abstractaccelerator/design/dbg/dbg.sv

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// SPDX-License-Identifier: Apache-2.0
// Copyright 2019 Western Digital Corporation or its affiliates.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//********************************************************************************
// $Id$
//
// Function: Top level SWERV core file to control the debug mode
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// Comments: Responsible to put the rest of the core in quiesce mode,
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// Send the commands/address. sends WrData and Recieve read Data.
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// And then Resume the core to do the normal mode
// Author :
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//********************************************************************************
module dbg (
// outputs to the core for command and data interface
output logic [31:0] dbg_cmd_addr,
output logic [31:0] dbg_cmd_wrdata,
output logic dbg_cmd_valid,
output logic dbg_cmd_write, // 1: write command, 0: read_command
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output logic [1:0] dbg_cmd_type, // 0:gpr 1:csr 2: memory
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output logic [1:0] dbg_cmd_size, // size of the abstract mem access debug command
output logic dbg_core_rst_l, // core reset from dm
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// inputs back from the core/dec
input logic [31:0] core_dbg_rddata,
input logic core_dbg_cmd_done, // This will be treated like a valid signal
input logic core_dbg_cmd_fail, // Exception during command run
// Signals to dma to get a bubble
output logic dbg_dma_bubble, // Debug needs a bubble to send a valid
input logic dma_dbg_ready, // DMA is ready to accept debug request
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// interface with the rest of the core to halt/resume handshaking
output logic dbg_halt_req, // This is a pulse
output logic dbg_resume_req, // Debug sends a resume requests. Pulse
input logic dec_tlu_debug_mode, // Core is in debug mode
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input logic dec_tlu_dbg_halted, // The core has finished the queiscing sequence. Core is halted now
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input logic dec_tlu_mpc_halted_only, // Only halted due to MPC
input logic dec_tlu_resume_ack, // core sends back an ack for the resume (pulse)
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// inputs from the JTAG
input logic dmi_reg_en, // read or write
input logic [6:0] dmi_reg_addr, // address of DM register
input logic dmi_reg_wr_en, // write instruction
input logic [31:0] dmi_reg_wdata, // write data
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// output
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output logic [31:0] dmi_reg_rdata, // read data
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// output logic dmi_reg_ack,
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// AXI signals
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// AXI Write Channels
output logic sb_axi_awvalid,
input logic sb_axi_awready,
output logic [`RV_SB_BUS_TAG-1:0] sb_axi_awid,
output logic [31:0] sb_axi_awaddr,
output logic [3:0] sb_axi_awregion,
output logic [7:0] sb_axi_awlen,
output logic [2:0] sb_axi_awsize,
output logic [1:0] sb_axi_awburst,
output logic sb_axi_awlock,
output logic [3:0] sb_axi_awcache,
output logic [2:0] sb_axi_awprot,
output logic [3:0] sb_axi_awqos,
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output logic sb_axi_wvalid,
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input logic sb_axi_wready,
output logic [63:0] sb_axi_wdata,
output logic [7:0] sb_axi_wstrb,
output logic sb_axi_wlast,
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input logic sb_axi_bvalid,
output logic sb_axi_bready,
input logic [1:0] sb_axi_bresp,
input logic [`RV_SB_BUS_TAG-1:0] sb_axi_bid,
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// AXI Read Channels
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output logic sb_axi_arvalid,
input logic sb_axi_arready,
output logic [`RV_SB_BUS_TAG-1:0] sb_axi_arid,
output logic [31:0] sb_axi_araddr,
output logic [3:0] sb_axi_arregion,
output logic [7:0] sb_axi_arlen,
output logic [2:0] sb_axi_arsize,
output logic [1:0] sb_axi_arburst,
output logic sb_axi_arlock,
output logic [3:0] sb_axi_arcache,
output logic [2:0] sb_axi_arprot,
output logic [3:0] sb_axi_arqos,
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input logic sb_axi_rvalid,
output logic sb_axi_rready,
input logic [`RV_SB_BUS_TAG-1:0] sb_axi_rid,
input logic [63:0] sb_axi_rdata,
input logic [1:0] sb_axi_rresp,
input logic sb_axi_rlast,
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input logic dbg_bus_clk_en,
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// general inputs
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input logic clk,
input logic free_clk,
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input logic rst_l, // This includes both top rst and dbg rst
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input logic dbg_rst_l,
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input logic clk_override,
input logic scan_mode
);
`include "global.h"
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typedef enum logic [3:0] {IDLE=4'h0, HALTING=4'h1, HALTED=4'h2, CORE_CMD_START=4'h3, CORE_CMD_WAIT=4'h4, SB_CMD_START=4'h5, SB_CMD_SEND=4'h6, SB_CMD_RESP=4'h7, CMD_DONE=4'h8, RESUMING=4'h9} state_t;
typedef enum logic [3:0] {SBIDLE=4'h0, WAIT_RD=4'h1, WAIT_WR=4'h2, CMD_RD=4'h3, CMD_WR=4'h4, CMD_WR_ADDR=4'h5, CMD_WR_DATA=4'h6, RSP_RD=4'h7, RSP_WR=4'h8, DONE=4'h9} sb_state_t;
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`ifdef RV_ICCM_ENABLE
localparam ICCM_ENABLE = 1'b1;
`else
localparam ICCM_ENABLE = 1'b0;
`endif
`ifdef RV_DCCM_ENABLE
localparam DCCM_ENABLE = 1'b1;
`else
localparam DCCM_ENABLE = 1'b0;
`endif
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state_t dbg_state;
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state_t dbg_nxtstate;
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logic dbg_state_en;
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// these are the registers that the debug module implements
logic [31:0] dmstatus_reg; // [26:24]-dmerr, [17:16]-resume ack, [9:8]-halted, [3:0]-version
logic [31:0] dmcontrol_reg; // dmcontrol register has only 6 bits implemented. 31: haltreq, 30: resumereq, 29: haltreset, 28: ackhavereset, 1: ndmreset, 0: dmactive.
