URL
https://opencores.org/ocsvn/openmsp430/openmsp430/trunk
Subversion Repositories openmsp430
Compare Revisions
- This comparison shows the changes necessary to convert path
/
- from Rev 37 to Rev 38
- ↔ Reverse comparison
Rev 37 → Rev 38
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/sfr.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/dbg.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/dbg.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/dbg.v (nonexistent)
@@ -1,796 +0,0 @@
-//----------------------------------------------------------------------------
-// Copyright (C) 2001 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, write to the Free Software Foundation,
-// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
-//
-//----------------------------------------------------------------------------
-//
-// *File Name: dbg.v
-//
-// *Module Description:
-// Debug interface
-//
-// *Author(s):
-// - Olivier Girard, olgirard@gmail.com
-//
-//----------------------------------------------------------------------------
-// $Rev$
-// $LastChangedBy$
-// $LastChangedDate$
-//----------------------------------------------------------------------------
-`include "timescale.v"
-`include "openMSP430_defines.v"
-
-module dbg (
-
-// OUTPUTs
- dbg_freeze, // Freeze peripherals
- dbg_halt_cmd, // Halt CPU command
- dbg_mem_addr, // Debug address for rd/wr access
- dbg_mem_dout, // Debug unit data output
- dbg_mem_en, // Debug unit memory enable
- dbg_mem_wr, // Debug unit memory write
- dbg_reg_wr, // Debug unit CPU register write
- dbg_reset, // Reset CPU from debug interface
- dbg_uart_txd, // Debug interface: UART TXD
-
-// INPUTs
- dbg_halt_st, // Halt/Run status from CPU
- dbg_mem_din, // Debug unit Memory data input
- dbg_reg_din, // Debug unit CPU register data input
- dbg_uart_rxd, // Debug interface: UART RXD
- decode, // Frontend decode instruction
- eu_mab, // Execution-Unit Memory address bus
- eu_mb_en, // Execution-Unit Memory bus enable
- eu_mb_wr, // Execution-Unit Memory bus write transfer
- eu_mdb_in, // Memory data bus input
- eu_mdb_out, // Memory data bus output
- exec_done, // Execution completed
- fe_mb_en, // Frontend Memory bus enable
- fe_mdb_in, // Frontend Memory data bus input
- mclk, // Main system clock
- pc, // Program counter
- por, // Power on reset
- puc // Main system reset
-);
-
-// OUTPUTs
-//=========
-output dbg_freeze; // Freeze peripherals
-output dbg_halt_cmd; // Halt CPU command
-output [15:0] dbg_mem_addr; // Debug address for rd/wr access
-output [15:0] dbg_mem_dout; // Debug unit data output
-output dbg_mem_en; // Debug unit memory enable
-output [1:0] dbg_mem_wr; // Debug unit memory write
-output dbg_reg_wr; // Debug unit CPU register write
-output dbg_reset; // Reset CPU from debug interface
-output dbg_uart_txd; // Debug interface: UART TXD
-
-// INPUTs
-//=========
-input dbg_halt_st; // Halt/Run status from CPU
-input [15:0] dbg_mem_din; // Debug unit Memory data input
-input [15:0] dbg_reg_din; // Debug unit CPU register data input
-input dbg_uart_rxd; // Debug interface: UART RXD
-input decode; // Frontend decode instruction
-input [15:0] eu_mab; // Execution-Unit Memory address bus
-input eu_mb_en; // Execution-Unit Memory bus enable
-input [1:0] eu_mb_wr; // Execution-Unit Memory bus write transfer
-input [15:0] eu_mdb_in; // Memory data bus input
-input [15:0] eu_mdb_out; // Memory data bus output
-input exec_done; // Execution completed
-input fe_mb_en; // Frontend Memory bus enable
-input [15:0] fe_mdb_in; // Frontend Memory data bus input
-input mclk; // Main system clock
-input [15:0] pc; // Program counter
-input por; // Power on reset
-input puc; // Main system reset
-
-
-//=============================================================================
-// 1) WIRE & PARAMETER DECLARATION
-//=============================================================================
-
-// Diverse wires and registers
-wire [5:0] dbg_addr;
-wire [15:0] dbg_din;
-wire dbg_wr;
-reg mem_burst;
-wire dbg_reg_rd;
-wire dbg_mem_rd;
-reg dbg_mem_rd_dly;
-wire dbg_swbrk;
-wire dbg_rd;
-reg dbg_rd_rdy;
-wire mem_burst_rd;
-wire mem_burst_wr;
-wire brk0_halt;
-wire brk0_pnd;
-wire [15:0] brk0_dout;
-wire brk1_halt;
-wire brk1_pnd;
-wire [15:0] brk1_dout;
-wire brk2_halt;
-wire brk2_pnd;
-wire [15:0] brk2_dout;
-wire brk3_halt;
-wire brk3_pnd;
-wire [15:0] brk3_dout;
-
-// Register addresses
-parameter CPU_ID_LO = 6'h00;
-parameter CPU_ID_HI = 6'h01;
-parameter CPU_CTL = 6'h02;
-parameter CPU_STAT = 6'h03;
-parameter MEM_CTL = 6'h04;
-parameter MEM_ADDR = 6'h05;
-parameter MEM_DATA = 6'h06;
-parameter MEM_CNT = 6'h07;
-`ifdef DBG_HWBRK_0
-parameter BRK0_CTL = 6'h08;
-parameter BRK0_STAT = 6'h09;
-parameter BRK0_ADDR0 = 6'h0A;
-parameter BRK0_ADDR1 = 6'h0B;
-`endif
-`ifdef DBG_HWBRK_1
-parameter BRK1_CTL = 6'h0C;
-parameter BRK1_STAT = 6'h0D;
-parameter BRK1_ADDR0 = 6'h0E;
-parameter BRK1_ADDR1 = 6'h0F;
-`endif
-`ifdef DBG_HWBRK_2
-parameter BRK2_CTL = 6'h10;
-parameter BRK2_STAT = 6'h11;
-parameter BRK2_ADDR0 = 6'h12;
-parameter BRK2_ADDR1 = 6'h13;
-`endif
-`ifdef DBG_HWBRK_3
-parameter BRK3_CTL = 6'h14;
-parameter BRK3_STAT = 6'h15;
-parameter BRK3_ADDR0 = 6'h16;
-parameter BRK3_ADDR1 = 6'h17;
-`endif
-
-// Register one-hot decoder
-parameter CPU_ID_LO_D = (64'h1 << CPU_ID_LO);
-parameter CPU_ID_HI_D = (64'h1 << CPU_ID_HI);
-parameter CPU_CTL_D = (64'h1 << CPU_CTL);
-parameter CPU_STAT_D = (64'h1 << CPU_STAT);
-parameter MEM_CTL_D = (64'h1 << MEM_CTL);
-parameter MEM_ADDR_D = (64'h1 << MEM_ADDR);
-parameter MEM_DATA_D = (64'h1 << MEM_DATA);
-parameter MEM_CNT_D = (64'h1 << MEM_CNT);
-`ifdef DBG_HWBRK_0
-parameter BRK0_CTL_D = (64'h1 << BRK0_CTL);
-parameter BRK0_STAT_D = (64'h1 << BRK0_STAT);
-parameter BRK0_ADDR0_D = (64'h1 << BRK0_ADDR0);
-parameter BRK0_ADDR1_D = (64'h1 << BRK0_ADDR1);
-`endif
-`ifdef DBG_HWBRK_1
-parameter BRK1_CTL_D = (64'h1 << BRK1_CTL);
-parameter BRK1_STAT_D = (64'h1 << BRK1_STAT);
-parameter BRK1_ADDR0_D = (64'h1 << BRK1_ADDR0);
-parameter BRK1_ADDR1_D = (64'h1 << BRK1_ADDR1);
-`endif
-`ifdef DBG_HWBRK_2
-parameter BRK2_CTL_D = (64'h1 << BRK2_CTL);
-parameter BRK2_STAT_D = (64'h1 << BRK2_STAT);
-parameter BRK2_ADDR0_D = (64'h1 << BRK2_ADDR0);
-parameter BRK2_ADDR1_D = (64'h1 << BRK2_ADDR1);
-`endif
-`ifdef DBG_HWBRK_3
-parameter BRK3_CTL_D = (64'h1 << BRK3_CTL);
-parameter BRK3_STAT_D = (64'h1 << BRK3_STAT);
-parameter BRK3_ADDR0_D = (64'h1 << BRK3_ADDR0);
-parameter BRK3_ADDR1_D = (64'h1 << BRK3_ADDR1);
-`endif
-
-
-//============================================================================
-// 2) REGISTER DECODER
-//============================================================================
-
-// Select Data register during a burst
-wire [5:0] dbg_addr_in = mem_burst ? MEM_DATA : dbg_addr;
-
-// Register address decode
-reg [63:0] reg_dec;
-always @(dbg_addr_in)
- case (dbg_addr_in)
- CPU_ID_LO : reg_dec = CPU_ID_LO_D;
- CPU_ID_HI : reg_dec = CPU_ID_HI_D;
- CPU_CTL : reg_dec = CPU_CTL_D;
- CPU_STAT : reg_dec = CPU_STAT_D;
- MEM_CTL : reg_dec = MEM_CTL_D;
- MEM_ADDR : reg_dec = MEM_ADDR_D;
- MEM_DATA : reg_dec = MEM_DATA_D;
- MEM_CNT : reg_dec = MEM_CNT_D;
-`ifdef DBG_HWBRK_0
- BRK0_CTL : reg_dec = BRK0_CTL_D;
- BRK0_STAT : reg_dec = BRK0_STAT_D;
- BRK0_ADDR0: reg_dec = BRK0_ADDR0_D;
- BRK0_ADDR1: reg_dec = BRK0_ADDR1_D;
-`endif
-`ifdef DBG_HWBRK_1
- BRK1_CTL : reg_dec = BRK1_CTL_D;
- BRK1_STAT : reg_dec = BRK1_STAT_D;
- BRK1_ADDR0: reg_dec = BRK1_ADDR0_D;
- BRK1_ADDR1: reg_dec = BRK1_ADDR1_D;
-`endif
-`ifdef DBG_HWBRK_2
- BRK2_CTL : reg_dec = BRK2_CTL_D;
- BRK2_STAT : reg_dec = BRK2_STAT_D;
- BRK2_ADDR0: reg_dec = BRK2_ADDR0_D;
- BRK2_ADDR1: reg_dec = BRK2_ADDR1_D;
-`endif
-`ifdef DBG_HWBRK_3
- BRK3_CTL : reg_dec = BRK3_CTL_D;
- BRK3_STAT : reg_dec = BRK3_STAT_D;
- BRK3_ADDR0: reg_dec = BRK3_ADDR0_D;
- BRK3_ADDR1: reg_dec = BRK3_ADDR1_D;
-`endif
- default: reg_dec = {64{1'b0}};
- endcase
-
-// Read/Write probes
-wire reg_write = dbg_wr;
-wire reg_read = 1'b1;
-
-// Read/Write vectors
-wire [511:0] reg_wr = reg_dec & {64{reg_write}};
-wire [511:0] reg_rd = reg_dec & {64{reg_read}};
-
-
-//=============================================================================
-// 3) REGISTER: CORE INTERFACE
-//=============================================================================
-
-// CPU_ID Register
-//-----------------
-
-wire [3:0] cpu_id_rom = `ROM_AWIDTH;
-wire [3:0] cpu_id_ram = `RAM_AWIDTH;
-wire [31:0] cpu_id = {`DBG_ID, cpu_id_rom, cpu_id_ram};
-
-
-// CPU_CTL Register
-//-----------------------------------------------------------------------------
-// 7 6 5 4 3 2 1 0
-// Reserved CPU_RST RST_BRK_EN FRZ_BRK_EN SW_BRK_EN ISTEP RUN HALT
-//-----------------------------------------------------------------------------
-reg [6:3] cpu_ctl;
-
-wire cpu_ctl_wr = reg_wr[CPU_CTL];
-
-always @ (posedge mclk or posedge por)
- if (por) cpu_ctl <= 4'h0;
- else if (cpu_ctl_wr) cpu_ctl <= dbg_din[6:3];
-
-wire [7:0] cpu_ctl_full = {1'b0, cpu_ctl, 3'b000};
-
-wire halt_cpu = cpu_ctl_wr & dbg_din[`HALT] & ~dbg_halt_st;
-wire run_cpu = cpu_ctl_wr & dbg_din[`RUN] & dbg_halt_st;
-wire istep = cpu_ctl_wr & dbg_din[`ISTEP] & dbg_halt_st;
-
-
-// CPU_STAT Register
-//------------------------------------------------------------------------------------
-// 7 6 5 4 3 2 1 0
-// HWBRK3_PND HWBRK2_PND HWBRK1_PND HWBRK0_PND SWBRK_PND PUC_PND Res. HALT_RUN
-//------------------------------------------------------------------------------------
-reg [3:2] cpu_stat;
-
-wire cpu_stat_wr = reg_wr[CPU_STAT];
-wire [3:2] cpu_stat_set = {dbg_swbrk, puc};
-wire [3:2] cpu_stat_clr = ~dbg_din[3:2];
-
-always @ (posedge mclk or posedge por)
- if (por) cpu_stat <= 2'b00;
- else if (cpu_stat_wr) cpu_stat <= ((cpu_stat & cpu_stat_clr) | cpu_stat_set);
- else cpu_stat <= (cpu_stat | cpu_stat_set);
-
-wire [7:0] cpu_stat_full = {brk3_pnd, brk2_pnd, brk1_pnd, brk0_pnd,
- cpu_stat, 1'b0, dbg_halt_st};
-
-
-//=============================================================================
-// 4) REGISTER: MEMORY INTERFACE
-//=============================================================================
-
-// MEM_CTL Register
-//-----------------------------------------------------------------------------
-// 7 6 5 4 3 2 1 0
-// Reserved B/W MEM/REG RD/WR START
-//
-// START : - 0 : Do nothing.
-// - 1 : Initiate memory transfer.
-//
-// RD/WR : - 0 : Read access.
-// - 1 : Write access.
-//
-// MEM/REG: - 0 : Memory access.
-// - 1 : CPU Register access.
-//
-// B/W : - 0 : 16 bit access.
-// - 1 : 8 bit access (not valid for CPU Registers).
-//
-//-----------------------------------------------------------------------------
-reg [3:1] mem_ctl;
-
-wire mem_ctl_wr = reg_wr[MEM_CTL];
-
-always @ (posedge mclk or posedge por)
- if (por) mem_ctl <= 3'h0;
- else if (mem_ctl_wr) mem_ctl <= dbg_din[3:1];
-
-wire [7:0] mem_ctl_full = {4'b0000, mem_ctl, 1'b0};
-
-reg mem_start;
-always @ (posedge mclk or posedge por)
- if (por) mem_start <= 1'b0;
- else mem_start <= mem_ctl_wr & dbg_din[0];
-
-wire mem_bw = mem_ctl[3];
-
-// MEM_DATA Register
-//------------------
-reg [15:0] mem_data;
-reg [15:0] mem_addr;
-wire mem_access;
-
-wire mem_data_wr = reg_wr[MEM_DATA];
-
-wire [15:0] dbg_mem_din_bw = ~mem_bw ? dbg_mem_din :
- mem_addr[0] ? {8'h00, dbg_mem_din[15:8]} :
- {8'h00, dbg_mem_din[7:0]};
-
-always @ (posedge mclk or posedge por)
- if (por) mem_data <= 16'h0000;
- else if (mem_data_wr) mem_data <= dbg_din;
- else if (dbg_reg_rd) mem_data <= dbg_reg_din;
- else if (dbg_mem_rd_dly) mem_data <= dbg_mem_din_bw;
-
-
-// MEM_ADDR Register
-//------------------
-reg [15:0] mem_cnt;
-
-wire mem_addr_wr = reg_wr[MEM_ADDR];
-wire dbg_mem_acc = (|dbg_mem_wr | (dbg_rd_rdy & ~mem_ctl[2]));
-wire dbg_reg_acc = ( dbg_reg_wr | (dbg_rd_rdy & mem_ctl[2]));
-
-wire [15:0] mem_addr_inc = (mem_cnt==16'h0000) ? 16'h0000 :
- (dbg_mem_acc & ~mem_bw) ? 16'h0002 :
- (dbg_mem_acc | dbg_reg_acc) ? 16'h0001 : 16'h0000;
-
-always @ (posedge mclk or posedge por)
- if (por) mem_addr <= 16'h0000;
- else if (mem_addr_wr) mem_addr <= dbg_din;
- else mem_addr <= mem_addr + mem_addr_inc;
-
-// MEM_CNT Register
-//------------------
-
-wire mem_cnt_wr = reg_wr[MEM_CNT];
-
-wire [15:0] mem_cnt_dec = (mem_cnt==16'h0000) ? 16'h0000 :
- (dbg_mem_acc | dbg_reg_acc) ? 16'hffff : 16'h0000;
-
-always @ (posedge mclk or posedge por)
- if (por) mem_cnt <= 16'h0000;
- else if (mem_cnt_wr) mem_cnt <= dbg_din;
- else mem_cnt <= mem_cnt + mem_cnt_dec;
-
-
-//=============================================================================
-// 5) BREAKPOINTS / WATCHPOINTS
-//=============================================================================
-
-`ifdef DBG_HWBRK_0
-// Hardware Breakpoint/Watchpoint Register read select
-wire [3:0] brk0_reg_rd = {reg_rd[BRK0_ADDR1],
- reg_rd[BRK0_ADDR0],
- reg_rd[BRK0_STAT],
- reg_rd[BRK0_CTL]};
-
-// Hardware Breakpoint/Watchpoint Register write select
-wire [3:0] brk0_reg_wr = {reg_wr[BRK0_ADDR1],
- reg_wr[BRK0_ADDR0],
- reg_wr[BRK0_STAT],
- reg_wr[BRK0_CTL]};
-
-dbg_hwbrk dbg_hwbr_0 (
-
-// OUTPUTs
- .brk_halt (brk0_halt), // Hardware breakpoint command
- .brk_pnd (brk0_pnd), // Hardware break/watch-point pending
- .brk_dout (brk0_dout), // Hardware break/watch-point register data input
-
-// INPUTs
- .brk_reg_rd (brk0_reg_rd), // Hardware break/watch-point register read select
- .brk_reg_wr (brk0_reg_wr), // Hardware break/watch-point register write select
- .dbg_din (dbg_din), // Debug register data input
- .eu_mab (eu_mab), // Execution-Unit Memory address bus
- .eu_mb_en (eu_mb_en), // Execution-Unit Memory bus enable
- .eu_mb_wr (eu_mb_wr), // Execution-Unit Memory bus write transfer
- .eu_mdb_in (eu_mdb_in), // Memory data bus input
- .eu_mdb_out (eu_mdb_out), // Memory data bus output
- .exec_done (exec_done), // Execution completed
- .fe_mb_en (fe_mb_en), // Frontend Memory bus enable
- .mclk (mclk), // Main system clock
- .pc (pc), // Program counter
- .por (por) // Power on reset
-);
-
-`else
-assign brk0_halt = 1'b0;
-assign brk0_pnd = 1'b0;
-assign brk0_dout = 16'h0000;
-`endif
-
-`ifdef DBG_HWBRK_1
-// Hardware Breakpoint/Watchpoint Register read select
-wire [3:0] brk1_reg_rd = {reg_rd[BRK1_ADDR1],
- reg_rd[BRK1_ADDR0],
- reg_rd[BRK1_STAT],
- reg_rd[BRK1_CTL]};
-
-// Hardware Breakpoint/Watchpoint Register write select
-wire [3:0] brk1_reg_wr = {reg_wr[BRK1_ADDR1],
- reg_wr[BRK1_ADDR0],
- reg_wr[BRK1_STAT],
- reg_wr[BRK1_CTL]};
-
-dbg_hwbrk dbg_hwbr_1 (
-
-// OUTPUTs
- .brk_halt (brk1_halt), // Hardware breakpoint command
- .brk_pnd (brk1_pnd), // Hardware break/watch-point pending
- .brk_dout (brk1_dout), // Hardware break/watch-point register data input
-
-// INPUTs
- .brk_reg_rd (brk1_reg_rd), // Hardware break/watch-point register read select
- .brk_reg_wr (brk1_reg_wr), // Hardware break/watch-point register write select
- .dbg_din (dbg_din), // Debug register data input
- .eu_mab (eu_mab), // Execution-Unit Memory address bus
- .eu_mb_en (eu_mb_en), // Execution-Unit Memory bus enable
- .eu_mb_wr (eu_mb_wr), // Execution-Unit Memory bus write transfer
- .eu_mdb_in (eu_mdb_in), // Memory data bus input
- .eu_mdb_out (eu_mdb_out), // Memory data bus output
- .exec_done (exec_done), // Execution completed
- .fe_mb_en (fe_mb_en), // Frontend Memory bus enable
- .mclk (mclk), // Main system clock
- .pc (pc), // Program counter
- .por (por) // Power on reset
-);
-
-`else
-assign brk1_halt = 1'b0;
-assign brk1_pnd = 1'b0;
-assign brk1_dout = 16'h0000;
-`endif
-
- `ifdef DBG_HWBRK_2
-// Hardware Breakpoint/Watchpoint Register read select
-wire [3:0] brk2_reg_rd = {reg_rd[BRK2_ADDR1],
- reg_rd[BRK2_ADDR0],
- reg_rd[BRK2_STAT],
- reg_rd[BRK2_CTL]};
-
-// Hardware Breakpoint/Watchpoint Register write select
-wire [3:0] brk2_reg_wr = {reg_wr[BRK2_ADDR1],
- reg_wr[BRK2_ADDR0],
- reg_wr[BRK2_STAT],
- reg_wr[BRK2_CTL]};
-
-dbg_hwbrk dbg_hwbr_2 (
-
-// OUTPUTs
- .brk_halt (brk2_halt), // Hardware breakpoint command
- .brk_pnd (brk2_pnd), // Hardware break/watch-point pending
- .brk_dout (brk2_dout), // Hardware break/watch-point register data input
-
-// INPUTs
- .brk_reg_rd (brk2_reg_rd), // Hardware break/watch-point register read select
- .brk_reg_wr (brk2_reg_wr), // Hardware break/watch-point register write select
- .dbg_din (dbg_din), // Debug register data input
- .eu_mab (eu_mab), // Execution-Unit Memory address bus
- .eu_mb_en (eu_mb_en), // Execution-Unit Memory bus enable
- .eu_mb_wr (eu_mb_wr), // Execution-Unit Memory bus write transfer
- .eu_mdb_in (eu_mdb_in), // Memory data bus input
- .eu_mdb_out (eu_mdb_out), // Memory data bus output
- .exec_done (exec_done), // Execution completed
- .fe_mb_en (fe_mb_en), // Frontend Memory bus enable
- .mclk (mclk), // Main system clock
- .pc (pc), // Program counter
- .por (por) // Power on reset
-);
-
-`else
-assign brk2_halt = 1'b0;
-assign brk2_pnd = 1'b0;
-assign brk2_dout = 16'h0000;
-`endif
-
-`ifdef DBG_HWBRK_3
-// Hardware Breakpoint/Watchpoint Register read select
-wire [3:0] brk3_reg_rd = {reg_rd[BRK3_ADDR1],
- reg_rd[BRK3_ADDR0],
- reg_rd[BRK3_STAT],
- reg_rd[BRK3_CTL]};
-
-// Hardware Breakpoint/Watchpoint Register write select
-wire [3:0] brk3_reg_wr = {reg_wr[BRK3_ADDR1],
- reg_wr[BRK3_ADDR0],
- reg_wr[BRK3_STAT],
- reg_wr[BRK3_CTL]};
-
-dbg_hwbrk dbg_hwbr_3 (
-
-// OUTPUTs
- .brk_halt (brk3_halt), // Hardware breakpoint command
- .brk_pnd (brk3_pnd), // Hardware break/watch-point pending
- .brk_dout (brk3_dout), // Hardware break/watch-point register data input
-
-// INPUTs
- .brk_reg_rd (brk3_reg_rd), // Hardware break/watch-point register read select
- .brk_reg_wr (brk3_reg_wr), // Hardware break/watch-point register write select
- .dbg_din (dbg_din), // Debug register data input
- .eu_mab (eu_mab), // Execution-Unit Memory address bus
- .eu_mb_en (eu_mb_en), // Execution-Unit Memory bus enable
- .eu_mb_wr (eu_mb_wr), // Execution-Unit Memory bus write transfer
- .eu_mdb_in (eu_mdb_in), // Memory data bus input
- .eu_mdb_out (eu_mdb_out), // Memory data bus output
- .exec_done (exec_done), // Execution completed
- .fe_mb_en (fe_mb_en), // Frontend Memory bus enable
- .mclk (mclk), // Main system clock
- .pc (pc), // Program counter
- .por (por) // Power on reset
-);
-
-`else
-assign brk3_halt = 1'b0;
-assign brk3_pnd = 1'b0;
-assign brk3_dout = 16'h0000;
-`endif
-
-
-//============================================================================
-// 6) DATA OUTPUT GENERATION
-//============================================================================
-
-wire [15:0] cpu_id_lo_rd = cpu_id[15:0] & {16{reg_rd[CPU_ID_LO]}};
-wire [15:0] cpu_id_hi_rd = cpu_id[31:16] & {16{reg_rd[CPU_ID_HI]}};
-wire [15:0] cpu_ctl_rd = {8'h00, cpu_ctl_full} & {16{reg_rd[CPU_CTL]}};
-wire [15:0] cpu_stat_rd = {8'h00, cpu_stat_full} & {16{reg_rd[CPU_STAT]}};
-wire [15:0] mem_ctl_rd = {8'h00, mem_ctl_full} & {16{reg_rd[MEM_CTL]}};
-wire [15:0] mem_data_rd = mem_data & {16{reg_rd[MEM_DATA]}};
-wire [15:0] mem_addr_rd = mem_addr & {16{reg_rd[MEM_ADDR]}};
-wire [15:0] mem_cnt_rd = mem_cnt & {16{reg_rd[MEM_CNT]}};
-
-wire [15:0] dbg_dout = cpu_id_lo_rd |
- cpu_id_hi_rd |
- cpu_ctl_rd |
- cpu_stat_rd |
- mem_ctl_rd |
- mem_data_rd |
- mem_addr_rd |
- mem_cnt_rd |
- brk0_dout |
- brk1_dout |
- brk2_dout |
- brk3_dout;
-
-// Tell UART/JTAG interface that the data is ready to be read
-always @ (posedge mclk or posedge por)
- if (por) dbg_rd_rdy <= 1'b0;
- else if (mem_burst | mem_burst_rd) dbg_rd_rdy <= (dbg_reg_rd | dbg_mem_rd_dly);
- else dbg_rd_rdy <= dbg_rd;
-
-
-//============================================================================
-// 7) CPU CONTROL
-//============================================================================
-
-// Reset CPU
-//--------------------------
-wire dbg_reset = cpu_ctl[`CPU_RST];
-
-
-// Break after reset
-//--------------------------
-wire halt_rst = cpu_ctl[`RST_BRK_EN] & puc;
-
-
-// Freeze peripherals
-//--------------------------
-wire dbg_freeze = dbg_halt_st & cpu_ctl[`FRZ_BRK_EN];
-
-
-// Software break
-//--------------------------
-assign dbg_swbrk = (fe_mdb_in==`DBG_SWBRK_OP) & decode & cpu_ctl[`SW_BRK_EN];
-
-
-// Single step
-//--------------------------
-reg [1:0] inc_step;
-always @(posedge mclk or posedge por)
- if (por) inc_step <= 2'b00;
- else if (istep) inc_step <= 2'b11;
- else inc_step <= {inc_step[0], 1'b0};
-
-
-// Run / Halt
-//--------------------------
-reg halt_flag;
-
-wire mem_halt_cpu;
-wire mem_run_cpu;
-
-wire halt_flag_clr = run_cpu | mem_run_cpu;
-wire halt_flag_set = halt_cpu | halt_rst | dbg_swbrk | mem_halt_cpu |
- brk0_halt | brk1_halt | brk2_halt | brk3_halt;
-
-always @(posedge mclk or posedge por)
- if (por) halt_flag <= 1'b0;
- else if (halt_flag_clr) halt_flag <= 1'b0;
- else if (halt_flag_set) halt_flag <= 1'b1;
-
-wire dbg_halt_cmd = (halt_flag | halt_flag_set) & ~inc_step[1];
-
-
-//============================================================================
-// 8) MEMORY CONTROL
-//============================================================================
-
-// Control Memory bursts
-//------------------------------
-
-wire mem_burst_start = (mem_start & |mem_cnt);
-wire mem_burst_end = ((dbg_wr | dbg_rd_rdy) & ~|mem_cnt);
-
-// Detect when burst is on going
-always @(posedge mclk or posedge por)
- if (por) mem_burst <= 1'b0;
- else if (mem_burst_start) mem_burst <= 1'b1;
- else if (mem_burst_end) mem_burst <= 1'b0;
-
-// Control signals for UART/JTAG interface
-assign mem_burst_rd = (mem_burst_start & ~mem_ctl[1]);
-assign mem_burst_wr = (mem_burst_start & mem_ctl[1]);
-
-// Trigger CPU Register or memory access during a burst
-reg mem_startb;
-always @(posedge mclk or posedge por)
- if (por) mem_startb <= 1'b0;
- else mem_startb <= (mem_burst & (dbg_wr | dbg_rd)) | mem_burst_rd;
-
-// Combine single and burst memory start of sequence
-wire mem_seq_start = ((mem_start & ~|mem_cnt) | mem_startb);
-
-
-// Memory access state machine
-//------------------------------
-reg [1:0] mem_state;
