OpenCores
URL https://opencores.org/ocsvn/amber/amber/trunk

Subversion Repositories amber

[/] [amber/] [trunk/] [hw/] [vlog/] [amber23/] [a23_execute.v] - Diff between revs 2 and 15

Go to most recent revision | Show entire file | Details | Blame | View Log

Rev 2 Rev 15
Line 1... Line 1...
 
//////////////////////////////////////////////////////////////////
 
//                                                              //
 
//  Execute stage of Amber 2 Core                               //
 
//                                                              //
 
//  This file is part of the Amber project                      //
 
//  http://www.opencores.org/project,amber                      //
 
//                                                              //
 
//  Description                                                 //
 
//  Executes instructions. Instantiates the register file, ALU  //
 
//  multiplication unit and barrel shifter. This stage is       //
 
//  relitively simple. All the complex stuff is done in the     //
 
//  decode stage.                                               //
 
//                                                              //
 
//  Author(s):                                                  //
 
//      - Conor Santifort, csantifort.amber@gmail.com           //
 
//                                                              //
 
//////////////////////////////////////////////////////////////////
 
//                                                              //
 
// Copyright (C) 2010 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                     //
 
//                                                              //
 
//////////////////////////////////////////////////////////////////
 
 
 
 
 
module a23_execute (
 
 
 
input                       i_clk,
 
input       [31:0]          i_read_data,
 
input       [4:0]           i_read_data_alignment,  // 2 LSBs of address in [4:3], appended 
 
                                                    // with 3 zeros
 
input       [31:0]          i_copro_read_data,      // From Co-Processor, to either Register 
 
                                                    // or Memory
 
input                       i_data_access_exec,     // from Instruction Decode stage
 
                                                    // high means the memory access is a read 
 
                                                    // read or write, low for instruction
 
 
 
output reg  [31:0]          o_copro_write_data = 'd0,
 
output reg  [31:0]          o_write_data = 'd0,
 
output reg  [31:0]          o_address = 32'hdead_dead,
 
output reg                  o_adex = 'd0,           // Address Exception
 
output reg                  o_address_valid = 'd0,  // Prevents the reset address value being a 
 
                                                    // wishbone access
 
output      [31:0]          o_address_nxt,          // un-registered version of address to the 
 
                                                    // cache rams address ports
 
output reg                  o_priviledged = 'd0,    // Priviledged access
 
output reg                  o_exclusive = 'd0,      // swap access
 
output reg                  o_write_enable = 'd0,
 
output reg  [3:0]           o_byte_enable = 'd0,
 
output reg                  o_data_access = 'd0,    // To Fetch stage. high = data fetch, 
 
                                                    // low = instruction fetch
 
output      [31:0]          o_status_bits,          // Full PC will all status bits, but PC part zero'ed out
 
output                      o_multiply_done,
 
 
 
 
 
// --------------------------------------------------
 
// Control signals from Instruction Decode stage
 
// --------------------------------------------------
 
input                       i_fetch_stall,          // stall all stages of the cpu at the same time
 
input      [1:0]            i_status_bits_mode,
 
input                       i_status_bits_irq_mask,
 
input                       i_status_bits_firq_mask,
 
input      [31:0]           i_imm32,
 
input      [4:0]            i_imm_shift_amount,
 
input                       i_shift_imm_zero,
 
input      [3:0]            i_condition,
 
input                       i_exclusive_exec,       // swap access
 
 
 
input      [3:0]            i_rm_sel,
 
input      [3:0]            i_rds_sel,
 
input      [3:0]            i_rn_sel,
 
input      [1:0]            i_barrel_shift_amount_sel,
 
input      [1:0]            i_barrel_shift_data_sel,
 
input      [1:0]            i_barrel_shift_function,
 
input      [8:0]            i_alu_function,
 
input      [1:0]            i_multiply_function,
 
input      [2:0]            i_interrupt_vector_sel,
 
input      [3:0]            i_address_sel,
 
input      [1:0]            i_pc_sel,
 
input      [1:0]            i_byte_enable_sel,
 
input      [2:0]            i_status_bits_sel,
 
input      [2:0]            i_reg_write_sel,
 
input                       i_user_mode_regs_load,
 
input                       i_user_mode_regs_store_nxt,
 
input                       i_firq_not_user_mode,
 
 
 
input                       i_write_data_wen,
 
input                       i_base_address_wen,     // save LDM base address register, 
 