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logic [31:0] command_reg;
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logic [31:0] abstractcs_reg; // bits implemted are [12] - busy and [10:8]= command error
logic [31:0] haltsum0_reg;
logic [31:0] data0_reg;
logic [31:0] data1_reg;
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// data 0
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logic [31:0] data0_din;
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logic data0_reg_wren, data0_reg_wren0, data0_reg_wren1, data0_reg_wren2;
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// data 1
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logic [31:0] data1_din;
logic data1_reg_wren, data1_reg_wren0, data1_reg_wren1;
// abstractcs
logic abstractcs_busy_wren;
logic abstractcs_busy_din;
logic [2:0] abstractcs_error_din;
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logic abstractcs_error_sel0, abstractcs_error_sel1, abstractcs_error_sel2, abstractcs_error_sel3, abstractcs_error_sel4, abstractcs_error_sel5, abstractcs_error_sel6;
logic dbg_sb_bus_error;
// abstractauto
logic abstractauto_reg_wren;
logic [1:0] abstractauto_reg;
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// dmstatus
//logic dmstatus_wren;
logic dmstatus_dmerr_wren;
logic dmstatus_resumeack_wren;
logic dmstatus_resumeack_din;
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logic dmstatus_haveresetn_wren;
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logic dmstatus_resumeack;
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logic dmstatus_unavail;
logic dmstatus_running;
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logic dmstatus_halted;
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logic dmstatus_havereset, dmstatus_haveresetn;
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// dmcontrol
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logic resumereq;
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logic dmcontrol_wren, dmcontrol_wren_Q;
// command
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logic execute_command_ns, execute_command;
logic command_wren, command_regno_wren;
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logic command_transfer_din;
logic command_postexec_din;
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logic [31:0] command_din;
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logic [3:0] dbg_cmd_addr_incr;
logic [31:0] dbg_cmd_curr_addr;
logic [31:0] dbg_cmd_next_addr;
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// needed to send the read data back for dmi reads
logic [31:0] dmi_reg_rdata_din;
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sb_state_t sb_state;
sb_state_t sb_nxtstate;
logic sb_state_en;
//System bus section
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logic sbcs_wren;
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logic sbcs_sbbusy_wren;
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logic sbcs_sbbusy_din;
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logic sbcs_sbbusyerror_wren;
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logic sbcs_sbbusyerror_din;
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logic sbcs_sberror_wren;
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logic [2:0] sbcs_sberror_din;
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logic sbcs_unaligned;
logic sbcs_illegal_size;
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logic [19:15] sbcs_reg_int;
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// data
logic sbdata0_reg_wren0;
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logic sbdata0_reg_wren1;
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logic sbdata0_reg_wren;
logic [31:0] sbdata0_din;
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logic sbdata1_reg_wren0;
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logic sbdata1_reg_wren1;
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logic sbdata1_reg_wren;
logic [31:0] sbdata1_din;
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logic sbaddress0_reg_wren0;
logic sbaddress0_reg_wren1;
logic sbaddress0_reg_wren;
logic [31:0] sbaddress0_reg_din;
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logic [3:0] sbaddress0_incr;
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logic sbreadonaddr_access;
logic sbreadondata_access;
logic sbdata0wr_access;
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logic sb_abmem_cmd_done_in, sb_abmem_data_done_in;
logic sb_abmem_cmd_done_en, sb_abmem_data_done_en;
logic sb_abmem_cmd_done, sb_abmem_data_done;
logic [31:0] abmem_addr;
logic abmem_addr_in_dccm_region, abmem_addr_in_iccm_region, abmem_addr_in_pic_region;
logic abmem_addr_core_local;
logic abmem_addr_external;
logic sb_cmd_pending, sb_abmem_cmd_pending;
logic sb_abmem_cmd_arvalid, sb_abmem_cmd_awvalid, sb_abmem_cmd_wvalid;
logic sb_abmem_read_pend;
logic sb_abmem_cmd_write;
logic [2:0] sb_abmem_cmd_size;
logic [31:0] sb_abmem_cmd_addr;
logic [31:0] sb_abmem_cmd_wdata;
logic sb_cmd_awvalid, sb_cmd_wvalid, sb_cmd_arvalid;
logic sb_read_pend;
logic [2:0] sb_cmd_size;
logic [31:0] sb_cmd_addr;
logic [63:0] sb_cmd_wdata;
logic [31:0] sb_axi_addr;
logic [63:0] sb_axi_wrdata;
logic [2:0] sb_axi_size;
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logic sb_axi_awvalid_q, sb_axi_awready_q;
logic sb_axi_wvalid_q, sb_axi_wready_q;
logic sb_axi_arvalid_q, sb_axi_arready_q;
logic sb_axi_bvalid_q, sb_axi_bready_q;
logic sb_axi_rvalid_q, sb_axi_rready_q;
logic [1:0] sb_axi_bresp_q, sb_axi_rresp_q;
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logic [63:0] sb_bus_rdata;
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//registers
logic [31:0] sbcs_reg;
logic [31:0] sbaddress0_reg;
logic [31:0] sbdata0_reg;
logic [31:0] sbdata1_reg;
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logic dbg_dm_rst_l;
//clken
logic dbg_free_clken;
logic dbg_free_clk;
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logic sb_free_clken;
logic sb_free_clk;
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logic bus_clken;
logic bus_clk;
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// clocking
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// used for the abstract commands.
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assign dbg_free_clken = dmi_reg_en | execute_command | (dbg_state != IDLE) | dbg_state_en | dec_tlu_dbg_halted | clk_override;
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// used for the system bus
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assign sb_free_clken = dmi_reg_en | execute_command | sb_state_en | (sb_state != SBIDLE) | clk_override;
