URL https://opencores.org/ocsvn/openmsp430/openmsp430/trunk

Subversion Repositories openmsp430

[/] [openmsp430/] [trunk/] [fpga/] [actel_m1a3pl_dev_kit/] [rtl/] [verilog/] [openmsp430/] [omsp_dbg_uart.v] - Blame information for rev 202

Details | Compare with Previous | View Log


//----------------------------------------------------------------------------
// Copyright (C) 2009 , Olivier Girard
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions
// are met:
//     * Redistributions of source code must retain the above copyright
//       notice, this list of conditions and the following disclaimer.
//     * Redistributions in binary form must reproduce the above copyright
//       notice, this list of conditions and the following disclaimer in the
//       documentation and/or other materials provided with the distribution.
//     * Neither the name of the authors nor the names of its contributors
//       may be used to endorse or promote products derived from this software
//       without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY,
// OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
// THE POSSIBILITY OF SUCH DAMAGE
//
//----------------------------------------------------------------------------
//
// *File Name: omsp_dbg_uart.v
//
// *Module Description:
//                       Debug UART communication interface (8N1, Half-duplex)
//
// *Author(s):
//              - Olivier Girard,    olgirard@gmail.com
//
//----------------------------------------------------------------------------
// $Rev$
// $LastChangedBy$
// $LastChangedDate$
//----------------------------------------------------------------------------
`ifdef OMSP_NO_INCLUDE
`else
`include "openMSP430_defines.v"
`endif
 
module  omsp_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_clk,                        // Debug unit clock
    dbg_dout,                       // Debug register data output
    dbg_rd_rdy,                     // Debug register data is ready for read
    dbg_rst,                        // Debug unit reset
    dbg_uart_rxd,                   // Debug interface: UART RXD
    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
);
 
// 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               dbg_clk;        // Debug unit clock
input        [15:0] dbg_dout;       // Debug register data output
input               dbg_rd_rdy;     // Debug register data is ready for read
input               dbg_rst;        // Debug unit reset
input               dbg_uart_rxd;   // Debug interface: UART RXD
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
 
 
//=============================================================================
// 1)  UART RECEIVE LINE SYNCHRONIZTION & FILTERING
//=============================================================================
 
// Synchronize RXD input
//--------------------------------
`ifdef SYNC_DBG_UART_RXD
 
    wire uart_rxd_n;
 
    omsp_sync_cell sync_cell_uart_rxd (
        .data_out  (uart_rxd_n),
        .data_in   (~dbg_uart_rxd),
        .clk       (dbg_clk),
        .rst       (dbg_rst)
    );
    wire uart_rxd = ~uart_rxd_n;
`else
    wire uart_rxd = dbg_uart_rxd;
`endif
 
// RXD input buffer
//--------------------------------
reg  [1:0] rxd_buf;
always @ (posedge dbg_clk or posedge dbg_rst)
  if (dbg_rst) rxd_buf <=  2'h3;
  else         rxd_buf <=  {rxd_buf[0], uart_rxd};
 
// Majority decision
//------------------------
reg        rxd_maj;
 
wire       rxd_maj_nxt = (uart_rxd   & rxd_buf[0]) |
                         (uart_rxd   & rxd_buf[1]) |
                         (rxd_buf[0] & rxd_buf[1]);
 
always @ (posedge dbg_clk or posedge dbg_rst)
  if (dbg_rst) rxd_maj <=  1'b1;
  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;
wire rxd_edge =  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;
wire [19:0] xfer_buf_nxt;
 
// 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_nxt 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_nxt[`DBG_UART_WR]  ?
                                (xfer_buf_nxt[`DBG_UART_BW]  ? RX_DATA2 : RX_DATA1) :
                                (xfer_buf_nxt[`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;
  // pragma coverage off
    default  : uart_state_nxt =  RX_CMD;
  // pragma coverage on
  endcase
 
// State machine
always @(posedge dbg_clk or posedge dbg_rst)
  if (dbg_rst)                          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 rx_active = (uart_state==RX_DATA1) | (uart_state==RX_DATA2) | (uart_state==RX_CMD);
wire tx_active = (uart_state==TX_DATA1) | (uart_state==TX_DATA2);
 
