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[/] [openmsp430/] [trunk/] [core/] [rtl/] [verilog/] [omsp_dbg_hwbrk.v] - Blame information for rev 103

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//----------------------------------------------------------------------------
// 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: omsp_dbg_hwbrk.v
// 
// *Module Description:
//                       Hardware Breakpoint / Watchpoint module
//
// *Author(s):
//              - Olivier Girard,    olgirard@gmail.com
//
//----------------------------------------------------------------------------
// $Rev: 103 $
// $LastChangedBy: olivier.girard $
// $LastChangedDate: 2011-03-05 15:44:48 +0100 (Sat, 05 Mar 2011) $
//----------------------------------------------------------------------------
`ifdef OMSP_NO_INCLUDE
`else
`include "openMSP430_defines.v"
`endif
 
module  omsp_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 <=  {`HWBRK_RANGE & dbg_din[4], dbg_din[3:0]};
 
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 & `HWBRK_RANGE,
                            range_rd_set & `HWBRK_RANGE,
                            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] & `HWBRK_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] & `HWBRK_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 // omsp_dbg_hwbrk
 
`ifdef OMSP_NO_INCLUDE
`else
`include "openMSP430_undefines.v"
`endif

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[/] [openmsp430/] [trunk/] [core/] [rtl/] [verilog/] [omsp_dbg_hwbrk.v] - Blame information for rev 103

Line No.	Rev	Author	Line
1	2	olivier.gi	`//----------------------------------------------------------------------------`
2			`// Copyright (C) 2001 Authors`
3			`//`
4			`// This source file may be used and distributed without restriction provided`
5			`// that this copyright statement is not removed from the file and that any`
6			`// derivative work contains the original copyright notice and the associated`
7			`// disclaimer.`
8			`//`
9			`// This source file is free software; you can redistribute it and/or modify`
10			`// it under the terms of the GNU Lesser General Public License as published`
11			`// by the Free Software Foundation; either version 2.1 of the License, or`
12			`// (at your option) any later version.`
13			`//`
14			`// This source is distributed in the hope that it will be useful, but WITHOUT`
15			`// ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or`
16			`// FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public`
17			`// License for more details.`
18			`//`
19			`// You should have received a copy of the GNU Lesser General Public License`
20			`// along with this source; if not, write to the Free Software Foundation,`
21			`// Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA`
22			`//`
23			`//----------------------------------------------------------------------------`
24			`//`
25	34	olivier.gi	`// *File Name: omsp_dbg_hwbrk.v`
26	2	olivier.gi	`//`
27			`// *Module Description:`
28			`// Hardware Breakpoint / Watchpoint module`
29			`//`
30			`// *Author(s):`
31			`// - Olivier Girard, olgirard@gmail.com`
32			`//`
33			`//----------------------------------------------------------------------------`
34	17	olivier.gi	`// $Rev: 103 $`
35			`// $LastChangedBy: olivier.girard $`