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assign bus_clken = (sb_axi_awvalid | sb_axi_wvalid | sb_axi_arvalid | sb_axi_bvalid | sb_axi_rvalid | clk_override) & dbg_bus_clk_en;
rvoclkhdr dbg_free_cgc (.en(dbg_free_clken), .l1clk(dbg_free_clk), .*);
rvoclkhdr sb_free_cgc (.en(sb_free_clken), .l1clk(sb_free_clk), .*);
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`ifndef RV_FPGA_OPTIMIZE
rvclkhdr bus_cgc (.en(bus_clken), .l1clk(bus_clk), .*); // ifndef FPGA_OPTIMIZE
`endif
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// end clocking section
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// Reset logic
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assign dbg_dm_rst_l = dbg_rst_l & (dmcontrol_reg[0] | scan_mode);
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assign dbg_core_rst_l = ~dmcontrol_reg[1] | scan_mode;
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// system bus register
// sbcs[31:29], sbcs - [22]:sbbusyerror, [21]: sbbusy, [20]:sbreadonaddr, [19:17]:sbaccess, [16]:sbautoincrement, [15]:sbreadondata, [14:12]:sberror, sbsize=32, 128=0, 64/32/16/8 are legal
assign sbcs_reg[31:29] = 3'b1;
assign sbcs_reg[28:23] = '0;
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assign sbcs_reg[19:15] = {sbcs_reg_int[19], ~sbcs_reg_int[18], sbcs_reg_int[17:15]};
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assign sbcs_reg[11:5] = 7'h20;
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assign sbcs_reg[4:0] = 5'b01111;
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assign sbcs_wren = (dmi_reg_addr == 7'h38) & dmi_reg_en & dmi_reg_wr_en & (sb_state == SBIDLE); // & (sbcs_reg[14:12] == 3'b000);
assign sbcs_sbbusyerror_wren = (sbcs_wren & dmi_reg_wdata[22]) |
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(sbcs_reg[21] & dmi_reg_en & ((dmi_reg_wr_en & (dmi_reg_addr == 7'h39)) | (dmi_reg_addr == 7'h3c) | (dmi_reg_addr == 7'h3d)));
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assign sbcs_sbbusyerror_din = ~(sbcs_wren & dmi_reg_wdata[22]); // Clear when writing one
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rvdffs #(1) sbcs_sbbusyerror_reg (.din(sbcs_sbbusyerror_din), .dout(sbcs_reg[22]), .en(sbcs_sbbusyerror_wren), .rst_l(dbg_dm_rst_l), .clk(sb_free_clk));
rvdffs #(1) sbcs_sbbusy_reg (.din(sbcs_sbbusy_din), .dout(sbcs_reg[21]), .en(sbcs_sbbusy_wren), .rst_l(dbg_dm_rst_l), .clk(sb_free_clk));
rvdffs #(1) sbcs_sbreadonaddr_reg (.din(dmi_reg_wdata[20]), .dout(sbcs_reg[20]), .en(sbcs_wren), .rst_l(dbg_dm_rst_l), .clk(sb_free_clk));
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rvdffs #(5) sbcs_misc_reg (.din({dmi_reg_wdata[19],~dmi_reg_wdata[18],dmi_reg_wdata[17:15]}),
.dout(sbcs_reg_int[19:15]), .en(sbcs_wren), .rst_l(dbg_dm_rst_l), .clk(sb_free_clk));
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rvdffs #(3) sbcs_error_reg (.din(sbcs_sberror_din[2:0]), .dout(sbcs_reg[14:12]), .en(sbcs_sberror_wren), .rst_l(dbg_dm_rst_l), .clk(sb_free_clk));
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assign sbcs_unaligned = ((sbcs_reg[19:17] == 3'b001) & sbaddress0_reg[0]) |
((sbcs_reg[19:17] == 3'b010) & (|sbaddress0_reg[1:0])) |
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((sbcs_reg[19:17] == 3'b011) & (|sbaddress0_reg[2:0]));
assign sbcs_illegal_size = sbcs_reg[19]; // Anything bigger than 64 bits is illegal
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assign sbaddress0_incr[3:0] = ({4{(sbcs_reg[19:17] == 3'h0)}} & 4'b0001) |
({4{(sbcs_reg[19:17] == 3'h1)}} & 4'b0010) |
({4{(sbcs_reg[19:17] == 3'h2)}} & 4'b0100) |
({4{(sbcs_reg[19:17] == 3'h3)}} & 4'b1000);
// sbdata
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//assign sbdata0_reg_wren0 = dmi_reg_en & dmi_reg_wr_en & (dmi_reg_addr == 32'h3c);
assign sbdata0_reg_wren0 = dmi_reg_en & dmi_reg_wr_en & (dmi_reg_addr == 7'h3c); // write data only when single read is 0
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assign sbdata0_reg_wren1 = (sb_state == RSP_RD) & sb_state_en & ~sbcs_sberror_wren;
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assign sbdata0_reg_wren = sbdata0_reg_wren0 | sbdata0_reg_wren1;
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assign sbdata1_reg_wren0 = dmi_reg_en & dmi_reg_wr_en & (dmi_reg_addr == 7'h3d); // write data only when single read is 0;
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assign sbdata1_reg_wren1 = (sb_state == RSP_RD) & sb_state_en & ~sbcs_sberror_wren;
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assign sbdata1_reg_wren = sbdata1_reg_wren0 | sbdata1_reg_wren1;
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assign sbdata0_din[31:0] = ({32{sbdata0_reg_wren0}} & dmi_reg_wdata[31:0]) |
({32{sbdata0_reg_wren1}} & sb_bus_rdata[31:0]);
assign sbdata1_din[31:0] = ({32{sbdata1_reg_wren0}} & dmi_reg_wdata[31:0]) |
({32{sbdata1_reg_wren1}} & sb_bus_rdata[63:32]);
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rvdffe #(32) dbg_sbdata0_reg (.*, .din(sbdata0_din[31:0]), .dout(sbdata0_reg[31:0]), .en(sbdata0_reg_wren), .rst_l(dbg_dm_rst_l));
rvdffe #(32) dbg_sbdata1_reg (.*, .din(sbdata1_din[31:0]), .dout(sbdata1_reg[31:0]), .en(sbdata1_reg_wren), .rst_l(dbg_dm_rst_l));
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// sbaddress
assign sbaddress0_reg_wren0 = dmi_reg_en & dmi_reg_wr_en & (dmi_reg_addr == 7'h39);
assign sbaddress0_reg_wren = sbaddress0_reg_wren0 | sbaddress0_reg_wren1;
assign sbaddress0_reg_din[31:0]= ({32{sbaddress0_reg_wren0}} & dmi_reg_wdata[31:0]) |
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({32{sbaddress0_reg_wren1}} & (sbaddress0_reg[31:0] + {28'b0,sbaddress0_incr[3:0]}));
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rvdffe #(32) dbg_sbaddress0_reg (.*, .din(sbaddress0_reg_din[31:0]), .dout(sbaddress0_reg[31:0]), .en(sbaddress0_reg_wren), .rst_l(dbg_dm_rst_l));
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assign sbreadonaddr_access = dmi_reg_en & dmi_reg_wr_en & (dmi_reg_addr == 7'h39) & sbcs_reg[20]; // if readonaddr is set the next command will start upon writing of addr0
assign sbreadondata_access = dmi_reg_en & ~dmi_reg_wr_en & (dmi_reg_addr == 7'h3c) & sbcs_reg[15]; // if readondata is set the next command will start upon reading of data0
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assign sbdata0wr_access = dmi_reg_en & dmi_reg_wr_en & (dmi_reg_addr == 7'h3c); // write to sbdata0 will start write command to system bus
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// memory mapped registers
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// dmcontrol register has only 6 bits implemented. 31: haltreq, 30: resumereq, 28: ackhavereset, 1: ndmreset, 0: dmactive.