 
//=============================================================================
// 3)  UART SYNCHRONIZATION
//=============================================================================
// After DBG_RST, 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 dbg_clk or posedge dbg_rst)
  if (dbg_rst)                             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 [`DBG_UART_XFER_CNT_W+2:0] sync_cnt;
always @ (posedge dbg_clk or posedge dbg_rst)
  if (dbg_rst)                                     sync_cnt <=  {{`DBG_UART_XFER_CNT_W{1'b1}}, 3'b000};
  else if (sync_busy | (~sync_busy & sync_cnt[2])) sync_cnt <=  sync_cnt+{{`DBG_UART_XFER_CNT_W+2{1'b0}}, 1'b1};
 
wire [`DBG_UART_XFER_CNT_W-1:0] bit_cnt_max = sync_cnt[`DBG_UART_XFER_CNT_W+2:3];
`else
wire [`DBG_UART_XFER_CNT_W-1:0] bit_cnt_max = `DBG_UART_CNT;
`endif
 
 
//=============================================================================
// 4)  UART RECEIVE / TRANSMIT
//=============================================================================
 
// Transfer counter
//------------------------
reg                      [3:0] xfer_bit;
reg [`DBG_UART_XFER_CNT_W-1:0] 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=={`DBG_UART_XFER_CNT_W{1'b0}});
assign     xfer_done    = rx_active ? (xfer_bit==4'ha) : (xfer_bit==4'hb);
 
always @ (posedge dbg_clk or posedge dbg_rst)
  if (dbg_rst)                       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 dbg_clk or posedge dbg_rst)
  if (dbg_rst)                       xfer_cnt <=  {`DBG_UART_XFER_CNT_W{1'b0}};
  else if (rx_active & rxd_edge)     xfer_cnt <=  {1'b0, bit_cnt_max[`DBG_UART_XFER_CNT_W-1:1]};
  else if (txd_start | xfer_bit_inc) xfer_cnt <=  bit_cnt_max;
  else if (|xfer_cnt)                xfer_cnt <=  xfer_cnt+{`DBG_UART_XFER_CNT_W{1'b1}};
 
 
// Receive/Transmit buffer
//-------------------------
assign xfer_buf_nxt =  {rxd_s, xfer_buf[19:1]};
 
always @ (posedge dbg_clk or posedge dbg_rst)
  if (dbg_rst)           xfer_buf <=  20'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 dbg_clk or posedge dbg_rst)
  if (dbg_rst)                       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 dbg_clk or posedge dbg_rst)
  if (dbg_rst)        dbg_addr <=  6'h00;
  else if (cmd_valid) dbg_addr <=  xfer_buf_nxt[`DBG_UART_ADDR];
 
reg       dbg_bw;
always @ (posedge dbg_clk or posedge dbg_rst)
  if (dbg_rst)        dbg_bw   <=  1'b0;
  else if (cmd_valid) dbg_bw   <=  xfer_buf_nxt[`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_nxt[18:11]} :
                                       {xfer_buf_nxt[18:11], xfer_buf_nxt[9:2]};
wire        dbg_wr     = (xfer_done & (uart_state==RX_DATA2));
wire        dbg_rd     = mem_burst ? (xfer_done & (uart_state==TX_DATA2)) :
                                     (cmd_valid & ~xfer_buf_nxt[`DBG_UART_WR]) | mem_burst_rd;
 
 
 