                                                    // in case of data abort
 
input                       i_pc_wen,
 
input      [14:0]           i_reg_bank_wen,
 
input                       i_status_bits_flags_wen,
 
input                       i_status_bits_mode_wen,
 
input                       i_status_bits_irq_mask_wen,
 
input                       i_status_bits_firq_mask_wen,
 
input                       i_copro_write_data_wen
 
 
 
);
 
 
 
`include "a23_localparams.v"
 
`include "a23_functions.v"
 
 
 
// ========================================================
 
// Internal signals
 
// ========================================================
 
wire [31:0]         write_data_nxt;
 
wire [3:0]          byte_enable_nxt;
 
wire [31:0]         pc_plus4;
 
wire [31:0]         pc_minus4;
 
wire [31:0]         address_plus4;
 
wire [31:0]         alu_plus4;
 
wire [31:0]         rn_plus4;
 
wire [31:0]         alu_out;
 
wire [3:0]          alu_flags;
 
wire [31:0]         rm;
 
wire [31:0]         rs;
 
wire [31:0]         rd;
 
wire [31:0]         rn;
 
wire [31:0]         pc;
 
wire [31:0]         pc_nxt;
 
wire                write_enable_nxt;
 
wire [31:0]         interrupt_vector;
 
wire [7:0]          shift_amount;
 
wire [31:0]         barrel_shift_in;
 
wire [31:0]         barrel_shift_out;
 
wire                barrel_shift_carry;
 
 
 
wire [3:0]          status_bits_flags_nxt;
 
reg  [3:0]          status_bits_flags = 'd0;
 
wire [1:0]          status_bits_mode_nxt;
 
reg  [1:0]          status_bits_mode = SVC;
 
                    // one-hot encoded rs select
 
wire [3:0]          status_bits_mode_rds_oh_nxt;
 
reg  [3:0]          status_bits_mode_rds_oh = 1'd1 << OH_SVC;
 
wire                status_bits_mode_rds_oh_update;
 
wire                status_bits_irq_mask_nxt;
 
reg                 status_bits_irq_mask = 1'd1;
 
wire                status_bits_firq_mask_nxt;
 
reg                 status_bits_firq_mask = 1'd1;
 
 
 
wire                execute;           // high when condition execution is true
 
wire [31:0]         reg_write_nxt;
 
wire                pc_wen;
 
wire [14:0]         reg_bank_wen;
 
wire [31:0]         multiply_out;
 
wire [1:0]          multiply_flags;
 
reg  [31:0]         base_address = 'd0;    // Saves base address during LDM instruction in 
 
                                           // case of data abort
 
 
 
wire                priviledged_nxt;
 
wire                priviledged_update;
 
wire                address_update;
 
wire                base_address_update;
 
wire                write_data_update;
 
wire                copro_write_data_update;
 
wire                byte_enable_update;
 
wire                data_access_update;
 
wire                write_enable_update;
 
wire                exclusive_update;
 
wire                status_bits_flags_update;
 
wire                status_bits_mode_update;
 
wire                status_bits_irq_mask_update;
 
wire                status_bits_firq_mask_update;
 
 
 
wire [31:0]         alu_out_pc_filtered;
 
wire                adex_nxt;
 
 
 
// ========================================================
 
// Status Bits in PC register
 
// ========================================================
 
assign o_status_bits = {   status_bits_flags,           // 31:28
 
                           status_bits_irq_mask,        // 7
 
                           status_bits_firq_mask,       // 6
 
                           24'd0,
 
                           status_bits_mode };          // 1:0 = mode
 
 
 
 
 
// ========================================================
 
// Status Bits Select
 
// ========================================================
 
assign status_bits_flags_nxt     = i_status_bits_sel == 3'd0 ? alu_flags                           :
 
                                   i_status_bits_sel == 3'd1 ? alu_out          [31:28]            :
 
                                   i_status_bits_sel == 3'd3 ? i_copro_read_data[31:28]            :
 
                                   // 4 = update flags after a multiply operation
 
                                                        { multiply_flags, status_bits_flags[1:0] } ;
 
 
 
assign status_bits_mode_nxt      = i_status_bits_sel == 3'd0 ? i_status_bits_mode       :
 