36			`// $LastChangedDate: 2011-03-05 15:44:48 +0100 (Sat, 05 Mar 2011) $`
37			`//----------------------------------------------------------------------------`
38	103	olivier.gi	`ifdef OMSP_NO_INCLUDE
39			`else
40	23	olivier.gi	`include "openMSP430_defines.v"
41	103	olivier.gi	`endif
42	2	olivier.gi
43	34	olivier.gi	`module omsp_dbg_hwbrk (`
44	2	olivier.gi
45			`// OUTPUTs`
46			`brk_halt, // Hardware breakpoint command`
47			`brk_pnd, // Hardware break/watch-point pending`
48			`brk_dout, // Hardware break/watch-point register data input`
49
50			`// INPUTs`
51			`brk_reg_rd, // Hardware break/watch-point register read select`
52			`brk_reg_wr, // Hardware break/watch-point register write select`
53			`dbg_din, // Debug register data input`
54			`eu_mab, // Execution-Unit Memory address bus`
55			`eu_mb_en, // Execution-Unit Memory bus enable`
56			`eu_mb_wr, // Execution-Unit Memory bus write transfer`
57			`eu_mdb_in, // Memory data bus input`
58			`eu_mdb_out, // Memory data bus output`
59			`exec_done, // Execution completed`
60			`fe_mb_en, // Frontend Memory bus enable`
61			`mclk, // Main system clock`
62			`pc, // Program counter`
63			`por // Power on reset`
64			`);`
65
66			`// OUTPUTs`
67			`//=========`
68			`output brk_halt; // Hardware breakpoint command`
69			`output brk_pnd; // Hardware break/watch-point pending`
70			`output [15:0] brk_dout; // Hardware break/watch-point register data input`
71
72			`// INPUTs`
73			`//=========`
74			`input [3:0] brk_reg_rd; // Hardware break/watch-point register read select`
75			`input [3:0] brk_reg_wr; // Hardware break/watch-point register write select`
76			`input [15:0] dbg_din; // Debug register data input`
77			`input [15:0] eu_mab; // Execution-Unit Memory address bus`
78			`input eu_mb_en; // Execution-Unit Memory bus enable`
79			`input [1:0] eu_mb_wr; // Execution-Unit Memory bus write transfer`
80			`input [15:0] eu_mdb_in; // Memory data bus input`
81			`input [15:0] eu_mdb_out; // Memory data bus output`
82			`input exec_done; // Execution completed`
83			`input fe_mb_en; // Frontend Memory bus enable`
84			`input mclk; // Main system clock`
85			`input [15:0] pc; // Program counter`
86			`input por; // Power on reset`
87
88
89			`//=============================================================================`
90			`// 1) WIRE & PARAMETER DECLARATION`
91			`//=============================================================================`
92
93			`wire range_wr_set;`
94			`wire range_rd_set;`
95			`wire addr1_wr_set;`
96			`wire addr1_rd_set;`
97			`wire addr0_wr_set;`
98			`wire addr0_rd_set;`
99
100
101			`parameter BRK_CTL = 0,`
102			`BRK_STAT = 1,`
103			`BRK_ADDR0 = 2,`
104			`BRK_ADDR1 = 3;`
105
106
107			`//=============================================================================`
108			`// 2) CONFIGURATION REGISTERS`
109			`//=============================================================================`
110
111			`// BRK_CTL Register`
112			`//-----------------------------------------------------------------------------`
113			`// 7 6 5 4 3 2 1 0`
114			`// Reserved RANGE_MODE INST_EN BREAK_EN ACCESS_MODE`
115			`//`
116			`// ACCESS_MODE: - 00 : Disabled`
117			`// - 01 : Detect read access`
118			`// - 10 : Detect write access`
119			`// - 11 : Detect read/write access`