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// rest all the bits are zeroed out
// dmactive flop is reset based on core rst_l, all other flops use dm_rst_l
assign dmcontrol_wren = (dmi_reg_addr == 7'h10) & dmi_reg_en & dmi_reg_wr_en;
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assign dmcontrol_reg[29] = '0;
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assign dmcontrol_reg[27:2] = '0;
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assign resumereq = dmcontrol_reg[30] & ~dmcontrol_reg[31] & dmcontrol_wren_Q;
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rvdffs #(4) dmcontrolff (.din({dmi_reg_wdata[31:30],dmi_reg_wdata[28],dmi_reg_wdata[1]}), .dout({dmcontrol_reg[31:30], dmcontrol_reg[28], dmcontrol_reg[1]}), .en(dmcontrol_wren), .rst_l(dbg_dm_rst_l), .clk(dbg_free_clk));
rvdffs #(1) dmcontrol_dmactive_ff (.din(dmi_reg_wdata[0]), .dout(dmcontrol_reg[0]), .en(dmcontrol_wren), .rst_l(dbg_rst_l), .clk(dbg_free_clk));
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rvdff #(1) dmcontrol_wrenff(.din(dmcontrol_wren), .dout(dmcontrol_wren_Q), .rst_l(dbg_dm_rst_l), .clk(dbg_free_clk));
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// dmstatus register bits that are implemented
// [19:18]-havereset,[17:16]-resume ack, [9:8]-halted, [3:0]-version
// rest all the bits are zeroed out
assign dmstatus_reg[31:20] = '0;
assign dmstatus_reg[19:18] = {2{dmstatus_havereset}};
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assign dmstatus_reg[15:14] = '0;
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assign dmstatus_reg[7] = '1;
assign dmstatus_reg[6:4] = '0;
assign dmstatus_reg[17:16] = {2{dmstatus_resumeack}};
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assign dmstatus_reg[13:12] = {2{dmstatus_unavail}};
assign dmstatus_reg[11:10] = {2{dmstatus_running}};
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assign dmstatus_reg[9:8] = {2{dmstatus_halted}};
assign dmstatus_reg[3:0] = 4'h2;
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assign dmstatus_resumeack_wren = ((dbg_state == RESUMING) & dec_tlu_resume_ack) | (dmstatus_resumeack & resumereq & dmstatus_halted);
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assign dmstatus_resumeack_din = (dbg_state == RESUMING) & dec_tlu_resume_ack;
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assign dmstatus_haveresetn_wren = (dmi_reg_addr == 7'h10) & dmi_reg_wdata[28] & dmi_reg_en & dmi_reg_wr_en & dmcontrol_reg[0]; // clear the havereset
assign dmstatus_havereset = ~dmstatus_haveresetn;
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assign dmstatus_unavail = dmcontrol_reg[1] | ~rst_l;
assign dmstatus_running = ~(dmstatus_unavail | dmstatus_halted);
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rvdffs #(1) dmstatus_resumeack_reg (.din(dmstatus_resumeack_din), .dout(dmstatus_resumeack), .en(dmstatus_resumeack_wren), .rst_l(dbg_dm_rst_l), .clk(dbg_free_clk));
rvdff #(1) dmstatus_halted_reg (.din(dec_tlu_dbg_halted & ~dec_tlu_mpc_halted_only), .dout(dmstatus_halted), .rst_l(dbg_dm_rst_l), .clk(dbg_free_clk));
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rvdffs #(1) dmstatus_haveresetn_reg (.din(1'b1), .dout(dmstatus_haveresetn), .en(dmstatus_haveresetn_wren), .rst_l(rst_l), .clk(dbg_free_clk));
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// haltsum0 register
assign haltsum0_reg[31:1] = '0;
assign haltsum0_reg[0] = dmstatus_halted;
// abstractcs register
// bits implemted are [12] - busy and [10:8]= command error
assign abstractcs_reg[31:13] = '0;
assign abstractcs_reg[11] = '0;
assign abstractcs_reg[7:4] = '0;
assign abstractcs_reg[3:0] = 4'h2; // One data register
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assign abstractcs_error_sel0 = abstractcs_reg[12] & ~(|abstractcs_reg[10:8]) & dmi_reg_en & ((dmi_reg_wr_en & ((dmi_reg_addr == 7'h16) | (dmi_reg_addr == 7'h17)) | (dmi_reg_addr == 7'h18)) |
(dmi_reg_addr == 7'h4) | (dmi_reg_addr == 7'h5));
assign abstractcs_error_sel1 = execute_command & ~(|abstractcs_reg[10:8]) &
((~((command_reg[31:24] == 8'b0) | (command_reg[31:24] == 8'h2))) | // Illegal command
(((command_reg[22:20] == 3'b011) | (command_reg[22])) & (command_reg[31:24] == 8'h2)) | // Illegal abstract memory size (can't be DW or higher)
((command_reg[22:20] != 3'b010) & ((command_reg[31:24] == 8'h0) & command_reg[17])) | // Illegal abstract reg size
((command_reg[31:24] == 8'h0) & command_reg[18])); //postexec for abstract register access
assign abstractcs_error_sel2 = ((core_dbg_cmd_done & core_dbg_cmd_fail) | // exception from core
(execute_command & (command_reg[31:24] == 8'h0) & // unimplemented regs
(((command_reg[15:12] == 4'h1) & (command_reg[11:5] != 0)) | (command_reg[15:13] != 0)))) & ~(|abstractcs_reg[10:8]);
assign abstractcs_error_sel3 = execute_command & (dbg_state != HALTED) & ~(|abstractcs_reg[10:8]);
assign abstractcs_error_sel4 = dbg_sb_bus_error & dbg_bus_clk_en & ~(|abstractcs_reg[10:8]);// sb bus error for abstract memory command
assign abstractcs_error_sel5 = execute_command & (command_reg[31:24] == 8'h2) & ~(|abstractcs_reg[10:8]) &
(((command_reg[22:20] == 3'b001) & data1_reg[0]) | ((command_reg[22:20] == 3'b010) & (|data1_reg[1:0]))); //Unaligned address for abstract memory
assign abstractcs_error_sel6 = (dmi_reg_addr == 7'h16) & dmi_reg_en & dmi_reg_wr_en;
assign abstractcs_error_din[2:0] = abstractcs_error_sel0 ? 3'b001 : // writing command or abstractcs while a command was executing. Or accessing data0
abstractcs_error_sel1 ? 3'b010 : // writing a illegal command type to cmd field of command
abstractcs_error_sel2 ? 3'b011 : // exception while running command
abstractcs_error_sel3 ? 3'b100 : // writing a comnand when not in the halted state
abstractcs_error_sel4 ? 3'b101 : // Bus error
abstractcs_error_sel5 ? 3'b111 : // unaligned or illegal size abstract memory command
abstractcs_error_sel6 ? (~dmi_reg_wdata[10:8] & abstractcs_reg[10:8]) : //W1C
abstractcs_reg[10:8]; //hold
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rvdffs #(1) dmabstractcs_busy_reg (.din(abstractcs_busy_din), .dout(abstractcs_reg[12]), .en(abstractcs_busy_wren), .rst_l(dbg_dm_rst_l), .clk(dbg_free_clk));
rvdff #(3) dmabstractcs_error_reg (.din(abstractcs_error_din[2:0]), .dout(abstractcs_reg[10:8]), .rst_l(dbg_dm_rst_l), .clk(dbg_free_clk));
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// abstract auto reg