endmodule // omsp_dbg_uart
 
`ifdef OMSP_NO_INCLUDE
`else
`include "openMSP430_undefines.v"
`endif

Line No.	Rev	Author	Line
1	80	olivier.gi	`//----------------------------------------------------------------------------`
2	136	olivier.gi	`// Copyright (C) 2009 , Olivier Girard`
3	80	olivier.gi	`//`
4	136	olivier.gi	`// Redistribution and use in source and binary forms, with or without`
5			`// modification, are permitted provided that the following conditions`
6			`// are met:`
7			`// * Redistributions of source code must retain the above copyright`
8			`// notice, this list of conditions and the following disclaimer.`
9			`// * Redistributions in binary form must reproduce the above copyright`
10			`// notice, this list of conditions and the following disclaimer in the`
11			`// documentation and/or other materials provided with the distribution.`
12			`// * Neither the name of the authors nor the names of its contributors`
13			`// may be used to endorse or promote products derived from this software`
14			`// without specific prior written permission.`
15	80	olivier.gi	`//`
16	136	olivier.gi	`// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"`
17			`// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE`
18			`// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE`
19			`// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE`
20			`// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY,`
21			`// OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF`
22			`// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS`
23			`// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN`
24			`// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)`
25			`// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF`
26			`// THE POSSIBILITY OF SUCH DAMAGE`
27	80	olivier.gi	`//`
28			`//----------------------------------------------------------------------------`
29			`//`
30			`// *File Name: omsp_dbg_uart.v`
31	202	olivier.gi	`//`
32	80	olivier.gi	`// *Module Description:`
33			`// Debug UART communication interface (8N1, Half-duplex)`
34			`//`
35			`// *Author(s):`
36			`// - Olivier Girard, olgirard@gmail.com`
37			`//`
38			`//----------------------------------------------------------------------------`
39	202	olivier.gi	`// $Rev$`
40			`// $LastChangedBy$`
41			`// $LastChangedDate$`
42	80	olivier.gi	`//----------------------------------------------------------------------------`
43	104	olivier.gi	`ifdef OMSP_NO_INCLUDE
44			`else
45	80	olivier.gi	`include "openMSP430_defines.v"
46	104	olivier.gi	`endif
47	80	olivier.gi
48			`module omsp_dbg_uart (`
49
50			`// OUTPUTs`
51			`dbg_addr, // Debug register address`
52			`dbg_din, // Debug register data input`
53			`dbg_rd, // Debug register data read`
54			`dbg_uart_txd, // Debug interface: UART TXD`
55			`dbg_wr, // Debug register data write`
56	202	olivier.gi
57	80	olivier.gi	`// INPUTs`
58	107	olivier.gi	`dbg_clk, // Debug unit clock`
59	80	olivier.gi	`dbg_dout, // Debug register data output`
60			`dbg_rd_rdy, // Debug register data is ready for read`
61	107	olivier.gi	`dbg_rst, // Debug unit reset`
62	80	olivier.gi	`dbg_uart_rxd, // Debug interface: UART RXD`
63			`mem_burst, // Burst on going`
64			`mem_burst_end, // End TX/RX burst`
65			`mem_burst_rd, // Start TX burst`
66			`mem_burst_wr, // Start RX burst`
67	107	olivier.gi	`mem_bw // Burst byte width`
68	80	olivier.gi	`);`
69
70			`// OUTPUTs`
71			`//=========`
72			`output [5:0] dbg_addr; // Debug register address`
73			`output [15:0] dbg_din; // Debug register data input`