-reg [1:0] mem_state_nxt;
-
-// State machine definition
-parameter M_IDLE = 2'h0;
-parameter M_SET_BRK = 2'h1;
-parameter M_ACCESS_BRK = 2'h2;
-parameter M_ACCESS = 2'h3;
-
-// State transition
-always @(mem_state or mem_seq_start or dbg_halt_st)
- case (mem_state)
- M_IDLE : mem_state_nxt = ~mem_seq_start ? M_IDLE :
- dbg_halt_st ? M_ACCESS : M_SET_BRK;
- M_SET_BRK : mem_state_nxt = dbg_halt_st ? M_ACCESS_BRK : M_SET_BRK;
- M_ACCESS_BRK : mem_state_nxt = M_IDLE;
- M_ACCESS : mem_state_nxt = M_IDLE;
- default : mem_state_nxt = M_IDLE;
- endcase
-
-// State machine
-always @(posedge mclk or posedge por)
- if (por) mem_state <= M_IDLE;
- else mem_state <= mem_state_nxt;
-
-// Utility signals
-assign mem_halt_cpu = (mem_state==M_IDLE) & (mem_state_nxt==M_SET_BRK);
-assign mem_run_cpu = (mem_state==M_ACCESS_BRK) & (mem_state_nxt==M_IDLE);
-assign mem_access = (mem_state==M_ACCESS) | (mem_state==M_ACCESS_BRK);
-
-
-// Interface to CPU Registers and Memory bacbkone
-//------------------------------------------------
-assign dbg_mem_addr = mem_addr;
-assign dbg_mem_dout = ~mem_bw ? mem_data :
- mem_addr[0] ? {mem_data[7:0], 8'h00} :
- {8'h00, mem_data[7:0]};
-
-assign dbg_reg_wr = mem_access & mem_ctl[1] & mem_ctl[2];
-assign dbg_reg_rd = mem_access & ~mem_ctl[1] & mem_ctl[2];
-
-assign dbg_mem_en = mem_access & ~mem_ctl[2];
-assign dbg_mem_rd = dbg_mem_en & ~mem_ctl[1];
-
-wire [1:0] dbg_mem_wr_msk = ~mem_bw ? 2'b11 :
- mem_addr[0] ? 2'b10 : 2'b01;
-assign dbg_mem_wr = {2{dbg_mem_en & mem_ctl[1]}} & dbg_mem_wr_msk;
-
-
-// It takes one additional cycle to read from Memory as from registers
-always @(posedge mclk or posedge por)
- if (por) dbg_mem_rd_dly <= 1'b0;
- else dbg_mem_rd_dly <= dbg_mem_rd;
-
-
-//=============================================================================
-// 9) UART COMMUNICATION
-//=============================================================================
-`ifdef DBG_UART
-dbg_uart dbg_uart_0 (
-
-// OUTPUTs
- .dbg_addr (dbg_addr), // Debug register address
- .dbg_din (dbg_din), // Debug register data input
- .dbg_rd (dbg_rd), // Debug register data read
- .dbg_uart_txd (dbg_uart_txd), // Debug interface: UART TXD
- .dbg_wr (dbg_wr), // Debug register data write
-
-// INPUTs
- .dbg_dout (dbg_dout), // Debug register data output
- .dbg_rd_rdy (dbg_rd_rdy), // Debug register data is ready for read
- .dbg_uart_rxd (dbg_uart_rxd), // Debug interface: UART RXD
- .mclk (mclk), // Main system clock
- .mem_burst (mem_burst), // Burst on going
- .mem_burst_end(mem_burst_end), // End TX/RX burst
- .mem_burst_rd (mem_burst_rd), // Start TX burst
- .mem_burst_wr (mem_burst_wr), // Start RX burst
- .mem_bw (mem_bw), // Burst byte width
- .por (por) // Power on reset
-);
-
-`else
-assign dbg_addr = 6'h00;
-assign dbg_din = 16'h0000;
-assign dbg_rd = 1'b0;
-assign dbg_uart_txd = 1'b0;
-assign dbg_wr = 1'b0;
-`endif
-
-
-//=============================================================================
-// 10) JTAG COMMUNICATION
-//=============================================================================
-`ifdef DBG_JTAG
-JTAG INTERFACE IS NOT SUPPORTED YET
-`else
-`endif
-
-endmodule // dbg
-
-
-
-
-
-
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/dbg.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/frontend.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/frontend.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/frontend.v (nonexistent)
@@ -1,756 +0,0 @@
-//----------------------------------------------------------------------------
-// Copyright (C) 2001 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, write to the Free Software Foundation,
-// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
-//
-//----------------------------------------------------------------------------
-//
-// *File Name: frontend.v
-//
-// *Module Description:
-// openMSP430 Instruction fetch and decode unit
-//
-// *Author(s):
-// - Olivier Girard, olgirard@gmail.com
-//
-//----------------------------------------------------------------------------
-// $Rev$
-// $LastChangedBy$
-// $LastChangedDate$
-//----------------------------------------------------------------------------
-`include "timescale.v"
-`include "openMSP430_defines.v"
-
-module frontend (
-
-// OUTPUTs
- dbg_halt_st, // Halt/Run status from CPU
- decode, // Frontend decode instruction
- e_state, // Execution state
- exec_done, // Execution completed
- inst_ad, // Decoded Inst: destination addressing mode
- inst_as, // Decoded Inst: source addressing mode
- inst_alu, // ALU control signals
- inst_bw, // Decoded Inst: byte width
- inst_dest, // Decoded Inst: destination (one hot)
- inst_dext, // Decoded Inst: destination extended instruction word
- inst_irq_rst, // Decoded Inst: Reset interrupt
- inst_jmp, // Decoded Inst: Conditional jump
- inst_sext, // Decoded Inst: source extended instruction word
- inst_so, // Decoded Inst: Single-operand arithmetic
- inst_src, // Decoded Inst: source (one hot)
- inst_type, // Decoded Instruction type
- irq_acc, // Interrupt request accepted (one-hot signal)
- mab, // Frontend Memory address bus
- mb_en, // Frontend Memory bus enable
- nmi_acc, // Non-Maskable interrupt request accepted
- pc, // Program counter
- pc_nxt, // Next PC value (for CALL & IRQ)
-
-// INPUTs
- cpuoff, // Turns off the CPU
- dbg_halt_cmd, // Halt CPU command
- dbg_reg_sel, // Debug selected register for rd/wr access
- fe_rom_wait, // Frontend wait for ROM
- gie, // General interrupt enable
- irq, // Maskable interrupts
- mclk, // Main system clock
- mdb_in, // Frontend Memory data bus input
- nmi_evt, // Non-maskable interrupt event
- pc_sw, // Program counter software value
- pc_sw_wr, // Program counter software write
- puc, // Main system reset
- wdt_irq // Watchdog-timer interrupt
-);
-
-// OUTPUTs
-//=========
-output dbg_halt_st; // Halt/Run status from CPU
-output decode; // Frontend decode instruction
-output [3:0] e_state; // Execution state
-output exec_done; // Execution completed
-output [7:0] inst_ad; // Decoded Inst: destination addressing mode
-output [7:0] inst_as; // Decoded Inst: source addressing mode
-output [11:0] inst_alu; // ALU control signals
-output inst_bw; // Decoded Inst: byte width
-output [15:0] inst_dest; // Decoded Inst: destination (one hot)
-output [15:0] inst_dext; // Decoded Inst: destination extended instruction word
-output inst_irq_rst; // Decoded Inst: Reset interrupt
-output [7:0] inst_jmp; // Decoded Inst: Conditional jump
-output [15:0] inst_sext; // Decoded Inst: source extended instruction word
-output [7:0] inst_so; // Decoded Inst: Single-operand arithmetic
-output [15:0] inst_src; // Decoded Inst: source (one hot)
-output [2:0] inst_type; // Decoded Instruction type
-output [13:0] irq_acc; // Interrupt request accepted (one-hot signal)
-output [15:0] mab; // Frontend Memory address bus
-output mb_en; // Frontend Memory bus enable
-output nmi_acc; // Non-Maskable interrupt request accepted
-output [15:0] pc; // Program counter
-output [15:0] pc_nxt; // Next PC value (for CALL & IRQ)
-
-// INPUTs
-//=========
-input cpuoff; // Turns off the CPU
-input dbg_halt_cmd; // Halt CPU command
-input [3:0] dbg_reg_sel; // Debug selected register for rd/wr access
-input fe_rom_wait; // Frontend wait for ROM
-input gie; // General interrupt enable
-input [13:0] irq; // Maskable interrupts
-input mclk; // Main system clock
-input [15:0] mdb_in; // Frontend Memory data bus input
-input nmi_evt; // Non-maskable interrupt event
-input [15:0] pc_sw; // Program counter software value
-input pc_sw_wr; // Program counter software write
-input puc; // Main system reset
-input wdt_irq; // Watchdog-timer interrupt
-
-
-//=============================================================================
-// 1) FRONTEND STATE MACHINE
-//=============================================================================
-
-// The wire "conv" is used as state bits to calculate the next response
-reg [2:0] i_state;
-reg [2:0] i_state_nxt;
-
-reg [1:0] inst_sz;
-wire [1:0] inst_sz_nxt;
-wire irq_detect;
-wire [2:0] inst_type_nxt;
-wire is_const;
-reg [15:0] sconst_nxt;
-reg [3:0] e_state_nxt;
-
-// State machine definitons
-parameter I_IRQ_FETCH = 3'h0;
-parameter I_IRQ_DONE = 3'h1;
-parameter I_DEC = 3'h2; // New instruction ready for decode
-parameter I_EXT1 = 3'h3; // 1st Extension word
-parameter I_EXT2 = 3'h4; // 2nd Extension word
-parameter I_IDLE = 3'h5; // CPU is in IDLE mode
-
-// States Transitions
-always @(i_state or inst_sz or inst_sz_nxt or pc_sw_wr or exec_done or
- exec_done or irq_detect or cpuoff or dbg_halt_cmd or e_state)
- case(i_state)
- I_IDLE : i_state_nxt = (irq_detect & ~dbg_halt_cmd) ? I_IRQ_FETCH :
- (~cpuoff & ~dbg_halt_cmd) ? I_DEC : I_IDLE;
- I_IRQ_FETCH: i_state_nxt = I_IRQ_DONE;
- I_IRQ_DONE : i_state_nxt = I_DEC;
- I_DEC : i_state_nxt = irq_detect ? I_IRQ_FETCH :
- (cpuoff | dbg_halt_cmd) & exec_done ? I_IDLE :
- dbg_halt_cmd & (e_state==`E_IDLE) ? I_IDLE :
- pc_sw_wr ? I_DEC :
- ~exec_done & ~(e_state==`E_IDLE) ? I_DEC : // Wait in decode state
- (inst_sz_nxt!=2'b00) ? I_EXT1 : I_DEC; // until execution is completed
- I_EXT1 : i_state_nxt = irq_detect ? I_IRQ_FETCH :
- pc_sw_wr ? I_DEC :
- (inst_sz!=2'b01) ? I_EXT2 : I_DEC;
- I_EXT2 : i_state_nxt = irq_detect ? I_IRQ_FETCH : I_DEC;
- default : i_state_nxt = I_IRQ_FETCH;
- endcase
-
-// State machine
-always @(posedge mclk or posedge puc)
- if (puc) i_state <= I_IRQ_FETCH;
- else i_state <= i_state_nxt;
-
-// Utility signals
-wire decode = ((i_state==I_DEC) & (exec_done | (e_state==`E_IDLE))) | irq_detect;
-wire fetch = ~((i_state==I_DEC) & ~(exec_done | (e_state==`E_IDLE))) & ~(e_state_nxt==`E_IDLE);
-
-// Debug interface cpu status
-reg dbg_halt_st;
-always @(posedge mclk or posedge puc)
- if (puc) dbg_halt_st <= 1'b0;
- else dbg_halt_st <= dbg_halt_cmd & (i_state_nxt==I_IDLE);
-
-
-//=============================================================================
-// 2) INTERRUPT HANDLING
-//=============================================================================
-
-// Detect nmi interrupt
-reg inst_nmi;
-always @(posedge mclk or posedge puc)
- if (puc) inst_nmi <= 1'b0;
- else if (nmi_evt) inst_nmi <= 1'b1;
- else if (i_state==I_IRQ_DONE) inst_nmi <= 1'b0;
-
-
-// Detect reset interrupt
-reg inst_irq_rst;
-always @(posedge mclk or posedge puc)
- if (puc) inst_irq_rst <= 1'b1;
- else if (exec_done) inst_irq_rst <= 1'b0;
-
-// Detect other interrupts
-assign irq_detect = (inst_nmi | ((|irq | wdt_irq) & gie)) & ~dbg_halt_cmd & (exec_done | (i_state==I_IDLE));
-
-// Select interrupt vector
-reg [3:0] irq_num;
-always @(posedge mclk or posedge puc)
- if (puc) irq_num <= 4'hf;
- else if (irq_detect) irq_num <= inst_nmi ? 4'he :
- irq[13] ? 4'hd :
- irq[12] ? 4'hc :
- irq[11] ? 4'hb :
- (irq[10] | wdt_irq) ? 4'ha :
- irq[9] ? 4'h9 :
- irq[8] ? 4'h8 :
- irq[7] ? 4'h7 :
- irq[6] ? 4'h6 :
- irq[5] ? 4'h5 :
- irq[4] ? 4'h4 :
- irq[3] ? 4'h3 :
- irq[2] ? 4'h2 :
- irq[1] ? 4'h1 :
- irq[0] ? 4'h0 : 4'hf;
-
-wire [15:0] irq_addr = {11'h7ff, irq_num, 1'b0};
-
-// Interrupt request accepted
-wire [15:0] irq_acc_all = (16'h0001 << irq_num) & {16{(i_state==I_IRQ_FETCH)}};
-wire [13:0] irq_acc = irq_acc_all[13:0];
-wire nmi_acc = irq_acc_all[14];
-
-
-//=============================================================================
-// 3) FETCH INSTRUCTION
-//=============================================================================
-
-//
-// 3.1) PROGRAM COUNTER & MEMORY INTERFACE
-//-----------------------------------------
-
-// Program counter
-reg [15:0] pc;
-
-// Detect if PC needs to be incremented
-wire pc_inc = (~pc_sw_wr & fetch) & ~(i_state==I_IRQ_FETCH) & ~(i_state==I_IRQ_DONE);
-
-// Mux between software update and old PC
-wire [15:0] pc_sel = pc_sw_wr ? pc_sw :
- (i_state==I_IRQ_FETCH) ? irq_addr :
- (i_state==I_IRQ_DONE) ? mdb_in : pc;
-
-// Compute next PC value
-wire [15:0] pc_nxt = pc_sel + {14'h0000, pc_inc, 1'b0};
-
-always @(posedge mclk or posedge puc)
- if (puc) pc <= 16'h0000;
- else pc <= pc_nxt;
-
-// Check if ROM has been busy in order to retry ROM access
-reg rom_busy;
-always @(posedge mclk or posedge puc)
- if (puc) rom_busy <= 16'h0000;
- else rom_busy <= fe_rom_wait;
-
-// Memory interface
-wire [15:0] mab = pc_nxt;
-wire mb_en = fetch | pc_sw_wr | (i_state==I_IRQ_FETCH) | rom_busy | (dbg_halt_st & ~dbg_halt_cmd);
-
-
-//
-// 3.2) INSTRUCTION REGISTER
-//--------------------------------
-
-// Instruction register
-wire [15:0] ir = mdb_in;
-
-// Detect if source extension word is required
-wire is_sext = (inst_as[`IDX] | inst_as[`SYMB] | inst_as[`ABS] | inst_as[`IMM]);
-
-// Detect if destination extension word is required
-wire is_dext = (inst_ad[`IDX] | inst_ad[`SYMB] | inst_ad[`ABS]);
-
-// For the Symbolic addressing mode, add -2 to the extension word in order
-// to make up for the PC address
-wire [15:0] ext_incr = ((i_state==I_EXT1) & inst_as[`SYMB]) |
- ((i_state==I_EXT2) & inst_ad[`SYMB]) |
- ((i_state==I_EXT1) & ~inst_as[`SYMB] &
- ~(i_state_nxt==I_EXT2) & inst_ad[`SYMB]) ? 16'hfffe : 16'h0000;
-
-wire [15:0] ext_nxt = ir + ext_incr;
-
-// Store source extension word
-reg [15:0] inst_sext;
-always @(posedge mclk or posedge puc)
- if (puc) inst_sext <= 16'h0000;
- else if (decode & is_const) inst_sext <= sconst_nxt;
- else if (decode & inst_type_nxt[`INST_JMP]) inst_sext <= {{5{ir[9]}},ir[9:0],1'b0};
- else if ((i_state==I_EXT1) & is_sext) inst_sext <= ext_nxt;
-
-// Source extension word is ready
-wire inst_sext_rdy = (i_state==I_EXT1) & is_sext;
-
-
-// Store destination extension word
-reg [15:0] inst_dext;
-always @(posedge mclk or posedge puc)
- if (puc) inst_dext <= 16'h0000;
- else if ((i_state==I_EXT1) & ~is_sext) inst_dext <= ext_nxt;
- else if (i_state==I_EXT2) inst_dext <= ext_nxt;
-
-// Destination extension word is ready
-wire inst_dext_rdy = (((i_state==I_EXT1) & ~is_sext) | (i_state==I_EXT2));
-
-
-//=============================================================================
-// 4) DECODE INSTRUCTION
-//=============================================================================
-
-//
-// 4.1) OPCODE: INSTRUCTION TYPE
-//----------------------------------------
-// Instructions type is encoded in a one hot fashion as following:
-//
-// 3'b001: Single-operand arithmetic
-// 3'b010: Conditional jump
-// 3'b100: Two-operand arithmetic
-
-reg [2:0] inst_type;
-assign inst_type_nxt = {(ir[15:14]!=2'b00),
- (ir[15:13]==3'b001),
- (ir[15:13]==3'b000)} & {3{~irq_detect}};
-
-always @(posedge mclk or posedge puc)
- if (puc) inst_type <= 3'b000;
- else if (decode) inst_type <= inst_type_nxt;
-
-//
-// 4.2) OPCODE: SINGLE-OPERAND ARITHMETIC
-//----------------------------------------
-// Instructions are encoded in a one hot fashion as following:
-//
-// 8'b00000001: RRC
-// 8'b00000010: SWPB
-// 8'b00000100: RRA
-// 8'b00001000: SXT
-// 8'b00010000: PUSH
-// 8'b00100000: CALL
-// 8'b01000000: RETI
-// 8'b10000000: IRQ
-
-reg [7:0] inst_so;
-wire [7:0] inst_so_nxt = irq_detect ? 8'h80 : ((8'h01<
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/frontend.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/watchdog.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/watchdog.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/watchdog.v (nonexistent)
@@ -1,220 +0,0 @@
-//----------------------------------------------------------------------------
-// Copyright (C) 2001 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, write to the Free Software Foundation,
-// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
-//
-//----------------------------------------------------------------------------
-//
-// *File Name: watchdog.v
-//
-// *Module Description:
-// Watchdog Timer
-//
-// *Author(s):
-// - Olivier Girard, olgirard@gmail.com
-//
-//----------------------------------------------------------------------------
-// $Rev$
-// $LastChangedBy$
-// $LastChangedDate$
-//----------------------------------------------------------------------------
-`include "timescale.v"
-`include "openMSP430_defines.v"
-
-module watchdog (
-
-// OUTPUTs
- nmi_evt, // NMI Event
- per_dout, // Peripheral data output
- wdtifg_set, // Set Watchdog-timer interrupt flag
- wdtpw_error, // Watchdog-timer password error
- wdttmsel, // Watchdog-timer mode select
-
-// INPUTs
- aclk_en, // ACLK enable
- dbg_freeze, // Freeze Watchdog counter
- mclk, // Main system clock
- nmi, // Non-maskable interrupt (asynchronous)
- nmie, // Non-maskable interrupt enable
- per_addr, // Peripheral address
- per_din, // Peripheral data input
- per_en, // Peripheral enable (high active)
- per_wen, // Peripheral write enable (high active)
- puc, // Main system reset
- smclk_en, // SMCLK enable
- wdtie // Watchdog timer interrupt enable
-);
-
-// OUTPUTs
-//=========
-output nmi_evt; // NMI Event
-output [15:0] per_dout; // Peripheral data output
-output wdtifg_set; // Set Watchdog-timer interrupt flag
-output wdtpw_error; // Watchdog-timer password error
-output wdttmsel; // Watchdog-timer mode select
-
-// INPUTs
-//=========
-input aclk_en; // ACLK enable
-input dbg_freeze; // Freeze Watchdog counter
-input mclk; // Main system clock
-input nmi; // Non-maskable interrupt (asynchronous)
-input nmie; // Non-maskable interrupt enable
-input [7:0] per_addr; // Peripheral address
-input [15:0] per_din; // Peripheral data input
-input per_en; // Peripheral enable (high active)
-input [1:0] per_wen; // Peripheral write enable (high active)
-input puc; // Main system reset
-input smclk_en; // SMCLK enable
-input wdtie; // Watchdog timer interrupt enable
-
-
-//=============================================================================
-// 1) PARAMETER DECLARATION
-//=============================================================================
-
-// Register addresses
-parameter WDTCTL = 9'h120;
-
-
-// Register one-hot decoder
-parameter WDTCTL_D = (512'h1 << WDTCTL);
-
-
-//============================================================================
-// 2) REGISTER DECODER
-//============================================================================
-
-// Register address decode
-reg [511:0] reg_dec;
-always @(per_addr)
- case ({per_addr,1'b0})
- WDTCTL : reg_dec = WDTCTL_D;
- default: reg_dec = {512{1'b0}};
- endcase
-
-// Read/Write probes
-wire reg_write = |per_wen & per_en;
-wire reg_read = ~|per_wen & per_en;
-
-// Read/Write vectors
-wire [511:0] reg_wr = reg_dec & {512{reg_write}};
-wire [511:0] reg_rd = reg_dec & {512{reg_read}};
-
-
-//============================================================================
-// 3) REGISTERS
-//============================================================================
-
-// WDTCTL Register
-//-----------------
-// WDTNMI & WDTSSEL are not implemented and therefore masked
-
-reg [7:0] wdtctl;
-
-wire wdtctl_wr = reg_wr[WDTCTL];
-
-always @ (posedge mclk or posedge puc)
- if (puc) wdtctl <= 8'h00;
- else if (wdtctl_wr) wdtctl <= per_din[7:0] & 8'hd7;
-
-wire wdtpw_error = wdtctl_wr & (per_din[15:8]!=8'h5a);
-wire wdttmsel = wdtctl[4];
-
-
-//============================================================================
-// 3) REGISTERS
-//============================================================================
-
-// Data output mux
-wire [15:0] wdtctl_rd = {8'h69, wdtctl} & {16{reg_rd[WDTCTL]}};
-
-wire [15:0] per_dout = wdtctl_rd;
-
-
-//=============================================================================
-// 4) NMI GENERATION
-//=============================================================================
-
-// Synchronization state
-reg [2:0] nmi_sync;
-always @ (posedge mclk or posedge puc)
- if (puc) nmi_sync <= 3'h0;
- else nmi_sync <= {nmi_sync[1:0], nmi};
-
-// Edge detection
-wire nmi_re = ~nmi_sync[2] & nmi_sync[0] & nmie;
-wire nmi_fe = nmi_sync[2] & ~nmi_sync[0] & nmie;
-
-// NMI event
-wire nmi_evt = wdtctl[6] ? nmi_fe : nmi_re;
-
-
-//=============================================================================
-// 5) WATCHDOG TIMER
-//=============================================================================
-
-// Watchdog clock source selection
-//---------------------------------
-wire clk_src_en = wdtctl[2] ? aclk_en : smclk_en;
-
-
-// Watchdog 16 bit counter
-//--------------------------
-reg [15:0] wdtcnt;
-
-wire wdtcnt_clr = (wdtctl_wr & per_din[3]) | wdtifg_set;
-
-always @ (posedge mclk or posedge puc)
- if (puc) wdtcnt <= 16'h0000;
- else if (wdtcnt_clr) wdtcnt <= 16'h0000;
- else if (~wdtctl[7] & clk_src_en & ~dbg_freeze) wdtcnt <= wdtcnt+16'h0001;
-
-
-// Interval selection mux
-//--------------------------
-reg wdtqn;
-
-always @(wdtctl or wdtcnt)
- case(wdtctl[1:0])
- 2'b00 : wdtqn = wdtcnt[15];
- 2'b01 : wdtqn = wdtcnt[13];
- 2'b10 : wdtqn = wdtcnt[9];
- default: wdtqn = wdtcnt[6];
- endcase
-
-
-// Watchdog event detection
-//-----------------------------
-reg wdtqn_dly;
-
-always @ (posedge mclk or posedge puc)
- if (puc) wdtqn_dly <= 1'b0;
- else wdtqn_dly <= wdtqn;
-
-wire wdtifg_set = (~wdtqn_dly & wdtqn) | wdtpw_error;
-
-
-endmodule // watchdog
-
-
-
-
-
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/watchdog.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/clock_module.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/clock_module.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/clock_module.v (nonexistent)
@@ -1,246 +0,0 @@
-//----------------------------------------------------------------------------
-// Copyright (C) 2001 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, write to the Free Software Foundation,
-// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
-//
-//----------------------------------------------------------------------------
-//
-// *File Name: clock_module.v
-//
-// *Module Description:
-// Basic clock module implementation.
-// Since the openMSP430 mainly targets FPGA and hobby
-// designers. The clock structure has been greatly
-// symplified in order to ease integration.
-// See online wiki for more info.