                                   i_status_bits_sel == 3'd1 ? alu_out            [1:0] :
 
                                                               i_copro_read_data  [1:0] ;
 
 
 
 
 
// Used for the Rds output of register_bank - this special version of
 
// status_bits_mode speeds up the critical path from status_bits_mode through the
 
// register_bank, barrel_shifter and alu. It moves a mux needed for the
 
// i_user_mode_regs_store_nxt signal back into the previous stage -
 
// so its really part of the decode stage even though the logic is right here
 
// In addition the signal is one-hot encoded to further speed up the logic
 
 
 
assign status_bits_mode_rds_oh_nxt    = i_user_mode_regs_store_nxt ? 1'd1 << OH_USR                            :
 
                                        status_bits_mode_update    ? oh_status_bits_mode(status_bits_mode_nxt) :
 
                                                                     oh_status_bits_mode(status_bits_mode)     ;
 
 
 
 
 
assign status_bits_irq_mask_nxt  = i_status_bits_sel == 3'd0 ? i_status_bits_irq_mask      :
 
                                   i_status_bits_sel == 3'd1 ? alu_out                [27] :
 
                                                               i_copro_read_data      [27] ;
 
 
 
assign status_bits_firq_mask_nxt = i_status_bits_sel == 3'd0 ? i_status_bits_firq_mask     :
 
                                   i_status_bits_sel == 3'd1 ? alu_out                [26] :
 
                                                               i_copro_read_data      [26] ;
 
 
 
 
 
 
 
// ========================================================
 
// Adders
 
// ========================================================
 
assign pc_plus4      = pc        + 32'd4;
 
assign pc_minus4     = pc        - 32'd4;
 
assign address_plus4 = o_address + 32'd4;
 
assign alu_plus4     = alu_out   + 32'd4;
 
assign rn_plus4      = rn        + 32'd4;
 
 
 
// ========================================================
 
// Barrel Shift Amount Select
 
// ========================================================
 
// An immediate shift value of 0 is translated into 32
 
assign shift_amount = i_barrel_shift_amount_sel == 2'd0 ? 8'd0                           :
 
                      i_barrel_shift_amount_sel == 2'd1 ? rs[7:0]                       :
 
                      i_barrel_shift_amount_sel == 2'd2 ? {3'd0, i_imm_shift_amount    } :
 
                                                          {3'd0, i_read_data_alignment } ;
 
 
 
// ========================================================
 
// Barrel Shift Data Select
 
// ========================================================
 
assign barrel_shift_in = i_barrel_shift_data_sel == 2'd0 ? i_imm32       :
 
                         i_barrel_shift_data_sel == 2'd1 ? i_read_data   :
 
                                                           rm            ;
 
 
 
// ========================================================
 
// Interrupt vector Select
 
// ========================================================
 
 
 
assign interrupt_vector = // Reset vector
 
                          (i_interrupt_vector_sel == 3'd0) ? 32'h00000000 :
 
                          // Data abort interrupt vector                 
 
                          (i_interrupt_vector_sel == 3'd1) ? 32'h00000010 :
 
                          // Fast interrupt vector  
 
                          (i_interrupt_vector_sel == 3'd2) ? 32'h0000001c :
 
                          // Regular interrupt vector
 
                          (i_interrupt_vector_sel == 3'd3) ? 32'h00000018 :
 
                          // Prefetch abort interrupt vector
 
                          (i_interrupt_vector_sel == 3'd5) ? 32'h0000000c :
 
                          // Undefined instruction interrupt vector
 
                          (i_interrupt_vector_sel == 3'd6) ? 32'h00000004 :
 
                          // Software (SWI) interrupt vector
 
                          (i_interrupt_vector_sel == 3'd7) ? 32'h00000008 :
 
                          // Default is the address exception interrupt
 
                                                             32'h00000014 ;
 
 
 
 
 
// ========================================================
 
// Address Select
 
// ========================================================
 
 
 
// If rd is the pc, then seperate the address bits from the status bits for
 
// generating the next address to fetch
 
assign alu_out_pc_filtered = pc_wen && i_pc_sel == 2'd1 ? pcf(alu_out) : alu_out;
 
 
 
// if current instruction does not execute because it does not meet the condition
 
// then address advances to next instruction
 
assign o_address_nxt = (!execute)              ? pc_plus4              :
 