assign abstractauto_reg_wren = dmi_reg_en & dmi_reg_wr_en & (dmi_reg_addr == 7'h18) & ~abstractcs_reg[12];
rvdffs #(2) dbg_abstractauto_reg (.*, .din(dmi_reg_wdata[1:0]), .dout(abstractauto_reg[1:0]), .en(abstractauto_reg_wren), .rst_l(dbg_dm_rst_l), .clk(dbg_free_clk));
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// command register - implemented all the bits in this register
// command[16] = 1: write, 0: read
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assign execute_command_ns = command_wren |
(dmi_reg_en & ~abstractcs_reg[12] & (((dmi_reg_addr == 7'h4) & abstractauto_reg[0]) | ((dmi_reg_addr == 7'h5) & abstractauto_reg[1])));
assign command_wren = (dmi_reg_addr == 7'h17) & dmi_reg_en & dmi_reg_wr_en;
//assign command_wren = (dmi_reg_addr == 7'h17) & dmi_reg_en & dmi_reg_wr_en & (dbg_state == HALTED) & ~abstractcs_reg[12];
assign command_regno_wren = command_wren | ((command_reg[31:24] == 8'h0) & command_reg[19] & (dbg_state == CMD_DONE) & ~(|abstractcs_reg[10:8])); // aarpostincrement
assign command_postexec_din = (dmi_reg_wdata[31:24] == 8'h0) & dmi_reg_wdata[18];
assign command_transfer_din = (dmi_reg_wdata[31:24] == 8'h0) & dmi_reg_wdata[17];
assign command_din[31:16] = {dmi_reg_wdata[31:24],1'b0,dmi_reg_wdata[22:19],command_postexec_din,command_transfer_din, dmi_reg_wdata[16]};
assign command_din[15:0] = command_wren ? dmi_reg_wdata[15:0] : dbg_cmd_next_addr[15:0];
rvdff #(1) execute_commandff (.*, .din(execute_command_ns), .dout(execute_command), .clk(dbg_free_clk), .rst_l(dbg_dm_rst_l));
rvdffe #(16) dmcommand_reg (.*, .din(command_din[31:16]), .dout(command_reg[31:16]), .en(command_wren), .rst_l(dbg_dm_rst_l));
rvdffe #(16) dmcommand_regno_reg (.*, .din(command_din[15:0]), .dout(command_reg[15:0]), .en(command_regno_wren), .rst_l(dbg_dm_rst_l));
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// data0 reg
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assign data0_reg_wren0 = (dmi_reg_en & dmi_reg_wr_en & (dmi_reg_addr == 7'h4) & (dbg_state == HALTED) & ~abstractcs_reg[12]);
assign data0_reg_wren1 = core_dbg_cmd_done & (dbg_state == CORE_CMD_WAIT) & ~command_reg[16];
assign data0_reg_wren = data0_reg_wren0 | data0_reg_wren1 | data0_reg_wren2;
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assign data0_din[31:0] = ({32{data0_reg_wren0}} & dmi_reg_wdata[31:0]) |
({32{data0_reg_wren1}} & core_dbg_rddata[31:0]) |
({32{data0_reg_wren2}} & sb_bus_rdata[31:0]);
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rvdffe #(32) dbg_data0_reg (.*, .din(data0_din[31:0]), .dout(data0_reg[31:0]), .en(data0_reg_wren), .rst_l(dbg_dm_rst_l));
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// data 1
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assign data1_reg_wren0 = (dmi_reg_en & dmi_reg_wr_en & (dmi_reg_addr == 7'h5) & (dbg_state == HALTED) & ~abstractcs_reg[12]);
assign data1_reg_wren1 = (dbg_state == CMD_DONE) & (command_reg[31:24] == 8'h2) & command_reg[19] & ~(|abstractcs_reg[10:8]); // aampostincrement
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assign data1_reg_wren = data1_reg_wren0 | data1_reg_wren1;
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assign data1_din[31:0] = ({32{data1_reg_wren0}} & dmi_reg_wdata[31:0]) |
({32{data1_reg_wren1}} & dbg_cmd_next_addr[31:0]);
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rvdffe #(32) dbg_data1_reg (.*, .din(data1_din[31:0]), .dout(data1_reg[31:0]), .en(data1_reg_wren), .rst_l(dbg_dm_rst_l));
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rvdffs #(1) sb_abmem_cmd_doneff (.din(sb_abmem_cmd_done_in), .dout(sb_abmem_cmd_done), .en(sb_abmem_cmd_done_en), .clk(dbg_free_clk), .rst_l(dbg_dm_rst_l), .*);
rvdffs #(1) sb_abmem_data_doneff (.din(sb_abmem_data_done_in), .dout(sb_abmem_data_done), .en(sb_abmem_data_done_en), .clk(dbg_free_clk), .rst_l(dbg_dm_rst_l), .*);
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// FSM to control the debug mode entry, command send/recieve, and Resume flow.
always_comb begin
dbg_nxtstate = IDLE;
dbg_state_en = 1'b0;
abstractcs_busy_wren = 1'b0;
abstractcs_busy_din = 1'b0;
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dbg_halt_req = dmcontrol_wren_Q & dmcontrol_reg[31] & ~dmcontrol_reg[1]; // single pulse output to the core. Need to drive every time this register is written since core might be halted due to MPC
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dbg_resume_req = 1'b0; // single pulse output to the core
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dbg_sb_bus_error = 1'b0;
data0_reg_wren2 = 1'b0;
sb_abmem_cmd_done_in = 1'b0;
sb_abmem_data_done_in = 1'b0;
sb_abmem_cmd_done_en = 1'b0;
sb_abmem_data_done_en = 1'b0;
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case (dbg_state)
IDLE: begin
dbg_nxtstate = (dmstatus_reg[9] | dec_tlu_mpc_halted_only) ? HALTED : HALTING; // initiate the halt command to the core
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dbg_state_en = ((dmcontrol_reg[31] & ~dec_tlu_debug_mode) | dmstatus_reg[9] | dec_tlu_mpc_halted_only) & ~dmcontrol_reg[1]; // when the jtag writes the halt bit in the DM register, OR when the status indicates Halted
dbg_halt_req = dmcontrol_reg[31] & ~dmcontrol_reg[1]; // Removed debug mode qualification during MPC changes
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end
HALTING : begin
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dbg_nxtstate = dmcontrol_reg[1] ? IDLE : HALTED; // Goto HALTED once the core sends an ACK
dbg_state_en = dmstatus_reg[9] | dmcontrol_reg[1]; // core indicates halted
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end
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HALTED: begin
// wait for halted to go away before send to resume. Else start of new command
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dbg_nxtstate = (dmstatus_reg[9] & ~dmcontrol_reg[1]) ? (resumereq ? RESUMING : (((command_reg[31:24] == 8'h2) & abmem_addr_external) ? SB_CMD_START : CORE_CMD_START)) :
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(dmcontrol_reg[31] ? HALTING : IDLE); // This is MPC halted case
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dbg_state_en = (dmstatus_reg[9] & resumereq) | execute_command | dmcontrol_reg[1] | ~(dmstatus_reg[9] | dec_tlu_mpc_halted_only);
abstractcs_busy_wren = dbg_state_en & ((dbg_nxtstate == CORE_CMD_START) | (dbg_nxtstate == SB_CMD_START)); // write busy when a new command was written by jtag