-//
-// *Author(s):
-// - Olivier Girard, olgirard@gmail.com
-//
-//----------------------------------------------------------------------------
-// $Rev$
-// $LastChangedBy$
-// $LastChangedDate$
-//----------------------------------------------------------------------------
-`include "timescale.v"
-`include "openMSP430_defines.v"
-
-module clock_module (
-
-// OUTPUTs
- aclk_en, // ACLK enable
- mclk, // Main system clock
- per_dout, // Peripheral data output
- por, // Power-on reset
- puc, // Main system reset
- smclk_en, // SMCLK enable
-
-// INPUTs
- dbg_reset, // Reset CPU from debug interface
- dco_clk, // Fast oscillator (fast clock)
- lfxt_clk, // Low frequency oscillator (typ 32kHz)
- oscoff, // Turns off LFXT1 clock input
- per_addr, // Peripheral address
- per_din, // Peripheral data input
- per_en, // Peripheral enable (high active)
- per_wen, // Peripheral write enable (high active)
- reset_n, // Reset Pin (low active)
- scg1, // System clock generator 1. Turns off the SMCLK
- wdt_reset // Watchdog-timer reset
-);
-
-// OUTPUTs
-//=========
-output aclk_en; // ACLK enable
-output mclk; // Main system clock
-output [15:0] per_dout; // Peripheral data output
-output por; // Power-on reset
-output puc; // Main system reset
-output smclk_en; // SMCLK enable
-
-// INPUTs
-//=========
-input dbg_reset; // Reset CPU from debug interface
-input dco_clk; // Fast oscillator (fast clock)
-input lfxt_clk; // Low frequency oscillator (typ 32kHz)
-input oscoff; // Turns off LFXT1 clock input
-input [7:0] per_addr; // Peripheral address
-input [15:0] per_din; // Peripheral data input
-input per_en; // Peripheral enable (high active)
-input [1:0] per_wen; // Peripheral write enable (high active)
-input reset_n; // Reset Pin (low active)
-input scg1; // System clock generator 1. Turns off the SMCLK
-input wdt_reset; // Watchdog-timer reset
-
-
-//=============================================================================
-// 1) PARAMETER DECLARATION
-//=============================================================================
-
-// Register addresses
-parameter BCSCTL1 = 9'h057;
-parameter BCSCTL2 = 9'h058;
-
-// Register one-hot decoder
-parameter BCSCTL1_D = (256'h1 << (BCSCTL1 /2));
-parameter BCSCTL2_D = (256'h1 << (BCSCTL2 /2));
-
-
-//============================================================================
-// 2) REGISTER DECODER
-//============================================================================
-
-// Register address decode
-reg [255:0] reg_dec;
-always @(per_addr)
- case (per_addr)
- (BCSCTL1 /2): reg_dec = BCSCTL1_D;
- (BCSCTL2 /2): reg_dec = BCSCTL2_D;
- default : reg_dec = {256{1'b0}};
- endcase
-
-// Read/Write probes
-wire reg_lo_write = per_wen[0] & per_en;
-wire reg_hi_write = per_wen[1] & per_en;
-wire reg_read = ~|per_wen & per_en;
-
-// Read/Write vectors
-wire [255:0] reg_hi_wr = reg_dec & {256{reg_hi_write}};
-wire [255:0] reg_lo_wr = reg_dec & {256{reg_lo_write}};
-wire [255:0] reg_rd = reg_dec & {256{reg_read}};
-
-
-//============================================================================
-// 3) REGISTERS
-//============================================================================
-
-// BCSCTL1 Register
-//--------------
-reg [7:0] bcsctl1;
-wire bcsctl1_wr = BCSCTL1[0] ? reg_hi_wr[BCSCTL1/2] : reg_lo_wr[BCSCTL1/2];
-wire [7:0] bcsctl1_nxt = BCSCTL1[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) bcsctl1 <= 8'h00;
- else if (bcsctl1_wr) bcsctl1 <= bcsctl1_nxt & 8'h30; // Mask unused bits
-
-
-// BCSCTL2 Register
-//--------------
-reg [7:0] bcsctl2;
-wire bcsctl2_wr = BCSCTL2[0] ? reg_hi_wr[BCSCTL2/2] : reg_lo_wr[BCSCTL2/2];
-wire [7:0] bcsctl2_nxt = BCSCTL2[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) bcsctl2 <= 8'h00;
- else if (bcsctl2_wr) bcsctl2 <= bcsctl2_nxt & 8'h0e; // Mask unused bits
-
-
-//============================================================================
-// 4) DATA OUTPUT GENERATION
-//============================================================================
-
-// Data output mux
-wire [15:0] bcsctl1_rd = (bcsctl1 & {8{reg_rd[BCSCTL1/2]}}) << (8 & {4{BCSCTL1[0]}});
-wire [15:0] bcsctl2_rd = (bcsctl2 & {8{reg_rd[BCSCTL2/2]}}) << (8 & {4{BCSCTL2[0]}});
-
-wire [15:0] per_dout = bcsctl1_rd |
- bcsctl2_rd;
-
-
-//=============================================================================
-// 5) CLOCK GENERATION
-//=============================================================================
-
-// Synchronize LFXT_CLK & edge detection
-//---------------------------------------
-reg [2:0] lfxt_clk_s;
-
-always @ (posedge mclk or posedge puc)
- if (puc) lfxt_clk_s <= 3'b000;
- else lfxt_clk_s <= {lfxt_clk_s[1:0], lfxt_clk};
-
-wire lfxt_clk_en = (lfxt_clk_s[1] & ~lfxt_clk_s[2]) & ~(oscoff & ~bcsctl2[`SELS]);
-
-
-// Generate main system clock
-//----------------------------
-
-wire mclk = dco_clk;
-wire mclk_n = !dco_clk;
-
-
-// Generate ACLK
-//----------------------------
-
-reg [2:0] aclk_div;
-
-wire aclk_en = lfxt_clk_en & ((bcsctl1[`DIVAx]==2'b00) ? 1'b1 :
- (bcsctl1[`DIVAx]==2'b01) ? aclk_div[0] :
- (bcsctl1[`DIVAx]==2'b10) ? &aclk_div[1:0] :
- &aclk_div[2:0]);
-
-always @ (posedge mclk or posedge puc)
- if (puc) aclk_div <= 3'h0;
- else if ((bcsctl1[`DIVAx]!=2'b00) & lfxt_clk_en) aclk_div <= aclk_div+3'h1;
-
-
-// Generate SMCLK
-//----------------------------
-
-reg [2:0] smclk_div;
-
-wire smclk_in = ~scg1 & (bcsctl2[`SELS] ? lfxt_clk_en : 1'b1);
-
-wire smclk_en = smclk_in & ((bcsctl2[`DIVSx]==2'b00) ? 1'b1 :
- (bcsctl2[`DIVSx]==2'b01) ? smclk_div[0] :
- (bcsctl2[`DIVSx]==2'b10) ? &smclk_div[1:0] :
- &smclk_div[2:0]);
-
-always @ (posedge mclk or posedge puc)
- if (puc) smclk_div <= 3'h0;
- else if ((bcsctl2[`DIVSx]!=2'b00) & smclk_in) smclk_div <= smclk_div+3'h1;
-
-
-//=============================================================================
-// 6) RESET GENERATION
-//=============================================================================
-
-// Generate synchronized POR
-wire por_reset = !reset_n;
-
-reg [1:0] por_s;
-always @(posedge mclk_n or posedge por_reset)
- if (por_reset) por_s <= 2'b11;
- else por_s <= {por_s[0], 1'b0};
-wire por = por_s[1];
-
-// Generate main system reset
-wire puc_reset = por_reset | wdt_reset | dbg_reset;
-
-reg [1:0] puc_s;
-always @(posedge mclk_n or posedge puc_reset)
- if (puc_reset) puc_s <= 2'b11;
- else puc_s <= {puc_s[0], 1'b0};
-wire puc = puc_s[1];
-
-
-endmodule // clock_module
-
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/clock_module.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/alu.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/alu.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/alu.v (nonexistent)
@@ -1,248 +0,0 @@
-//----------------------------------------------------------------------------
-// Copyright (C) 2001 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, write to the Free Software Foundation,
-// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
-//
-//----------------------------------------------------------------------------
-//
-// *File Name: alu.v
-//
-// *Module Description:
-// openMSP430 ALU
-//
-// *Author(s):
-// - Olivier Girard, olgirard@gmail.com
-//
-//----------------------------------------------------------------------------
-// $Rev$
-// $LastChangedBy$
-// $LastChangedDate$
-//----------------------------------------------------------------------------
-`include "timescale.v"
-`include "openMSP430_defines.v"
-
-module alu (
-
-// OUTPUTs
- alu_out, // ALU output value
- alu_out_add, // ALU adder output value
- alu_stat, // ALU Status {V,N,Z,C}
- alu_stat_wr, // ALU Status write {V,N,Z,C}
-
-// INPUTs
- dbg_halt_st, // Halt/Run status from CPU
- exec_cycle, // Instruction execution cycle
- inst_alu, // ALU control signals
- inst_bw, // Decoded Inst: byte width
- inst_jmp, // Decoded Inst: Conditional jump
- inst_so, // Single-operand arithmetic
- op_dst, // Destination operand
- op_src, // Source operand
- status // R2 Status {V,N,Z,C}
-);
-
-// OUTPUTs
-//=========
-output [15:0] alu_out; // ALU output value
-output [15:0] alu_out_add; // ALU adder output value
-output [3:0] alu_stat; // ALU Status {V,N,Z,C}
-output [3:0] alu_stat_wr; // ALU Status write {V,N,Z,C}
-
-// INPUTs
-//=========
-input dbg_halt_st; // Halt/Run status from CPU
-input exec_cycle; // Instruction execution cycle
-input [11:0] inst_alu; // ALU control signals
-input inst_bw; // Decoded Inst: byte width
-input [7:0] inst_jmp; // Decoded Inst: Conditional jump
-input [7:0] inst_so; // Single-operand arithmetic
-input [15:0] op_dst; // Destination operand
-input [15:0] op_src; // Source operand
-input [3:0] status; // R2 Status {V,N,Z,C}
-
-
-//=============================================================================
-// 1) FUNCTIONS
-//=============================================================================
-
-function [4:0] bcd_add;
-
- input [3:0] X;
- input [3:0] Y;
- input C;
-
- reg [4:0] Z;
- begin
- Z = {1'b0,X}+{1'b0,Y}+C;
- if (Z<10) bcd_add = Z;
- else bcd_add = Z+6;
- end
-
-endfunction
-
-
-//=============================================================================
-// 2) INSTRUCTION FETCH/DECODE CONTROL STATE MACHINE
-//=============================================================================
-// SINGLE-OPERAND ARITHMETIC:
-//-----------------------------------------------------------------------------
-// Mnemonic S-Reg, Operation Status bits
-// D-Reg, V N Z C
-//
-// RRC dst C->MSB->...LSB->C * * * *
-// RRA dst MSB->MSB->...LSB->C 0 * * *
-// SWPB dst Swap bytes - - - -
-// SXT dst Bit7->Bit8...Bit15 0 * * *
-// PUSH src SP-2->SP, src->@SP - - - -
-// CALL dst SP-2->SP, PC+2->@SP, dst->PC - - - -
-// RETI TOS->SR, SP+2->SP, TOS->PC, SP+2->SP * * * *
-//
-//-----------------------------------------------------------------------------
-// TWO-OPERAND ARITHMETIC:
-//-----------------------------------------------------------------------------
-// Mnemonic S-Reg, Operation Status bits
-// D-Reg, V N Z C
-//
-// MOV src,dst src -> dst - - - -
-// ADD src,dst src + dst -> dst * * * *
-// ADDC src,dst src + dst + C -> dst * * * *
-// SUB src,dst dst + ~src + 1 -> dst * * * *
-// SUBC src,dst dst + ~src + C -> dst * * * *
-// CMP src,dst dst + ~src + 1 * * * *
-// DADD src,dst src + dst + C -> dst (decimaly) * * * *
-// BIT src,dst src & dst 0 * * *
-// BIC src,dst ~src & dst -> dst - - - -
-// BIS src,dst src | dst -> dst - - - -
-// XOR src,dst src ^ dst -> dst * * * *
-// AND src,dst src & dst -> dst 0 * * *
-//
-//-----------------------------------------------------------------------------
-// * the status bit is affected
-// - the status bit is not affected
-// 0 the status bit is cleared
-// 1 the status bit is set
-//-----------------------------------------------------------------------------
-
-// Invert source for substract and compare instructions.
-wire op_src_inv_cmd = exec_cycle & (inst_alu[`ALU_SRC_INV]);
-wire [15:0] op_src_inv = {16{op_src_inv_cmd}} ^ op_src;
-
-
-// Mask the bit 8 for the Byte instructions for correct flags generation
-wire op_bit8_msk = ~exec_cycle | ~inst_bw;
-wire [16:0] op_src_in = {1'b0, op_src_inv[15:9], op_src_inv[8] & op_bit8_msk, op_src_inv[7:0]};
-wire [16:0] op_dst_in = {1'b0, op_dst[15:9], op_dst[8] & op_bit8_msk, op_dst[7:0]};
-
-// Clear the source operand (= jump offset) for conditional jumps
-wire jmp_not_taken = (inst_jmp[`JL] & ~(status[3]^status[2])) |
- (inst_jmp[`JGE] & (status[3]^status[2])) |
- (inst_jmp[`JN] & ~status[2]) |
- (inst_jmp[`JC] & ~status[0]) |
- (inst_jmp[`JNC] & status[0]) |
- (inst_jmp[`JEQ] & ~status[1]) |
- (inst_jmp[`JNE] & status[1]);
-wire [16:0] op_src_in_jmp = op_src_in & {17{~jmp_not_taken}};
-
-// Adder / AND / OR / XOR
-wire [16:0] alu_add = op_src_in_jmp + op_dst_in;
-wire [16:0] alu_and = op_src_in & op_dst_in;
-wire [16:0] alu_or = op_src_in | op_dst_in;
-wire [16:0] alu_xor = op_src_in ^ op_dst_in;
-
-
-// Incrementer
-wire alu_inc = exec_cycle & ((inst_alu[`ALU_INC_C] & status[0]) |
- inst_alu[`ALU_INC]);
-wire [16:0] alu_add_inc = alu_add + {16'h0000, alu_inc};
-
-
-
-// Decimal adder (DADD)
-wire [4:0] alu_dadd0 = bcd_add(op_src_in[3:0], op_dst_in[3:0], status[0]);
-wire [4:0] alu_dadd1 = bcd_add(op_src_in[7:4], op_dst_in[7:4], alu_dadd0[4]);
-wire [4:0] alu_dadd2 = bcd_add(op_src_in[11:8], op_dst_in[11:8], alu_dadd1[4]);
-wire [4:0] alu_dadd3 = bcd_add(op_src_in[15:12], op_dst_in[15:12],alu_dadd2[4]);
-wire [16:0] alu_dadd = {alu_dadd3, alu_dadd2[3:0], alu_dadd1[3:0], alu_dadd0[3:0]};
-
-
-// Shifter for rotate instructions (RRC & RRA)
-wire alu_shift_msb = inst_so[`RRC] ? status[0] :
- inst_bw ? op_src[7] : op_src[15];
-wire alu_shift_7 = inst_bw ? alu_shift_msb : op_src[8];
-wire [16:0] alu_shift = {1'b0, alu_shift_msb, op_src[15:9], alu_shift_7, op_src[7:1]};
-
-
-// Swap bytes / Extend Sign
-wire [16:0] alu_swpb = {1'b0, op_src[7:0],op_src[15:8]};
-wire [16:0] alu_sxt = {1'b0, {8{op_src[7]}},op_src[7:0]};
-
-
-// Combine short paths toghether to simplify final ALU mux
-wire alu_short_thro = ~(inst_alu[`ALU_AND] |
- inst_alu[`ALU_OR] |
- inst_alu[`ALU_XOR] |
- inst_alu[`ALU_SHIFT] |
- inst_so[`SWPB] |
- inst_so[`SXT]);
-
-wire [16:0] alu_short = ({16{inst_alu[`ALU_AND]}} & alu_and) |
- ({16{inst_alu[`ALU_OR]}} & alu_or) |
- ({16{inst_alu[`ALU_XOR]}} & alu_xor) |
- ({16{inst_alu[`ALU_SHIFT]}} & alu_shift) |
- ({16{inst_so[`SWPB]}} & alu_swpb) |
- ({16{inst_so[`SXT]}} & alu_sxt) |
- ({16{alu_short_thro}} & op_src_in);
-
-
-// ALU output mux
-wire [16:0] alu_out_nxt = (inst_so[`IRQ] | dbg_halt_st |
- inst_alu[`ALU_ADD]) ? alu_add_inc :
- inst_alu[`ALU_DADD] ? alu_dadd : alu_short;
-
-assign alu_out = alu_out_nxt[15:0];
-assign alu_out_add = alu_add[15:0];
-
-
-//-----------------------------------------------------------------------------
-// STATUS FLAG GENERATION
-//-----------------------------------------------------------------------------
-
-wire V_xor = inst_bw ? (op_src_in[7] & op_dst_in[7]) :
- (op_src_in[15] & op_dst_in[15]);
-
-wire V = inst_bw ? ((~op_src_in[7] & ~op_dst_in[7] & alu_out[7]) |
- ( op_src_in[7] & op_dst_in[7] & ~alu_out[7])) :
- ((~op_src_in[15] & ~op_dst_in[15] & alu_out[15]) |
- ( op_src_in[15] & op_dst_in[15] & ~alu_out[15]));
-
-wire N = inst_bw ? alu_out[7] : alu_out[15];
-wire Z = inst_bw ? (alu_out[7:0]==0) : (alu_out==0);
-wire C = inst_bw ? alu_out[8] : alu_out_nxt[16];
-
-assign alu_stat = inst_alu[`ALU_SHIFT] ? {1'b0, N,Z,op_src_in[0]} :
- inst_alu[`ALU_STAT_7] ? {1'b0, N,Z,~Z} :
- inst_alu[`ALU_XOR] ? {V_xor,N,Z,~Z} : {V,N,Z,C};
-
-assign alu_stat_wr = (inst_alu[`ALU_STAT_F] & exec_cycle) ? 4'b1111 : 4'b0000;
-
-
-endmodule // alu
-
-
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/alu.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/mem_backbone.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/mem_backbone.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/mem_backbone.v (nonexistent)
@@ -1,246 +0,0 @@
-//----------------------------------------------------------------------------
-// Copyright (C) 2001 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, write to the Free Software Foundation,
-// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
-//
-//----------------------------------------------------------------------------
-//
-// *File Name: mem_backbone.v
-//
-// *Module Description:
-// Memory interface backbone (decoder + arbiter)
-//
-// *Author(s):
-// - Olivier Girard, olgirard@gmail.com
-//
-//----------------------------------------------------------------------------
-// $Rev$
-// $LastChangedBy$
-// $LastChangedDate$
-//----------------------------------------------------------------------------
-`include "timescale.v"
-`include "openMSP430_defines.v"
-
-module mem_backbone (
-
-// OUTPUTs
- dbg_mem_din, // Debug unit Memory data input
- eu_mdb_in, // Execution Unit Memory data bus input
- fe_mdb_in, // Frontend Memory data bus input
- fe_rom_wait, // Frontend wait for ROM
- per_addr, // Peripheral address
- per_din, // Peripheral data input
- per_wen, // Peripheral write enable (high active)
- per_en, // Peripheral enable (high active)
- ram_addr, // RAM address
- ram_cen, // RAM chip enable (low active)
- ram_din, // RAM data input
- ram_wen, // RAM write enable (low active)
- rom_addr, // ROM address
- rom_cen, // ROM chip enable (low active)
- rom_din_dbg, // ROM data input --FOR DEBUG INTERFACE--
- rom_wen_dbg, // ROM write enable (low active) --FOR DBG IF--
-
-// INPUTs
- dbg_halt_st, // Halt/Run status from CPU
- dbg_mem_addr, // Debug address for rd/wr access
- dbg_mem_dout, // Debug unit data output
- dbg_mem_en, // Debug unit memory enable
- dbg_mem_wr, // Debug unit memory write
- eu_mab, // Execution Unit Memory address bus
- eu_mb_en, // Execution Unit Memory bus enable
- eu_mb_wr, // Execution Unit Memory bus write transfer
- eu_mdb_out, // Execution Unit Memory data bus output
- fe_mab, // Frontend Memory address bus
- fe_mb_en, // Frontend Memory bus enable
- mclk, // Main system clock
- per_dout, // Peripheral data output
- puc, // Main system reset
- ram_dout, // RAM data output
- rom_dout // ROM data output
-);
-
-// OUTPUTs
-//=========
-output [15:0] dbg_mem_din; // Debug unit Memory data input
-output [15:0] eu_mdb_in; // Execution Unit Memory data bus input
-output [15:0] fe_mdb_in; // Frontend Memory data bus input
-output fe_rom_wait; // Frontend wait for ROM
-output [7:0] per_addr; // Peripheral address
-output [15:0] per_din; // Peripheral data input
-output [1:0] per_wen; // Peripheral write enable (high active)
-output per_en; // Peripheral enable (high active)
-output [`RAM_MSB:0] ram_addr; // RAM address
-output ram_cen; // RAM chip enable (low active)
-output [15:0] ram_din; // RAM data input
-output [1:0] ram_wen; // RAM write enable (low active)
-output [`ROM_MSB:0] rom_addr; // ROM address
-output rom_cen; // ROM chip enable (low active)
-output [15:0] rom_din_dbg; // ROM data input --FOR DEBUG INTERFACE--
-output [1:0] rom_wen_dbg; // ROM write enable (low active) --FOR DBG IF--
-
-// INPUTs
-//=========
-input dbg_halt_st; // Halt/Run status from CPU
-input [15:0] dbg_mem_addr; // Debug address for rd/wr access
-input [15:0] dbg_mem_dout; // Debug unit data output
-input dbg_mem_en; // Debug unit memory enable
-input [1:0] dbg_mem_wr; // Debug unit memory write
-input [14:0] eu_mab; // Execution Unit Memory address bus
-input eu_mb_en; // Execution Unit Memory bus enable
-input [1:0] eu_mb_wr; // Execution Unit Memory bus write transfer
-input [15:0] eu_mdb_out; // Execution Unit Memory data bus output
-input [14:0] fe_mab; // Frontend Memory address bus
-input fe_mb_en; // Frontend Memory bus enable
-input mclk; // Main system clock
-input [15:0] per_dout; // Peripheral data output
-input puc; // Main system reset
-input [15:0] ram_dout; // RAM data output
-input [15:0] rom_dout; // ROM data output
-
-
-//=============================================================================
-// 1) DECODER
-//=============================================================================
-
-// RAM Interface
-//------------------
-
-// Execution unit access
-wire eu_ram_cen = ~(eu_mb_en & (eu_mab>=(`RAM_BASE>>1)) &
- (eu_mab<((`RAM_BASE+`RAM_SIZE)>>1)));
-wire [15:0] eu_ram_addr = eu_mab-(`RAM_BASE>>1);
-
-// Debug interface access
-wire dbg_ram_cen = ~(dbg_mem_en & (dbg_mem_addr[15:1]>=(`RAM_BASE>>1)) &
- (dbg_mem_addr[15:1]<((`RAM_BASE+`RAM_SIZE)>>1)));
-wire [15:0] dbg_ram_addr = dbg_mem_addr[15:1]-(`RAM_BASE>>1);
-
-
-// RAM Interface
-wire [`RAM_MSB:0] ram_addr = ~dbg_ram_cen ? dbg_ram_addr[`RAM_MSB:0] : eu_ram_addr[`RAM_MSB:0];
-wire ram_cen = dbg_ram_cen & eu_ram_cen;
-wire [1:0] ram_wen = ~(dbg_mem_wr | eu_mb_wr);
-wire [15:0] ram_din = ~dbg_ram_cen ? dbg_mem_dout : eu_mdb_out;
-
-
-// ROM Interface
-//------------------
-parameter ROM_OFFSET = (16'hFFFF-`ROM_SIZE+1);
-
-// Execution unit access (only read access are accepted)
-wire eu_rom_cen = ~(eu_mb_en & ~|eu_mb_wr & (eu_mab>=(ROM_OFFSET>>1)));
-wire [15:0] eu_rom_addr = eu_mab-(ROM_OFFSET>>1);
-
-// Front-end access
-wire fe_rom_cen = ~(fe_mb_en & (fe_mab>=(ROM_OFFSET>>1)));
-wire [15:0] fe_rom_addr = fe_mab-(ROM_OFFSET>>1);
-
-// Debug interface access
-wire dbg_rom_cen = ~(dbg_mem_en & (dbg_mem_addr[15:1]>=(ROM_OFFSET>>1)));
-wire [15:0] dbg_rom_addr = dbg_mem_addr[15:1]-(ROM_OFFSET>>1);
-
-
-// ROM Interface (Execution unit has priority)
-wire [`ROM_MSB:0] rom_addr = ~dbg_rom_cen ? dbg_rom_addr[`ROM_MSB:0] :
- ~eu_rom_cen ? eu_rom_addr[`ROM_MSB:0] : fe_rom_addr[`ROM_MSB:0];
-wire rom_cen = fe_rom_cen & eu_rom_cen & dbg_rom_cen;
-wire [1:0] rom_wen_dbg = ~dbg_mem_wr;
-wire [15:0] rom_din_dbg = dbg_mem_dout;
-
-wire fe_rom_wait = (~fe_rom_cen & ~eu_rom_cen);
-
-
-// Peripherals
-//--------------------
-wire dbg_per_en = dbg_mem_en & (dbg_mem_addr[15:9]==7'h00);
-wire eu_per_en = eu_mb_en & (eu_mab[14:8]==7'h00);
-
-wire [7:0] per_addr = dbg_mem_en ? dbg_mem_addr[8:1] : eu_mab[7:0];
-wire [15:0] per_din = dbg_mem_en ? dbg_mem_dout : eu_mdb_out;
-wire [1:0] per_wen = dbg_mem_en ? dbg_mem_wr : eu_mb_wr;
-wire per_en = dbg_mem_en ? dbg_per_en : eu_per_en;
-
-reg [15:0] per_dout_val;
-always @ (posedge mclk or posedge puc)
- if (puc) per_dout_val <= 16'h0000;
- else per_dout_val <= per_dout;
-
-
-// Frontend data Mux
-//---------------------------------
-// Whenever the frontend doesn't access the ROM, backup the data
-
-// Detect whenever the data should be backuped and restored
-reg fe_rom_cen_dly;
-always @(posedge mclk or posedge puc)
- if (puc) fe_rom_cen_dly <= 1'b0;
- else fe_rom_cen_dly <= fe_rom_cen;
-
-wire fe_rom_save = ( fe_rom_cen & ~fe_rom_cen_dly) & ~dbg_halt_st;
-wire fe_rom_restore = (~fe_rom_cen & fe_rom_cen_dly) | dbg_halt_st;
-
-reg [15:0] rom_dout_bckup;
-always @(posedge mclk or posedge puc)
- if (puc) rom_dout_bckup <= 16'h0000;
- else if (fe_rom_save) rom_dout_bckup <= rom_dout;
-
-// Mux between the ROM data and the backup
-reg rom_dout_bckup_sel;
-always @(posedge mclk or posedge puc)
- if (puc) rom_dout_bckup_sel <= 1'b0;
- else if (fe_rom_save) rom_dout_bckup_sel <= 1'b1;
- else if (fe_rom_restore) rom_dout_bckup_sel <= 1'b0;
-
-assign fe_mdb_in = rom_dout_bckup_sel ? rom_dout_bckup : rom_dout;
-
-
-// Execution-Unit data Mux
-//---------------------------------
-
-// Select between peripherals, RAM and ROM
-reg [1:0] eu_mdb_in_sel;
-always @(posedge mclk or posedge puc)
- if (puc) eu_mdb_in_sel <= 2'b00;
- else eu_mdb_in_sel <= {~eu_rom_cen, per_en};
-
-// Mux
-assign eu_mdb_in = eu_mdb_in_sel[1] ? rom_dout :
- eu_mdb_in_sel[0] ? per_dout_val : ram_dout;
-
-// Debug interface data Mux
-//---------------------------------
-
-// Select between peripherals, RAM and ROM
-reg [1:0] dbg_mem_din_sel;
-always @(posedge mclk or posedge puc)
- if (puc) dbg_mem_din_sel <= 2'b00;
- else dbg_mem_din_sel <= {~dbg_rom_cen, dbg_per_en};
-
-// Mux
-assign dbg_mem_din = dbg_mem_din_sel[1] ? rom_dout :
- dbg_mem_din_sel[0] ? per_dout_val : ram_dout;
-
-
-endmodule // mem_backbone
-
-
-
-
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/mem_backbone.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/execution_unit.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/execution_unit.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/execution_unit.v (nonexistent)
@@ -1,366 +0,0 @@
-//----------------------------------------------------------------------------
-// Copyright (C) 2001 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, write to the Free Software Foundation,
-// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
-//
-//----------------------------------------------------------------------------
-//
-// *File Name: execution_unit.v
-//
-// *Module Description:
-// openMSP430 Execution unit
-//
-// *Author(s):
-// - Olivier Girard, olgirard@gmail.com
-//
-//----------------------------------------------------------------------------
-// $Rev$
-// $LastChangedBy$
-// $LastChangedDate$
-//----------------------------------------------------------------------------
-`include "timescale.v"
-`include "openMSP430_defines.v"
-
-module execution_unit (
-
-// OUTPUTs
- cpuoff, // Turns off the CPU
- dbg_reg_din, // Debug unit CPU register data input
- gie, // General interrupt enable
- mab, // Memory address bus
- mb_en, // Memory bus enable
- mb_wr, // Memory bus write transfer
- mdb_out, // Memory data bus output
- oscoff, // Turns off LFXT1 clock input
- pc_sw, // Program counter software value
- pc_sw_wr, // Program counter software write
- scg1, // System clock generator 1. Turns off the SMCLK
-
-// INPUTs
- dbg_halt_st, // Halt/Run status from CPU
- dbg_mem_dout, // Debug unit data output
- dbg_reg_wr, // Debug unit CPU register write
- e_state, // Execution state
- exec_done, // Execution completed
- inst_ad, // Decoded Inst: destination addressing mode
- inst_as, // Decoded Inst: source addressing mode
- inst_alu, // ALU control signals
- inst_bw, // Decoded Inst: byte width
- inst_dest, // Decoded Inst: destination (one hot)
- inst_dext, // Decoded Inst: destination extended instruction word
- inst_irq_rst, // Decoded Inst: reset interrupt
- inst_jmp, // Decoded Inst: Conditional jump
- inst_sext, // Decoded Inst: source extended instruction word
- inst_so, // Decoded Inst: Single-operand arithmetic
- inst_src, // Decoded Inst: source (one hot)
- inst_type, // Decoded Instruction type
- mclk, // Main system clock
- mdb_in, // Memory data bus input
- pc, // Program counter
- pc_nxt, // Next PC value (for CALL & IRQ)
- puc // Main system reset
-);
-
-// OUTPUTs
-//=========
-output cpuoff; // Turns off the CPU
-output [15:0] dbg_reg_din; // Debug unit CPU register data input
-output gie; // General interrupt enable
-output [15:0] mab; // Memory address bus
-output mb_en; // Memory bus enable
-output [1:0] mb_wr; // Memory bus write transfer
-output [15:0] mdb_out; // Memory data bus output
-output oscoff; // Turns off LFXT1 clock input
-output [15:0] pc_sw; // Program counter software value
-output pc_sw_wr; // Program counter software write
-output scg1; // System clock generator 1. Turns off the SMCLK
-
-// INPUTs
-//=========
-input dbg_halt_st; // Halt/Run status from CPU
-input [15:0] dbg_mem_dout; // Debug unit data output
-input dbg_reg_wr; // Debug unit CPU register write
-input [3:0] e_state; // Execution state
-input exec_done; // Execution completed
-input [7:0] inst_ad; // Decoded Inst: destination addressing mode
-input [7:0] inst_as; // Decoded Inst: source addressing mode
-input [11:0] inst_alu; // ALU control signals
-input inst_bw; // Decoded Inst: byte width
-input [15:0] inst_dest; // Decoded Inst: destination (one hot)
-input [15:0] inst_dext; // Decoded Inst: destination extended instruction word
-input inst_irq_rst; // Decoded Inst: reset interrupt
-input [7:0] inst_jmp; // Decoded Inst: Conditional jump
-input [15:0] inst_sext; // Decoded Inst: source extended instruction word
-input [7:0] inst_so; // Decoded Inst: Single-operand arithmetic
-input [15:0] inst_src; // Decoded Inst: source (one hot)
-input [2:0] inst_type; // Decoded Instruction type
-input mclk; // Main system clock
-input [15:0] mdb_in; // Memory data bus input
-input [15:0] pc; // Program counter
-input [15:0] pc_nxt; // Next PC value (for CALL & IRQ)
-input puc; // Main system reset
-
-
-//=============================================================================
-// 1) INTERNAL WIRES/REGISTERS/PARAMETERS DECLARATION
-//=============================================================================
-
-wire [15:0] alu_out;
-wire [15:0] alu_out_add;
-wire [3:0] alu_stat;
-wire [3:0] alu_stat_wr;
-wire [15:0] op_dst;
-wire [15:0] op_src;
-wire [15:0] reg_dest;
-wire [15:0] reg_src;
-wire [15:0] mdb_in_bw;
-wire [15:0] mdb_in_val;
-wire [3:0] status;
-
-
-//=============================================================================
-// 2) REGISTER FILE
-//=============================================================================
-
-wire reg_dest_wr = ((e_state==`E_EXEC) & (
- (inst_type[`INST_TO] & inst_ad[`DIR] & ~inst_alu[`EXEC_NO_WR]) |
- (inst_type[`INST_SO] & inst_as[`DIR] & ~(inst_so[`PUSH] | inst_so[`CALL] | inst_so[`RETI])) |
- inst_type[`INST_JMP])) | dbg_reg_wr;
-
-wire reg_sp_wr = (((e_state==`E_IRQ_1) | (e_state==`E_IRQ_3)) & ~inst_irq_rst) |
- ((e_state==`E_DST_RD) & (inst_so[`PUSH] | inst_so[`CALL]));
-
-wire reg_sr_wr = (e_state==`E_DST_RD) & inst_so[`RETI];
-
-wire reg_sr_clr = (e_state==`E_IRQ_2);
-
-wire reg_pc_call = ((e_state==`E_EXEC) & inst_so[`CALL]) |
- ((e_state==`E_DST_WR) & inst_so[`RETI]);
-
-wire reg_incr = (exec_done & inst_as[`INDIR_I]) |
- ((e_state==`E_SRC_RD) & inst_so[`RETI]) |
- ((e_state==`E_EXEC) & inst_so[`RETI]);
-
-assign dbg_reg_din = reg_dest;
-
-
-register_file register_file_0 (
-
-// OUTPUTs
- .cpuoff (cpuoff), // Turns off the CPU
- .gie (gie), // General interrupt enable
- .oscoff (oscoff), // Turns off LFXT1 clock input
- .pc_sw (pc_sw), // Program counter software value
- .pc_sw_wr (pc_sw_wr), // Program counter software write
- .reg_dest (reg_dest), // Selected register destination content
- .reg_src (reg_src), // Selected register source content
- .scg1 (scg1), // System clock generator 1. Turns off the SMCLK
- .status (status), // R2 Status {V,N,Z,C}
-
-// INPUTs
- .alu_stat (alu_stat), // ALU Status {V,N,Z,C}
- .alu_stat_wr (alu_stat_wr), // ALU Status write {V,N,Z,C}
- .inst_bw (inst_bw), // Decoded Inst: byte width
- .inst_dest (inst_dest), // Register destination selection
- .inst_src (inst_src), // Register source selection
- .mclk (mclk), // Main system clock
- .pc (pc), // Program counter
- .puc (puc), // Main system reset
- .reg_dest_val (alu_out), // Selected register destination value
- .reg_dest_wr (reg_dest_wr), // Write selected register destination
- .reg_pc_call (reg_pc_call), // Trigger PC update for a CALL instruction
- .reg_sp_val (alu_out_add), // Stack Pointer next value
- .reg_sp_wr (reg_sp_wr), // Stack Pointer write
- .reg_sr_clr (reg_sr_clr), // Status register clear for interrupts
- .reg_sr_wr (reg_sr_wr), // Status Register update for RETI instruction
- .reg_incr (reg_incr) // Increment source register
-);
-
-
-//=============================================================================
-// 3) SOURCE OPERAND MUXING
-//=============================================================================
-// inst_as[`DIR] : Register direct. -> Source is in register
-// inst_as[`IDX] : Register indexed. -> Source is in memory, address is register+offset
-// inst_as[`INDIR] : Register indirect.
