, wb_error_tck; reg wb_overrun, wb_overrun_csff, wb_overrun_tck; reg underrun_tck; reg busy_wb; reg busy_tck; reg wb_end; reg wb_end_rst; reg wb_end_rst_csff; reg wb_end_csff; reg wb_end_tck, wb_end_tck_q; reg busy_csff; reg latch_data; reg update_dr_csff, update_dr_wb; reg set_addr, set_addr_csff, set_addr_wb, set_addr_wb_q; wire [31:0] input_data; wire len_eq_0; wire crc_cnt_31; reg [1:0] ptr; reg [2:0] fifo_cnt; wire fifo_full; wire fifo_empty; reg [7:0] mem [0:3]; reg [2:0] mem_ptr_dsff; reg wishbone_ce_csff; reg mem_ptr_init; reg [`DBG_WB_CMD_LEN_INT -1: 0] curr_cmd; wire curr_cmd_go; reg curr_cmd_go_q; wire curr_cmd_wr_comm; wire curr_cmd_rd_comm; wire acc_type_read; wire acc_type_write; wire acc_type_8bit; wire acc_type_16bit; wire acc_type_32bit; assign enable = wishbone_ce_i & shift_dr_i; assign crc_en_o = enable & crc_cnt_end & (~status_cnt_end); assign shift_crc_o = enable & status_cnt_end; // Signals dbg module to shift out the CRC assign curr_cmd_go = (curr_cmd == `DBG_WB_GO) && cmd_cnt_end; assign curr_cmd_wr_comm = (curr_cmd == `DBG_WB_WR_COMM) && cmd_cnt_end; assign curr_cmd_rd_comm = (curr_cmd == `DBG_WB_RD_COMM) && cmd_cnt_end; assign acc_type_read = (acc_type == `DBG_WB_READ8 || acc_type == `DBG_WB_READ16 || acc_type == `DBG_WB_READ32); assign acc_type_write = (acc_type == `DBG_WB_WRITE8 || acc_type == `DBG_WB_WRITE16 || acc_type == `DBG_WB_WRITE32); assign acc_type_8bit = (acc_type == `DBG_WB_READ8 || acc_type == `DBG_WB_WRITE8); assign acc_type_16bit = (acc_type == `DBG_WB_READ16 || acc_type == `DBG_WB_WRITE16); assign acc_type_32bit = (acc_type == `DBG_WB_READ32 || acc_type == `DBG_WB_WRITE32); // Selecting where to take the data from always @ (posedge tck_i or posedge rst_i) begin if (rst_i) ptr <= 2'h0; else if (update_dr_i) ptr <= 2'h0; else if (curr_cmd_go && acc_type_read && crc_cnt_31) // first latch ptr <= ptr + 1'b1; else if (curr_cmd_go && acc_type_read && byte && (!byte_q)) ptr <= ptr + 1'd1; end // Shift register for shifting in and out the data always @ (posedge tck_i or posedge rst_i) begin if (rst_i) begin latch_data <= 1'b0; dr <= {`DBG_WB_DR_LEN{1'b0}}; end else if (curr_cmd_rd_comm && crc_cnt_31) // Latching data (from iternal regs) begin dr[`DBG_WB_ACC_TYPE_LEN + `DBG_WB_ADR_LEN + `DBG_WB_LEN_LEN -1:0] <= {acc_type, adr, len}; end else if (acc_type_read && curr_cmd_go && crc_cnt_31 && !busy_tck) // Latchind first data (from WB) begin dr[31:0] <= input_data[31:0]; latch_data <= 1'b1; end else if (acc_type_read && curr_cmd_go && crc_cnt_end && !busy_tck && wb_end_tck_q) begin // Had to wait for data from WB. dr[31:0] <= input_data[31:0]; latch_data <= 1'b1; end else if (acc_type_read && curr_cmd_go && crc_cnt_end && !busy_tck) // Latching data (from WB) begin if (acc_type == `DBG_WB_READ8) begin if(byte & (~byte_q)) begin case (ptr) // synthesis parallel_case 2'b00 : dr[31:24] <= input_data[31:24]; 2'b01 : dr[31:24] <= input_data[23:16]; 2'b10 : dr[31:24] <= input_data[15:8]; 2'b11 : dr[31:24] <= input_data[7:0]; endcase latch_data <= 1'b1; end else begin if (enable) // jb dr[31:24] <= {dr[30:24], 1'b0}; latch_data <= 1'b0; end end else if (acc_type == `DBG_WB_READ16) begin if(half & (~half_q)) begin if (ptr[1]) dr[31:16] <= input_data[15:0]; else dr[31:16] <= input_data[31:16]; latch_data <= 1'b1; end else begin if (enable) // jb dr[31:16] <= {dr[30:16], 1'b0}; latch_data <= 1'b0; end end else if (acc_type == `DBG_WB_READ32) begin if(long & (~long_q)) begin dr[31:0] <= input_data[31:0]; latch_data <= 1'b1; end else begin if (enable) // jb dr[31:0] <= {dr[30:0], 1'b0}; latch_data <= 1'b0; end end end else if (enable && (!addr_len_cnt_end)) begin dr <= {dr[`DBG_WB_DR_LEN -2:0], tdi_i}; end end assign cmd_cnt_en = enable & (~cmd_cnt_end); // Command counter always @ (posedge tck_i or posedge rst_i) begin if (rst_i) cmd_cnt <= {`DBG_WB_CMD_CNT_WIDTH{1'b0}}; else if (update_dr_i) cmd_cnt <= {`DBG_WB_CMD_CNT_WIDTH{1'b0}}; else if (cmd_cnt_en) cmd_cnt <= cmd_cnt + `DBG_WB_CMD_CNT_WIDTH'd1; end // Assigning current command always @ (posedge tck_i or posedge rst_i) begin if (rst_i) curr_cmd <= {`DBG_WB_CMD_LEN_INT{1'b0}}; else if (update_dr_i) curr_cmd <= {`DBG_WB_CMD_LEN_INT{1'b0}}; else if (cmd_cnt == (`DBG_WB_CMD_LEN_INT -1)) curr_cmd <= {dr[`DBG_WB_CMD_LEN_INT-2 :0], tdi_i}; end // Assigning current command always @ (posedge tck_i or posedge rst_i) begin if (rst_i) curr_cmd_go_q <= 1'b0; else curr_cmd_go_q <= curr_cmd_go; end always @ (enable or cmd_cnt_end or addr_len_cnt_end or curr_cmd_wr_comm or curr_cmd_rd_comm or crc_cnt_end) begin if (enable && (!addr_len_cnt_end)) begin if (cmd_cnt_end && curr_cmd_wr_comm) addr_len_cnt_en = 1'b1; else if (crc_cnt_end && curr_cmd_rd_comm) addr_len_cnt_en = 1'b1; else addr_len_cnt_en = 1'b0; end else addr_len_cnt_en = 1'b0; end // Address/length counter always @ (posedge tck_i or posedge rst_i) begin if (rst_i) addr_len_cnt <= 6'd0; else if (update_dr_i) addr_len_cnt <= 6'd0; else if (addr_len_cnt_en) addr_len_cnt <= addr_len_cnt + 6'd1; end always @ (enable or data_cnt_end or cmd_cnt_end or curr_cmd_go or acc_type_write or acc_type_read or crc_cnt_end) begin if (enable && (!data_cnt_end)) begin if (cmd_cnt_end && curr_cmd_go && acc_type_write) data_cnt_en = 1'b1; else if (crc_cnt_end && curr_cmd_go && acc_type_read) data_cnt_en = 1'b1; else data_cnt_en = 1'b0; end else data_cnt_en = 1'b0; end // Data counter always @ (posedge tck_i or posedge rst_i) begin if (rst_i) data_cnt <= {`DBG_WB_DATA_CNT_WIDTH+1{1'b0}}; else if (update_dr_i) data_cnt <= {`DBG_WB_DATA_CNT_WIDTH+1{1'b0}}; else if (data_cnt_en) data_cnt <= data_cnt + 1; end // Upper limit. Data counter counts until this value is reached. always @ (posedge tck_i or posedge rst_i) begin if (rst_i) data_cnt_limit <= {`DBG_WB_DATA_CNT_LIM_WIDTH+1{1'b0}}; else if (update_dr_i) data_cnt_limit <= len + 1; end always @ (enable or crc_cnt_end