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abstractcs_busy_din = 1'b1;
dbg_resume_req = dbg_state_en & (dbg_nxtstate == RESUMING); // single cycle pulse to core if resuming
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end
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CORE_CMD_START: begin
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// Don't execute the command if cmderror or transfer=0 for abstract register access
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dbg_nxtstate = dmcontrol_reg[1] ? IDLE : ((|abstractcs_reg[10:8]) | ((command_reg[31:24] == 8'h0) & ~command_reg[17])) ? CMD_DONE : CORE_CMD_WAIT; // new command sent to the core
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dbg_state_en = dbg_cmd_valid | (|abstractcs_reg[10:8]) | ((command_reg[31:24] == 8'h0) & ~command_reg[17]) | dmcontrol_reg[1];
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end
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CORE_CMD_WAIT: begin
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dbg_nxtstate = dmcontrol_reg[1] ? IDLE : CMD_DONE;
dbg_state_en = core_dbg_cmd_done | dmcontrol_reg[1]; // go to done state for one cycle after completing current command
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end
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SB_CMD_START: begin
dbg_nxtstate = dmcontrol_reg[1] ? IDLE : (|abstractcs_reg[10:8]) ? CMD_DONE : SB_CMD_SEND;
dbg_state_en = (dbg_bus_clk_en & ~sb_cmd_pending) | (|abstractcs_reg[10:8]) | dmcontrol_reg[1];
end
SB_CMD_SEND: begin
sb_abmem_cmd_done_in = 1'b1;
sb_abmem_data_done_in= 1'b1;
sb_abmem_cmd_done_en = ((sb_axi_awvalid & sb_axi_awready) | (sb_axi_arvalid & sb_axi_arready)) & dbg_bus_clk_en;
sb_abmem_data_done_en= ((sb_axi_wvalid & sb_axi_wready) | (sb_axi_arvalid & sb_axi_arready)) & dbg_bus_clk_en;
dbg_nxtstate = dmcontrol_reg[1] ? IDLE : SB_CMD_RESP;
dbg_state_en = (sb_abmem_cmd_done | sb_abmem_cmd_done_en) & (sb_abmem_data_done | sb_abmem_data_done_en) & dbg_bus_clk_en;
end
SB_CMD_RESP: begin
dbg_nxtstate = dmcontrol_reg[1] ? IDLE : CMD_DONE;
dbg_state_en = ((sb_axi_rvalid & sb_axi_rready) | (sb_axi_bvalid & sb_axi_bready)) & dbg_bus_clk_en;
dbg_sb_bus_error = ((sb_axi_rvalid & sb_axi_rready & sb_axi_rresp[1]) | (sb_axi_bvalid & sb_axi_bready & sb_axi_bresp[1])) & dbg_bus_clk_en;
data0_reg_wren2 = dbg_state_en & ~sb_abmem_cmd_write & ~dbg_sb_bus_error;
end
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CMD_DONE: begin
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dbg_nxtstate = dmcontrol_reg[1] ? IDLE : HALTED;
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dbg_state_en = 1'b1;
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abstractcs_busy_wren = dbg_state_en; // remove the busy bit from the abstracts ( bit 12 )
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abstractcs_busy_din = 1'b0;
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sb_abmem_cmd_done_in = 1'b0;
sb_abmem_data_done_in= 1'b0;
sb_abmem_cmd_done_en = 1'b1;
sb_abmem_data_done_en= 1'b1;
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end
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RESUMING : begin
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dbg_nxtstate = IDLE;
dbg_state_en = dmstatus_reg[17] | dmcontrol_reg[1]; // resume ack has been updated in the dmstatus register
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end
default : begin
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dbg_nxtstate = IDLE;
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dbg_state_en = 1'b0;
abstractcs_busy_wren = 1'b0;
abstractcs_busy_din = 1'b0;
dbg_halt_req = 1'b0; // single pulse output to the core
dbg_resume_req = 1'b0; // single pulse output to the core
end
endcase
end // always_comb begin
assign dmi_reg_rdata_din[31:0] = ({32{dmi_reg_addr == 7'h4}} & data0_reg[31:0]) |
({32{dmi_reg_addr == 7'h5}} & data1_reg[31:0]) |
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({32{dmi_reg_addr == 7'h10}} & {2'b0,dmcontrol_reg[29],1'b0,dmcontrol_reg[27:0]}) | // Read0 to Write only bits
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({32{dmi_reg_addr == 7'h11}} & dmstatus_reg[31:0]) |
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({32{dmi_reg_addr == 7'h16}} & abstractcs_reg[31:0]) |
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({32{dmi_reg_addr == 7'h17}} & command_reg[31:0]) |
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({32{dmi_reg_addr == 7'h18}} & {30'h0,abstractauto_reg[1:0]}) |
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({32{dmi_reg_addr == 7'h40}} & haltsum0_reg[31:0]) |
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({32{dmi_reg_addr == 7'h38}} & sbcs_reg[31:0]) |
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({32{dmi_reg_addr == 7'h39}} & sbaddress0_reg[31:0]) |
({32{dmi_reg_addr == 7'h3c}} & sbdata0_reg[31:0]) |
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({32{dmi_reg_addr == 7'h3d}} & sbdata1_reg[31:0]);
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rvdffs #($bits(state_t)) dbg_state_reg (.din(dbg_nxtstate), .dout({dbg_state}), .en(dbg_state_en), .rst_l(dbg_dm_rst_l & rst_l), .clk(dbg_free_clk)); // Reset for both core/dbg reset
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// Ack will use the power on reset only otherwise there won't be any ack until dmactive is 1
// rvdff #(1) dmi_ack_reg (.din(dmi_reg_en), .dout(dmi_reg_ack), .rst_l(rst_l), .clk(free_clk));
rvdffs #(32) dmi_rddata_reg(.din(dmi_reg_rdata_din), .dout(dmi_reg_rdata), .en(dmi_reg_en), .rst_l(dbg_dm_rst_l), .clk(dbg_free_clk));
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assign abmem_addr[31:0] = data1_reg[31:0];
assign abmem_addr_core_local = (abmem_addr_in_dccm_region | abmem_addr_in_iccm_region | abmem_addr_in_pic_region);
assign abmem_addr_external = ~abmem_addr_core_local;
assign abmem_addr_in_dccm_region = (abmem_addr[31:28] == `RV_DCCM_REGION) & DCCM_ENABLE;
assign abmem_addr_in_iccm_region = (abmem_addr[31:28] == `RV_ICCM_REGION) & ICCM_ENABLE;
assign abmem_addr_in_pic_region = (abmem_addr[31:28] == `RV_PIC_REGION);
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// interface for the core
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assign dbg_cmd_addr[31:0] = (command_reg[31:24] == 8'h2) ? data1_reg[31:0] : {20'b0, command_reg[11:0]};
assign dbg_cmd_wrdata[31:0] = data0_reg[31:0];