-// inst_as[`INDIR_I]: Register indirect autoincrement.
-// inst_as[`SYMB] : Symbolic (operand is in memory at address PC+x).
-// inst_as[`IMM] : Immediate (operand is next word in the instruction stream).
-// inst_as[`ABS] : Absolute (operand is in memory at address x).
-// inst_as[`CONST] : Constant.
-
-wire src_reg_src_sel = (e_state==`E_IRQ_0) |
- (e_state==`E_IRQ_2) |
- ((e_state==`E_SRC_RD) & ~inst_as[`ABS]) |
- ((e_state==`E_SRC_WR) & ~inst_as[`ABS]) |
- ((e_state==`E_EXEC) & inst_as[`DIR] & ~inst_type[`INST_JMP]);
-
-wire src_reg_dest_sel = (e_state==`E_IRQ_1) |
- (e_state==`E_IRQ_3) |
- ((e_state==`E_DST_RD) & (inst_so[`PUSH] | inst_so[`CALL]));
-
-wire src_mdb_in_val_sel = ((e_state==`E_DST_RD) & inst_so[`RETI]) |
- ((e_state==`E_EXEC) & (inst_as[`INDIR] | inst_as[`INDIR_I] |
- inst_as[`IDX] | inst_as[`SYMB] |
- inst_as[`ABS]));
-
-wire src_inst_dext_sel = ((e_state==`E_DST_RD) & ~(inst_so[`PUSH] | inst_so[`CALL])) |
- ((e_state==`E_DST_WR) & ~(inst_so[`PUSH] | inst_so[`CALL] |
- inst_so[`RETI]));
-
-wire src_inst_sext_sel = ((e_state==`E_EXEC) & (inst_type[`INST_JMP] | inst_as[`IMM] |
- inst_as[`CONST] | inst_so[`RETI]));
-
-
-assign op_src = src_reg_src_sel ? reg_src :
- src_reg_dest_sel ? reg_dest :
- src_mdb_in_val_sel ? mdb_in_val :
- src_inst_dext_sel ? inst_dext :
- src_inst_sext_sel ? inst_sext : 16'h0000;
-
-
-//=============================================================================
-// 4) DESTINATION OPERAND MUXING
-//=============================================================================
-// inst_ad[`DIR] : Register direct.
-// inst_ad[`IDX] : Register indexed.
-// inst_ad[`SYMB] : Symbolic (operand is in memory at address PC+x).
-// inst_ad[`ABS] : Absolute (operand is in memory at address x).
-
-
-wire dst_inst_sext_sel = ((e_state==`E_SRC_RD) & (inst_as[`IDX] | inst_as[`SYMB] |
- inst_as[`ABS])) |
- ((e_state==`E_SRC_WR) & (inst_as[`IDX] | inst_as[`SYMB] |
- inst_as[`ABS]));
-
-wire dst_mdb_in_bw_sel = ((e_state==`E_DST_WR) & inst_so[`RETI]) |
- ((e_state==`E_EXEC) & ~(inst_ad[`DIR] | inst_type[`INST_JMP] |
- inst_type[`INST_SO]) & ~inst_so[`RETI]);
-
-wire dst_fffe_sel = (e_state==`E_IRQ_0) |
- (e_state==`E_IRQ_1) |
- (e_state==`E_IRQ_3) |
- ((e_state==`E_DST_RD) & (inst_so[`PUSH] | inst_so[`CALL]) & ~inst_so[`RETI]);
-
-wire dst_reg_dest_sel = ((e_state==`E_DST_RD) & ~(inst_so[`PUSH] | inst_so[`CALL] | inst_ad[`ABS] | inst_so[`RETI])) |
- ((e_state==`E_DST_WR) & ~inst_ad[`ABS]) |
- ((e_state==`E_EXEC) & (inst_ad[`DIR] | inst_type[`INST_JMP] |
- inst_type[`INST_SO]) & ~inst_so[`RETI]);
-
-
-assign op_dst = dbg_halt_st ? dbg_mem_dout :
- dst_inst_sext_sel ? inst_sext :
- dst_mdb_in_bw_sel ? mdb_in_bw :
- dst_reg_dest_sel ? reg_dest :
- dst_fffe_sel ? 16'hfffe : 16'h0000;
-
-
-//=============================================================================
-// 5) ALU
-//=============================================================================
-
-wire exec_cycle = (e_state==`E_EXEC);
-
-alu alu_0 (
-
-// OUTPUTs
- .alu_out (alu_out), // ALU output value
- .alu_out_add (alu_out_add), // ALU adder output value
- .alu_stat (alu_stat), // ALU Status {V,N,Z,C}
- .alu_stat_wr (alu_stat_wr), // ALU Status write {V,N,Z,C}
-
-// INPUTs
- .dbg_halt_st (dbg_halt_st), // Halt/Run status from CPU
- .exec_cycle (exec_cycle), // Instruction execution cycle
- .inst_alu (inst_alu), // ALU control signals
- .inst_bw (inst_bw), // Decoded Inst: byte width
- .inst_jmp (inst_jmp), // Decoded Inst: Conditional jump
- .inst_so (inst_so), // Single-operand arithmetic
- .op_dst (op_dst), // Destination operand
- .op_src (op_src), // Source operand
- .status (status) // R2 Status {V,N,Z,C}
-);
-
-
-//=============================================================================
-// 6) MEMORY INTERFACE
-//=============================================================================
-
-// Detect memory read/write access
-assign mb_en = ((e_state==`E_IRQ_1) & ~inst_irq_rst) |
- ((e_state==`E_IRQ_3) & ~inst_irq_rst) |
- ((e_state==`E_SRC_RD) & ~inst_as[`IMM]) |
- (e_state==`E_SRC_WR) |
- ((e_state==`E_EXEC) & inst_so[`RETI]) |
- (e_state==`E_DST_RD) |
- (e_state==`E_DST_WR);
-
-wire [1:0] mb_wr_msk = inst_alu[`EXEC_NO_WR] ? 2'b00 :
- ~inst_bw ? 2'b11 :
- alu_out_add[0] ? 2'b10 : 2'b01;
-assign mb_wr = ({2{(e_state==`E_IRQ_1)}} |
- {2{(e_state==`E_IRQ_3)}} |
- {2{(e_state==`E_DST_WR)}} |
- {2{(e_state==`E_SRC_WR)}}) & mb_wr_msk;
-
-// Memory address bus
-assign mab = alu_out_add[15:0];
-
-// Memory data bus output
-reg [15:0] mdb_out_nxt;
-always @(posedge mclk or posedge puc)
- if (puc) mdb_out_nxt <= 16'h0000;
- else if (e_state==`E_DST_RD) mdb_out_nxt <= pc_nxt;
- else if ((e_state==`E_EXEC & ~inst_so[`CALL]) |
- (e_state==`E_IRQ_0) | (e_state==`E_IRQ_2)) mdb_out_nxt <= alu_out;
-
-assign mdb_out = inst_bw ? {2{mdb_out_nxt[7:0]}} : mdb_out_nxt;
-
-// Format memory data bus input depending on BW
-reg mab_lsb;
-always @(posedge mclk or posedge puc)
- if (puc) mab_lsb <= 1'b0;
- else if (mb_en) mab_lsb <= alu_out_add[0];
-
-assign mdb_in_bw = ~inst_bw ? mdb_in :
- mab_lsb ? {2{mdb_in[15:8]}} : mdb_in;
-
-// Memory data bus input buffer (buffer after a source read)
-reg mdb_in_buf_en;
-always @(posedge mclk or posedge puc)
- if (puc) mdb_in_buf_en <= 1'b0;
- else mdb_in_buf_en <= (e_state==`E_SRC_RD);
-
-reg mdb_in_buf_valid;
-always @(posedge mclk or posedge puc)
- if (puc) mdb_in_buf_valid <= 1'b0;
- else if (e_state==`E_EXEC) mdb_in_buf_valid <= 1'b0;
- else if (mdb_in_buf_en) mdb_in_buf_valid <= 1'b1;
-
-reg [15:0] mdb_in_buf;
-always @(posedge mclk or posedge puc)
- if (puc) mdb_in_buf <= 16'h0000;
- else if (mdb_in_buf_en) mdb_in_buf <= mdb_in_bw;
-
-assign mdb_in_val = mdb_in_buf_valid ? mdb_in_buf : mdb_in_bw;
-
-
-endmodule // execution_unit
-
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/execution_unit.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/periph/template_periph_16b.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/periph/template_periph_16b.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/periph/template_periph_16b.v (nonexistent)
@@ -1,181 +0,0 @@
-//----------------------------------------------------------------------------
-// Copyright (C) 2001 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, write to the Free Software Foundation,
-// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
-//
-//----------------------------------------------------------------------------
-//
-// *File Name: template_periph_16b.v
-//
-// *Module Description:
-// 16 bit peripheral template.
-//
-// *Author(s):
-// - Olivier Girard, olgirard@gmail.com
-//
-//----------------------------------------------------------------------------
-// $Rev$
-// $LastChangedBy$
-// $LastChangedDate$
-//----------------------------------------------------------------------------
-`include "timescale.v"
-`include "openMSP430_defines.v"
-
-module template_periph_16b (
-
-// OUTPUTs
- per_dout, // Peripheral data output
-
-// INPUTs
- mclk, // Main system clock
- per_addr, // Peripheral address
- per_din, // Peripheral data input
- per_en, // Peripheral enable (high active)
- per_wen, // Peripheral write enable (high active)
- puc // Main system reset
-);
-
-// OUTPUTs
-//=========
-output [15:0] per_dout; // Peripheral data output
-
-// INPUTs
-//=========
-input mclk; // Main system clock
-input [7:0] per_addr; // Peripheral address
-input [15:0] per_din; // Peripheral data input
-input per_en; // Peripheral enable (high active)
-input [1:0] per_wen; // Peripheral write enable (high active)
-input puc; // Main system reset
-
-
-//=============================================================================
-// 1) PARAMETER DECLARATION
-//=============================================================================
-
-// Register addresses
-parameter CNTRL1 = 9'h190;
-parameter CNTRL2 = 9'h192;
-parameter CNTRL3 = 9'h194;
-parameter CNTRL4 = 9'h196;
-
-
-// Register one-hot decoder
-parameter CNTRL1_D = (512'h1 << CNTRL1);
-parameter CNTRL2_D = (512'h1 << CNTRL2);
-parameter CNTRL3_D = (512'h1 << CNTRL3);
-parameter CNTRL4_D = (512'h1 << CNTRL4);
-
-
-//============================================================================
-// 2) REGISTER DECODER
-//============================================================================
-
-// Register address decode
-reg [511:0] reg_dec;
-always @(per_addr)
- case ({per_addr,1'b0})
- CNTRL1 : reg_dec = CNTRL1_D;
- CNTRL2 : reg_dec = CNTRL2_D;
- CNTRL3 : reg_dec = CNTRL3_D;
- CNTRL4 : reg_dec = CNTRL4_D;
- default: reg_dec = {512{1'b0}};
- endcase
-
-// Read/Write probes
-wire reg_write = |per_wen & per_en;
-wire reg_read = ~|per_wen & per_en;
-
-// Read/Write vectors
-wire [511:0] reg_wr = reg_dec & {512{reg_write}};
-wire [511:0] reg_rd = reg_dec & {512{reg_read}};
-
-
-//============================================================================
-// 3) REGISTERS
-//============================================================================
-
-// CNTRL1 Register
-//-----------------
-reg [15:0] cntrl1;
-
-wire cntrl1_wr = reg_wr[CNTRL1];
-
-always @ (posedge mclk or posedge puc)
- if (puc) cntrl1 <= 16'h0000;
- else if (cntrl1_wr) cntrl1 <= per_din;
-
-
-// CNTRL2 Register
-//-----------------
-reg [15:0] cntrl2;
-
-wire cntrl2_wr = reg_wr[CNTRL2];
-
-always @ (posedge mclk or posedge puc)
- if (puc) cntrl2 <= 16'h0000;
- else if (cntrl2_wr) cntrl2 <= per_din;
-
-
-// CNTRL3 Register
-//-----------------
-reg [15:0] cntrl3;
-
-wire cntrl3_wr = reg_wr[CNTRL3];
-
-always @ (posedge mclk or posedge puc)
- if (puc) cntrl3 <= 16'h0000;
- else if (cntrl3_wr) cntrl3 <= per_din;
-
-
-// CNTRL4 Register
-//-----------------
-reg [15:0] cntrl4;
-
-wire cntrl4_wr = reg_wr[CNTRL4];
-
-always @ (posedge mclk or posedge puc)
- if (puc) cntrl4 <= 16'h0000;
- else if (cntrl4_wr) cntrl4 <= per_din;
-
-
-//============================================================================
-// 4) DATA OUTPUT GENERATION
-//============================================================================
-
-// Data output mux
-wire [15:0] cntrl1_rd = cntrl1 & {16{reg_rd[CNTRL1]}};
-wire [15:0] cntrl2_rd = cntrl2 & {16{reg_rd[CNTRL2]}};
-wire [15:0] cntrl3_rd = cntrl3 & {16{reg_rd[CNTRL3]}};
-wire [15:0] cntrl4_rd = cntrl4 & {16{reg_rd[CNTRL4]}};
-
-wire [15:0] per_dout = cntrl1_rd |
- cntrl2_rd |
- cntrl3_rd |
- cntrl4_rd;
-
-
-endmodule // template_periph_16b
-
-
-
-
-
-
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/periph/template_periph_16b.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/periph/template_periph_8b.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/periph/template_periph_8b.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/periph/template_periph_8b.v (nonexistent)
@@ -1,189 +0,0 @@
-//----------------------------------------------------------------------------
-// Copyright (C) 2001 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, write to the Free Software Foundation,
-// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
-//
-//----------------------------------------------------------------------------
-//
-// *File Name: template_periph_8b.v
-//
-// *Module Description:
-// 8 bit peripheral template.
-//
-// *Author(s):
-// - Olivier Girard, olgirard@gmail.com
-//
-//----------------------------------------------------------------------------
-// $Rev$
-// $LastChangedBy$
-// $LastChangedDate$
-//----------------------------------------------------------------------------
-`include "timescale.v"
-`include "openMSP430_defines.v"
-
-module template_periph_8b (
-
-// OUTPUTs
- per_dout, // Peripheral data output
-
-// INPUTs
- mclk, // Main system clock
- per_addr, // Peripheral address
- per_din, // Peripheral data input
- per_en, // Peripheral enable (high active)
- per_wen, // Peripheral write enable (high active)
- puc // Main system reset
-);
-
-// OUTPUTs
-//=========
-output [15:0] per_dout; // Peripheral data output
-
-// INPUTs
-//=========
-input mclk; // Main system clock
-input [7:0] per_addr; // Peripheral address
-input [15:0] per_din; // Peripheral data input
-input per_en; // Peripheral enable (high active)
-input [1:0] per_wen; // Peripheral write enable (high active)
-input puc; // Main system reset
-
-
-//=============================================================================
-// 1) PARAMETER DECLARATION
-//=============================================================================
-
-// Register addresses
-parameter CNTRL1 = 9'h090;
-parameter CNTRL2 = 9'h091;
-parameter CNTRL3 = 9'h092;
-parameter CNTRL4 = 9'h093;
-
-
-// Register one-hot decoder
-parameter CNTRL1_D = (256'h1 << (CNTRL1 /2));
-parameter CNTRL2_D = (256'h1 << (CNTRL2 /2));
-parameter CNTRL3_D = (256'h1 << (CNTRL3 /2));
-parameter CNTRL4_D = (256'h1 << (CNTRL4 /2));
-
-
-//============================================================================
-// 2) REGISTER DECODER
-//============================================================================
-
-// Register address decode
-reg [255:0] reg_dec;
-always @(per_addr)
- case (per_addr)
- (CNTRL1 /2): reg_dec = CNTRL1_D;
- (CNTRL2 /2): reg_dec = CNTRL2_D;
- (CNTRL3 /2): reg_dec = CNTRL3_D;
- (CNTRL4 /2): reg_dec = CNTRL4_D;
- default : reg_dec = {256{1'b0}};
- endcase
-
-// Read/Write probes
-wire reg_lo_write = per_wen[0] & per_en;
-wire reg_hi_write = per_wen[1] & per_en;
-wire reg_read = ~|per_wen & per_en;
-
-// Read/Write vectors
-wire [255:0] reg_hi_wr = reg_dec & {256{reg_hi_write}};
-wire [255:0] reg_lo_wr = reg_dec & {256{reg_lo_write}};
-wire [255:0] reg_rd = reg_dec & {256{reg_read}};
-
-
-//============================================================================
-// 3) REGISTERS
-//============================================================================
-
-// CNTRL1 Register
-//-----------------
-reg [7:0] cntrl1;
-
-wire cntrl1_wr = CNTRL1[0] ? reg_hi_wr[CNTRL1/2] : reg_lo_wr[CNTRL1/2];
-wire [7:0] cntrl1_nxt = CNTRL1[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) cntrl1 <= 8'h00;
- else if (cntrl1_wr) cntrl1 <= cntrl1_nxt;
-
-
-// CNTRL2 Register
-//-----------------
-reg [7:0] cntrl2;
-
-wire cntrl2_wr = CNTRL2[0] ? reg_hi_wr[CNTRL2/2] : reg_lo_wr[CNTRL2/2];
-wire [7:0] cntrl2_nxt = CNTRL2[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) cntrl2 <= 8'h00;
- else if (cntrl2_wr) cntrl2 <= cntrl2_nxt;
-
-
-// CNTRL3 Register
-//-----------------
-reg [7:0] cntrl3;
-
-wire cntrl3_wr = CNTRL3[0] ? reg_hi_wr[CNTRL3/2] : reg_lo_wr[CNTRL3/2];
-wire [7:0] cntrl3_nxt = CNTRL3[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) cntrl3 <= 8'h00;
- else if (cntrl3_wr) cntrl3 <= cntrl3_nxt;
-
-
-// CNTRL4 Register
-//-----------------
-reg [7:0] cntrl4;
-
-wire cntrl4_wr = CNTRL4[0] ? reg_hi_wr[CNTRL4/2] : reg_lo_wr[CNTRL4/2];
-wire [7:0] cntrl4_nxt = CNTRL4[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) cntrl4 <= 8'h00;
- else if (cntrl4_wr) cntrl4 <= cntrl4_nxt;
-
-
-
-//============================================================================
-// 4) DATA OUTPUT GENERATION
-//============================================================================
-
-// Data output mux
-wire [15:0] cntrl1_rd = (cntrl1 & {8{reg_rd[CNTRL1/2]}}) << (8 & {4{CNTRL1[0]}});
-wire [15:0] cntrl2_rd = (cntrl2 & {8{reg_rd[CNTRL2/2]}}) << (8 & {4{CNTRL2[0]}});
-wire [15:0] cntrl3_rd = (cntrl3 & {8{reg_rd[CNTRL3/2]}}) << (8 & {4{CNTRL3[0]}});
-wire [15:0] cntrl4_rd = (cntrl4 & {8{reg_rd[CNTRL4/2]}}) << (8 & {4{CNTRL4[0]}});
-
-wire [15:0] per_dout = cntrl1_rd |
- cntrl2_rd |
- cntrl3_rd |
- cntrl4_rd;
-
-
-endmodule // template_periph_8b
-
-
-
-
-
-
-
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/periph/template_periph_8b.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/periph/gpio.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/periph/gpio.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/periph/gpio.v (nonexistent)
@@ -1,778 +0,0 @@
-//----------------------------------------------------------------------------
-// Copyright (C) 2001 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, write to the Free Software Foundation,
-// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
-//
-//----------------------------------------------------------------------------
-//
-// *File Name: gpio.v
-//
-// *Module Description:
-// Digital I/O interface
-//
-// *Author(s):
-// - Olivier Girard, olgirard@gmail.com
-//
-//----------------------------------------------------------------------------
-// $Rev$
-// $LastChangedBy$
-// $LastChangedDate$
-//----------------------------------------------------------------------------
-`include "timescale.v"
-`include "openMSP430_defines.v"
-
-module gpio (
-
-// OUTPUTs
- irq_port1, // Port 1 interrupt
- irq_port2, // Port 2 interrupt
- p1_dout, // Port 1 data output
- p1_dout_en, // Port 1 data output enable
- p1_sel, // Port 1 function select
- p2_dout, // Port 2 data output
- p2_dout_en, // Port 2 data output enable
- p2_sel, // Port 2 function select
- p3_dout, // Port 3 data output
- p3_dout_en, // Port 3 data output enable
- p3_sel, // Port 3 function select
- p4_dout, // Port 4 data output
- p4_dout_en, // Port 4 data output enable
- p4_sel, // Port 4 function select
- p5_dout, // Port 5 data output
- p5_dout_en, // Port 5 data output enable
- p5_sel, // Port 5 function select
- p6_dout, // Port 6 data output
- p6_dout_en, // Port 6 data output enable
- p6_sel, // Port 6 function select
- per_dout, // Peripheral data output
-
-// INPUTs
- mclk, // Main system clock
- p1_din, // Port 1 data input
- p2_din, // Port 2 data input
- p3_din, // Port 3 data input
- p4_din, // Port 4 data input
- p5_din, // Port 5 data input
- p6_din, // Port 6 data input
- per_addr, // Peripheral address
- per_din, // Peripheral data input
- per_en, // Peripheral enable (high active)
- per_wen, // Peripheral write enable (high active)
- puc // Main system reset
-);
-
-// PARAMETERs
-//============
-parameter P1_EN = 1'b1; // Enable Port 1
-parameter P2_EN = 1'b1; // Enable Port 2
-parameter P3_EN = 1'b0; // Enable Port 3
-parameter P4_EN = 1'b0; // Enable Port 4
-parameter P5_EN = 1'b0; // Enable Port 5
-parameter P6_EN = 1'b0; // Enable Port 6
-
-
-// OUTPUTs
-//=========
-output irq_port1; // Port 1 interrupt
-output irq_port2; // Port 2 interrupt
-output [7:0] p1_dout; // Port 1 data output
-output [7:0] p1_dout_en; // Port 1 data output enable
-output [7:0] p1_sel; // Port 1 function select
-output [7:0] p2_dout; // Port 2 data output
-output [7:0] p2_dout_en; // Port 2 data output enable
-output [7:0] p2_sel; // Port 2 function select
-output [7:0] p3_dout; // Port 3 data output
-output [7:0] p3_dout_en; // Port 3 data output enable
-output [7:0] p3_sel; // Port 3 function select
-output [7:0] p4_dout; // Port 4 data output
-output [7:0] p4_dout_en; // Port 4 data output enable
-output [7:0] p4_sel; // Port 4 function select
-output [7:0] p5_dout; // Port 5 data output
-output [7:0] p5_dout_en; // Port 5 data output enable
-output [7:0] p5_sel; // Port 5 function select
-output [7:0] p6_dout; // Port 6 data output
-output [7:0] p6_dout_en; // Port 6 data output enable
-output [7:0] p6_sel; // Port 6 function select
-output [15:0] per_dout; // Peripheral data output
-
-// INPUTs
-//=========
-input mclk; // Main system clock
-input [7:0] p1_din; // Port 1 data input
-input [7:0] p2_din; // Port 2 data input
-input [7:0] p3_din; // Port 3 data input
-input [7:0] p4_din; // Port 4 data input
-input [7:0] p5_din; // Port 5 data input
-input [7:0] p6_din; // Port 6 data input
-input [7:0] per_addr; // Peripheral address
-input [15:0] per_din; // Peripheral data input
-input per_en; // Peripheral enable (high active)
-input [1:0] per_wen; // Peripheral write enable (high active)
-input puc; // Main system reset
-
-
-//=============================================================================
-// 1) PARAMETER DECLARATION
-//=============================================================================
-
-// Masks
-parameter P1_EN_MSK = {8{P1_EN[0]}};
-parameter P2_EN_MSK = {8{P2_EN[0]}};
-parameter P3_EN_MSK = {8{P3_EN[0]}};
-parameter P4_EN_MSK = {8{P4_EN[0]}};
-parameter P5_EN_MSK = {8{P5_EN[0]}};
-parameter P6_EN_MSK = {8{P6_EN[0]}};
-
-// Register addresses
-parameter P1IN = 9'h020; // Port 1
-parameter P1OUT = 9'h021;
-parameter P1DIR = 9'h022;
-parameter P1IFG = 9'h023;
-parameter P1IES = 9'h024;
-parameter P1IE = 9'h025;
-parameter P1SEL = 9'h026;
-parameter P2IN = 9'h028; // Port 2
-parameter P2OUT = 9'h029;
-parameter P2DIR = 9'h02A;
-parameter P2IFG = 9'h02B;
-parameter P2IES = 9'h02C;
-parameter P2IE = 9'h02D;
-parameter P2SEL = 9'h02E;
-parameter P3IN = 9'h018; // Port 3
-parameter P3OUT = 9'h019;
-parameter P3DIR = 9'h01A;
-parameter P3SEL = 9'h01B;
-parameter P4IN = 9'h01C; // Port 4
-parameter P4OUT = 9'h01D;
-parameter P4DIR = 9'h01E;