                       (i_address_sel == 4'd0) ? pc_plus4              :
 
                       (i_address_sel == 4'd1) ? alu_out_pc_filtered   :
 
                       (i_address_sel == 4'd2) ? interrupt_vector      :
 
                       (i_address_sel == 4'd3) ? pc                    :
 
                       (i_address_sel == 4'd4) ? rn                    :
 
                       (i_address_sel == 4'd5) ? address_plus4         :  // MTRANS address incrementer
 
                       (i_address_sel == 4'd6) ? alu_plus4             :  // MTRANS decrement after
 
                                                 rn_plus4              ;  // MTRANS increment before
 
 
 
// Data accesses use 32-bit address space, but instruction
 
// accesses are restricted to 26 bit space
 
assign adex_nxt      = |o_address_nxt[31:26] && !i_data_access_exec;
 
 
 
// ========================================================
 
// Program Counter Select
 
// ========================================================
 
// If current instruction does not execute because it does not meet the condition
 
// then PC advances to next instruction
 
assign pc_nxt = (!execute)       ? pc_plus4              :
 
                i_pc_sel == 2'd0 ? pc_plus4              :
 
                i_pc_sel == 2'd1 ? alu_out               :
 
                                   interrupt_vector      ;
 
 
 
 
 
// ========================================================
 
// Register Write Select
 
// ========================================================
 
wire [31:0] save_int_pc;
 
wire [31:0] save_int_pc_m4;
 
 
 
assign save_int_pc    = { status_bits_flags,
 
                          status_bits_irq_mask,
 
                          status_bits_firq_mask,
 
                          pc[25:2],
 
                          status_bits_mode      };
 
 
 
 
 
assign save_int_pc_m4 = { status_bits_flags,
 
                          status_bits_irq_mask,
 
                          status_bits_firq_mask,
 
                          pc_minus4[25:2],
 
                          status_bits_mode      };
 
 
 
 
 
assign reg_write_nxt = i_reg_write_sel == 3'd0 ? alu_out               :
 
                       // save pc to lr on an interrupt                    
 
                       i_reg_write_sel == 3'd1 ? save_int_pc_m4        :
 
                       // to update Rd at the end of Multiplication
 
                       i_reg_write_sel == 3'd2 ? multiply_out          :
 
                       i_reg_write_sel == 3'd3 ? o_status_bits         :
 
                       i_reg_write_sel == 3'd5 ? i_copro_read_data     :  // mrc
 
                       i_reg_write_sel == 3'd6 ? base_address          :
 
                                                 save_int_pc           ;
 
 
 
 
 
// ========================================================
 
// Byte Enable Select
 
// ========================================================
 
assign byte_enable_nxt = i_byte_enable_sel == 2'd0  ? 4'b1111 :  // word write
 
                         i_byte_enable_sel == 2'd2  ?            // halfword write
 
                         ( o_address_nxt[1] == 1'd0 ? 4'b0011 :
 
                                                      4'b1100  ) :
 
 
 
                         o_address_nxt[1:0] == 2'd0 ? 4'b0001 :  // byte write
 
                         o_address_nxt[1:0] == 2'd1 ? 4'b0010 :
 
                         o_address_nxt[1:0] == 2'd2 ? 4'b0100 :
 
                                                      4'b1000 ;
 
 
 
 
 
// ========================================================
 
// Write Data Select
 
// ========================================================
 
assign write_data_nxt = i_byte_enable_sel == 2'd0 ? rd            :
 
                                                    {4{rd[ 7:0]}} ;
 
 
 
 
 
// ========================================================
 
// Conditional Execution
 
// ========================================================
 
assign execute = conditional_execute ( i_condition, status_bits_flags );
 
 
 
// allow the PC to increment to the next instruction when current
 
// instruction does not execute
 
assign pc_wen       = i_pc_wen || !execute;
 
 
 
// only update register bank if current instruction executes
 
assign reg_bank_wen = {{15{execute}} & i_reg_bank_wen};
 
 
 
 
 
// ========================================================
 
// Priviledged output flag
 
// ========================================================
 
// Need to look at status_bits_mode_nxt so switch to priviledged mode
 
// at the same time as assert interrupt vector address
 
assign priviledged_nxt  = ( i_status_bits_mode_wen ? status_bits_mode_nxt : status_bits_mode ) != USR ;
 
 
 
 
 