assign dbg_cmd_valid = (dbg_state == CORE_CMD_START) & ~((|abstractcs_reg[10:8]) | ((command_reg[31:24] == 8'h0) & ~command_reg[17]) | ((command_reg[31:24] == 8'h2) & abmem_addr_external)) & dma_dbg_ready;
assign dbg_cmd_write = command_reg[16];
assign dbg_cmd_type[1:0] = (command_reg[31:24] == 8'h2) ? 2'b10 : {1'b0, (command_reg[15:12] == 4'b0)};
assign dbg_cmd_size[1:0] = command_reg[21:20];
assign dbg_cmd_addr_incr[3:0] = (command_reg[31:24] == 8'h2) ? (4'h1 << sb_abmem_cmd_size[1:0]) : 4'h1;
assign dbg_cmd_curr_addr[31:0] = (command_reg[31:24] == 8'h2) ? data1_reg[31:0] : {16'b0, command_reg[15:0]};
assign dbg_cmd_next_addr[31:0] = dbg_cmd_curr_addr[31:0] + {28'h0,dbg_cmd_addr_incr[3:0]};
assign sb_abmem_cmd_awvalid = (dbg_state == SB_CMD_SEND) & sb_abmem_cmd_write & ~sb_abmem_cmd_done;
assign sb_abmem_cmd_wvalid = (dbg_state == SB_CMD_SEND) & sb_abmem_cmd_write & ~sb_abmem_data_done;
assign sb_abmem_cmd_arvalid = (dbg_state == SB_CMD_SEND) & ~sb_abmem_cmd_write & ~sb_abmem_cmd_done & ~sb_abmem_data_done;
assign sb_abmem_read_pend = (dbg_state == SB_CMD_RESP) & ~sb_abmem_cmd_write;
assign sb_abmem_cmd_write = command_reg[16];
assign sb_abmem_cmd_size[2:0] = {1'b0, command_reg[21:20]};
assign sb_abmem_cmd_addr[31:0] = abmem_addr[31:0];
assign sb_abmem_cmd_wdata[31:0] = data0_reg[31:0];
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// Ask DMA to stop taking bus trxns since debug request is done
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assign dbg_dma_bubble = ((dbg_state == CORE_CMD_START) & ~(|abstractcs_reg[10:8])) | (dbg_state == CORE_CMD_WAIT);
assign sb_cmd_pending = (sb_state == CMD_RD) | (sb_state == CMD_WR) | (sb_state == CMD_WR_ADDR) | (sb_state == CMD_WR_DATA) | (sb_state == RSP_RD) | (sb_state == RSP_WR);
assign sb_abmem_cmd_pending = (dbg_state == SB_CMD_START) | (dbg_state == SB_CMD_SEND) | (dbg_state== SB_CMD_RESP);
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// system bus FSM
always_comb begin
sb_nxtstate = SBIDLE;
sb_state_en = 1'b0;
sbcs_sbbusy_wren = 1'b0;
sbcs_sbbusy_din = 1'b0;
sbcs_sberror_wren = 1'b0;
sbcs_sberror_din[2:0] = 3'b0;
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sbaddress0_reg_wren1 = 1'b0;
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case (sb_state)
SBIDLE: begin
sb_nxtstate = sbdata0wr_access ? WAIT_WR : WAIT_RD;
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sb_state_en = (sbdata0wr_access | sbreadondata_access | sbreadonaddr_access) & ~(|sbcs_reg[14:12]) & ~sbcs_reg[22];
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sbcs_sbbusy_wren = sb_state_en; // set the single read bit if it is a singlread command
sbcs_sbbusy_din = 1'b1;
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sbcs_sberror_wren = sbcs_wren & (|dmi_reg_wdata[14:12]); // write to clear the error bits
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sbcs_sberror_din[2:0] = ~dmi_reg_wdata[14:12] & sbcs_reg[14:12];
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end
WAIT_RD: begin
sb_nxtstate = (sbcs_unaligned | sbcs_illegal_size) ? DONE : CMD_RD;
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sb_state_en = (dbg_bus_clk_en & ~sb_abmem_cmd_pending) | sbcs_unaligned | sbcs_illegal_size;
sbcs_sberror_wren = sbcs_unaligned | sbcs_illegal_size;
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sbcs_sberror_din[2:0] = sbcs_unaligned ? 3'b011 : 3'b100;
end
WAIT_WR: begin
sb_nxtstate = (sbcs_unaligned | sbcs_illegal_size) ? DONE : CMD_WR;
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sb_state_en = (dbg_bus_clk_en & ~sb_abmem_cmd_pending) | sbcs_unaligned | sbcs_illegal_size;
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sbcs_sberror_wren = sbcs_unaligned | sbcs_illegal_size;
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sbcs_sberror_din[2:0] = sbcs_unaligned ? 3'b011 : 3'b100;
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end
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CMD_RD : begin
sb_nxtstate = RSP_RD;
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sb_state_en = sb_axi_arvalid & sb_axi_arready & dbg_bus_clk_en;
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end
CMD_WR : begin
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sb_nxtstate = (sb_axi_awready & sb_axi_wready) ? RSP_WR : (sb_axi_awready ? CMD_WR_DATA : CMD_WR_ADDR);
sb_state_en = ((sb_axi_awvalid & sb_axi_awready) | (sb_axi_wvalid & sb_axi_wready)) & dbg_bus_clk_en;
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end
CMD_WR_ADDR : begin
sb_nxtstate = RSP_WR;
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sb_state_en = sb_axi_awvalid & sb_axi_awready & dbg_bus_clk_en;
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end
CMD_WR_DATA : begin
sb_nxtstate = RSP_WR;
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sb_state_en = sb_axi_wvalid & sb_axi_wready & dbg_bus_clk_en;
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end
RSP_RD: begin
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sb_nxtstate = DONE;
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sb_state_en = sb_axi_rvalid & sb_axi_rready & dbg_bus_clk_en;
sbcs_sberror_wren = sb_state_en & sb_axi_rresp[1];
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sbcs_sberror_din[2:0] = 3'b010;
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end
RSP_WR: begin
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sb_nxtstate = DONE;
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sb_state_en = sb_axi_bvalid & sb_axi_bready & dbg_bus_clk_en;
sbcs_sberror_wren = sb_state_en & sb_axi_bresp[1];
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sbcs_sberror_din[2:0] = 3'b010;
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end
DONE: begin
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sb_nxtstate = SBIDLE;
sb_state_en = 1'b1;
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sbcs_sbbusy_wren = 1'b1; // reset the single read
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sbcs_sbbusy_din = 1'b0;
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sbaddress0_reg_wren1 = sbcs_reg[16] & (sbcs_reg[14:12] == 3'b0); // auto increment was set and no error. Update to new address after completing the current command
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end
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default : begin
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sb_nxtstate = SBIDLE;
sb_state_en = 1'b0;
sbcs_sbbusy_wren = 1'b0;
sbcs_sbbusy_din = 1'b0;
sbcs_sberror_wren = 1'b0;