120			`// NOTE: '10' & '11' modes are not supported on the instruction flow`
121			`//`
122			`// BREAK_EN: - 0 : Watchmode enable`
123			`// - 1 : Break enable`
124			`//`
125			`// INST_EN: - 0 : Checks are done on the execution unit (data flow)`
126			`// - 1 : Checks are done on the frontend (instruction flow)`
127			`//`
128			`// RANGE_MODE: - 0 : Address match on BRK_ADDR0 or BRK_ADDR1`
129			`// - 1 : Address match on BRK_ADDR0->BRK_ADDR1 range`
130			`//`
131			`//-----------------------------------------------------------------------------`
132			`reg [4:0] brk_ctl;`
133
134			`wire brk_ctl_wr = brk_reg_wr[BRK_CTL];`
135
136			`always @ (posedge mclk or posedge por)`
137			`if (por) brk_ctl <= 5'h00;`
138	57	olivier.gi	else if (brk_ctl_wr) brk_ctl <= {`HWBRK_RANGE & dbg_din[4], dbg_din[3:0]};
139	2	olivier.gi
140			`wire [7:0] brk_ctl_full = {3'b000, brk_ctl};`
141
142
143			`// BRK_STAT Register`
144			`//-----------------------------------------------------------------------------`
145			`// 7 6 5 4 3 2 1 0`
146			`// Reserved RANGE_WR RANGE_RD ADDR1_WR ADDR1_RD ADDR0_WR ADDR0_RD`
147			`//-----------------------------------------------------------------------------`
148			`reg [5:0] brk_stat;`
149
150			`wire brk_stat_wr = brk_reg_wr[BRK_STAT];`
151	57	olivier.gi	wire [5:0] brk_stat_set = {range_wr_set & `HWBRK_RANGE,
152			range_rd_set & `HWBRK_RANGE,
153	2	olivier.gi	`addr1_wr_set, addr1_rd_set,`
154			`addr0_wr_set, addr0_rd_set};`
155			`wire [5:0] brk_stat_clr = ~dbg_din[5:0];`
156
157			`always @ (posedge mclk or posedge por)`
158			`if (por) brk_stat <= 6'h00;`
159			`else if (brk_stat_wr) brk_stat <= ((brk_stat & brk_stat_clr) \| brk_stat_set);`
160			`else brk_stat <= (brk_stat \| brk_stat_set);`
161
162			`wire [7:0] brk_stat_full = {2'b00, brk_stat};`
163			`wire brk_pnd = \|brk_stat;`
164
165
166			`// BRK_ADDR0 Register`
167			`//-----------------------------------------------------------------------------`
168			`reg [15:0] brk_addr0;`
169
170			`wire brk_addr0_wr = brk_reg_wr[BRK_ADDR0];`
171
172			`always @ (posedge mclk or posedge por)`
173			`if (por) brk_addr0 <= 16'h0000;`
174			`else if (brk_addr0_wr) brk_addr0 <= dbg_din;`
175
176
177			`// BRK_ADDR1/DATA0 Register`
178			`//-----------------------------------------------------------------------------`
179			`reg [15:0] brk_addr1;`
180
181			`wire brk_addr1_wr = brk_reg_wr[BRK_ADDR1];`
182
183			`always @ (posedge mclk or posedge por)`
184			`if (por) brk_addr1 <= 16'h0000;`
185			`else if (brk_addr1_wr) brk_addr1 <= dbg_din;`
186
187
188			`//============================================================================`
189			`// 3) DATA OUTPUT GENERATION`
190			`//============================================================================`
191
192			`wire [15:0] brk_ctl_rd = {8'h00, brk_ctl_full} & {16{brk_reg_rd[BRK_CTL]}};`
193			`wire [15:0] brk_stat_rd = {8'h00, brk_stat_full} & {16{brk_reg_rd[BRK_STAT]}};`
194			`wire [15:0] brk_addr0_rd = brk_addr0 & {16{brk_reg_rd[BRK_ADDR0]}};`
195			`wire [15:0] brk_addr1_rd = brk_addr1 & {16{brk_reg_rd[BRK_ADDR1]}};`
196
197			`wire [15:0] brk_dout = brk_ctl_rd \|`
198			`brk_stat_rd \|`
199			`brk_addr0_rd \|`
200			`brk_addr1_rd;`
201
202
203			`//============================================================================`