74			`output dbg_rd; // Debug register data read`
75			`output dbg_uart_txd; // Debug interface: UART TXD`
76			`output dbg_wr; // Debug register data write`
77
78			`// INPUTs`
79			`//=========`
80	107	olivier.gi	`input dbg_clk; // Debug unit clock`
81	80	olivier.gi	`input [15:0] dbg_dout; // Debug register data output`
82			`input dbg_rd_rdy; // Debug register data is ready for read`
83	107	olivier.gi	`input dbg_rst; // Debug unit reset`
84	80	olivier.gi	`input dbg_uart_rxd; // Debug interface: UART RXD`
85			`input mem_burst; // Burst on going`
86			`input mem_burst_end; // End TX/RX burst`
87			`input mem_burst_rd; // Start TX burst`
88			`input mem_burst_wr; // Start RX burst`
89			`input mem_bw; // Burst byte width`
90
91
92			`//=============================================================================`
93			`// 1) UART RECEIVE LINE SYNCHRONIZTION & FILTERING`
94			`//=============================================================================`
95
96	111	olivier.gi	`// Synchronize RXD input`
97	80	olivier.gi	`//--------------------------------`
98	111	olivier.gi	`ifdef SYNC_DBG_UART_RXD
99
100			`wire uart_rxd_n;`
101
102			`omsp_sync_cell sync_cell_uart_rxd (`
103	136	olivier.gi	`.data_out (uart_rxd_n),`
104			`.data_in (~dbg_uart_rxd),`
105			`.clk (dbg_clk),`
106			`.rst (dbg_rst)`
107	111	olivier.gi	`);`
108			`wire uart_rxd = ~uart_rxd_n;`
109			`else
110			`wire uart_rxd = dbg_uart_rxd;`
111			`endif
112	202	olivier.gi
113	111	olivier.gi	`// RXD input buffer`
114			`//--------------------------------`
115			`reg [1:0] rxd_buf;`
116	107	olivier.gi	`always @ (posedge dbg_clk or posedge dbg_rst)`
117	111	olivier.gi	`if (dbg_rst) rxd_buf <= 2'h3;`
118			`else rxd_buf <= {rxd_buf[0], uart_rxd};`
119	80	olivier.gi
120			`// Majority decision`
121			`//------------------------`
122			`reg rxd_maj;`
123
124	136	olivier.gi	`wire rxd_maj_nxt = (uart_rxd & rxd_buf[0]) \|`
125	202	olivier.gi	`(uart_rxd & rxd_buf[1]) \|`
126			`(rxd_buf[0] & rxd_buf[1]);`
127
128	107	olivier.gi	`always @ (posedge dbg_clk or posedge dbg_rst)`
129	136	olivier.gi	`if (dbg_rst) rxd_maj <= 1'b1;`
130	107	olivier.gi	`else rxd_maj <= rxd_maj_nxt;`
131	80	olivier.gi
132	136	olivier.gi	`wire rxd_s = rxd_maj;`
133			`wire rxd_fe = rxd_maj & ~rxd_maj_nxt;`
134			`wire rxd_re = ~rxd_maj & rxd_maj_nxt;`
135			`wire rxd_edge = rxd_maj ^ rxd_maj_nxt;`
136	202	olivier.gi
137	80	olivier.gi	`//=============================================================================`
138			`// 2) UART STATE MACHINE`
139			`//=============================================================================`
140
141			`// Receive state`
142			`//------------------------`
143	136	olivier.gi	`reg [2:0] uart_state;`
144			`reg [2:0] uart_state_nxt;`
145	80	olivier.gi
146	136	olivier.gi	`wire sync_done;`
147			`wire xfer_done;`
148			`reg [19:0] xfer_buf;`
149			`wire [19:0] xfer_buf_nxt;`
150	80	olivier.gi
151			`// State machine definition`
152			`parameter RX_SYNC = 3'h0;`
153			`parameter RX_CMD = 3'h1;`
154			`parameter RX_DATA1 = 3'h2;`
155			`parameter RX_DATA2 = 3'h3;`
156			`parameter TX_DATA1 = 3'h4;`
157			`parameter TX_DATA2 = 3'h5;`
158
159			`// State transition`
160	136	olivier.gi	`always @(uart_state or xfer_buf_nxt or mem_burst or mem_burst_wr or mem_burst_rd or mem_burst_end or mem_bw)`
161	80	olivier.gi	`case (uart_state)`
162			`RX_SYNC : uart_state_nxt = RX_CMD;`
163			`RX_CMD : uart_state_nxt = mem_burst_wr ?`
164			`(mem_bw ? RX_DATA2 : RX_DATA1) :`
165			`mem_burst_rd ?`
166			`(mem_bw ? TX_DATA2 : TX_DATA1) :`
167	136	olivier.gi	(xfer_buf_nxt[`DBG_UART_WR] ?