sbcs_sberror_din[2:0] = 3'b0;
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sbaddress0_reg_wren1 = 1'b0;
end
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endcase
end // always_comb begin
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rvdffs #($bits(sb_state_t)) sb_state_reg (.din(sb_nxtstate), .dout({sb_state}), .en(sb_state_en), .rst_l(dbg_dm_rst_l), .clk(sb_free_clk));
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rvdff_fpga #(2) axi_bresp_ff (.din(sb_axi_bresp[1:0]), .dout(sb_axi_bresp_q[1:0]), .rst_l(dbg_dm_rst_l), .clk(bus_clk), .clken(bus_clken), .rawclk(clk), .*);
rvdff_fpga #(2) axi_rresp_ff (.din(sb_axi_rresp[1:0]), .dout(sb_axi_rresp_q[1:0]), .rst_l(dbg_dm_rst_l), .clk(bus_clk), .clken(bus_clken), .rawclk(clk), .*);
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rvdffs #(.WIDTH(1)) axi_awvalid_ff (.din(sb_axi_awvalid), .dout(sb_axi_awvalid_q), .en(dbg_bus_clk_en), .rst_l(dbg_dm_rst_l), .clk(sb_free_clk), .*);
rvdffs #(.WIDTH(1)) axi_awready_ff (.din(sb_axi_awready), .dout(sb_axi_awready_q), .en(dbg_bus_clk_en), .rst_l(dbg_dm_rst_l), .clk(sb_free_clk), .*);
rvdffs #(.WIDTH(1)) axi_wvalid_ff (.din(sb_axi_wvalid), .dout(sb_axi_wvalid_q), .en(dbg_bus_clk_en), .rst_l(dbg_dm_rst_l), .clk(sb_free_clk), .*);
rvdffs #(.WIDTH(1)) axi_wready_ff (.din(sb_axi_wready), .dout(sb_axi_wready_q), .en(dbg_bus_clk_en), .rst_l(dbg_dm_rst_l), .clk(sb_free_clk), .*);
rvdffs #(.WIDTH(1)) axi_arvalid_ff (.din(sb_axi_arvalid), .dout(sb_axi_arvalid_q), .en(dbg_bus_clk_en), .rst_l(dbg_dm_rst_l), .clk(sb_free_clk), .*);
rvdffs #(.WIDTH(1)) axi_arready_ff (.din(sb_axi_arready), .dout(sb_axi_arready_q), .en(dbg_bus_clk_en), .rst_l(dbg_dm_rst_l), .clk(sb_free_clk), .*);
rvdffs #(.WIDTH(1)) axi_bvalid_ff (.din(sb_axi_bvalid), .dout(sb_axi_bvalid_q), .en(dbg_bus_clk_en), .rst_l(dbg_dm_rst_l), .clk(sb_free_clk), .*);
rvdffs #(.WIDTH(1)) axi_bready_ff (.din(sb_axi_bready), .dout(sb_axi_bready_q), .en(dbg_bus_clk_en), .rst_l(dbg_dm_rst_l), .clk(sb_free_clk), .*);
rvdffs #(.WIDTH(1)) axi_rvalid_ff (.din(sb_axi_rvalid), .dout(sb_axi_rvalid_q), .en(dbg_bus_clk_en), .rst_l(dbg_dm_rst_l), .clk(sb_free_clk), .*);
rvdffs #(.WIDTH(1)) axi_rready_ff (.din(sb_axi_rready), .dout(sb_axi_rready_q), .en(dbg_bus_clk_en), .rst_l(dbg_dm_rst_l), .clk(sb_free_clk), .*);
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assign sb_cmd_awvalid = ((sb_state == CMD_WR) | (sb_state == CMD_WR_ADDR));
assign sb_cmd_wvalid = ((sb_state == CMD_WR) | (sb_state == CMD_WR_DATA));
assign sb_cmd_arvalid = (sb_state == CMD_RD);
assign sb_read_pend = (sb_state == RSP_RD);
assign sb_cmd_size[2:0] = sbcs_reg[19:17];
assign sb_cmd_wdata[63:0] = {sbdata1_reg[31:0], sbdata0_reg[31:0]};
assign sb_cmd_addr[31:0] = sbaddress0_reg[31:0];
assign sb_axi_size[2:0] = (sb_abmem_cmd_awvalid | sb_abmem_cmd_wvalid | sb_abmem_cmd_arvalid | sb_abmem_read_pend) ? sb_abmem_cmd_size[2:0] : sb_cmd_size[2:0];
assign sb_axi_addr[31:0] = (sb_abmem_cmd_awvalid | sb_abmem_cmd_wvalid | sb_abmem_cmd_arvalid | sb_abmem_read_pend) ? sb_abmem_cmd_addr[31:0] : sb_cmd_addr[31:0];
assign sb_axi_wrdata[63:0] = (sb_abmem_cmd_awvalid | sb_abmem_cmd_wvalid) ? {2{sb_abmem_cmd_wdata[31:0]}} : sb_cmd_wdata[63:0];
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// AXI Request signals
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assign sb_axi_awvalid = sb_abmem_cmd_awvalid | sb_cmd_awvalid;
assign sb_axi_awaddr[31:0] = sb_axi_addr[31:0];
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assign sb_axi_awid[SB_BUS_TAG-1:0] = '0;
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assign sb_axi_awsize[2:0] = sb_axi_size[2:0];
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assign sb_axi_awprot[2:0] = '0;
assign sb_axi_awcache[3:0] = 4'b1111;
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assign sb_axi_awregion[3:0] = sb_axi_addr[31:28];
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assign sb_axi_awlen[7:0] = '0;
assign sb_axi_awburst[1:0] = 2'b01;
assign sb_axi_awqos[3:0] = '0;
assign sb_axi_awlock = '0;
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assign sb_axi_wvalid = sb_abmem_cmd_wvalid | sb_cmd_wvalid;
assign sb_axi_wdata[63:0] = ({64{(sb_axi_size[2:0] == 3'h0)}} & {8{sb_axi_wrdata[7:0]}}) |
({64{(sb_axi_size[2:0] == 3'h1)}} & {4{sb_axi_wrdata[15:0]}}) |
({64{(sb_axi_size[2:0] == 3'h2)}} & {2{sb_axi_wrdata[31:0]}}) |
({64{(sb_axi_size[2:0] == 3'h3)}} & {sb_axi_wrdata[63:0]});
assign sb_axi_wstrb[7:0] = ({8{(sb_axi_size[2:0] == 3'h0)}} & (8'h1 << sb_axi_addr[2:0])) |
({8{(sb_axi_size[2:0] == 3'h1)}} & (8'h3 << {sb_axi_addr[2:1],1'b0})) |
({8{(sb_axi_size[2:0] == 3'h2)}} & (8'hf << {sb_axi_addr[2],2'b0})) |
({8{(sb_axi_size[2:0] == 3'h3)}} & 8'hff);
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assign sb_axi_wlast = '1;
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assign sb_axi_arvalid = sb_abmem_cmd_arvalid | sb_cmd_arvalid;
assign sb_axi_araddr[31:0] = sb_axi_addr[31:0];
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assign sb_axi_arid[SB_BUS_TAG-1:0] = '0;
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assign sb_axi_arsize[2:0] = sb_axi_size[2:0];
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assign sb_axi_arprot[2:0] = '0;
assign sb_axi_arcache[3:0] = 4'b0;
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assign sb_axi_arregion[3:0] = sb_axi_addr[31:28];
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assign sb_axi_arlen[7:0] = '0;
assign sb_axi_arburst[1:0] = 2'b01;
assign sb_axi_arqos[3:0] = '0;
assign sb_axi_arlock = '0;
// AXI Response signals
assign sb_axi_bready = 1'b1;
assign sb_axi_rready = 1'b1;
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assign sb_bus_rdata[63:0] = ({64{sb_axi_size == 3'h0}} & ((sb_axi_rdata[63:0] >> 8*sb_axi_addr[2:0]) & 64'hff)) |
({64{sb_axi_size == 3'h1}} & ((sb_axi_rdata[63:0] >> 16*sb_axi_addr[2:1]) & 64'hffff)) |
({64{sb_axi_size == 3'h2}} & ((sb_axi_rdata[63:0] >> 32*sb_axi_addr[2]) & 64'hffff_ffff)) |
({64{sb_axi_size == 3'h3}} & sb_axi_rdata[63:0]);
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`ifdef ASSERT_ON
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// assertion.
// when the resume_ack is asserted then the dec_tlu_dbg_halted should be 0
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dm_check_resume_and_halted: assert property (@(posedge clk) disable iff(~rst_l) (~dec_tlu_resume_ack | ~dec_tlu_dbg_halted));
`endif
endmodule