-parameter P4SEL = 9'h01F;
-parameter P5IN = 9'h030; // Port 5
-parameter P5OUT = 9'h031;
-parameter P5DIR = 9'h032;
-parameter P5SEL = 9'h033;
-parameter P6IN = 9'h034; // Port 6
-parameter P6OUT = 9'h035;
-parameter P6DIR = 9'h036;
-parameter P6SEL = 9'h037;
-
-
-// Register one-hot decoder
-parameter P1IN_D = (256'h1 << (P1IN /2)); // Port 1
-parameter P1OUT_D = (256'h1 << (P1OUT /2));
-parameter P1DIR_D = (256'h1 << (P1DIR /2));
-parameter P1IFG_D = (256'h1 << (P1IFG /2));
-parameter P1IES_D = (256'h1 << (P1IES /2));
-parameter P1IE_D = (256'h1 << (P1IE /2));
-parameter P1SEL_D = (256'h1 << (P1SEL /2));
-parameter P2IN_D = (256'h1 << (P2IN /2)); // Port 2
-parameter P2OUT_D = (256'h1 << (P2OUT /2));
-parameter P2DIR_D = (256'h1 << (P2DIR /2));
-parameter P2IFG_D = (256'h1 << (P2IFG /2));
-parameter P2IES_D = (256'h1 << (P2IES /2));
-parameter P2IE_D = (256'h1 << (P2IE /2));
-parameter P2SEL_D = (256'h1 << (P2SEL /2));
-parameter P3IN_D = (256'h1 << (P3IN /2)); // Port 3
-parameter P3OUT_D = (256'h1 << (P3OUT /2));
-parameter P3DIR_D = (256'h1 << (P3DIR /2));
-parameter P3SEL_D = (256'h1 << (P3SEL /2));
-parameter P4IN_D = (256'h1 << (P4IN /2)); // Port 4
-parameter P4OUT_D = (256'h1 << (P4OUT /2));
-parameter P4DIR_D = (256'h1 << (P4DIR /2));
-parameter P4SEL_D = (256'h1 << (P4SEL /2));
-parameter P5IN_D = (256'h1 << (P5IN /2)); // Port 5
-parameter P5OUT_D = (256'h1 << (P5OUT /2));
-parameter P5DIR_D = (256'h1 << (P5DIR /2));
-parameter P5SEL_D = (256'h1 << (P5SEL /2));
-parameter P6IN_D = (256'h1 << (P6IN /2)); // Port 6
-parameter P6OUT_D = (256'h1 << (P6OUT /2));
-parameter P6DIR_D = (256'h1 << (P6DIR /2));
-parameter P6SEL_D = (256'h1 << (P6SEL /2));
-
-
-//============================================================================
-// 2) REGISTER DECODER
-//============================================================================
-
-// Register address decode
-reg [255:0] reg_dec;
-always @(per_addr)
- case (per_addr)
- (P1IN /2): reg_dec = P1IN_D & {256{P1_EN[0]}};
- (P1OUT /2): reg_dec = P1OUT_D & {256{P1_EN[0]}};
- (P1DIR /2): reg_dec = P1DIR_D & {256{P1_EN[0]}};
- (P1IFG /2): reg_dec = P1IFG_D & {256{P1_EN[0]}};
- (P1IES /2): reg_dec = P1IES_D & {256{P1_EN[0]}};
- (P1IE /2): reg_dec = P1IE_D & {256{P1_EN[0]}};
- (P1SEL /2): reg_dec = P1SEL_D & {256{P1_EN[0]}};
- (P2IN /2): reg_dec = P2IN_D & {256{P2_EN[0]}};
- (P2OUT /2): reg_dec = P2OUT_D & {256{P2_EN[0]}};
- (P2DIR /2): reg_dec = P2DIR_D & {256{P2_EN[0]}};
- (P2IFG /2): reg_dec = P2IFG_D & {256{P2_EN[0]}};
- (P2IES /2): reg_dec = P2IES_D & {256{P2_EN[0]}};
- (P2IE /2): reg_dec = P2IE_D & {256{P2_EN[0]}};
- (P2SEL /2): reg_dec = P2SEL_D & {256{P2_EN[0]}};
- (P3IN /2): reg_dec = P3IN_D & {256{P3_EN[0]}};
- (P3OUT /2): reg_dec = P3OUT_D & {256{P3_EN[0]}};
- (P3DIR /2): reg_dec = P3DIR_D & {256{P3_EN[0]}};
- (P3SEL /2): reg_dec = P3SEL_D & {256{P3_EN[0]}};
- (P4IN /2): reg_dec = P4IN_D & {256{P4_EN[0]}};
- (P4OUT /2): reg_dec = P4OUT_D & {256{P4_EN[0]}};
- (P4DIR /2): reg_dec = P4DIR_D & {256{P4_EN[0]}};
- (P4SEL /2): reg_dec = P4SEL_D & {256{P4_EN[0]}};
- (P5IN /2): reg_dec = P5IN_D & {256{P5_EN[0]}};
- (P5OUT /2): reg_dec = P5OUT_D & {256{P5_EN[0]}};
- (P5DIR /2): reg_dec = P5DIR_D & {256{P5_EN[0]}};
- (P5SEL /2): reg_dec = P5SEL_D & {256{P5_EN[0]}};
- (P6IN /2): reg_dec = P6IN_D & {256{P6_EN[0]}};
- (P6OUT /2): reg_dec = P6OUT_D & {256{P6_EN[0]}};
- (P6DIR /2): reg_dec = P6DIR_D & {256{P6_EN[0]}};
- (P6SEL /2): reg_dec = P6SEL_D & {256{P6_EN[0]}};
- default : reg_dec = {256{1'b0}};
- endcase
-
-// Read/Write probes
-wire reg_lo_write = per_wen[0] & per_en;
-wire reg_hi_write = per_wen[1] & per_en;
-wire reg_read = ~|per_wen & per_en;
-
-// Read/Write vectors
-wire [255:0] reg_hi_wr = reg_dec & {256{reg_hi_write}};
-wire [255:0] reg_lo_wr = reg_dec & {256{reg_lo_write}};
-wire [255:0] reg_rd = reg_dec & {256{reg_read}};
-
-
-//============================================================================
-// 3) REGISTERS
-//============================================================================
-
-// P1IN Register
-//---------------
-reg [7:0] p1in;
-
-always @ (posedge mclk or posedge puc)
- if (puc) p1in <= 8'h00;
- else p1in <= p1_din & P1_EN_MSK;
-
-
-// P1OUT Register
-//----------------
-reg [7:0] p1out;
-
-wire p1out_wr = P1OUT[0] ? reg_hi_wr[P1OUT/2] : reg_lo_wr[P1OUT/2];
-wire [7:0] p1out_nxt = P1OUT[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p1out <= 8'h00;
- else if (p1out_wr) p1out <= p1out_nxt & P1_EN_MSK;
-
-assign p1_dout = p1out;
-
-
-// P1DIR Register
-//----------------
-reg [7:0] p1dir;
-
-wire p1dir_wr = P1DIR[0] ? reg_hi_wr[P1DIR/2] : reg_lo_wr[P1DIR/2];
-wire [7:0] p1dir_nxt = P1DIR[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p1dir <= 8'h00;
- else if (p1dir_wr) p1dir <= p1dir_nxt & P1_EN_MSK;
-
-assign p1_dout_en = p1dir;
-
-
-// P1IFG Register
-//----------------
-reg [7:0] p1ifg;
-
-wire p1ifg_wr = P1IFG[0] ? reg_hi_wr[P1IFG/2] : reg_lo_wr[P1IFG/2];
-wire [7:0] p1ifg_nxt = P1IFG[0] ? per_din[15:8] : per_din[7:0];
-wire [7:0] p1ifg_set;
-
-always @ (posedge mclk or posedge puc)
- if (puc) p1ifg <= 8'h00;
- else if (p1ifg_wr) p1ifg <= (p1ifg_nxt | p1ifg_set) & P1_EN_MSK;
- else p1ifg <= (p1ifg | p1ifg_set) & P1_EN_MSK;
-
-// P1IES Register
-//----------------
-reg [7:0] p1ies;
-
-wire p1ies_wr = P1IES[0] ? reg_hi_wr[P1IES/2] : reg_lo_wr[P1IES/2];
-wire [7:0] p1ies_nxt = P1IES[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p1ies <= 8'h00;
- else if (p1ies_wr) p1ies <= p1ies_nxt & P1_EN_MSK;
-
-
-// P1IE Register
-//----------------
-reg [7:0] p1ie;
-
-wire p1ie_wr = P1IE[0] ? reg_hi_wr[P1IE/2] : reg_lo_wr[P1IE/2];
-wire [7:0] p1ie_nxt = P1IE[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p1ie <= 8'h00;
- else if (p1ie_wr) p1ie <= p1ie_nxt & P1_EN_MSK;
-
-
-// P1SEL Register
-//----------------
-reg [7:0] p1sel;
-
-wire p1sel_wr = P1SEL[0] ? reg_hi_wr[P1SEL/2] : reg_lo_wr[P1SEL/2];
-wire [7:0] p1sel_nxt = P1SEL[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p1sel <= 8'h00;
- else if (p1sel_wr) p1sel <= p1sel_nxt & P1_EN_MSK;
-
-assign p1_sel = p1sel;
-
-
-// P2IN Register
-//---------------
-reg [7:0] p2in;
-
-always @ (posedge mclk or posedge puc)
- if (puc) p2in <= 8'h00;
- else p2in <= p2_din & P2_EN_MSK;
-
-
-// P2OUT Register
-//----------------
-reg [7:0] p2out;
-
-wire p2out_wr = P2OUT[0] ? reg_hi_wr[P2OUT/2] : reg_lo_wr[P2OUT/2];
-wire [7:0] p2out_nxt = P2OUT[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p2out <= 8'h00;
- else if (p2out_wr) p2out <= p2out_nxt & P2_EN_MSK;
-
-assign p2_dout = p2out;
-
-
-// P2DIR Register
-//----------------
-reg [7:0] p2dir;
-
-wire p2dir_wr = P2DIR[0] ? reg_hi_wr[P2DIR/2] : reg_lo_wr[P2DIR/2];
-wire [7:0] p2dir_nxt = P2DIR[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p2dir <= 8'h00;
- else if (p2dir_wr) p2dir <= p2dir_nxt & P2_EN_MSK;
-
-assign p2_dout_en = p2dir;
-
-
-// P2IFG Register
-//----------------
-reg [7:0] p2ifg;
-
-wire p2ifg_wr = P2IFG[0] ? reg_hi_wr[P2IFG/2] : reg_lo_wr[P2IFG/2];
-wire [7:0] p2ifg_nxt = P2IFG[0] ? per_din[15:8] : per_din[7:0];
-wire [7:0] p2ifg_set;
-
-always @ (posedge mclk or posedge puc)
- if (puc) p2ifg <= 8'h00;
- else if (p2ifg_wr) p2ifg <= (p2ifg_nxt | p2ifg_set) & P2_EN_MSK;
- else p2ifg <= (p2ifg | p2ifg_set) & P2_EN_MSK;
-
-
-// P2IES Register
-//----------------
-reg [7:0] p2ies;
-
-wire p2ies_wr = P2IES[0] ? reg_hi_wr[P2IES/2] : reg_lo_wr[P2IES/2];
-wire [7:0] p2ies_nxt = P2IES[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p2ies <= 8'h00;
- else if (p2ies_wr) p2ies <= p2ies_nxt & P2_EN_MSK;
-
-
-// P2IE Register
-//----------------
-reg [7:0] p2ie;
-
-wire p2ie_wr = P2IE[0] ? reg_hi_wr[P2IE/2] : reg_lo_wr[P2IE/2];
-wire [7:0] p2ie_nxt = P2IE[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p2ie <= 8'h00;
- else if (p2ie_wr) p2ie <= p2ie_nxt & P2_EN_MSK;
-
-
-// P2SEL Register
-//----------------
-reg [7:0] p2sel;
-
-wire p2sel_wr = P2SEL[0] ? reg_hi_wr[P2SEL/2] : reg_lo_wr[P2SEL/2];
-wire [7:0] p2sel_nxt = P2SEL[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p2sel <= 8'h00;
- else if (p2sel_wr) p2sel <= p2sel_nxt & P2_EN_MSK;
-
-assign p2_sel = p2sel;
-
-
-// P3IN Register
-//---------------
-reg [7:0] p3in;
-
-always @ (posedge mclk or posedge puc)
- if (puc) p3in <= 8'h00;
- else p3in <= p3_din & P3_EN_MSK;
-
-
-// P3OUT Register
-//----------------
-reg [7:0] p3out;
-
-wire p3out_wr = P3OUT[0] ? reg_hi_wr[P3OUT/2] : reg_lo_wr[P3OUT/2];
-wire [7:0] p3out_nxt = P3OUT[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p3out <= 8'h00;
- else if (p3out_wr) p3out <= p3out_nxt & P3_EN_MSK;
-
-assign p3_dout = p3out;
-
-
-// P3DIR Register
-//----------------
-reg [7:0] p3dir;
-
-wire p3dir_wr = P3DIR[0] ? reg_hi_wr[P3DIR/2] : reg_lo_wr[P3DIR/2];
-wire [7:0] p3dir_nxt = P3DIR[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p3dir <= 8'h00;
- else if (p3dir_wr) p3dir <= p3dir_nxt & P3_EN_MSK;
-
-assign p3_dout_en = p3dir;
-
-
-// P3SEL Register
-//----------------
-reg [7:0] p3sel;
-
-wire p3sel_wr = P3SEL[0] ? reg_hi_wr[P3SEL/2] : reg_lo_wr[P3SEL/2];
-wire [7:0] p3sel_nxt = P3SEL[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p3sel <= 8'h00;
- else if (p3sel_wr) p3sel <= p3sel_nxt & P3_EN_MSK;
-
-assign p3_sel = p3sel;
-
-
-// P4IN Register
-//---------------
-reg [7:0] p4in;
-
-always @ (posedge mclk or posedge puc)
- if (puc) p4in <= 8'h00;
- else p4in <= p4_din & P4_EN_MSK;
-
-
-// P4OUT Register
-//----------------
-reg [7:0] p4out;
-
-wire p4out_wr = P4OUT[0] ? reg_hi_wr[P4OUT/2] : reg_lo_wr[P4OUT/2];
-wire [7:0] p4out_nxt = P4OUT[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p4out <= 8'h00;
- else if (p4out_wr) p4out <= p4out_nxt & P4_EN_MSK;
-
-assign p4_dout = p4out;
-
-
-// P4DIR Register
-//----------------
-reg [7:0] p4dir;
-
-wire p4dir_wr = P4DIR[0] ? reg_hi_wr[P4DIR/2] : reg_lo_wr[P4DIR/2];
-wire [7:0] p4dir_nxt = P4DIR[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p4dir <= 8'h00;
- else if (p4dir_wr) p4dir <= p4dir_nxt & P4_EN_MSK;
-
-assign p4_dout_en = p4dir;
-
-
-// P4SEL Register
-//----------------
-reg [7:0] p4sel;
-
-wire p4sel_wr = P4SEL[0] ? reg_hi_wr[P4SEL/2] : reg_lo_wr[P4SEL/2];
-wire [7:0] p4sel_nxt = P4SEL[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p4sel <= 8'h00;
- else if (p4sel_wr) p4sel <= p4sel_nxt & P4_EN_MSK;
-
-assign p4_sel = p4sel;
-
-
-// P5IN Register
-//---------------
-reg [7:0] p5in;
-
-always @ (posedge mclk or posedge puc)
- if (puc) p5in <= 8'h00;
- else p5in <= p5_din & P5_EN_MSK;
-
-
-// P5OUT Register
-//----------------
-reg [7:0] p5out;
-
-wire p5out_wr = P5OUT[0] ? reg_hi_wr[P5OUT/2] : reg_lo_wr[P5OUT/2];
-wire [7:0] p5out_nxt = P5OUT[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p5out <= 8'h00;
- else if (p5out_wr) p5out <= p5out_nxt & P5_EN_MSK;
-
-assign p5_dout = p5out;
-
-
-// P5DIR Register
-//----------------
-reg [7:0] p5dir;
-
-wire p5dir_wr = P5DIR[0] ? reg_hi_wr[P5DIR/2] : reg_lo_wr[P5DIR/2];
-wire [7:0] p5dir_nxt = P5DIR[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p5dir <= 8'h00;
- else if (p5dir_wr) p5dir <= p5dir_nxt & P5_EN_MSK;
-
-assign p5_dout_en = p5dir;
-
-
-// P5SEL Register
-//----------------
-reg [7:0] p5sel;
-
-wire p5sel_wr = P5SEL[0] ? reg_hi_wr[P5SEL/2] : reg_lo_wr[P5SEL/2];
-wire [7:0] p5sel_nxt = P5SEL[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p5sel <= 8'h00;
- else if (p5sel_wr) p5sel <= p5sel_nxt & P5_EN_MSK;
-
-assign p5_sel = p5sel;
-
-
-// P6IN Register
-//---------------
-reg [7:0] p6in;
-
-always @ (posedge mclk or posedge puc)
- if (puc) p6in <= 8'h00;
- else p6in <= p6_din & P6_EN_MSK;
-
-
-// P6OUT Register
-//----------------
-reg [7:0] p6out;
-
-wire p6out_wr = P6OUT[0] ? reg_hi_wr[P6OUT/2] : reg_lo_wr[P6OUT/2];
-wire [7:0] p6out_nxt = P6OUT[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p6out <= 8'h00;
- else if (p6out_wr) p6out <= p6out_nxt & P6_EN_MSK;
-
-assign p6_dout = p6out;
-
-
-// P6DIR Register
-//----------------
-reg [7:0] p6dir;
-
-wire p6dir_wr = P6DIR[0] ? reg_hi_wr[P6DIR/2] : reg_lo_wr[P6DIR/2];
-wire [7:0] p6dir_nxt = P6DIR[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p6dir <= 8'h00;
- else if (p6dir_wr) p6dir <= p6dir_nxt & P6_EN_MSK;
-
-assign p6_dout_en = p6dir;
-
-
-// P6SEL Register
-//----------------
-reg [7:0] p6sel;
-
-wire p6sel_wr = P6SEL[0] ? reg_hi_wr[P6SEL/2] : reg_lo_wr[P6SEL/2];
-wire [7:0] p6sel_nxt = P6SEL[0] ? per_din[15:8] : per_din[7:0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) p6sel <= 8'h00;
- else if (p6sel_wr) p6sel <= p6sel_nxt & P6_EN_MSK;
-
-assign p6_sel = p6sel;
-
-
-
-//============================================================================
-// 4) INTERRUPT GENERATION
-//============================================================================
-
-// Port 1 interrupt
-//------------------
-
-// Delay input
-reg [7:0] p1in_dly;
-always @ (posedge mclk or posedge puc)
- if (puc) p1in_dly <= 8'h00;
- else p1in_dly <= p1in & P1_EN_MSK;
-
-// Edge detection
-wire [7:0] p1in_re = p1in & ~p1in_dly;
-wire [7:0] p1in_fe = ~p1in & p1in_dly;
-
-// Set interrupt flag
-assign p1ifg_set = {p1ies[7] ? p1in_fe[7] : p1in_re[7],
- p1ies[6] ? p1in_fe[6] : p1in_re[6],
- p1ies[5] ? p1in_fe[5] : p1in_re[5],
- p1ies[4] ? p1in_fe[4] : p1in_re[4],
- p1ies[3] ? p1in_fe[3] : p1in_re[3],
- p1ies[2] ? p1in_fe[2] : p1in_re[2],
- p1ies[1] ? p1in_fe[1] : p1in_re[1],
- p1ies[0] ? p1in_fe[0] : p1in_re[0]} & P1_EN_MSK;
-
-// Generate CPU interrupt
-assign irq_port1 = |(p1ie & p1ifg) & P1_EN[0];
-
-
-// Port 1 interrupt
-//------------------
-
-// Delay input
-reg [7:0] p2in_dly;
-always @ (posedge mclk or posedge puc)
- if (puc) p2in_dly <= 8'h00;
- else p2in_dly <= p2in & P2_EN_MSK;
-
-// Edge detection
-wire [7:0] p2in_re = p2in & ~p2in_dly;
-wire [7:0] p2in_fe = ~p2in & p2in_dly;
-
-// Set interrupt flag
-assign p2ifg_set = {p2ies[7] ? p2in_fe[7] : p2in_re[7],
- p2ies[6] ? p2in_fe[6] : p2in_re[6],
- p2ies[5] ? p2in_fe[5] : p2in_re[5],
- p2ies[4] ? p2in_fe[4] : p2in_re[4],
- p2ies[3] ? p2in_fe[3] : p2in_re[3],
- p2ies[2] ? p2in_fe[2] : p2in_re[2],
- p2ies[1] ? p2in_fe[1] : p2in_re[1],
- p2ies[0] ? p2in_fe[0] : p2in_re[0]} & P2_EN_MSK;
-
-// Generate CPU interrupt
-assign irq_port2 = |(p2ie & p2ifg) & P2_EN[0];
-
-
-//============================================================================
-// 5) DATA OUTPUT GENERATION
-//============================================================================
-
-// Data output mux
-wire [15:0] p1in_rd = (p1in & {8{reg_rd[P1IN/2]}}) << (8 & {4{P1IN[0]}});
-wire [15:0] p1out_rd = (p1out & {8{reg_rd[P1OUT/2]}}) << (8 & {4{P1OUT[0]}});
-wire [15:0] p1dir_rd = (p1dir & {8{reg_rd[P1DIR/2]}}) << (8 & {4{P1DIR[0]}});
-wire [15:0] p1ifg_rd = (p1ifg & {8{reg_rd[P1IFG/2]}}) << (8 & {4{P1IFG[0]}});
-wire [15:0] p1ies_rd = (p1ies & {8{reg_rd[P1IES/2]}}) << (8 & {4{P1IES[0]}});
-wire [15:0] p1ie_rd = (p1ie & {8{reg_rd[P1IE/2]}}) << (8 & {4{P1IE[0]}});
-wire [15:0] p1sel_rd = (p1sel & {8{reg_rd[P1SEL/2]}}) << (8 & {4{P1SEL[0]}});
-wire [15:0] p2in_rd = (p2in & {8{reg_rd[P2IN/2]}}) << (8 & {4{P2IN[0]}});
-wire [15:0] p2out_rd = (p2out & {8{reg_rd[P2OUT/2]}}) << (8 & {4{P2OUT[0]}});
-wire [15:0] p2dir_rd = (p2dir & {8{reg_rd[P2DIR/2]}}) << (8 & {4{P2DIR[0]}});
-wire [15:0] p2ifg_rd = (p2ifg & {8{reg_rd[P2IFG/2]}}) << (8 & {4{P2IFG[0]}});
-wire [15:0] p2ies_rd = (p2ies & {8{reg_rd[P2IES/2]}}) << (8 & {4{P2IES[0]}});
-wire [15:0] p2ie_rd = (p2ie & {8{reg_rd[P2IE/2]}}) << (8 & {4{P2IE[0]}});
-wire [15:0] p2sel_rd = (p2sel & {8{reg_rd[P2SEL/2]}}) << (8 & {4{P2SEL[0]}});
-wire [15:0] p3in_rd = (p3in & {8{reg_rd[P3IN/2]}}) << (8 & {4{P3IN[0]}});
-wire [15:0] p3out_rd = (p3out & {8{reg_rd[P3OUT/2]}}) << (8 & {4{P3OUT[0]}});
-wire [15:0] p3dir_rd = (p3dir & {8{reg_rd[P3DIR/2]}}) << (8 & {4{P3DIR[0]}});
-wire [15:0] p3sel_rd = (p3sel & {8{reg_rd[P3SEL/2]}}) << (8 & {4{P3SEL[0]}});
-wire [15:0] p4in_rd = (p4in & {8{reg_rd[P4IN/2]}}) << (8 & {4{P4IN[0]}});
-wire [15:0] p4out_rd = (p4out & {8{reg_rd[P4OUT/2]}}) << (8 & {4{P4OUT[0]}});
-wire [15:0] p4dir_rd = (p4dir & {8{reg_rd[P4DIR/2]}}) << (8 & {4{P4DIR[0]}});
-wire [15:0] p4sel_rd = (p4sel & {8{reg_rd[P4SEL/2]}}) << (8 & {4{P4SEL[0]}});
-wire [15:0] p5in_rd = (p5in & {8{reg_rd[P5IN/2]}}) << (8 & {4{P5IN[0]}});
-wire [15:0] p5out_rd = (p5out & {8{reg_rd[P5OUT/2]}}) << (8 & {4{P5OUT[0]}});
-wire [15:0] p5dir_rd = (p5dir & {8{reg_rd[P5DIR/2]}}) << (8 & {4{P5DIR[0]}});
-wire [15:0] p5sel_rd = (p5sel & {8{reg_rd[P5SEL/2]}}) << (8 & {4{P5SEL[0]}});
-wire [15:0] p6in_rd = (p6in & {8{reg_rd[P6IN/2]}}) << (8 & {4{P6IN[0]}});
-wire [15:0] p6out_rd = (p6out & {8{reg_rd[P6OUT/2]}}) << (8 & {4{P6OUT[0]}});
-wire [15:0] p6dir_rd = (p6dir & {8{reg_rd[P6DIR/2]}}) << (8 & {4{P6DIR[0]}});
-wire [15:0] p6sel_rd = (p6sel & {8{reg_rd[P6SEL/2]}}) << (8 & {4{P6SEL[0]}});
-
-wire [15:0] per_dout = p1in_rd |
- p1out_rd |
- p1dir_rd |
- p1ifg_rd |
- p1ies_rd |
- p1ie_rd |
- p1sel_rd |
- p2in_rd |
- p2out_rd |
- p2dir_rd |
- p2ifg_rd |
- p2ies_rd |
- p2ie_rd |
- p2sel_rd |
- p3in_rd |
- p3out_rd |
- p3dir_rd |
- p3sel_rd |
- p4in_rd |
- p4out_rd |
- p4dir_rd |
- p4sel_rd |
- p5in_rd |
- p5out_rd |
- p5dir_rd |
- p5sel_rd |
- p6in_rd |
- p6out_rd |
- p6dir_rd |
- p6sel_rd;
-
-endmodule // gpio
-
-
-
-
-
-
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/periph/gpio.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/periph/timerA.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/periph/timerA.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/periph/timerA.v (nonexistent)
@@ -1,694 +0,0 @@
-//----------------------------------------------------------------------------
-// Copyright (C) 2001 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, write to the Free Software Foundation,
-// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
-//
-//----------------------------------------------------------------------------
-//
-// *File Name: timerA.v
-//
-// *Module Description:
-// Timer A top-level
-//
-// *Author(s):
-// - Olivier Girard, olgirard@gmail.com
-//
-//----------------------------------------------------------------------------
-// $Rev$
-// $LastChangedBy$
-// $LastChangedDate$
-//----------------------------------------------------------------------------
-`include "timescale.v"
-`include "openMSP430_defines.v"
-
-module timerA (
-
-// OUTPUTs
- irq_ta0, // Timer A interrupt: TACCR0
- irq_ta1, // Timer A interrupt: TAIV, TACCR1, TACCR2
- per_dout, // Peripheral data output
- ta_out0, // Timer A output 0
- ta_out0_en, // Timer A output 0 enable
- ta_out1, // Timer A output 1
- ta_out1_en, // Timer A output 1 enable
- ta_out2, // Timer A output 2
- ta_out2_en, // Timer A output 2 enable
-
-// INPUTs
- aclk_en, // ACLK enable (from CPU)
- dbg_freeze, // Freeze Timer A counter
- inclk, // INCLK external timer clock (SLOW)
- irq_ta0_acc, // Interrupt request TACCR0 accepted
- mclk, // Main system clock
- per_addr, // Peripheral address
- per_din, // Peripheral data input
- per_en, // Peripheral enable (high active)
- per_wen, // Peripheral write enable (high active)
- puc, // Main system reset
- smclk_en, // SMCLK enable (from CPU)
- ta_cci0a, // Timer A capture 0 input A
- ta_cci0b, // Timer A capture 0 input B
- ta_cci1a, // Timer A capture 1 input A
- ta_cci1b, // Timer A capture 1 input B
- ta_cci2a, // Timer A capture 2 input A
- ta_cci2b, // Timer A capture 2 input B
- taclk // TACLK external timer clock (SLOW)
-);
-
-// OUTPUTs
-//=========
-output irq_ta0; // Timer A interrupt: TACCR0
-output irq_ta1; // Timer A interrupt: TAIV, TACCR1, TACCR2
-output [15:0] per_dout; // Peripheral data output
-output ta_out0; // Timer A output 0
-output ta_out0_en; // Timer A output 0 enable
-output ta_out1; // Timer A output 1
-output ta_out1_en; // Timer A output 1 enable
-output ta_out2; // Timer A output 2
-output ta_out2_en; // Timer A output 2 enable
-
-// INPUTs
-//=========
-input aclk_en; // ACLK enable (from CPU)
-input dbg_freeze; // Freeze Timer A counter
-input inclk; // INCLK external timer clock (SLOW)
-input irq_ta0_acc; // Interrupt request TACCR0 accepted
-input mclk; // Main system clock
-input [7:0] per_addr; // Peripheral address
-input [15:0] per_din; // Peripheral data input
-input per_en; // Peripheral enable (high active)
-input [1:0] per_wen; // Peripheral write enable (high active)
-input puc; // Main system reset
-input smclk_en; // SMCLK enable (from CPU)
-input ta_cci0a; // Timer A capture 0 input A
-input ta_cci0b; // Timer A capture 0 input B
-input ta_cci1a; // Timer A capture 1 input A
-input ta_cci1b; // Timer A capture 1 input B
-input ta_cci2a; // Timer A capture 2 input A
-input ta_cci2b; // Timer A capture 2 input B
-input taclk; // TACLK external timer clock (SLOW)
-
-
-//=============================================================================
-// 1) PARAMETER DECLARATION