// ========================================================
 
// Write Enable
 
// ========================================================
 
// This must be de-asserted when execute is fault
 
assign write_enable_nxt = execute && i_write_data_wen;
 
 
 
 
 
// ========================================================
 
// Register Update
 
// ========================================================
 
 
 
assign priviledged_update              = !i_fetch_stall;
 
assign data_access_update              = !i_fetch_stall && execute;
 
assign write_enable_update             = !i_fetch_stall;
 
assign write_data_update               = !i_fetch_stall && execute && i_write_data_wen;
 
assign exclusive_update                = !i_fetch_stall && execute;
 
assign address_update                  = !i_fetch_stall;
 
assign byte_enable_update              = !i_fetch_stall && execute && i_write_data_wen;
 
assign copro_write_data_update         = !i_fetch_stall && execute && i_copro_write_data_wen;
 
 
 
assign base_address_update             = !i_fetch_stall && execute && i_base_address_wen;
 
assign status_bits_flags_update        = !i_fetch_stall && execute && i_status_bits_flags_wen;
 
assign status_bits_mode_update         = !i_fetch_stall && execute && i_status_bits_mode_wen;
 
assign status_bits_mode_rds_oh_update  = !i_fetch_stall;
 
assign status_bits_irq_mask_update     = !i_fetch_stall && execute && i_status_bits_irq_mask_wen;
 
assign status_bits_firq_mask_update    = !i_fetch_stall && execute && i_status_bits_firq_mask_wen;
 
 
 
 
 
always @( posedge i_clk )
 
    begin
 
    o_priviledged           <= priviledged_update             ? priviledged_nxt              : o_priviledged;
 
    o_exclusive             <= exclusive_update               ? i_exclusive_exec             : o_exclusive;
 
    o_data_access           <= data_access_update             ? i_data_access_exec           : o_data_access;
 
    o_write_enable          <= write_enable_update            ? write_enable_nxt             : o_write_enable;
 
    o_write_data            <= write_data_update              ? write_data_nxt               : o_write_data;
 
    o_address               <= address_update                 ? o_address_nxt                : o_address;
 
    o_adex                  <= address_update                 ? adex_nxt                     : o_adex;
 
    o_address_valid         <= address_update                 ? 1'd1                         : o_address_valid;
 
    o_byte_enable           <= byte_enable_update             ? byte_enable_nxt              : o_byte_enable;
 
    o_copro_write_data      <= copro_write_data_update        ? write_data_nxt               : o_copro_write_data;
 
 
 
    base_address            <= base_address_update            ? rn                           : base_address;
 
 
 
    status_bits_flags       <= status_bits_flags_update       ? status_bits_flags_nxt        : status_bits_flags;
 
    status_bits_mode        <= status_bits_mode_update        ? status_bits_mode_nxt         : status_bits_mode;
 
    status_bits_mode_rds_oh <= status_bits_mode_rds_oh_update ? status_bits_mode_rds_oh_nxt  : status_bits_mode_rds_oh;
 
    status_bits_irq_mask    <= status_bits_irq_mask_update    ? status_bits_irq_mask_nxt     : status_bits_irq_mask;
 
    status_bits_firq_mask   <= status_bits_firq_mask_update   ? status_bits_firq_mask_nxt    : status_bits_firq_mask;
 
    end
 
 
 
 
 
// ========================================================
 
// Instantiate Barrel Shift
 
// ========================================================
 
a23_barrel_shift u_barrel_shift  (
 
    .i_in             ( barrel_shift_in           ),
 
    .i_carry_in       ( status_bits_flags[1]      ),
 
    .i_shift_amount   ( shift_amount              ),
 
    .i_shift_imm_zero ( i_shift_imm_zero          ),
 
    .i_function       ( i_barrel_shift_function   ),
 
 
 
    .o_out            ( barrel_shift_out          ),
 
    .o_carry_out      ( barrel_shift_carry        )
 
);
 
 
 
 
 
// ========================================================
 
// Instantiate ALU
 
// ========================================================
 
a23_alu u_alu (
 
    .i_a_in                 ( rn                    ),
 
    .i_b_in                 ( barrel_shift_out      ),
 
    .i_barrel_shift_carry   ( barrel_shift_carry    ),
 
    .i_status_bits_carry    ( status_bits_flags[1]  ),
 
    .i_function             ( i_alu_function        ),
 
 
 