204			`// 4) BREAKPOINT / WATCHPOINT GENERATION`
205			`//============================================================================`
206
207			`// Comparators`
208			`//---------------------------`
209			`// Note: here the comparison logic is instanciated several times in order`
210			`// to improve the timings, at the cost of a bit more area.`
211
212			wire equ_d_addr0 = eu_mb_en & (eu_mab==brk_addr0) & ~brk_ctl[`BRK_RANGE];
213			wire equ_d_addr1 = eu_mb_en & (eu_mab==brk_addr1) & ~brk_ctl[`BRK_RANGE];
214	57	olivier.gi	`wire equ_d_range = eu_mb_en & ((eu_mab>=brk_addr0) & (eu_mab<=brk_addr1)) &`
215			brk_ctl[`BRK_RANGE] & `HWBRK_RANGE;
216	2	olivier.gi
217			`reg fe_mb_en_buf;`
218			`always @ (posedge mclk or posedge por)`
219			`if (por) fe_mb_en_buf <= 1'b0;`
220			`else fe_mb_en_buf <= fe_mb_en;`
221
222			wire equ_i_addr0 = fe_mb_en_buf & (pc==brk_addr0) & ~brk_ctl[`BRK_RANGE];
223			wire equ_i_addr1 = fe_mb_en_buf & (pc==brk_addr1) & ~brk_ctl[`BRK_RANGE];
224	57	olivier.gi	`wire equ_i_range = fe_mb_en_buf & ((pc>=brk_addr0) & (pc<=brk_addr1)) &`
225			brk_ctl[`BRK_RANGE] & `HWBRK_RANGE;
226	2	olivier.gi
227
228			`// Detect accesses`
229			`//---------------------------`
230
231			`// Detect Instruction read access`
232			wire i_addr0_rd = equ_i_addr0 & brk_ctl[`BRK_I_EN];
233			wire i_addr1_rd = equ_i_addr1 & brk_ctl[`BRK_I_EN];
234			wire i_range_rd = equ_i_range & brk_ctl[`BRK_I_EN];
235
236			`// Detect Execution-Unit write access`
237			wire d_addr0_wr = equ_d_addr0 & ~brk_ctl[`BRK_I_EN] & \|eu_mb_wr;
238			wire d_addr1_wr = equ_d_addr1 & ~brk_ctl[`BRK_I_EN] & \|eu_mb_wr;
239			wire d_range_wr = equ_d_range & ~brk_ctl[`BRK_I_EN] & \|eu_mb_wr;
240
241			`// Detect DATA read access`
242			`// Whenever an "ADD r9. &0x200" instruction is executed, &0x200 will be read`
243			`// before being written back. In that case, the read flag should not be set.`
244			`// In general, We should here make sure no write access occures during the`
245			`// same instruction cycle before setting the read flag.`
246			`reg [2:0] d_rd_trig;`
247			`always @ (posedge mclk or posedge por)`
248			`if (por) d_rd_trig <= 3'h0;`
249			`else if (exec_done) d_rd_trig <= 3'h0;`
250			else d_rd_trig <= {equ_d_range & ~brk_ctl[`BRK_I_EN] & ~\|eu_mb_wr,
251			equ_d_addr1 & ~brk_ctl[`BRK_I_EN] & ~\|eu_mb_wr,
252			equ_d_addr0 & ~brk_ctl[`BRK_I_EN] & ~\|eu_mb_wr};
253
254			`wire d_addr0_rd = d_rd_trig[0] & exec_done & ~d_addr0_wr;`
255			`wire d_addr1_rd = d_rd_trig[1] & exec_done & ~d_addr1_wr;`
256			`wire d_range_rd = d_rd_trig[2] & exec_done & ~d_range_wr;`
257
258
259			`// Set flags`
260			assign addr0_rd_set = brk_ctl[`BRK_MODE_RD] & (d_addr0_rd \| i_addr0_rd);
261			assign addr0_wr_set = brk_ctl[`BRK_MODE_WR] & d_addr0_wr;
262			assign addr1_rd_set = brk_ctl[`BRK_MODE_RD] & (d_addr1_rd \| i_addr1_rd);
263			assign addr1_wr_set = brk_ctl[`BRK_MODE_WR] & d_addr1_wr;
264			assign range_rd_set = brk_ctl[`BRK_MODE_RD] & (d_range_rd \| i_range_rd);
265			assign range_wr_set = brk_ctl[`BRK_MODE_WR] & d_range_wr;
266
267
268			`// Break CPU`
269			assign brk_halt = brk_ctl[`BRK_EN] & \|brk_stat_set;
270
271
272	34	olivier.gi	`endmodule // omsp_dbg_hwbrk`
273	2	olivier.gi
274	103	olivier.gi	`ifdef OMSP_NO_INCLUDE
275			`else
276	33	olivier.gi	`include "openMSP430_undefines.v"
277	103	olivier.gi	`endif