-//=============================================================================
-
-// Register addresses
-parameter TACTL = 9'h160;
-parameter TAR = 9'h170;
-parameter TACCTL0 = 9'h162;
-parameter TACCR0 = 9'h172;
-parameter TACCTL1 = 9'h164;
-parameter TACCR1 = 9'h174;
-parameter TACCTL2 = 9'h166;
-parameter TACCR2 = 9'h176;
-parameter TAIV = 9'h12E;
-
-
-// Register one-hot decoder
-parameter TACTL_D = (512'h1 << TACTL);
-parameter TAR_D = (512'h1 << TAR);
-parameter TACCTL0_D = (512'h1 << TACCTL0);
-parameter TACCR0_D = (512'h1 << TACCR0);
-parameter TACCTL1_D = (512'h1 << TACCTL1);
-parameter TACCR1_D = (512'h1 << TACCR1);
-parameter TACCTL2_D = (512'h1 << TACCTL2);
-parameter TACCR2_D = (512'h1 << TACCR2);
-parameter TAIV_D = (512'h1 << TAIV);
-
-
-//============================================================================
-// 2) REGISTER DECODER
-//============================================================================
-
-// Register address decode
-reg [511:0] reg_dec;
-always @(per_addr)
- case ({per_addr,1'b0})
- TACTL : reg_dec = TACTL_D;
- TAR : reg_dec = TAR_D;
- TACCTL0: reg_dec = TACCTL0_D;
- TACCR0 : reg_dec = TACCR0_D;
- TACCTL1: reg_dec = TACCTL1_D;
- TACCR1 : reg_dec = TACCR1_D;
- TACCTL2: reg_dec = TACCTL2_D;
- TACCR2 : reg_dec = TACCR2_D;
- TAIV : reg_dec = TAIV_D;
- default: reg_dec = {512{1'b0}};
- endcase
-
-// Read/Write probes
-wire reg_write = |per_wen & per_en;
-wire reg_read = ~|per_wen & per_en;
-
-// Read/Write vectors
-wire [511:0] reg_wr = reg_dec & {512{reg_write}};
-wire [511:0] reg_rd = reg_dec & {512{reg_read}};
-
-
-//============================================================================
-// 3) REGISTERS
-//============================================================================
-
-// TACTL Register
-//-----------------
-reg [9:0] tactl;
-
-wire tactl_wr = reg_wr[TACTL];
-wire taclr = tactl_wr & per_din[`TACLR];
-wire taifg_set;
-wire taifg_clr;
-
-always @ (posedge mclk or posedge puc)
- if (puc) tactl <= 10'h000;
- else if (tactl_wr) tactl <= ((per_din[9:0] & 10'h3f3) | {9'h000, taifg_set}) & {9'h1ff, ~taifg_clr};
- else tactl <= (tactl | {9'h000, taifg_set}) & {9'h1ff, ~taifg_clr};
-
-
-// TAR Register
-//-----------------
-reg [15:0] tar;
-
-wire tar_wr = reg_wr[TAR];
-
-wire tar_clk;
-wire tar_clr;
-wire tar_inc;
-wire tar_dec;
-wire [15:0] tar_add = tar_inc ? 16'h0001 :
- tar_dec ? 16'hffff : 16'h0000;
-wire [15:0] tar_nxt = tar_clr ? 16'h0000 : (tar+tar_add);
-
-always @ (posedge mclk or posedge puc)
- if (puc) tar <= 16'h0000;
- else if (tar_wr) tar <= per_din;
- else if (taclr) tar <= 16'h0000;
- else if (tar_clk & ~dbg_freeze) tar <= tar_nxt;
-
-
-// TACCTL0 Register
-//------------------
-reg [15:0] tacctl0;
-
-wire tacctl0_wr = reg_wr[TACCTL0];
-wire ccifg0_set;
-wire cov0_set;
-
-always @ (posedge mclk or posedge puc)
- if (puc) tacctl0 <= 16'h0000;
- else if (tacctl0_wr) tacctl0 <= ((per_din & 16'hf9f7) | {14'h0000, cov0_set, ccifg0_set}) & {15'h7fff, ~irq_ta0_acc};
- else tacctl0 <= (tacctl0 | {14'h0000, cov0_set, ccifg0_set}) & {15'h7fff, ~irq_ta0_acc};
-
-wire cci0;
-reg scci0;
-wire [15:0] tacctl0_full = tacctl0 | {5'h00, scci0, 6'h00, cci0, 3'h0};
-
-
-// TACCR0 Register
-//------------------
-reg [15:0] taccr0;
-
-wire taccr0_wr = reg_wr[TACCR0];
-wire cci0_cap;
-
-always @ (posedge mclk or posedge puc)
- if (puc) taccr0 <= 16'h0000;
- else if (taccr0_wr) taccr0 <= per_din;
- else if (cci0_cap) taccr0 <= tar;
-
-
-// TACCTL1 Register
-//------------------
-reg [15:0] tacctl1;
-
-wire tacctl1_wr = reg_wr[TACCTL1];
-wire ccifg1_set;
-wire ccifg1_clr;
-wire cov1_set;
-
-always @ (posedge mclk or posedge puc)
- if (puc) tacctl1 <= 16'h0000;
- else if (tacctl1_wr) tacctl1 <= ((per_din & 16'hf9f7) | {14'h0000, cov1_set, ccifg1_set}) & {15'h7fff, ~ccifg1_clr};
- else tacctl1 <= (tacctl1 | {14'h0000, cov1_set, ccifg1_set}) & {15'h7fff, ~ccifg1_clr};
-
-wire cci1;
-reg scci1;
-wire [15:0] tacctl1_full = tacctl1 | {5'h00, scci1, 6'h00, cci1, 3'h0};
-
-
-// TACCR1 Register
-//------------------
-reg [15:0] taccr1;
-
-wire taccr1_wr = reg_wr[TACCR1];
-wire cci1_cap;
-
-always @ (posedge mclk or posedge puc)
- if (puc) taccr1 <= 16'h0000;
- else if (taccr1_wr) taccr1 <= per_din;
- else if (cci1_cap) taccr1 <= tar;
-
-
-// TACCTL2 Register
-//------------------
-reg [15:0] tacctl2;
-
-wire tacctl2_wr = reg_wr[TACCTL2];
-wire ccifg2_set;
-wire ccifg2_clr;
-wire cov2_set;
-
-always @ (posedge mclk or posedge puc)
- if (puc) tacctl2 <= 16'h0000;
- else if (tacctl2_wr) tacctl2 <= ((per_din & 16'hf9f7) | {14'h0000, cov2_set, ccifg2_set}) & {15'h7fff, ~ccifg2_clr};
- else tacctl2 <= (tacctl2 | {14'h0000, cov2_set, ccifg2_set}) & {15'h7fff, ~ccifg2_clr};
-
-wire cci2;
-reg scci2;
-wire [15:0] tacctl2_full = tacctl2 | {5'h00, scci2, 6'h00, cci2, 3'h0};
-
-
-// TACCR2 Register
-//------------------
-reg [15:0] taccr2;
-
-wire taccr2_wr = reg_wr[TACCR2];
-wire cci2_cap;
-
-always @ (posedge mclk or posedge puc)
- if (puc) taccr2 <= 16'h0000;
- else if (taccr2_wr) taccr2 <= per_din;
- else if (cci2_cap) taccr2 <= tar;
-
-
-// TAIV Register
-//------------------
-
-wire [3:0] taiv = (tacctl1[`TACCIFG] & tacctl1[`TACCIE]) ? 4'h2 :
- (tacctl2[`TACCIFG] & tacctl2[`TACCIE]) ? 4'h4 :
- (tactl[`TAIFG] & tactl[`TAIE]) ? 4'hA :
- 4'h0;
-
-assign ccifg1_clr = (reg_rd[TAIV] | reg_wr[TAIV]) & (taiv==4'h2);
-assign ccifg2_clr = (reg_rd[TAIV] | reg_wr[TAIV]) & (taiv==4'h4);
-assign taifg_clr = (reg_rd[TAIV] | reg_wr[TAIV]) & (taiv==4'hA);
-
-
-//============================================================================
-// 4) DATA OUTPUT GENERATION
-//============================================================================
-
-// Data output mux
-wire [15:0] tactl_rd = {6'h00, tactl} & {16{reg_rd[TACTL]}};
-wire [15:0] tar_rd = tar & {16{reg_rd[TAR]}};
-wire [15:0] tacctl0_rd = tacctl0_full & {16{reg_rd[TACCTL0]}};
-wire [15:0] taccr0_rd = taccr0 & {16{reg_rd[TACCR0]}};
-wire [15:0] tacctl1_rd = tacctl1_full & {16{reg_rd[TACCTL1]}};
-wire [15:0] taccr1_rd = taccr1 & {16{reg_rd[TACCR1]}};
-wire [15:0] tacctl2_rd = tacctl2_full & {16{reg_rd[TACCTL2]}};
-wire [15:0] taccr2_rd = taccr2 & {16{reg_rd[TACCR2]}};
-wire [15:0] taiv_rd = {12'h000, taiv} & {16{reg_rd[TAIV]}};
-
-wire [15:0] per_dout = tactl_rd |
- tar_rd |
- tacctl0_rd |
- taccr0_rd |
- tacctl1_rd |
- taccr1_rd |
- tacctl2_rd |
- taccr2_rd |
- taiv_rd;
-
-
-//============================================================================
-// 5) Timer A counter control
-//============================================================================
-
-// Clock input synchronization (TACLK & INCLK)
-//-----------------------------------------------------------
-reg [2:0] taclk_s;
-
-always @ (posedge mclk or posedge puc)
- if (puc) taclk_s <= 3'b000;
- else taclk_s <= {taclk_s[1:0], taclk};
-
-wire taclk_en = taclk_s[1] & ~taclk_s[2];
-
-
-reg [2:0] inclk_s;
-
-always @ (posedge mclk or posedge puc)
- if (puc) inclk_s <= 3'b000;
- else inclk_s <= {inclk_s[1:0], inclk};
-
-wire inclk_en = inclk_s[1] & ~inclk_s[2];
-
-
-// Timer clock input mux
-//-----------------------------------------------------------
-
-wire sel_clk = (tactl[`TASSELx]==2'b00) ? taclk_en :
- (tactl[`TASSELx]==2'b01) ? aclk_en :
- (tactl[`TASSELx]==2'b10) ? smclk_en : inclk_en;
-
-
-// Generate update pluse for the counter (<=> divided clock)
-//-----------------------------------------------------------
-reg [2:0] clk_div;
-
-assign tar_clk = sel_clk & ((tactl[`TAIDx]==2'b00) ? 1'b1 :
- (tactl[`TAIDx]==2'b01) ? clk_div[0] :
- (tactl[`TAIDx]==2'b10) ? &clk_div[1:0] :
- &clk_div[2:0]);
-
-always @ (posedge mclk or posedge puc)
- if (puc) clk_div <= 3'h0;
- else if (tar_clk | taclr) clk_div <= 3'h0;
- else if ((tactl[`TAMCx]!=2'b00) & sel_clk) clk_div <= clk_div+3'h1;
-
-
-// Time counter control signals
-//-----------------------------------------------------------
-
-assign tar_clr = ((tactl[`TAMCx]==2'b01) & (tar>=taccr0)) |
- ((tactl[`TAMCx]==2'b11) & (taccr0==16'h0000));
-
-assign tar_inc = (tactl[`TAMCx]==2'b01) | (tactl[`TAMCx]==2'b10) |
- ((tactl[`TAMCx]==2'b11) & ~tar_dec);
-
-reg tar_dir;
-always @ (posedge mclk or posedge puc)
- if (puc) tar_dir <= 1'b0;
- else if (taclr) tar_dir <= 1'b0;
- else if (tactl[`TAMCx]==2'b11)
- begin
- if (tar_clk & (tar==16'h0001)) tar_dir <= 1'b0;
- else if (tar>=taccr0) tar_dir <= 1'b1;
- end
- else tar_dir <= 1'b0;
-
-assign tar_dec = tar_dir | ((tactl[`TAMCx]==2'b11) & (tar>=taccr0));
-
-
-//============================================================================
-// 6) Timer A comparator
-//============================================================================
-
-wire equ0 = (tar_nxt==taccr0) & (tar!=taccr0);
-wire equ1 = (tar_nxt==taccr1) & (tar!=taccr1);
-wire equ2 = (tar_nxt==taccr2) & (tar!=taccr2);
-
-
-//============================================================================
-// 7) Timer A capture logic
-//============================================================================
-
-// Input selection
-//------------------
-assign cci0 = (tacctl0[`TACCISx]==2'b00) ? ta_cci0a :
- (tacctl0[`TACCISx]==2'b01) ? ta_cci0b :
- (tacctl0[`TACCISx]==2'b10) ? 1'b0 : 1'b1;
-
-assign cci1 = (tacctl1[`TACCISx]==2'b00) ? ta_cci1a :
- (tacctl1[`TACCISx]==2'b01) ? ta_cci1b :
- (tacctl1[`TACCISx]==2'b10) ? 1'b0 : 1'b1;
-
-assign cci2 = (tacctl2[`TACCISx]==2'b00) ? ta_cci2a :
- (tacctl2[`TACCISx]==2'b01) ? ta_cci2b :
- (tacctl2[`TACCISx]==2'b10) ? 1'b0 : 1'b1;
-
-// Register CCIx for synchronization and edge detection
-reg [2:0] cci_s;
-always @ (posedge mclk or posedge puc)
- if (puc) cci_s <= 3'h0;
- else cci_s <= {cci2, cci1, cci0};
-reg [2:0] cci_ss;
-always @ (posedge mclk or posedge puc)
- if (puc) cci_ss <= 3'h0;
- else cci_ss <= cci_s;
-reg [2:0] cci_sss;
-always @ (posedge mclk or posedge puc)
- if (puc) cci_sss <= 3'h0;
- else cci_sss <= cci_ss;
-
-
-// Generate SCCIx
-//------------------
-
-always @ (posedge mclk or posedge puc)
- if (puc) scci0 <= 1'b0;
- else if (tar_clk & equ0) scci0 <= cci_ss[0];
-
-always @ (posedge mclk or posedge puc)
- if (puc) scci1 <= 1'b0;
- else if (tar_clk & equ1) scci1 <= cci_ss[1];
-
-always @ (posedge mclk or posedge puc)
- if (puc) scci2 <= 1'b0;
- else if (tar_clk & equ2) scci2 <= cci_ss[2];
-
-
-// Capture mode
-//------------------
-wire cci0_evt = (tacctl0[`TACMx]==2'b00) ? 1'b0 :
- (tacctl0[`TACMx]==2'b01) ? ( cci_ss[0] & ~cci_sss[0]) : // Rising edge
- (tacctl0[`TACMx]==2'b10) ? (~cci_ss[0] & cci_sss[0]) : // Falling edge
- ( cci_ss[0] ^ cci_sss[0]); // Both edges
-
-wire cci1_evt = (tacctl1[`TACMx]==2'b00) ? 1'b0 :
- (tacctl1[`TACMx]==2'b01) ? ( cci_ss[1] & ~cci_sss[1]) : // Rising edge
- (tacctl1[`TACMx]==2'b10) ? (~cci_ss[1] & cci_sss[1]) : // Falling edge
- ( cci_ss[1] ^ cci_sss[1]); // Both edges
-
-wire cci2_evt = (tacctl2[`TACMx]==2'b00) ? 1'b0 :
- (tacctl2[`TACMx]==2'b01) ? ( cci_ss[2] & ~cci_sss[2]) : // Rising edge
- (tacctl2[`TACMx]==2'b10) ? (~cci_ss[2] & cci_sss[2]) : // Falling edge
- ( cci_ss[2] ^ cci_sss[2]); // Both edges
-
-// Event Synchronization
-//-----------------------
-
-reg cci0_evt_s;
-always @ (posedge mclk or posedge puc)
- if (puc) cci0_evt_s <= 1'b0;
- else if (tar_clk) cci0_evt_s <= 1'b0;
- else if (cci0_evt) cci0_evt_s <= 1'b1;
-
-reg cci1_evt_s;
-always @ (posedge mclk or posedge puc)
- if (puc) cci1_evt_s <= 1'b0;
- else if (tar_clk) cci1_evt_s <= 1'b0;
- else if (cci1_evt) cci1_evt_s <= 1'b1;
-
-reg cci2_evt_s;
-always @ (posedge mclk or posedge puc)
- if (puc) cci2_evt_s <= 1'b0;
- else if (tar_clk) cci2_evt_s <= 1'b0;
- else if (cci2_evt) cci2_evt_s <= 1'b1;
-
-reg cci0_sync;
-always @ (posedge mclk or posedge puc)
- if (puc) cci0_sync <= 1'b0;
- else cci0_sync <= (tar_clk & cci0_evt_s) | (tar_clk & cci0_evt & ~cci0_evt_s);
-
-reg cci1_sync;
-always @ (posedge mclk or posedge puc)
- if (puc) cci1_sync <= 1'b0;
- else cci1_sync <= (tar_clk & cci1_evt_s) | (tar_clk & cci1_evt & ~cci1_evt_s);
-
-reg cci2_sync;
-always @ (posedge mclk or posedge puc)
- if (puc) cci2_sync <= 1'b0;
- else cci2_sync <= (tar_clk & cci2_evt_s) | (tar_clk & cci2_evt & ~cci2_evt_s);
-
-
-// Generate final capture command
-//-----------------------------------
-
-assign cci0_cap = tacctl0[`TASCS] ? cci0_sync : cci0_evt;
-assign cci1_cap = tacctl1[`TASCS] ? cci1_sync : cci1_evt;
-assign cci2_cap = tacctl2[`TASCS] ? cci2_sync : cci2_evt;
-
-
-// Generate capture overflow flag
-//-----------------------------------
-
-reg cap0_taken;
-wire cap0_taken_clr = reg_rd[TACCR0] | (tacctl0_wr & tacctl0[`TACOV] & ~per_din[`TACOV]);
-always @ (posedge mclk or posedge puc)
- if (puc) cap0_taken <= 1'b0;
- else if (cci0_cap) cap0_taken <= 1'b1;
- else if (cap0_taken_clr) cap0_taken <= 1'b0;
-
-reg cap1_taken;
-wire cap1_taken_clr = reg_rd[TACCR1] | (tacctl1_wr & tacctl1[`TACOV] & ~per_din[`TACOV]);
-always @ (posedge mclk or posedge puc)
- if (puc) cap1_taken <= 1'b0;
- else if (cci1_cap) cap1_taken <= 1'b1;
- else if (cap1_taken_clr) cap1_taken <= 1'b0;
-
-reg cap2_taken;
-wire cap2_taken_clr = reg_rd[TACCR2] | (tacctl2_wr & tacctl2[`TACOV] & ~per_din[`TACOV]);
-always @ (posedge mclk or posedge puc)
- if (puc) cap2_taken <= 1'b0;
- else if (cci2_cap) cap2_taken <= 1'b1;
- else if (cap2_taken_clr) cap2_taken <= 1'b0;
-
-
-assign cov0_set = cap0_taken & cci0_cap & ~reg_rd[TACCR0];
-assign cov1_set = cap1_taken & cci1_cap & ~reg_rd[TACCR1];
-assign cov2_set = cap2_taken & cci2_cap & ~reg_rd[TACCR2];
-
-
-//============================================================================
-// 8) Timer A output unit
-//============================================================================
-
-// Output unit 0
-//-------------------
-reg ta_out0;
-
-wire ta_out0_mode0 = tacctl0[`TAOUT]; // Output
-wire ta_out0_mode1 = equ0 ? 1'b1 : ta_out0; // Set
-wire ta_out0_mode2 = equ0 ? ~ta_out0 : // Toggle/Reset
- equ0 ? 1'b0 : ta_out0;
-wire ta_out0_mode3 = equ0 ? 1'b1 : // Set/Reset
- equ0 ? 1'b0 : ta_out0;
-wire ta_out0_mode4 = equ0 ? ~ta_out0 : ta_out0; // Toggle
-wire ta_out0_mode5 = equ0 ? 1'b0 : ta_out0; // Reset
-wire ta_out0_mode6 = equ0 ? ~ta_out0 : // Toggle/Set
- equ0 ? 1'b1 : ta_out0;
-wire ta_out0_mode7 = equ0 ? 1'b0 : // Reset/Set
- equ0 ? 1'b1 : ta_out0;
-
-wire ta_out0_nxt = (tacctl0[`TAOUTMODx]==3'b000) ? ta_out0_mode0 :
- (tacctl0[`TAOUTMODx]==3'b001) ? ta_out0_mode1 :
- (tacctl0[`TAOUTMODx]==3'b010) ? ta_out0_mode2 :
- (tacctl0[`TAOUTMODx]==3'b011) ? ta_out0_mode3 :
- (tacctl0[`TAOUTMODx]==3'b100) ? ta_out0_mode4 :
- (tacctl0[`TAOUTMODx]==3'b101) ? ta_out0_mode5 :
- (tacctl0[`TAOUTMODx]==3'b110) ? ta_out0_mode6 :
- ta_out0_mode7;
-
-always @ (posedge mclk or posedge puc)
- if (puc) ta_out0 <= 1'b0;
- else if ((tacctl0[`TAOUTMODx]==3'b001) & taclr) ta_out0 <= 1'b0;
- else if (tar_clk) ta_out0 <= ta_out0_nxt;
-
-assign ta_out0_en = ~tacctl0[`TACAP];
-
-
-// Output unit 1
-//-------------------
-reg ta_out1;
-
-wire ta_out1_mode0 = tacctl1[`TAOUT]; // Output
-wire ta_out1_mode1 = equ1 ? 1'b1 : ta_out1; // Set
-wire ta_out1_mode2 = equ1 ? ~ta_out1 : // Toggle/Reset
- equ0 ? 1'b0 : ta_out1;
-wire ta_out1_mode3 = equ1 ? 1'b1 : // Set/Reset
- equ0 ? 1'b0 : ta_out1;
-wire ta_out1_mode4 = equ1 ? ~ta_out1 : ta_out1; // Toggle
-wire ta_out1_mode5 = equ1 ? 1'b0 : ta_out1; // Reset
-wire ta_out1_mode6 = equ1 ? ~ta_out1 : // Toggle/Set
- equ0 ? 1'b1 : ta_out1;
-wire ta_out1_mode7 = equ1 ? 1'b0 : // Reset/Set
- equ0 ? 1'b1 : ta_out1;
-
-wire ta_out1_nxt = (tacctl1[`TAOUTMODx]==3'b000) ? ta_out1_mode0 :
- (tacctl1[`TAOUTMODx]==3'b001) ? ta_out1_mode1 :
- (tacctl1[`TAOUTMODx]==3'b010) ? ta_out1_mode2 :
- (tacctl1[`TAOUTMODx]==3'b011) ? ta_out1_mode3 :
- (tacctl1[`TAOUTMODx]==3'b100) ? ta_out1_mode4 :
- (tacctl1[`TAOUTMODx]==3'b101) ? ta_out1_mode5 :
- (tacctl1[`TAOUTMODx]==3'b110) ? ta_out1_mode6 :
- ta_out1_mode7;
-
-always @ (posedge mclk or posedge puc)
- if (puc) ta_out1 <= 1'b0;
- else if ((tacctl1[`TAOUTMODx]==3'b001) & taclr) ta_out1 <= 1'b0;
- else if (tar_clk) ta_out1 <= ta_out1_nxt;
-
-assign ta_out1_en = ~tacctl1[`TACAP];
-
-
-// Output unit 2
-//-------------------
-reg ta_out2;
-
-wire ta_out2_mode0 = tacctl2[`TAOUT]; // Output
-wire ta_out2_mode1 = equ2 ? 1'b1 : ta_out2; // Set
-wire ta_out2_mode2 = equ2 ? ~ta_out2 : // Toggle/Reset
- equ0 ? 1'b0 : ta_out2;
-wire ta_out2_mode3 = equ2 ? 1'b1 : // Set/Reset
- equ0 ? 1'b0 : ta_out2;
-wire ta_out2_mode4 = equ2 ? ~ta_out2 : ta_out2; // Toggle
-wire ta_out2_mode5 = equ2 ? 1'b0 : ta_out2; // Reset
-wire ta_out2_mode6 = equ2 ? ~ta_out2 : // Toggle/Set
- equ0 ? 1'b1 : ta_out2;
-wire ta_out2_mode7 = equ2 ? 1'b0 : // Reset/Set
- equ0 ? 1'b1 : ta_out2;
-
-wire ta_out2_nxt = (tacctl2[`TAOUTMODx]==3'b000) ? ta_out2_mode0 :
- (tacctl2[`TAOUTMODx]==3'b001) ? ta_out2_mode1 :
- (tacctl2[`TAOUTMODx]==3'b010) ? ta_out2_mode2 :
- (tacctl2[`TAOUTMODx]==3'b011) ? ta_out2_mode3 :
- (tacctl2[`TAOUTMODx]==3'b100) ? ta_out2_mode4 :
- (tacctl2[`TAOUTMODx]==3'b101) ? ta_out2_mode5 :
- (tacctl2[`TAOUTMODx]==3'b110) ? ta_out2_mode6 :
- ta_out2_mode7;
-
-always @ (posedge mclk or posedge puc)
- if (puc) ta_out2 <= 1'b0;
- else if ((tacctl2[`TAOUTMODx]==3'b001) & taclr) ta_out2 <= 1'b0;
- else if (tar_clk) ta_out2 <= ta_out2_nxt;
-
-assign ta_out2_en = ~tacctl2[`TACAP];
-
-
-//============================================================================
-// 9) Timer A interrupt generation
-//============================================================================
-
-
-assign taifg_set = tar_clk & (((tactl[`TAMCx]==2'b01) & (tar==taccr0)) |
- ((tactl[`TAMCx]==2'b10) & (tar==16'hffff)) |
- ((tactl[`TAMCx]==2'b11) & (tar_nxt==16'h0000) & tar_dec));
-
-assign ccifg0_set = tacctl0[`TACAP] ? cci0_cap : (tar_clk & ((tactl[`TAMCx]!=2'b00) & equ0));
-assign ccifg1_set = tacctl1[`TACAP] ? cci1_cap : (tar_clk & ((tactl[`TAMCx]!=2'b00) & equ1));
-assign ccifg2_set = tacctl2[`TACAP] ? cci2_cap : (tar_clk & ((tactl[`TAMCx]!=2'b00) & equ2));
-
-
-wire irq_ta0 = (tacctl0[`TACCIFG] & tacctl0[`TACCIE]);
-
-wire irq_ta1 = (tactl[`TAIFG] & tactl[`TAIE]) |
- (tacctl1[`TACCIFG] & tacctl1[`TACCIE]) |
- (tacctl2[`TACCIFG] & tacctl2[`TACCIE]);
-
-
-endmodule // timerA
-
-
-
-
-
-
-
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/periph/timerA.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/register_file.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/register_file.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/register_file.v (nonexistent)
@@ -1,347 +0,0 @@
-//----------------------------------------------------------------------------
-// Copyright (C) 2001 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, write to the Free Software Foundation,
-// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
-//
-//----------------------------------------------------------------------------
-//
-// *File Name: register_file.v
-//
-// *Module Description:
-// openMSP430 Register files
-//
-// *Author(s):
-// - Olivier Girard, olgirard@gmail.com
-//
-//----------------------------------------------------------------------------
-// $Rev$
-// $LastChangedBy$
-// $LastChangedDate$
-//----------------------------------------------------------------------------
-`include "timescale.v"
-`include "openMSP430_defines.v"
-
-module register_file (
-
-// OUTPUTs
- cpuoff, // Turns off the CPU
- gie, // General interrupt enable
- oscoff, // Turns off LFXT1 clock input
- pc_sw, // Program counter software value
- pc_sw_wr, // Program counter software write
- reg_dest, // Selected register destination content
- reg_src, // Selected register source content
- scg1, // System clock generator 1. Turns off the SMCLK
- status, // R2 Status {V,N,Z,C}
-
-// INPUTs
- alu_stat, // ALU Status {V,N,Z,C}
- alu_stat_wr, // ALU Status write {V,N,Z,C}
- inst_bw, // Decoded Inst: byte width
- inst_dest, // Register destination selection
- inst_src, // Register source selection
- mclk, // Main system clock
- pc, // Program counter
- puc, // Main system reset
- reg_dest_val, // Selected register destination value
- reg_dest_wr, // Write selected register destination
- reg_pc_call, // Trigger PC update for a CALL instruction
- reg_sp_val, // Stack Pointer next value
- reg_sp_wr, // Stack Pointer write
- reg_sr_wr, // Status register update for RETI instruction
- reg_sr_clr, // Status register clear for interrupts
- reg_incr // Increment source register
-);
-
-// OUTPUTs
-//=========
-output cpuoff; // Turns off the CPU
-output gie; // General interrupt enable
-output oscoff; // Turns off LFXT1 clock input
-output [15:0] pc_sw; // Program counter software value
-output pc_sw_wr; // Program counter software write
-output [15:0] reg_dest; // Selected register destination content
-output [15:0] reg_src; // Selected register source content
-output scg1; // System clock generator 1. Turns off the SMCLK
-output [3:0] status; // R2 Status {V,N,Z,C}
-
-// INPUTs
-//=========
-input [3:0] alu_stat; // ALU Status {V,N,Z,C}