or curr_cmd_rd_comm or curr_cmd_wr_comm or curr_cmd_go or addr_len_cnt_end or data_cnt_end or acc_type_write or acc_type_read or cmd_cnt_end) begin if (enable && (!crc_cnt_end) && cmd_cnt_end) begin if (addr_len_cnt_end && curr_cmd_wr_comm) crc_cnt_en = 1'b1; else if (data_cnt_end && curr_cmd_go && acc_type_write) crc_cnt_en = 1'b1; else if (cmd_cnt_end && (curr_cmd_go && acc_type_read || curr_cmd_rd_comm)) crc_cnt_en = 1'b1; else crc_cnt_en = 1'b0; end else crc_cnt_en = 1'b0; end // crc counter always @ (posedge tck_i or posedge rst_i) begin if (rst_i) crc_cnt <= {`DBG_WB_CRC_CNT_WIDTH{1'b0}}; else if(crc_cnt_en) crc_cnt <= crc_cnt + 1; else if (update_dr_i) crc_cnt <= {`DBG_WB_CRC_CNT_WIDTH{1'b0}}; end assign cmd_cnt_end = cmd_cnt == `DBG_WB_CMD_LEN; assign addr_len_cnt_end = addr_len_cnt == `DBG_WB_DR_LEN; assign crc_cnt_end = crc_cnt == `DBG_WB_CRC_CNT_WIDTH'd32; assign crc_cnt_31 = crc_cnt == `DBG_WB_CRC_CNT_WIDTH'd31; assign data_cnt_end = (data_cnt == {data_cnt_limit, 3'b000}); always @ (posedge tck_i or posedge rst_i) begin if (rst_i) begin crc_cnt_end_q <= 1'b0; cmd_cnt_end_q <= 1'b0; data_cnt_end_q <= 1'b0; addr_len_cnt_end_q <= 1'b0; end else begin crc_cnt_end_q <= crc_cnt_end; cmd_cnt_end_q <= cmd_cnt_end; data_cnt_end_q <= data_cnt_end; addr_len_cnt_end_q <= addr_len_cnt_end; end end // Status counter is made of 4 serialy connected registers always @ (posedge tck_i or posedge rst_i) begin if (rst_i) status_cnt <= {`DBG_WB_STATUS_CNT_WIDTH{1'b0}}; else if (update_dr_i) status_cnt <= {`DBG_WB_STATUS_CNT_WIDTH{1'b0}}; else if (status_cnt_en) status_cnt <= status_cnt + `DBG_WB_STATUS_CNT_WIDTH'd1; end always @ (enable or status_cnt_end or crc_cnt_end or curr_cmd_rd_comm or curr_cmd_wr_comm or curr_cmd_go or acc_type_write or acc_type_read or data_cnt_end or addr_len_cnt_end) begin if (enable && (!status_cnt_end)) begin if (crc_cnt_end && curr_cmd_wr_comm) status_cnt_en = 1'b1; else if (crc_cnt_end && curr_cmd_go && acc_type_write) status_cnt_en = 1'b1; else if (data_cnt_end && curr_cmd_go && acc_type_read) status_cnt_en = 1'b1; else if (addr_len_cnt_end && curr_cmd_rd_comm) status_cnt_en = 1'b1; else status_cnt_en = 1'b0; end else status_cnt_en = 1'b0; end assign status_cnt_end = status_cnt == `DBG_WB_STATUS_LEN; // Latching acc_type, address and length always @ (posedge tck_i or posedge rst_i) begin if (rst_i) begin acc_type <= {`DBG_WB_ACC_TYPE_LEN{1'b0}}; adr <= {`DBG_WB_ADR_LEN{1'b0}}; len <= {`DBG_WB_LEN_LEN{1'b0}}; set_addr <= 1'b0; end else if(crc_cnt_end && (!crc_cnt_end_q) && crc_match_i && curr_cmd_wr_comm) begin acc_type <= dr[`DBG_WB_ACC_TYPE_LEN + `DBG_WB_ADR_LEN + `DBG_WB_LEN_LEN -1 : `DBG_WB_ADR_LEN + `DBG_WB_LEN_LEN]; adr <= dr[`DBG_WB_ADR_LEN + `DBG_WB_LEN_LEN -1 : `DBG_WB_LEN_LEN]; len <= dr[`DBG_WB_LEN_LEN -1:0]; set_addr <= 1'b1; end else if(wb_end_tck) // Writing back the address begin adr <= wb_adr_dsff; end else set_addr <= 1'b0; end always @ (posedge tck_i or posedge rst_i) begin if (rst_i) crc_match_reg <= 1'b0; else if(crc_cnt_end & (~crc_cnt_end_q)) crc_match_reg <= crc_match_i; end // Length counter always @ (posedge tck_i or posedge rst_i) begin if (rst_i) len_var <= {1'b0, {`DBG_WB_LEN_LEN{1'b0}}}; else if(update_dr_i) len_var <= len + 1; else if (start_rd_tck) begin case (acc_type) // synthesis parallel_case `DBG_WB_READ8 : if (len_var > 'd1) len_var <= len_var - 1; else len_var <= {1'b0, {`DBG_WB_LEN_LEN{1'b0}}}; `DBG_WB_READ16: if (len_var > 'd2) len_var <= len_var - 2; else len_var <= {1'b0, {`DBG_WB_LEN_LEN{1'b0}}}; `DBG_WB_READ32: if (len_var > 'd4) len_var <= len_var - 4; else len_var <= {1'b0, {`DBG_WB_LEN_LEN{1'b0}}}; default: len_var <= {1'bx, {`DBG_WB_LEN_LEN{1'bx}}}; endcase end end assign len_eq_0 = !(|len_var); assign byte = data_cnt[2:0] == 3'd7; assign half = data_cnt[3:0] == 4'd15; assign long = data_cnt[4:0] == 5'd31; always @ (posedge tck_i or posedge rst_i) begin if (rst_i) begin byte_q <= 1'b0; half_q <= 1'b0; long_q <= 1'b0; end else begin byte_q <= byte; half_q <= half; long_q <= long; end end // Start wishbone write cycle always @ (posedge tck_i or posedge rst_i) begin if (rst_i) begin start_wr_tck <= 1'b0; wb_dat_tmp <= 32'h0; end else if (curr_cmd_go && acc_type_write) begin case (acc_type) // synthesis parallel_case full_case `DBG_WB_WRITE8 : begin if (byte_q) begin start_wr_tck <= 1'b1; wb_dat_tmp <= {4{dr[7:0]}}; end else begin start_wr_tck <= 1'b0; end end `DBG_WB_WRITE16 : begin if (half_q) begin start_wr_tck <= 1'b1; wb_dat_tmp <= {2{dr[15:0]}}; end else begin start_wr_tck <= 1'b0; end end `DBG_WB_WRITE32 : begin if (long_q) begin start_wr_tck <= 1'b1; wb_dat_tmp <= dr[31:0]; end else begin start_wr_tck <= 1'b0; end end default: begin end endcase end else start_wr_tck <= 1'b0; end // wb_dat_o in WB clk domain always @ (posedge wb_clk_i) begin wb_dat_dsff <= wb_dat_tmp; end assign wb_dat_o = wb_dat_dsff; // Start wishbone read cycle always @ (posedge tck_i or posedge rst_i) begin if (rst_i) start_rd_tck <= 1'b0; else if (curr_cmd_go && (!curr_cmd_go_q) && acc_type_read) // First read after cmd is entered start_rd_tck <= 1'b1; else if ((!start_rd_tck) && curr_cmd_go && acc_type_read && (!len_eq_0) && (!fifo_full) && (!rd_tck_started)) start_rd_tck <= 1'b1; else start_rd_tck <= 1'b0; end always @ (posedge tck_i or posedge rst_i) begin if (rst_i) rd_tck_started <= 1'b0; else if (update_dr_i || wb_end_tck && (!wb_end_tck_q)) rd_tck_started <= 1'b0; else if (start_rd_tck) rd_tck_started <= 1'b1; end always @ (posedge wb_clk_i or posedge rst_i) begin if (rst_i) begin start_rd_csff <= 1'b0; start_wb_rd <= 1'b0; start_wb_rd_q <= 1'b0; start_wr_csff <= 1'b0; start_wb_wr <= 1'b0; start_wb_wr_q <= 1'b0; set_addr_csff <= 1'b0; set_addr_wb <= 1'b0; set_addr_wb_q <= 1'b0; end else begin start_rd_csff <= start_rd_tck; start_wb_rd <= start_rd_csff; start_wb_rd_q <= start_wb_rd; start_wr_csff <= start_wr_tck; start_wb_wr <= start_wr_csff; start_wb_wr_q <= start_wb_wr; set_addr_csff <= set_addr; set_addr_wb <= set_addr_csff; set_addr_wb_q <= set_addr_wb; end end // wb_cyc_o always @ (posedge wb_clk_i or posedge rst_i) begin if (rst_i) wb_cyc_o <= 1'b0; else if ((start_wb_wr && (!start_wb_wr_q)) || (start_wb_rd && (!start_wb_rd_q))) wb_cyc_o <= 1'b1; else if (wb_ack_i || wb_err_i) wb_cyc_o <= 1'b0; end // wb_adr_o logic always @ (posedge wb_clk_i or posedge rst_i) begin if (rst_i) wb_adr_dsff <= 32'd0; else if (set_addr_wb && (!set_addr_wb_q)) // Setting starting address wb_adr_dsff <= adr; else if (wb_ack_i) begin if ((acc_type == `DBG_WB_WRITE8) || (acc_type == `DBG_WB_READ8)) wb_adr_dsff <= wb_adr_dsff + 32'd1; else if ((acc_type == `DBG_WB_WRITE16) || (acc_type == `DBG_WB_READ16)) wb_adr_dsff <= wb_adr_dsff + 32'd2; else wb_adr_dsff <= wb_adr_dsff + 32'd4; end end assign wb_adr_o = wb_adr_dsff; // adr byte | short | long // 0 1000 1100 1111 // 1 0100 err err // 2 0010 0011 err // 3 0001 err err // wb_sel_o logic always @ (posedge wb_clk_i or posedge rst_i) begin if (rst_i) wb_sel_dsff[3:0] <= 4'h0; else if ((start_wb_wr && (!start_wb_wr_q))) begin case ({wb_adr_dsff[1:0], acc_type_8bit, acc_type_16bit, acc_type_32bit}) // synthesis parallel_case {2'd0, 3'b100} : wb_sel_dsff[3:0] <= 4'h8; {2'd0, 3'b010} : wb_sel_dsff[3:0] <= 4'hC; {2'd0, 3'b001} : wb_sel_dsff[3:0] <= 4'hF; {2'd1, 3'b100} : wb_sel_dsff[3:0] <= 4'h4; {2'd2, 3'b100} : wb_sel_dsff[3:0] <= 4'h2; {2'd2, 3'b010} : wb_sel_dsff[3:0] <= 4'h3; {2'd3, 3'b100} : wb_sel_dsff[3:0] <= 4'h1; default: wb_sel_dsff[3:0] <= 4'hx; endcase end end assign wb_sel_o = wb_sel_dsff; /* always @ (posedge wb_clk_i) begin wb_we_dsff <= curr_cmd_go && acc_type_write; end */ always @ (posedge wb_clk_i or posedge rst_i) begin if (rst_i) wb_we_dsff <= 1'b0; else if ((start_wb_wr && (!start_wb_wr_q))) wb_we_dsff <= 1'b1; else if (wb_ack_i || wb_err_i) wb_we_dsff <= 1'b0; end assign wb_we_o = wb_we_dsff; assign wb_cab_o = 1'b0; assign wb_stb_o = wb_cyc_o; assign wb_cti_o = 3'h0; // always performing single access assign wb_bte_o = 2'h0; // always performing single access // Logic for detecting end of transaction always @ (posedge wb_clk_i or posedge rst_i) begin if (rst_i) wb_end <= 1'b0; else if (wb_ack_i || wb_err_i) wb_end <= 1'b1; else if (wb_end_rst) wb_end <= 1'b0; end always @ (posedge tck_i or posedge rst_i) begin if (rst_i) begin wb_end_csff <= 1'b0; wb_end_tck <= 1'b0; wb_end_tck_q <= 1'b0; end else begin wb_end_csff <= wb_end; wb_end_tck <= wb_end_csff; wb_end_tck_q <= wb_end_tck; end end always @ (posedge wb_clk_i or posedge rst_i) begin if (rst_i) begin wb_end_rst_csff <= 1'b0; wb_end_rst <= 1'b0; end else begin wb_end_rst_csff <= wb_end_tck; wb_end_rst <= wb_end_rst_csff; end end always @ (posedge wb_clk_i or posedge rst_i) begin if (rst_i) busy_wb <= 1'b0; else if (wb_end_rst) busy_wb <= 1'b0; else if (wb_cyc_o) busy_wb <= 1'b1; end