    .o_out                  ( alu_out               ),
 
    .o_flags                ( alu_flags             )
 
);
 
 
 
 
 
// ========================================================
 
// Instantiate Booth 64-bit Multiplier-Accumulator
 
// ========================================================
 
a23_multiply u_multiply (
 
    .i_clk          ( i_clk                 ),
 
    .i_fetch_stall  ( i_fetch_stall         ),
 
    .i_a_in         ( rs                    ),
 
    .i_b_in         ( rm                    ),
 
    .i_function     ( i_multiply_function   ),
 
    .i_execute      ( execute               ),
 
    .o_out          ( multiply_out          ),
 
    .o_flags        ( multiply_flags        ),  // [1] = N, [0] = Z
 
    .o_done         ( o_multiply_done       )
 
);
 
 
 
 
 
// ========================================================
 
// Instantiate Register Bank
 
// ========================================================
 
a23_register_bank u_register_bank(
 
    .i_clk                   ( i_clk                     ),
 
    .i_fetch_stall           ( i_fetch_stall             ),
 
    .i_rm_sel                ( i_rm_sel                  ),
 
    .i_rds_sel               ( i_rds_sel                 ),
 
    .i_rn_sel                ( i_rn_sel                  ),
 
    .i_pc_wen                ( pc_wen                    ),
 
    .i_reg_bank_wen          ( reg_bank_wen              ),
 
    .i_pc                    ( pc_nxt[25:2]              ),
 
    .i_reg                   ( reg_write_nxt             ),
 
    .i_mode_idec             ( i_status_bits_mode        ),
 
    .i_mode_exec             ( status_bits_mode          ),
 
 
 
    .i_status_bits_flags     ( status_bits_flags         ),
 
    .i_status_bits_irq_mask  ( status_bits_irq_mask      ),
 
    .i_status_bits_firq_mask ( status_bits_firq_mask     ),
 
 
 
    // pre-encoded in decode stage to speed up long path
 
    .i_firq_not_user_mode    ( i_firq_not_user_mode      ),
 
 
 
    // use one-hot version for speed, combine with i_user_mode_regs_store
 
    .i_mode_rds_exec         ( status_bits_mode_rds_oh   ),
 
 
 
    .i_user_mode_regs_load   ( i_user_mode_regs_load     ),
 
    .o_rm                    ( rm                        ),
 
    .o_rs                    ( rs                        ),
 
    .o_rd                    ( rd                        ),
 
    .o_rn                    ( rn                        ),
 
    .o_pc                    ( pc                        )
 
);
 
 
 
 
 
// ========================================================
 
// Debug - non-synthesizable code
 
// ========================================================
 
//synopsys translate_off
 
 
 
wire    [(2*8)-1:0]    xCONDITION;
 
wire    [(4*8)-1:0]    xMODE;
 
 
 
assign  xCONDITION           = i_condition == EQ ? "EQ"  :
 
                               i_condition == NE ? "NE"  :
 
                               i_condition == CS ? "CS"  :
 
                               i_condition == CC ? "CC"  :
 
                               i_condition == MI ? "MI"  :
 
                               i_condition == PL ? "PL"  :
 
                               i_condition == VS ? "VS"  :
 
                               i_condition == VC ? "VC"  :
 
                               i_condition == HI ? "HI"  :
 
                               i_condition == LS ? "LS"  :
 
                               i_condition == GE ? "GE"  :
 
                               i_condition == LT ? "LT"  :
 
                               i_condition == GT ? "GT"  :
 
                               i_condition == LE ? "LE"  :
 
                               i_condition == AL ? "AL"  :
 
                                                   "NV " ;
 
 
 
assign  xMODE  =  status_bits_mode == SVC  ? "SVC"  :
 
                  status_bits_mode == IRQ  ? "IRQ"  :
 
                  status_bits_mode == FIRQ ? "FIRQ" :
 
                  status_bits_mode == USR  ? "USR"  :
 
                                             "XXX"  ;
 
 
 
 
 
//synopsys translate_on
 
 
 
endmodule
 
 
 
 
 
 
 No newline at end of file
 No newline at end of file

powered by: WebSVN 2.1.0

© copyright 1999-2024 OpenCores.org, equivalent to Oliscience, all rights reserved. OpenCores®, registered trademark.