-input [3:0] alu_stat_wr; // ALU Status write {V,N,Z,C}
-input inst_bw; // Decoded Inst: byte width
-input [15:0] inst_dest; // Register destination selection
-input [15:0] inst_src; // Register source selection
-input mclk; // Main system clock
-input [15:0] pc; // Program counter
-input puc; // Main system reset
-input [15:0] reg_dest_val; // Selected register destination value
-input reg_dest_wr; // Write selected register destination
-input reg_pc_call; // Trigger PC update for a CALL instruction
-input [15:0] reg_sp_val; // Stack Pointer next value
-input reg_sp_wr; // Stack Pointer write
-input reg_sr_wr; // Status register update for RETI instruction
-input reg_sr_clr; // Status register clear for interrupts
-input reg_incr; // Increment source register
-
-
-//=============================================================================
-// 1) AUTOINCREMENT UNIT
-//=============================================================================
-
-wire [15:0] incr_op = inst_bw ? 16'h0001 : 16'h0002;
-wire [15:0] reg_incr_val = reg_src+incr_op;
-
-wire [15:0] reg_dest_val_in = inst_bw ? {8'h00,reg_dest_val[7:0]} : reg_dest_val;
-
-
-//=============================================================================
-// 2) SPECIAL REGISTERS (R1/R2/R3)
-//=============================================================================
-
-// Source input selection mask (for interrupt support)
-//-----------------------------------------------------
-
-wire [15:0] inst_src_in = reg_sr_clr ? 16'h0004 : inst_src;
-
-
-// R0: Program counter
-//---------------------
-
-wire [15:0] r0 = pc;
-
-wire [15:0] pc_sw = reg_dest_val_in;
-wire pc_sw_wr = (inst_dest[0] & reg_dest_wr) | reg_pc_call;
-
-
-// R1: Stack pointer
-//-------------------
-reg [15:0] r1;
-wire r1_wr = inst_dest[1] & reg_dest_wr;
-wire r1_inc = inst_src_in[1] & reg_incr;
-
-always @(posedge mclk or posedge puc)
- if (puc) r1 <= 16'h0000;
- else if (r1_wr) r1 <= reg_dest_val_in & 16'hfffe;
- else if (reg_sp_wr) r1 <= reg_sp_val & 16'hfffe;
- else if (r1_inc) r1 <= reg_incr_val & 16'hfffe;
-
-
-// R2: Status register
-//---------------------
-reg [15:0] r2;
-wire r2_wr = (inst_dest[2] & reg_dest_wr) | reg_sr_wr;
-
-wire r2_c = alu_stat_wr[0] ? alu_stat[0] :
- r2_wr ? reg_dest_val_in[0] : r2[0]; // C
-
-wire r2_z = alu_stat_wr[1] ? alu_stat[1] :
- r2_wr ? reg_dest_val_in[1] : r2[1]; // Z
-
-wire r2_n = alu_stat_wr[2] ? alu_stat[2] :
- r2_wr ? reg_dest_val_in[2] : r2[2]; // N
-
-wire [7:3] r2_nxt = r2_wr ? reg_dest_val_in[7:3] : r2[7:3];
-
-wire r2_v = alu_stat_wr[3] ? alu_stat[3] :
- r2_wr ? reg_dest_val_in[8] : r2[8]; // V
-
-
-always @(posedge mclk or posedge puc)
- if (puc) r2 <= 16'h0000;
- else if (reg_sr_clr) r2 <= 16'h0000;
- else r2 <= {7'h00, r2_v, r2_nxt, r2_n, r2_z, r2_c};
-
-assign status = {r2[8], r2[2:0]};
-assign gie = r2[3];
-assign cpuoff = r2[4] | (r2_nxt[4] & r2_wr);
-assign oscoff = r2[5];
-assign scg1 = r2[7];
-
-
-// R3: Constant generator
-//------------------------
-reg [15:0] r3;
-wire r3_wr = inst_dest[3] & reg_dest_wr;
-wire r3_inc = inst_src_in[3] & reg_incr;
-
-always @(posedge mclk or posedge puc)
- if (puc) r3 <= 16'h0000;
- else if (r3_wr) r3 <= reg_dest_val_in;
- else if (r3_inc) r3 <= reg_incr_val;
-
-
-//=============================================================================
-// 4) GENERAL PURPOSE REGISTERS (R4...R15)
-//=============================================================================
-
-// R4
-reg [15:0] r4;
-wire r4_wr = inst_dest[4] & reg_dest_wr;
-wire r4_inc = inst_src_in[4] & reg_incr;
-always @(posedge mclk or posedge puc)
- if (puc) r4 <= 16'h0000;
- else if (r4_wr) r4 <= reg_dest_val_in;
- else if (r4_inc) r4 <= reg_incr_val;
-
-// R5
-reg [15:0] r5;
-wire r5_wr = inst_dest[5] & reg_dest_wr;
-wire r5_inc = inst_src_in[5] & reg_incr;
-always @(posedge mclk or posedge puc)
- if (puc) r5 <= 16'h0000;
- else if (r5_wr) r5 <= reg_dest_val_in;
- else if (r5_inc) r5 <= reg_incr_val;
-
-// R6
-reg [15:0] r6;
-wire r6_wr = inst_dest[6] & reg_dest_wr;
-wire r6_inc = inst_src_in[6] & reg_incr;
-always @(posedge mclk or posedge puc)
- if (puc) r6 <= 16'h0000;
- else if (r6_wr) r6 <= reg_dest_val_in;
- else if (r6_inc) r6 <= reg_incr_val;
-
-// R7
-reg [15:0] r7;
-wire r7_wr = inst_dest[7] & reg_dest_wr;
-wire r7_inc = inst_src_in[7] & reg_incr;
-always @(posedge mclk or posedge puc)
- if (puc) r7 <= 16'h0000;
- else if (r7_wr) r7 <= reg_dest_val_in;
- else if (r7_inc) r7 <= reg_incr_val;
-
-// R8
-reg [15:0] r8;
-wire r8_wr = inst_dest[8] & reg_dest_wr;
-wire r8_inc = inst_src_in[8] & reg_incr;
-always @(posedge mclk or posedge puc)
- if (puc) r8 <= 16'h0000;
- else if (r8_wr) r8 <= reg_dest_val_in;
- else if (r8_inc) r8 <= reg_incr_val;
-
-// R9
-reg [15:0] r9;
-wire r9_wr = inst_dest[9] & reg_dest_wr;
-wire r9_inc = inst_src_in[9] & reg_incr;
-always @(posedge mclk or posedge puc)
- if (puc) r9 <= 16'h0000;
- else if (r9_wr) r9 <= reg_dest_val_in;
- else if (r9_inc) r9 <= reg_incr_val;
-
-// R10
-reg [15:0] r10;
-wire r10_wr = inst_dest[10] & reg_dest_wr;
-wire r10_inc = inst_src_in[10] & reg_incr;
-always @(posedge mclk or posedge puc)
- if (puc) r10 <= 16'h0000;
- else if (r10_wr) r10 <= reg_dest_val_in;
- else if (r10_inc) r10 <= reg_incr_val;
-
-// R11
-reg [15:0] r11;
-wire r11_wr = inst_dest[11] & reg_dest_wr;
-wire r11_inc = inst_src_in[11] & reg_incr;
-always @(posedge mclk or posedge puc)
- if (puc) r11 <= 16'h0000;
- else if (r11_wr) r11 <= reg_dest_val_in;
- else if (r11_inc) r11 <= reg_incr_val;
-
-// R12
-reg [15:0] r12;
-wire r12_wr = inst_dest[12] & reg_dest_wr;
-wire r12_inc = inst_src_in[12] & reg_incr;
-always @(posedge mclk or posedge puc)
- if (puc) r12 <= 16'h0000;
- else if (r12_wr) r12 <= reg_dest_val_in;
- else if (r12_inc) r12 <= reg_incr_val;
-
-// R13
-reg [15:0] r13;
-wire r13_wr = inst_dest[13] & reg_dest_wr;
-wire r13_inc = inst_src_in[13] & reg_incr;
-always @(posedge mclk or posedge puc)
- if (puc) r13 <= 16'h0000;
- else if (r13_wr) r13 <= reg_dest_val_in;
- else if (r13_inc) r13 <= reg_incr_val;
-
-// R14
-reg [15:0] r14;
-wire r14_wr = inst_dest[14] & reg_dest_wr;
-wire r14_inc = inst_src_in[14] & reg_incr;
-always @(posedge mclk or posedge puc)
- if (puc) r14 <= 16'h0000;
- else if (r14_wr) r14 <= reg_dest_val_in;
- else if (r14_inc) r14 <= reg_incr_val;
-
-// R15
-reg [15:0] r15;
-wire r15_wr = inst_dest[15] & reg_dest_wr;
-wire r15_inc = inst_src_in[15] & reg_incr;
-always @(posedge mclk or posedge puc)
- if (puc) r15 <= 16'h0000;
- else if (r15_wr) r15 <= reg_dest_val_in;
- else if (r15_inc) r15 <= reg_incr_val;
-
-
-//=============================================================================
-// 5) READ MUX
-//=============================================================================
-
-assign reg_src = (r0 & {16{inst_src_in[0]}}) |
- (r1 & {16{inst_src_in[1]}}) |
- (r2 & {16{inst_src_in[2]}}) |
- (r3 & {16{inst_src_in[3]}}) |
- (r4 & {16{inst_src_in[4]}}) |
- (r5 & {16{inst_src_in[5]}}) |
- (r6 & {16{inst_src_in[6]}}) |
- (r7 & {16{inst_src_in[7]}}) |
- (r8 & {16{inst_src_in[8]}}) |
- (r9 & {16{inst_src_in[9]}}) |
- (r10 & {16{inst_src_in[10]}}) |
- (r11 & {16{inst_src_in[11]}}) |
- (r12 & {16{inst_src_in[12]}}) |
- (r13 & {16{inst_src_in[13]}}) |
- (r14 & {16{inst_src_in[14]}}) |
- (r15 & {16{inst_src_in[15]}});
-
-assign reg_dest = (r0 & {16{inst_dest[0]}}) |
- (r1 & {16{inst_dest[1]}}) |
- (r2 & {16{inst_dest[2]}}) |
- (r3 & {16{inst_dest[3]}}) |
- (r4 & {16{inst_dest[4]}}) |
- (r5 & {16{inst_dest[5]}}) |
- (r6 & {16{inst_dest[6]}}) |
- (r7 & {16{inst_dest[7]}}) |
- (r8 & {16{inst_dest[8]}}) |
- (r9 & {16{inst_dest[9]}}) |
- (r10 & {16{inst_dest[10]}}) |
- (r11 & {16{inst_dest[11]}}) |
- (r12 & {16{inst_dest[12]}}) |
- (r13 & {16{inst_dest[13]}}) |
- (r14 & {16{inst_dest[14]}}) |
- (r15 & {16{inst_dest[15]}});
-
-
-endmodule // register_file
-
-
-
-
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/register_file.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/openMSP430_defines.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/openMSP430_defines.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/openMSP430_defines.v (nonexistent)
@@ -1,296 +0,0 @@
-`ifdef OPENMSP430_DEFINES
-`else
-`define OPENMSP430_DEFINES
-//----------------------------------------------------------------------------
-// Copyright (C) 2001 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, write to the Free Software Foundation,
-// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
-//
-//----------------------------------------------------------------------------
-//
-// *File Name: openMSP430_defines.v
-//
-// *Module Description:
-// openMSP430 Configuration file
-//
-// *Author(s):
-// - Olivier Girard, olgirard@gmail.com
-//
-//----------------------------------------------------------------------------
-// $Rev$
-// $LastChangedBy$
-// $LastChangedDate$
-//----------------------------------------------------------------------------
-
-//----------------------------------------------------------------------------
-// SYSTEM CONFIGURATION
-//----------------------------------------------------------------------------
-
-// ROM Size:
-// 9 -> 1kB
-// 10 -> 2kB
-// 11 -> 4kB
-// 12 -> 8kB
-// 13 -> 16kB
-`define ROM_AWIDTH 11
-
-// RAM Size:
-// 6 -> 128 B
-// 7 -> 256 B
-// 8 -> 512 B
-// 9 -> 1 kB
-// 10 -> 2 kB
-`define RAM_AWIDTH 9
-
-//----------------------------------------------------------------------------
-// REMOTE DEBUGGING INTERFACE CONFIGURATION
-//----------------------------------------------------------------------------
-
-// Include Debug interface
-//`define DBG_EN
-
-// Debug interface selection
-// `define DBG_UART -> Enable UART (8N1) debug interface
-// `define DBG_JTAG -> DON'T UNCOMMENT, NOT SUPPORTED YET
-//
-`define DBG_UART
-//`define DBG_JTAG
-
-// Number of hardware breakpoints (each unit contains 2 hw address breakpoints)
-// `define DBG_HWBRK_0 -> Include hardware breakpoints unit 0
-// `define DBG_HWBRK_1 -> Include hardware breakpoints unit 1
-// `define DBG_HWBRK_2 -> Include hardware breakpoints unit 2
-// `define DBG_HWBRK_3 -> Include hardware breakpoints unit 3
-//
-`define DBG_HWBRK_0
-`define DBG_HWBRK_1
-`define DBG_HWBRK_2
-`define DBG_HWBRK_3
-
-
-//==========================================================================//
-//==========================================================================//
-//==========================================================================//
-//==========================================================================//
-//===== SYSTEM CONSTANTS --- !!!!!!!! DO NOT EDIT !!!!!!!! =====//
-//==========================================================================//
-//==========================================================================//
-//==========================================================================//
-//==========================================================================//
-
-// ROM and RAM sizes
-`define ROM_SIZE (2 << `ROM_AWIDTH)
-`define RAM_SIZE (2 << `RAM_AWIDTH)
-
-// RAM Base Adresses
-`define RAM_BASE 16'h0200 // RAM base address
-
-// ROM & RAM most significant address bit (for 16 bit words)
-`define ROM_MSB `ROM_AWIDTH-1
-`define RAM_MSB `RAM_AWIDTH-1
-
-
-// Instructions type
-`define INST_SO 0
-`define INST_JMP 1
-`define INST_TO 2
-
-// Single-operand arithmetic
-`define RRC 0
-`define SWPB 1
-`define RRA 2
-`define SXT 3
-`define PUSH 4
-`define CALL 5
-`define RETI 6
-`define IRQ 7
-
-// Conditional jump
-`define JNE 0
-`define JEQ 1
-`define JNC 2
-`define JC 3
-`define JN 4
-`define JGE 5
-`define JL 6
-`define JMP 7
-
-// Two-operand arithmetic
-`define MOV 0
-`define ADD 1
-`define ADDC 2
-`define SUBC 3
-`define SUB 4
-`define CMP 5
-`define DADD 6
-`define BIT 7
-`define BIC 8
-`define BIS 9
-`define XOR 10
-`define AND 11
-
-// Addressing modes
-`define DIR 0
-`define IDX 1
-`define INDIR 2
-`define INDIR_I 3
-`define SYMB 4
-`define IMM 5
-`define ABS 6
-`define CONST 7
-
-// Execution state machine
-`define E_IRQ_0 4'h0
-`define E_IRQ_1 4'h1
-`define E_IRQ_2 4'h2
-`define E_IRQ_3 4'h3
-`define E_IRQ_4 4'h4
-`define E_SRC_AD 4'h5
-`define E_SRC_RD 4'h6
-`define E_SRC_WR 4'h7
-`define E_DST_AD 4'h8
-`define E_DST_RD 4'h9
-`define E_DST_WR 4'hA
-`define E_EXEC 4'hB
-`define E_JUMP 4'hC
-`define E_IDLE 4'hD
-
-// ALU control signals
-`define ALU_SRC_INV 0
-`define ALU_INC 1
-`define ALU_INC_C 2
-`define ALU_ADD 3
-`define ALU_AND 4
-`define ALU_OR 5
-`define ALU_XOR 6
-`define ALU_DADD 7
-`define ALU_STAT_7 8
-`define ALU_STAT_F 9
-`define ALU_SHIFT 10
-`define EXEC_NO_WR 11
-
-// Debug interface
-`define DBG_UART_WR 18
-`define DBG_UART_BW 17
-`define DBG_UART_ADDR 16:11
-
-// Debug interface CPU_CTL register
-`define HALT 0
-`define RUN 1
-`define ISTEP 2
-`define SW_BRK_EN 3
-`define FRZ_BRK_EN 4
-`define RST_BRK_EN 5
-`define CPU_RST 6
-
-// Debug interface CPU_STAT register
-`define HALT_RUN 0
-`define PUC_PND 1
-`define SWBRK_PND 3
-`define HWBRK0_PND 4
-`define HWBRK1_PND 5
-
-// Debug interface BRKx_CTL register
-`define BRK_MODE_RD 0
-`define BRK_MODE_WR 1
-`define BRK_MODE 1:0
-`define BRK_EN 2
-`define BRK_I_EN 3
-`define BRK_RANGE 4
-
-// Basic clock module: BCSCTL1 Control Register
-`define DIVAx 5:4
-
-// Basic clock module: BCSCTL2 Control Register
-`define SELS 3
-`define DIVSx 2:1
-
-// Timer A: TACTL Control Register
-`define TASSELx 9:8
-`define TAIDx 7:6
-`define TAMCx 5:4
-`define TACLR 2
-`define TAIE 1
-`define TAIFG 0
-
-// Timer A: TACCTLx Capture/Compare Control Register
-`define TACMx 15:14
-`define TACCISx 13:12
-`define TASCS 11
-`define TASCCI 10
-`define TACAP 8
-`define TAOUTMODx 7:5
-`define TACCIE 4
-`define TACCI 3
-`define TAOUT 2
-`define TACOV 1
-`define TACCIFG 0
-
-//
-// DEBUG INTERFACE EXTRA CONFIGURATION
-//======================================
-
-// Debug interface: Software breakpoint opcode
-`define DBG_SWBRK_OP 16'h4343
-
-// Debug interface ID
-`define DBG_ID 24'h4D5350
-
-// Debug UART interface auto data synchronization
-// If the following define is commented out, then
-// the DBG_UART_BAUD and DBG_DCO_FREQ need to be properly
-// defined.
-`define DBG_UART_AUTO_SYNC
-
-// Debug UART interface data rate
-// In order to properly setup the UART debug interface, you
-// need to specify the DCO_CLK frequency (DBG_DCO_FREQ) and
-// the chosen BAUD rate from the UART interface.
-//
-//`define DBG_UART_BAUD 9600
-//`define DBG_UART_BAUD 19200
-//`define DBG_UART_BAUD 38400
-//`define DBG_UART_BAUD 57600
-//`define DBG_UART_BAUD 115200
-//`define DBG_UART_BAUD 230400
-//`define DBG_UART_BAUD 460800
-//`define DBG_UART_BAUD 576000
-//`define DBG_UART_BAUD 921600
-`define DBG_UART_BAUD 2000000
-`define DBG_DCO_FREQ 20000000
-`define DBG_UART_CNT ((`DBG_DCO_FREQ/`DBG_UART_BAUD)-1)
-
-// Check configuration
-`ifdef DBG_EN
- `ifdef DBG_UART
- `ifdef DBG_JTAG
-CONFIGURATION ERROR: JTAG AND UART DEBUG INTERFACE ARE BOTH ENABLED
- `endif
- `else
- `ifdef DBG_JTAG
-CONFIGURATION ERROR: JTAG INTERFACE NOT SUPPORTED YET
- `else
-CONFIGURATION ERROR: JTAG OR UART DEBUG INTERFACE SHOULD BE ENABLED
- `endif
- `endif
-`endif
-
-
-`endif
\ No newline at end of file
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/openMSP430_defines.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/timescale.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/timescale.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/timescale.v (nonexistent)
@@ -1 +0,0 @@
-`timescale 1ns / 100ps
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/timescale.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/dbg_uart.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/dbg_uart.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/dbg_uart.v (nonexistent)
@@ -1,273 +0,0 @@
-//----------------------------------------------------------------------------
-// Copyright (C) 2001 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, write to the Free Software Foundation,
-// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
-//
-//----------------------------------------------------------------------------
-//
-// *File Name: dbg_uart.v
-//
-// *Module Description:
-// Debug UART communication interface (8N1, Half-duplex)
-//
-// *Author(s):
-// - Olivier Girard, olgirard@gmail.com
-//
-//----------------------------------------------------------------------------
-// $Rev$
-// $LastChangedBy$
-// $LastChangedDate$
-//----------------------------------------------------------------------------
-`include "timescale.v"
-`include "openMSP430_defines.v"
-
-module dbg_uart (
-
-// OUTPUTs
- dbg_addr, // Debug register address
- dbg_din, // Debug register data input
- dbg_rd, // Debug register data read
- dbg_uart_txd, // Debug interface: UART TXD
- dbg_wr, // Debug register data write
-
-// INPUTs
- dbg_dout, // Debug register data output
- dbg_rd_rdy, // Debug register data is ready for read
- dbg_uart_rxd, // Debug interface: UART RXD
- mclk, // Main system clock
- mem_burst, // Burst on going
- mem_burst_end, // End TX/RX burst
- mem_burst_rd, // Start TX burst
- mem_burst_wr, // Start RX burst
- mem_bw, // Burst byte width
- por // Power on reset
-);
-
-// OUTPUTs
-//=========
-output [5:0] dbg_addr; // Debug register address
-output [15:0] dbg_din; // Debug register data input
-output dbg_rd; // Debug register data read
-output dbg_uart_txd; // Debug interface: UART TXD
-output dbg_wr; // Debug register data write
-
-// INPUTs
-//=========
-input [15:0] dbg_dout; // Debug register data output
-input dbg_rd_rdy; // Debug register data is ready for read
-input dbg_uart_rxd; // Debug interface: UART RXD
-input mclk; // Main system clock
-input mem_burst; // Burst on going
-input mem_burst_end; // End TX/RX burst
-input mem_burst_rd; // Start TX burst
-input mem_burst_wr; // Start RX burst
-input mem_bw; // Burst byte width
-input por; // Power on reset
-
-
-//=============================================================================
-// 1) UART RECEIVE LINE SYNCHRONIZTION & FILTERING
-//=============================================================================
-
-// Synchronize RXD input & buffer
-//--------------------------------
-reg [3:0] rxd_sync;
-always @ (posedge mclk or posedge por)
- if (por) rxd_sync <= 4'h0;
- else rxd_sync <= {rxd_sync[2:0], dbg_uart_rxd};
-
-// Majority decision
-//------------------------
-reg rxd_maj;
-
-wire [1:0] rxd_maj_cnt = {1'b0, rxd_sync[1]} +
- {1'b0, rxd_sync[2]} +
- {1'b0, rxd_sync[3]};
-wire rxd_maj_nxt = (rxd_maj_cnt>=2'b10);
-
-always @ (posedge mclk or posedge por)
- if (por) rxd_maj <= 1'b0;
- else rxd_maj <= rxd_maj_nxt;
-
-wire rxd_s = rxd_maj;
-wire rxd_fe = rxd_maj & ~rxd_maj_nxt;
-wire rxd_re = ~rxd_maj & rxd_maj_nxt;
-
-
-//=============================================================================
-// 2) UART STATE MACHINE
-//=============================================================================
-
-// Receive state
-//------------------------
-reg [2:0] uart_state;
-reg [2:0] uart_state_nxt;
-
-wire sync_done;
-wire xfer_done;
-reg [19:0] xfer_buf;
-
-// State machine definition
-parameter RX_SYNC = 3'h0;
-parameter RX_CMD = 3'h1;
-parameter RX_DATA1 = 3'h2;
-parameter RX_DATA2 = 3'h3;
-parameter TX_DATA1 = 3'h4;
-parameter TX_DATA2 = 3'h5;
-
-// State transition
-always @(uart_state or xfer_buf or mem_burst or mem_burst_wr or mem_burst_rd or mem_burst_end or mem_bw)
- case (uart_state)
- RX_SYNC : uart_state_nxt = RX_CMD;
- RX_CMD : uart_state_nxt = mem_burst_wr ?
- (mem_bw ? RX_DATA2 : RX_DATA1) :
- mem_burst_rd ?
- (mem_bw ? TX_DATA2 : TX_DATA1) :
- (xfer_buf[`DBG_UART_WR] ?
- (xfer_buf[`DBG_UART_BW] ? RX_DATA2 : RX_DATA1) :
- (xfer_buf[`DBG_UART_BW] ? TX_DATA2 : TX_DATA1));
- RX_DATA1 : uart_state_nxt = RX_DATA2;
- RX_DATA2 : uart_state_nxt = (mem_burst & ~mem_burst_end) ?
- (mem_bw ? RX_DATA2 : RX_DATA1) :
- RX_CMD;
- TX_DATA1 : uart_state_nxt = TX_DATA2;
- TX_DATA2 : uart_state_nxt = (mem_burst & ~mem_burst_end) ?
- (mem_bw ? TX_DATA2 : TX_DATA1) :
- RX_CMD;
- default : uart_state_nxt = RX_CMD;
- endcase
-
-// State machine
-always @(posedge mclk or posedge por)
- if (por) uart_state <= RX_SYNC;
- else if (xfer_done | sync_done |
- mem_burst_wr | mem_burst_rd) uart_state <= uart_state_nxt;
-
-// Utility signals
-wire cmd_valid = (uart_state==RX_CMD) & xfer_done;
-wire tx_active = (uart_state==TX_DATA1) | (uart_state==TX_DATA2);
-
-
-//=============================================================================
-// 3) UART SYNCHRONIZATION
-//=============================================================================
-// After POR, the host needs to fist send a synchronization character (0x80)
-// If this feature doesn't work properly, it is possible to disable it by
-// commenting the DBG_UART_AUTO_SYNC define in the openMSP430.inc file.