always @ (posedge tck_i or posedge rst_i) begin if (rst_i) begin busy_csff <= 1'b0; busy_tck <= 1'b0; update_dr_csff <= 1'b0; update_dr_wb <= 1'b0; end else begin busy_csff <= busy_wb; busy_tck <= busy_csff; update_dr_csff <= update_dr_i; update_dr_wb <= update_dr_csff; end end // Detecting WB error always @ (posedge wb_clk_i or posedge rst_i) begin if (rst_i) wb_error <= 1'b0; else if(wb_err_i) wb_error <= 1'b1; else if(update_dr_wb) // error remains active until update_dr arrives wb_error <= 1'b0; end // Detecting overrun when write operation. always @ (posedge wb_clk_i or posedge rst_i) begin if (rst_i) wb_overrun <= 1'b0; else if(start_wb_wr && (!start_wb_wr_q) && wb_cyc_o) wb_overrun <= 1'b1; else if(update_dr_wb) // error remains active until update_dr arrives wb_overrun <= 1'b0; end // Detecting underrun when read operation always @ (posedge tck_i or posedge rst_i) begin if (rst_i) underrun_tck <= 1'b0; else if(latch_data && fifo_empty && (!data_cnt_end)) underrun_tck <= 1'b1; else if(update_dr_i) // error remains active until update_dr arrives underrun_tck <= 1'b0; end always @ (posedge tck_i or posedge rst_i) begin if (rst_i) begin wb_error_csff <= 1'b0; wb_error_tck <= 1'b0; wb_overrun_csff <= 1'b0; wb_overrun_tck <= 1'b0; end else begin wb_error_csff <= wb_error; wb_error_tck <= wb_error_csff; wb_overrun_csff <= wb_overrun; wb_overrun_tck <= wb_overrun_csff; end end always @ (posedge wb_clk_i or posedge rst_i) begin if (rst_i) begin wishbone_ce_csff <= 1'b0; mem_ptr_init <= 1'b0; end else begin wishbone_ce_csff <= wishbone_ce_i; mem_ptr_init <= ~wishbone_ce_csff; end end // Logic for latching data that is read from wishbone always @ (posedge wb_clk_i or posedge rst_i) begin if (rst_i) mem_ptr_dsff <= 3'h0; else if(mem_ptr_init) mem_ptr_dsff <= 3'h0; else if (wb_ack_i) begin if (acc_type == `DBG_WB_READ8) mem_ptr_dsff <= mem_ptr_dsff + 3'd1; else if (acc_type == `DBG_WB_READ16) mem_ptr_dsff <= mem_ptr_dsff + 3'd2; end end // Logic for latching data that is read from wishbone always @ (posedge wb_clk_i) begin if (wb_ack_i) begin case (wb_sel_dsff) // synthesis parallel_case 4'b1000 : mem[mem_ptr_dsff[1:0]] <= wb_dat_i[31:24];// byte 4'b0100 : mem[mem_ptr_dsff[1:0]] <= wb_dat_i[23:16];// byte 4'b0010 : mem[mem_ptr_dsff[1:0]] <= wb_dat_i[15:08];// byte 4'b0001 : mem[mem_ptr_dsff[1:0]] <= wb_dat_i[07:00];// byte 4'b1100 : // half begin mem[mem_ptr_dsff[1:0]] <= wb_dat_i[31:24]; mem[mem_ptr_dsff[1:0]+1'b1] <= wb_dat_i[23:16]; end 4'b0011 : // half begin mem[mem_ptr_dsff[1:0]] <= wb_dat_i[15:08]; mem[mem_ptr_dsff[1:0]+1'b1] <= wb_dat_i[07:00]; end /*4'b1111 : // long*/ default: begin mem[0] <= wb_dat_i[31:24]; mem[1] <= wb_dat_i[23:16]; mem[2] <= wb_dat_i[15:08]; mem[3] <= wb_dat_i[07:00]; end /* default : // long begin mem[0] <= 8'hxx; mem[1] <= 8'hxx; mem[2] <= 8'hxx; mem[3] <= 8'hxx; end */ endcase end end assign input_data = {mem[0], mem[1], mem[2], mem[3]}; // Fifo counter