-
-reg sync_busy;
-always @ (posedge mclk or posedge por)
- if (por) sync_busy <= 1'b0;
- else if ((uart_state==RX_SYNC) & rxd_fe) sync_busy <= 1'b1;
- else if ((uart_state==RX_SYNC) & rxd_re) sync_busy <= 1'b0;
-
-assign sync_done = (uart_state==RX_SYNC) & rxd_re & sync_busy;
-
-`ifdef DBG_UART_AUTO_SYNC
-
-reg [14:0] sync_cnt;
-always @ (posedge mclk or posedge por)
- if (por) sync_cnt <= 15'h7ff8;
- else if (sync_busy) sync_cnt <= sync_cnt+15'h0001;
-
-wire [11:0] bit_cnt_max = sync_cnt[14:3];
-`else
-wire [11:0] bit_cnt_max = `DBG_UART_CNT;
-`endif
-
-
-//=============================================================================
-// 4) UART RECEIVE / TRANSMIT
-//=============================================================================
-
-// Transfer counter
-//------------------------
-reg [3:0] xfer_bit;
-reg [11:0] xfer_cnt;
-
-wire txd_start = dbg_rd_rdy | (xfer_done & (uart_state==TX_DATA1));
-wire rxd_start = (xfer_bit==4'h0) & rxd_fe & ((uart_state!=RX_SYNC));
-wire xfer_bit_inc = (xfer_bit!=4'h0) & (xfer_cnt==12'h000);
-assign xfer_done = (xfer_bit==4'hb);
-
-always @ (posedge mclk or posedge por)
- if (por) xfer_bit <= 4'h0;
- else if (txd_start | rxd_start) xfer_bit <= 4'h1;
- else if (xfer_done) xfer_bit <= 4'h0;
- else if (xfer_bit_inc) xfer_bit <= xfer_bit+4'h1;
-
-always @ (posedge mclk or posedge por)
- if (por) xfer_cnt <= 12'h000;
- else if (rxd_start) xfer_cnt <= {1'b0, bit_cnt_max[11:1]};
- else if (txd_start | xfer_bit_inc) xfer_cnt <= bit_cnt_max;
- else xfer_cnt <= xfer_cnt+12'hfff;
-
-
-// Receive/Transmit buffer
-//-------------------------
-wire [19:0] xfer_buf_nxt = {rxd_s, xfer_buf[19:1]};
-
-always @ (posedge mclk or posedge por)
- if (por) xfer_buf <= 18'h00000;
- else if (dbg_rd_rdy) xfer_buf <= {1'b1, dbg_dout[15:8], 2'b01, dbg_dout[7:0], 1'b0};
- else if (xfer_bit_inc) xfer_buf <= xfer_buf_nxt;
-
-
-// Generate TXD output
-//------------------------
-reg dbg_uart_txd;
-
-always @ (posedge mclk or posedge por)
- if (por) dbg_uart_txd <= 1'b1;
- else if (xfer_bit_inc & tx_active) dbg_uart_txd <= xfer_buf[0];
-
-
-//=============================================================================
-// 5) INTERFACE TO DEBUG REGISTERS
-//=============================================================================
-
-reg [5:0] dbg_addr;
- always @ (posedge mclk or posedge por)
- if (por) dbg_addr <= 6'h00;
- else if (cmd_valid) dbg_addr <= xfer_buf[`DBG_UART_ADDR];
-
-reg dbg_bw;
-always @ (posedge mclk or posedge por)
- if (por) dbg_bw <= 1'b0;
- else if (cmd_valid) dbg_bw <= xfer_buf[`DBG_UART_BW];
-
-wire dbg_din_bw = mem_burst ? mem_bw : dbg_bw;
-
-wire [15:0] dbg_din = dbg_din_bw ? {8'h00, xfer_buf[18:11]} :
- {xfer_buf[18:11], xfer_buf[8:1]};
-wire dbg_wr = (xfer_done & (uart_state==RX_DATA2));
-wire dbg_rd = mem_burst ? (xfer_done & (uart_state==TX_DATA2)) :
- (cmd_valid & ~xfer_buf[`DBG_UART_WR]) | mem_burst_rd;
-
-
-
-endmodule // dbg_uart
-
-
-
-
-
-
-
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/dbg_uart.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/openMSP430.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/openMSP430.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/openMSP430.v (nonexistent)
@@ -1,439 +0,0 @@
-//----------------------------------------------------------------------------
-// Copyright (C) 2001 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, write to the Free Software Foundation,
-// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
-//
-//----------------------------------------------------------------------------
-//
-// *File Name: openMSP430.v
-//
-// *Module Description:
-// openMSP430 Top level file
-//
-// *Author(s):
-// - Olivier Girard, olgirard@gmail.com
-//
-//----------------------------------------------------------------------------
-// $Rev$
-// $LastChangedBy$
-// $LastChangedDate$
-//----------------------------------------------------------------------------
-`include "timescale.v"
-`include "openMSP430_defines.v"
-
-module openMSP430 (
-
-// OUTPUTs
- aclk_en, // ACLK enable
- dbg_freeze, // Freeze peripherals
- dbg_uart_txd, // Debug interface: UART TXD
- irq_acc, // Interrupt request accepted (one-hot signal)
- mclk, // Main system clock
- per_addr, // Peripheral address
- per_din, // Peripheral data input
- per_wen, // Peripheral write enable (high active)
- per_en, // Peripheral enable (high active)
- puc, // Main system reset
- ram_addr, // RAM address
- ram_cen, // RAM chip enable (low active)
- ram_din, // RAM data input
- ram_wen, // RAM write enable (low active)
- rom_addr, // ROM address
- rom_cen, // ROM chip enable (low active)
- rom_din_dbg, // ROM data input --FOR DEBUG INTERFACE--
- rom_wen_dbg, // ROM write enable (low active) --FOR DBG IF--
- smclk_en, // SMCLK enable
-
-// INPUTs
- dbg_uart_rxd, // Debug interface: UART RXD
- dco_clk, // Fast oscillator (fast clock)
- irq, // Maskable interrupts
- lfxt_clk, // Low frequency oscillator (typ 32kHz)
- nmi, // Non-maskable interrupt (asynchronous)
- per_dout, // Peripheral data output
- ram_dout, // RAM data output
- reset_n, // Reset Pin (low active)
- rom_dout // ROM data output
-);
-
-// OUTPUTs
-//=========
-output aclk_en; // ACLK enable
-output dbg_freeze; // Freeze peripherals
-output dbg_uart_txd; // Debug interface: UART TXD
-output [13:0] irq_acc; // Interrupt request accepted (one-hot signal)
-output mclk; // Main system clock
-output [7:0] per_addr; // Peripheral address
-output [15:0] per_din; // Peripheral data input
-output [1:0] per_wen; // Peripheral write enable (high active)
-output per_en; // Peripheral enable (high active)
-output puc; // Main system reset
-output [`RAM_MSB:0] ram_addr; // RAM address
-output ram_cen; // RAM chip enable (low active)
-output [15:0] ram_din; // RAM data input
-output [1:0] ram_wen; // RAM write enable (low active)
-output [`ROM_MSB:0] rom_addr; // ROM address
-output rom_cen; // ROM chip enable (low active)
-output [15:0] rom_din_dbg; // ROM data input --FOR DEBUG INTERFACE--
-output [1:0] rom_wen_dbg; // ROM write enable (low active) --FOR DBG IF--
-output smclk_en; // SMCLK enable
-
-
-// INPUTs
-//=========
-input dbg_uart_rxd; // Debug interface: UART RXD
-input dco_clk; // Fast oscillator (fast clock)
-input [13:0] irq; // Maskable interrupts
-input lfxt_clk; // Low frequency oscillator (typ 32kHz)
-input nmi; // Non-maskable interrupt (asynchronous)
-input [15:0] per_dout; // Peripheral data output
-input [15:0] ram_dout; // RAM data output
-input reset_n; // Reset Pin (active low)
-input [15:0] rom_dout; // ROM data output
-
-
-
-//=============================================================================
-// 1) INTERNAL WIRES/REGISTERS/PARAMETERS DECLARATION
-//=============================================================================
-
-wire [7:0] inst_ad;
-wire [7:0] inst_as;
-wire [11:0] inst_alu;
-wire inst_bw;
-wire [15:0] inst_dest;
-wire [15:0] inst_dext;
-wire [15:0] inst_sext;
-wire [7:0] inst_so;
-wire [15:0] inst_src;
-wire [2:0] inst_type;
-wire [3:0] e_state;
-wire exec_done;
-
-wire [15:0] eu_mab;
-wire [15:0] eu_mdb_in;
-wire [15:0] eu_mdb_out;
-wire [1:0] eu_mb_wr;
-wire [15:0] fe_mab;
-wire [15:0] fe_mdb_in;
-
-wire [15:0] pc_sw;
-wire [7:0] inst_jmp;
-wire [15:0] pc;
-wire [15:0] pc_nxt;
-
-wire [15:0] dbg_mem_addr;
-wire [15:0] dbg_mem_dout;
-wire [15:0] dbg_mem_din;
-wire [15:0] dbg_reg_din;
-wire [1:0] dbg_mem_wr;
-
-wire [15:0] per_dout_or;
-wire [15:0] per_dout_sfr;
-wire [15:0] per_dout_wdog;
-wire [15:0] per_dout_clk;
-
-
-//=============================================================================
-// 2) GLOBAL CLOCK & RESET MANAGEMENT
-//=============================================================================
-
-clock_module clock_module_0 (
-
-// OUTPUTs
- .aclk_en (aclk_en), // ACLK enablex
- .mclk (mclk), // Main system clock
- .per_dout (per_dout_clk), // Peripheral data output
- .por (por), // Power-on reset
- .puc (puc), // Main system reset
- .smclk_en (smclk_en), // SMCLK enable
-
-// INPUTs
- .dbg_reset (dbg_reset), // Reset CPU from debug interface
- .dco_clk (dco_clk), // Fast oscillator (fast clock)
- .lfxt_clk (lfxt_clk), // Low frequency oscillator (typ 32kHz)
- .oscoff (oscoff), // Turns off LFXT1 clock input
- .per_addr (per_addr), // Peripheral address
- .per_din (per_din), // Peripheral data input
- .per_en (per_en), // Peripheral enable (high active)
- .per_wen (per_wen), // Peripheral write enable (high active)
- .reset_n (reset_n), // Reset Pin (low active)
- .scg1 (scg1), // System clock generator 1. Turns off the SMCLK
- .wdt_reset (wdt_reset) // Watchdog-timer reset
-);
-
-
-//=============================================================================
-// 3) FRONTEND (<=> FETCH & DECODE)
-//=============================================================================
-
-frontend frontend_0 (
-
-// OUTPUTs
- .dbg_halt_st (dbg_halt_st), // Halt/Run status from CPU
- .decode (decode), // Frontend decode instruction
- .e_state (e_state), // Execution state
- .exec_done (exec_done), // Execution completed
- .inst_ad (inst_ad), // Decoded Inst: destination addressing mode
- .inst_as (inst_as), // Decoded Inst: source addressing mode
- .inst_alu (inst_alu), // ALU control signals
- .inst_bw (inst_bw), // Decoded Inst: byte width
- .inst_dest (inst_dest), // Decoded Inst: destination (one hot)
- .inst_dext (inst_dext), // Decoded Inst: destination extended instruction word
- .inst_irq_rst (inst_irq_rst), // Decoded Inst: Reset interrupt
- .inst_jmp (inst_jmp), // Decoded Inst: Conditional jump
- .inst_sext (inst_sext), // Decoded Inst: source extended instruction word
- .inst_so (inst_so), // Decoded Inst: Single-operand arithmetic
- .inst_src (inst_src), // Decoded Inst: source (one hot)
- .inst_type (inst_type), // Decoded Instruction type
- .irq_acc (irq_acc), // Interrupt request accepted
- .mab (fe_mab), // Frontend Memory address bus
- .mb_en (fe_mb_en), // Frontend Memory bus enable
- .nmi_acc (nmi_acc), // Non-Maskable interrupt request accepted
- .pc (pc), // Program counter
- .pc_nxt (pc_nxt), // Next PC value (for CALL & IRQ)
-
-// INPUTs
- .cpuoff (cpuoff), // Turns off the CPU
- .dbg_halt_cmd (dbg_halt_cmd), // Halt CPU command
- .dbg_reg_sel (dbg_mem_addr[3:0]), // Debug selected register for rd/wr access
- .fe_rom_wait (fe_rom_wait), // Frontend wait for ROM
- .gie (gie), // General interrupt enable
- .irq (irq), // Maskable interrupts
- .mclk (mclk), // Main system clock
- .mdb_in (fe_mdb_in), // Frontend Memory data bus input
- .nmi_evt (nmi_evt), // Non-maskable interrupt event
- .pc_sw (pc_sw), // Program counter software value
- .pc_sw_wr (pc_sw_wr), // Program counter software write
- .puc (puc), // Main system reset
- .wdt_irq (wdt_irq) // Watchdog-timer interrupt
-);
-
-
-//=============================================================================
-// 4) EXECUTION UNIT
-//=============================================================================
-
-execution_unit execution_unit_0 (
-
-// OUTPUTs
- .cpuoff (cpuoff), // Turns off the CPU
- .dbg_reg_din (dbg_reg_din), // Debug unit CPU register data input
- .mab (eu_mab), // Memory address bus
- .mb_en (eu_mb_en), // Memory bus enable
- .mb_wr (eu_mb_wr), // Memory bus write transfer
- .mdb_out (eu_mdb_out), // Memory data bus output
- .oscoff (oscoff), // Turns off LFXT1 clock input
- .pc_sw (pc_sw), // Program counter software value
- .pc_sw_wr (pc_sw_wr), // Program counter software write
- .scg1 (scg1), // System clock generator 1. Turns off the SMCLK
-
-// INPUTs
- .dbg_halt_st (dbg_halt_st), // Halt/Run status from CPU
- .dbg_mem_dout (dbg_mem_dout), // Debug unit data output
- .dbg_reg_wr (dbg_reg_wr), // Debug unit CPU register write
- .e_state (e_state), // Execution state
- .exec_done (exec_done), // Execution completed
- .gie (gie), // General interrupt enable
- .inst_ad (inst_ad), // Decoded Inst: destination addressing mode
- .inst_as (inst_as), // Decoded Inst: source addressing mode
- .inst_alu (inst_alu), // ALU control signals
- .inst_bw (inst_bw), // Decoded Inst: byte width
- .inst_dest (inst_dest), // Decoded Inst: destination (one hot)
- .inst_dext (inst_dext), // Decoded Inst: destination extended instruction word
- .inst_irq_rst (inst_irq_rst), // Decoded Inst: reset interrupt
- .inst_jmp (inst_jmp), // Decoded Inst: Conditional jump
- .inst_sext (inst_sext), // Decoded Inst: source extended instruction word
- .inst_so (inst_so), // Decoded Inst: Single-operand arithmetic
- .inst_src (inst_src), // Decoded Inst: source (one hot)
- .inst_type (inst_type), // Decoded Instruction type
- .mclk (mclk), // Main system clock
- .mdb_in (eu_mdb_in), // Memory data bus input
- .pc (pc), // Program counter
- .pc_nxt (pc_nxt), // Next PC value (for CALL & IRQ)
- .puc (puc) // Main system reset
-);
-
-
-//=============================================================================
-// 5) MEMORY BACKBONE
-//=============================================================================
-
-mem_backbone mem_backbone_0 (
-
-// OUTPUTs
- .dbg_mem_din (dbg_mem_din), // Debug unit Memory data input
- .eu_mdb_in (eu_mdb_in), // Execution Unit Memory data bus input
- .fe_mdb_in (fe_mdb_in), // Frontend Memory data bus input
- .fe_rom_wait (fe_rom_wait), // Frontend wait for ROM
- .per_addr (per_addr), // Peripheral address
- .per_din (per_din), // Peripheral data input
- .per_wen (per_wen), // Peripheral write enable (high active)
- .per_en (per_en), // Peripheral enable (high active)
- .ram_addr (ram_addr), // RAM address
- .ram_cen (ram_cen), // RAM chip enable (low active)
- .ram_din (ram_din), // RAM data input
- .ram_wen (ram_wen), // RAM write enable (low active)
- .rom_addr (rom_addr), // ROM address
- .rom_cen (rom_cen), // ROM chip enable (low active)
- .rom_din_dbg (rom_din_dbg), // ROM data input --FOR DEBUG INTERFACE--
- .rom_wen_dbg (rom_wen_dbg), // ROM write enable (low active) --FOR DBG IF--
-
-// INPUTs
- .dbg_halt_st (dbg_halt_st), // Halt/Run status from CPU
- .dbg_mem_addr (dbg_mem_addr), // Debug address for rd/wr access
- .dbg_mem_dout (dbg_mem_dout), // Debug unit data output
- .dbg_mem_en (dbg_mem_en), // Debug unit memory enable
- .dbg_mem_wr (dbg_mem_wr), // Debug unit memory write
- .eu_mab (eu_mab[15:1]), // Execution Unit Memory address bus
- .eu_mb_en (eu_mb_en), // Execution Unit Memory bus enable
- .eu_mb_wr (eu_mb_wr), // Execution Unit Memory bus write transfer
- .eu_mdb_out (eu_mdb_out), // Execution Unit Memory data bus output
- .fe_mab (fe_mab[15:1]), // Frontend Memory address bus
- .fe_mb_en (fe_mb_en), // Frontend Memory bus enable
- .mclk (mclk), // Main system clock
- .per_dout (per_dout_or), // Peripheral data output
- .puc (puc), // Main system reset
- .ram_dout (ram_dout), // RAM data output
- .rom_dout (rom_dout) // ROM data output
-);
-
-
-//=============================================================================
-// 6) SPECIAL FUNCTION REGISTERS
-//=============================================================================
-
-sfr sfr_0 (
-
-// OUTPUTs
- .nmie (nmie), // Non-maskable interrupt enable
- .per_dout (per_dout_sfr), // Peripheral data output
- .wdt_irq (wdt_irq), // Watchdog-timer interrupt
- .wdt_reset (wdt_reset), // Watchdog-timer reset
- .wdtie (wdtie), // Watchdog-timer interrupt enable
-
-// INPUTs
- .mclk (mclk), // Main system clock
- .nmi_acc (nmi_acc), // Non-Maskable interrupt request accepted
- .per_addr (per_addr), // Peripheral address
- .per_din (per_din), // Peripheral data input
- .per_en (per_en), // Peripheral enable (high active)
- .per_wen (per_wen), // Peripheral write enable (high active)
- .por (por), // Power-on reset
- .puc (puc), // Main system reset
- .wdtifg_clr (irq_acc[10]), // Clear Watchdog-timer interrupt flag
- .wdtifg_set (wdtifg_set), // Set Watchdog-timer interrupt flag
- .wdtpw_error (wdtpw_error), // Watchdog-timer password error
- .wdttmsel (wdttmsel) // Watchdog-timer mode select
-);
-
-
-//=============================================================================
-// 7) WATCHDOG TIMER
-//=============================================================================
-
-watchdog watchdog_0 (
-
-// OUTPUTs
- .nmi_evt (nmi_evt), // NMI Event
- .per_dout (per_dout_wdog), // Peripheral data output
- .wdtifg_set (wdtifg_set), // Set Watchdog-timer interrupt flag
- .wdtpw_error (wdtpw_error), // Watchdog-timer password error
- .wdttmsel (wdttmsel), // Watchdog-timer mode select
-
-// INPUTs
- .aclk_en (aclk_en), // ACLK enable
- .dbg_freeze (dbg_freeze), // Freeze Watchdog counter
- .mclk (mclk), // Main system clock
- .nmi (nmi), // Non-maskable interrupt (asynchronous)
- .nmie (nmie), // Non-maskable interrupt enable
- .per_addr (per_addr), // Peripheral address
- .per_din (per_din), // Peripheral data input
- .per_en (per_en), // Peripheral enable (high active)
- .per_wen (per_wen), // Peripheral write enable (high active)
- .puc (puc), // Main system reset
- .smclk_en (smclk_en), // SMCLK enable
- .wdtie (wdtie) // Watchdog-timer interrupt enable
-);
-
-
-//=============================================================================
-// 8) PERIPHERALS' OUTPUT BUS
-//=============================================================================
-
-assign per_dout_or = per_dout |
- per_dout_clk |
- per_dout_sfr |
- per_dout_wdog;
-
-
-//=============================================================================
-// 9) DEBUG INTERFACE
-//=============================================================================
-
-`ifdef DBG_EN
-dbg dbg_0 (
-
-// OUTPUTs
- .dbg_freeze (dbg_freeze), // Freeze peripherals
- .dbg_halt_cmd (dbg_halt_cmd), // Halt CPU command
- .dbg_mem_addr (dbg_mem_addr), // Debug address for rd/wr access
- .dbg_mem_dout (dbg_mem_dout), // Debug unit data output
- .dbg_mem_en (dbg_mem_en), // Debug unit memory enable
- .dbg_mem_wr (dbg_mem_wr), // Debug unit memory write
- .dbg_reg_wr (dbg_reg_wr), // Debug unit CPU register write
- .dbg_reset (dbg_reset), // Reset CPU from debug interface
- .dbg_uart_txd (dbg_uart_txd), // Debug interface: UART TXD
-
-// INPUTs
- .dbg_halt_st (dbg_halt_st), // Halt/Run status from CPU
- .dbg_mem_din (dbg_mem_din), // Debug unit Memory data input
- .dbg_reg_din (dbg_reg_din), // Debug unit CPU register data input
- .dbg_uart_rxd (dbg_uart_rxd), // Debug interface: UART RXD
- .decode (decode), // Frontend decode instruction
- .eu_mab (eu_mab), // Execution-Unit Memory address bus
- .eu_mb_en (eu_mb_en), // Execution-Unit Memory bus enable
- .eu_mb_wr (eu_mb_wr), // Execution-Unit Memory bus write transfer
- .eu_mdb_in (eu_mdb_in), // Memory data bus input
- .eu_mdb_out (eu_mdb_out), // Memory data bus output
- .exec_done (exec_done), // Execution completed
- .fe_mb_en (fe_mb_en), // Frontend Memory bus enable
- .fe_mdb_in (fe_mdb_in), // Frontend Memory data bus input
- .mclk (mclk), // Main system clock
- .pc (pc), // Program counter
- .por (por), // Power on reset
- .puc (puc) // Main system reset
-);
-
-`else
-assign dbg_freeze = 1'b0;
-assign dbg_halt_cmd = 1'b0;
-assign dbg_mem_addr = 16'h0000;
-assign dbg_mem_dout = 16'h0000;
-assign dbg_mem_en = 1'b0;
-assign dbg_mem_wr = 2'b00;
-assign dbg_reg_wr = 1'b0;
-assign dbg_reset = 1'b0;
-assign dbg_uart_txd = 1'b0;
-`endif
-
-
-endmodule // openMSP430
-
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/openMSP430.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property
Index: openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/dbg_hwbrk.v
===================================================================
--- openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/dbg_hwbrk.v (revision 37)
+++ openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/dbg_hwbrk.v (nonexistent)
@@ -1,275 +0,0 @@
-//----------------------------------------------------------------------------
-// Copyright (C) 2001 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, write to the Free Software Foundation,
-// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
-//
-//----------------------------------------------------------------------------
-//
-// *File Name: dbg_hwbrk.v
-//
-// *Module Description:
-// Hardware Breakpoint / Watchpoint module
-//
-// *Author(s):
-// - Olivier Girard, olgirard@gmail.com
-//
-//----------------------------------------------------------------------------
-// $Rev$
-// $LastChangedBy$
-// $LastChangedDate$
-//----------------------------------------------------------------------------
-`include "timescale.v"
-`include "openMSP430_defines.v"
-
-module dbg_hwbrk (
-
-// OUTPUTs
- brk_halt, // Hardware breakpoint command
- brk_pnd, // Hardware break/watch-point pending
- brk_dout, // Hardware break/watch-point register data input
-
-// INPUTs
- brk_reg_rd, // Hardware break/watch-point register read select
- brk_reg_wr, // Hardware break/watch-point register write select
- dbg_din, // Debug register data input
- eu_mab, // Execution-Unit Memory address bus
- eu_mb_en, // Execution-Unit Memory bus enable
- eu_mb_wr, // Execution-Unit Memory bus write transfer
- eu_mdb_in, // Memory data bus input
- eu_mdb_out, // Memory data bus output
- exec_done, // Execution completed
- fe_mb_en, // Frontend Memory bus enable
- mclk, // Main system clock
- pc, // Program counter
- por // Power on reset
-);
-
-// OUTPUTs
-//=========
-output brk_halt; // Hardware breakpoint command
-output brk_pnd; // Hardware break/watch-point pending
-output [15:0] brk_dout; // Hardware break/watch-point register data input
-
-// INPUTs
-//=========
-input [3:0] brk_reg_rd; // Hardware break/watch-point register read select
-input [3:0] brk_reg_wr; // Hardware break/watch-point register write select
-input [15:0] dbg_din; // Debug register data input
-input [15:0] eu_mab; // Execution-Unit Memory address bus
-input eu_mb_en; // Execution-Unit Memory bus enable
-input [1:0] eu_mb_wr; // Execution-Unit Memory bus write transfer
-input [15:0] eu_mdb_in; // Memory data bus input
-input [15:0] eu_mdb_out; // Memory data bus output
-input exec_done; // Execution completed
-input fe_mb_en; // Frontend Memory bus enable
-input mclk; // Main system clock
-input [15:0] pc; // Program counter
-input por; // Power on reset
-
-
-//=============================================================================
-// 1) WIRE & PARAMETER DECLARATION
-//=============================================================================
-
-wire range_wr_set;
-wire range_rd_set;
-wire addr1_wr_set;
-wire addr1_rd_set;
-wire addr0_wr_set;
-wire addr0_rd_set;
-
-
-parameter BRK_CTL = 0,
- BRK_STAT = 1,
- BRK_ADDR0 = 2,
- BRK_ADDR1 = 3;
-
-
-//=============================================================================
-// 2) CONFIGURATION REGISTERS
-//=============================================================================
-
-// BRK_CTL Register
-//-----------------------------------------------------------------------------
-// 7 6 5 4 3 2 1 0
-// Reserved RANGE_MODE INST_EN BREAK_EN ACCESS_MODE
-//
-// ACCESS_MODE: - 00 : Disabled
-// - 01 : Detect read access
-// - 10 : Detect write access
-// - 11 : Detect read/write access
-// NOTE: '10' & '11' modes are not supported on the instruction flow
-//
-// BREAK_EN: - 0 : Watchmode enable
-// - 1 : Break enable
-//
-// INST_EN: - 0 : Checks are done on the execution unit (data flow)
-// - 1 : Checks are done on the frontend (instruction flow)
-//
-// RANGE_MODE: - 0 : Address match on BRK_ADDR0 or BRK_ADDR1
-// - 1 : Address match on BRK_ADDR0->BRK_ADDR1 range
-//
-//-----------------------------------------------------------------------------
-reg [4:0] brk_ctl;
-
-wire brk_ctl_wr = brk_reg_wr[BRK_CTL];
-
-always @ (posedge mclk or posedge por)
- if (por) brk_ctl <= 5'h00;
- else if (brk_ctl_wr) brk_ctl <= dbg_din[4:0];
-
-wire [7:0] brk_ctl_full = {3'b000, brk_ctl};
-
-
-// BRK_STAT Register
-//-----------------------------------------------------------------------------
-// 7 6 5 4 3 2 1 0
-// Reserved RANGE_WR RANGE_RD ADDR1_WR ADDR1_RD ADDR0_WR ADDR0_RD
-//-----------------------------------------------------------------------------
-reg [5:0] brk_stat;
-
-wire brk_stat_wr = brk_reg_wr[BRK_STAT];
-wire [5:0] brk_stat_set = {range_wr_set, range_rd_set,
- addr1_wr_set, addr1_rd_set,
- addr0_wr_set, addr0_rd_set};
-wire [5:0] brk_stat_clr = ~dbg_din[5:0];
-
-always @ (posedge mclk or posedge por)
- if (por) brk_stat <= 6'h00;
- else if (brk_stat_wr) brk_stat <= ((brk_stat & brk_stat_clr) | brk_stat_set);
- else brk_stat <= (brk_stat | brk_stat_set);
-
-wire [7:0] brk_stat_full = {2'b00, brk_stat};
-wire brk_pnd = |brk_stat;
-
-
-// BRK_ADDR0 Register
-//-----------------------------------------------------------------------------
-reg [15:0] brk_addr0;
-
-wire brk_addr0_wr = brk_reg_wr[BRK_ADDR0];
-
-always @ (posedge mclk or posedge por)
- if (por) brk_addr0 <= 16'h0000;
- else if (brk_addr0_wr) brk_addr0 <= dbg_din;
-
-
-// BRK_ADDR1/DATA0 Register
-//-----------------------------------------------------------------------------
-reg [15:0] brk_addr1;
-
-wire brk_addr1_wr = brk_reg_wr[BRK_ADDR1];
-
-always @ (posedge mclk or posedge por)
- if (por) brk_addr1 <= 16'h0000;
- else if (brk_addr1_wr) brk_addr1 <= dbg_din;
-
-
-//============================================================================
-// 3) DATA OUTPUT GENERATION
-//============================================================================
-
-wire [15:0] brk_ctl_rd = {8'h00, brk_ctl_full} & {16{brk_reg_rd[BRK_CTL]}};
-wire [15:0] brk_stat_rd = {8'h00, brk_stat_full} & {16{brk_reg_rd[BRK_STAT]}};
-wire [15:0] brk_addr0_rd = brk_addr0 & {16{brk_reg_rd[BRK_ADDR0]}};
-wire [15:0] brk_addr1_rd = brk_addr1 & {16{brk_reg_rd[BRK_ADDR1]}};
-
-wire [15:0] brk_dout = brk_ctl_rd |
- brk_stat_rd |
- brk_addr0_rd |
- brk_addr1_rd;
-
-
-//============================================================================
-// 4) BREAKPOINT / WATCHPOINT GENERATION
-//============================================================================
-
-// Comparators
-//---------------------------
-// Note: here the comparison logic is instanciated several times in order
-// to improve the timings, at the cost of a bit more area.
-
-wire equ_d_addr0 = eu_mb_en & (eu_mab==brk_addr0) & ~brk_ctl[`BRK_RANGE];
-wire equ_d_addr1 = eu_mb_en & (eu_mab==brk_addr1) & ~brk_ctl[`BRK_RANGE];
-wire equ_d_range = eu_mb_en & ((eu_mab>=brk_addr0) & (eu_mab<=brk_addr1)) & brk_ctl[`BRK_RANGE];
-
-reg fe_mb_en_buf;
-always @ (posedge mclk or posedge por)
- if (por) fe_mb_en_buf <= 1'b0;
- else fe_mb_en_buf <= fe_mb_en;
-
-wire equ_i_addr0 = fe_mb_en_buf & (pc==brk_addr0) & ~brk_ctl[`BRK_RANGE];
-wire equ_i_addr1 = fe_mb_en_buf & (pc==brk_addr1) & ~brk_ctl[`BRK_RANGE];
-wire equ_i_range = fe_mb_en_buf & ((pc>=brk_addr0) & (pc<=brk_addr1)) & brk_ctl[`BRK_RANGE];
-
-
-// Detect accesses
-//---------------------------
-
-// Detect Instruction read access
-wire i_addr0_rd = equ_i_addr0 & brk_ctl[`BRK_I_EN];
-wire i_addr1_rd = equ_i_addr1 & brk_ctl[`BRK_I_EN];
-wire i_range_rd = equ_i_range & brk_ctl[`BRK_I_EN];
-
-// Detect Execution-Unit write access
-wire d_addr0_wr = equ_d_addr0 & ~brk_ctl[`BRK_I_EN] & |eu_mb_wr;
-wire d_addr1_wr = equ_d_addr1 & ~brk_ctl[`BRK_I_EN] & |eu_mb_wr;
-wire d_range_wr = equ_d_range & ~brk_ctl[`BRK_I_EN] & |eu_mb_wr;
-
-// Detect DATA read access
-// Whenever an "ADD r9. &0x200" instruction is executed, &0x200 will be read
-// before being written back. In that case, the read flag should not be set.
-// In general, We should here make sure no write access occures during the
-// same instruction cycle before setting the read flag.
-reg [2:0] d_rd_trig;
-always @ (posedge mclk or posedge por)
- if (por) d_rd_trig <= 3'h0;
- else if (exec_done) d_rd_trig <= 3'h0;
- else d_rd_trig <= {equ_d_range & ~brk_ctl[`BRK_I_EN] & ~|eu_mb_wr,
- equ_d_addr1 & ~brk_ctl[`BRK_I_EN] & ~|eu_mb_wr,
- equ_d_addr0 & ~brk_ctl[`BRK_I_EN] & ~|eu_mb_wr};
-
-wire d_addr0_rd = d_rd_trig[0] & exec_done & ~d_addr0_wr;
-wire d_addr1_rd = d_rd_trig[1] & exec_done & ~d_addr1_wr;
-wire d_range_rd = d_rd_trig[2] & exec_done & ~d_range_wr;
-
-
-// Set flags
-assign addr0_rd_set = brk_ctl[`BRK_MODE_RD] & (d_addr0_rd | i_addr0_rd);
-assign addr0_wr_set = brk_ctl[`BRK_MODE_WR] & d_addr0_wr;
-assign addr1_rd_set = brk_ctl[`BRK_MODE_RD] & (d_addr1_rd | i_addr1_rd);
-assign addr1_wr_set = brk_ctl[`BRK_MODE_WR] & d_addr1_wr;
-assign range_rd_set = brk_ctl[`BRK_MODE_RD] & (d_range_rd | i_range_rd);
-assign range_wr_set = brk_ctl[`BRK_MODE_WR] & d_range_wr;
-
-
-// Break CPU
-assign brk_halt = brk_ctl[`BRK_EN] & |brk_stat_set;
-
-
-endmodule // dbg_hwbrk
-
-
-
-
-
-
-
-
openmsp430/trunk/fpga/altera_de1_board/rtl/verilog/openmsp430/dbg_hwbrk.v
Property changes :
Deleted: svn:eol-style
## -1 +0,0 ##
-native
\ No newline at end of property
Deleted: svn:keywords
## -1 +0,0 ##
-Date Revision Author
\ No newline at end of property