and empty/full detection always @ (posedge tck_i or posedge rst_i) begin if (rst_i) fifo_cnt <= 3'h0; else if (update_dr_i) fifo_cnt <= 3'h0; else if (wb_end_tck && (!wb_end_tck_q) && (!latch_data) && (!fifo_full)) // incrementing begin case (acc_type) // synthesis parallel_case `DBG_WB_READ8 : fifo_cnt <= fifo_cnt + 3'd1; `DBG_WB_READ16: fifo_cnt <= fifo_cnt + 3'd2; `DBG_WB_READ32: fifo_cnt <= fifo_cnt + 3'd4; default: fifo_cnt <= 3'bxxx; endcase end else if (!(wb_end_tck && (!wb_end_tck_q)) && latch_data && (!fifo_empty)) // decrementing begin case (acc_type) // synthesis parallel_case `DBG_WB_READ8 : fifo_cnt <= fifo_cnt - 3'd1; `DBG_WB_READ16: fifo_cnt <= fifo_cnt - 3'd2; `DBG_WB_READ32: fifo_cnt <= fifo_cnt - 3'd4; default: fifo_cnt <= 3'bxxx; endcase end end assign fifo_full = fifo_cnt == 3'h4; assign fifo_empty = fifo_cnt == 3'h0; // TDO multiplexer always @ (pause_dr_i or busy_tck or crc_cnt_end or crc_cnt_end_q or curr_cmd_wr_comm or curr_cmd_rd_comm or curr_cmd_go or acc_type_write or acc_type_read or crc_match_i or data_cnt_end or dr or data_cnt_end_q or crc_match_reg or status_cnt_en or status or addr_len_cnt_end or addr_len_cnt_end_q) begin if (pause_dr_i) begin tdo_o = busy_tck; end else if (crc_cnt_end && (!crc_cnt_end_q) && (curr_cmd_wr_comm || curr_cmd_go && acc_type_write )) begin tdo_o = ~crc_match_i; end else if (curr_cmd_go && acc_type_read && crc_cnt_end && (!data_cnt_end)) begin tdo_o = dr[31]; end else if (curr_cmd_go && acc_type_read && data_cnt_end && (!data_cnt_end_q)) begin tdo_o = ~crc_match_reg; end else if (curr_cmd_rd_comm && addr_len_cnt_end && (!addr_len_cnt_end_q)) begin tdo_o = ~crc_match_reg; end else if (curr_cmd_rd_comm && crc_cnt_end && (!addr_len_cnt_end)) begin tdo_o = dr[`DBG_WB_ACC_TYPE_LEN + `DBG_WB_ADR_LEN + `DBG_WB_LEN_LEN -1]; end else if (status_cnt_en) begin tdo_o = status[3]; end else begin tdo_o = 1'b0; end end // Status register always @ (posedge tck_i or posedge rst_i) begin if (rst_i) begin status <= {`DBG_WB_STATUS_LEN{1'b0}}; end else if(crc_cnt_end && (!crc_cnt_end_q) && (!(curr_cmd_go && acc_type_read))) begin status <= {1'b0, wb_error_tck, wb_overrun_tck, crc_match_i}; end else if (data_cnt_end && (!data_cnt_end_q) && curr_cmd_go && acc_type_read) begin status <= {1'b0, wb_error_tck, underrun_tck, crc_match_reg}; end else if (addr_len_cnt_end && (!addr_len_cnt_end) && curr_cmd_rd_comm) begin status <= {1'b0, 1'b0, 1'b0, crc_match_reg}; end else if (shift_dr_i && (!status_cnt_end)) begin status <= {status[`DBG_WB_STATUS_LEN -2:0], status[`DBG_WB_STATUS_LEN -1]}; end end // Following status is shifted out (MSB first): // 3. bit: 1 if crc is OK, else 0 // 2. bit: 1'b0 // 1. bit: 1 if WB error occured, else 0 // 0. bit: 1 if overrun occured during write (data couldn't be written fast enough) // or underrun occured during read (data couldn't be read fast enough) endmodule
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