168			(xfer_buf_nxt[`DBG_UART_BW] ? RX_DATA2 : RX_DATA1) :
169			(xfer_buf_nxt[`DBG_UART_BW] ? TX_DATA2 : TX_DATA1));
170	80	olivier.gi	`RX_DATA1 : uart_state_nxt = RX_DATA2;`
171			`RX_DATA2 : uart_state_nxt = (mem_burst & ~mem_burst_end) ?`
172			`(mem_bw ? RX_DATA2 : RX_DATA1) :`
173			`RX_CMD;`
174			`TX_DATA1 : uart_state_nxt = TX_DATA2;`
175			`TX_DATA2 : uart_state_nxt = (mem_burst & ~mem_burst_end) ?`
176			`(mem_bw ? TX_DATA2 : TX_DATA1) :`
177			`RX_CMD;`
178	136	olivier.gi	`// pragma coverage off`
179	80	olivier.gi	`default : uart_state_nxt = RX_CMD;`
180	136	olivier.gi	`// pragma coverage on`
181	80	olivier.gi	`endcase`
182	202	olivier.gi
183	80	olivier.gi	`// State machine`
184	107	olivier.gi	`always @(posedge dbg_clk or posedge dbg_rst)`
185			`if (dbg_rst) uart_state <= RX_SYNC;`
186	80	olivier.gi	`else if (xfer_done \| sync_done \|`
187			`mem_burst_wr \| mem_burst_rd) uart_state <= uart_state_nxt;`
188
189			`// Utility signals`
190			`wire cmd_valid = (uart_state==RX_CMD) & xfer_done;`
191	136	olivier.gi	`wire rx_active = (uart_state==RX_DATA1) \| (uart_state==RX_DATA2) \| (uart_state==RX_CMD);`
192	80	olivier.gi	`wire tx_active = (uart_state==TX_DATA1) \| (uart_state==TX_DATA2);`
193
194	202	olivier.gi
195	80	olivier.gi	`//=============================================================================`
196			`// 3) UART SYNCHRONIZATION`
197			`//=============================================================================`
198	107	olivier.gi	`// After DBG_RST, the host needs to fist send a synchronization character (0x80)`
199	80	olivier.gi	`// If this feature doesn't work properly, it is possible to disable it by`
200			`// commenting the DBG_UART_AUTO_SYNC define in the openMSP430.inc file.`
201
202			`reg sync_busy;`
203	107	olivier.gi	`always @ (posedge dbg_clk or posedge dbg_rst)`
204			`if (dbg_rst) sync_busy <= 1'b0;`
205	80	olivier.gi	`else if ((uart_state==RX_SYNC) & rxd_fe) sync_busy <= 1'b1;`
206			`else if ((uart_state==RX_SYNC) & rxd_re) sync_busy <= 1'b0;`
207
208			`assign sync_done = (uart_state==RX_SYNC) & rxd_re & sync_busy;`
209
210			`ifdef DBG_UART_AUTO_SYNC
211
212			reg [`DBG_UART_XFER_CNT_W+2:0] sync_cnt;
213	107	olivier.gi	`always @ (posedge dbg_clk or posedge dbg_rst)`
214	136	olivier.gi	if (dbg_rst) sync_cnt <= {{`DBG_UART_XFER_CNT_W{1'b1}}, 3'b000};
215			else if (sync_busy \| (~sync_busy & sync_cnt[2])) sync_cnt <= sync_cnt+{{`DBG_UART_XFER_CNT_W+2{1'b0}}, 1'b1};
216	80	olivier.gi
217			wire [`DBG_UART_XFER_CNT_W-1:0] bit_cnt_max = sync_cnt[`DBG_UART_XFER_CNT_W+2:3];
218			`else
219			wire [`DBG_UART_XFER_CNT_W-1:0] bit_cnt_max = `DBG_UART_CNT;
220			`endif
221	202	olivier.gi
222
223	80	olivier.gi	`//=============================================================================`
224			`// 4) UART RECEIVE / TRANSMIT`
225			`//=============================================================================`
226	202	olivier.gi
227	80	olivier.gi	`// Transfer counter`
228			`//------------------------`
229			`reg [3:0] xfer_bit;`
230			reg [`DBG_UART_XFER_CNT_W-1:0] xfer_cnt;
231
232			`wire txd_start = dbg_rd_rdy \| (xfer_done & (uart_state==TX_DATA1));`
233			`wire rxd_start = (xfer_bit==4'h0) & rxd_fe & ((uart_state!=RX_SYNC));`
234			wire xfer_bit_inc = (xfer_bit!=4'h0) & (xfer_cnt=={`DBG_UART_XFER_CNT_W{1'b0}});
235	136	olivier.gi	`assign xfer_done = rx_active ? (xfer_bit==4'ha) : (xfer_bit==4'hb);`
236	202	olivier.gi
237	107	olivier.gi	`always @ (posedge dbg_clk or posedge dbg_rst)`
238			`if (dbg_rst) xfer_bit <= 4'h0;`
239	80	olivier.gi	`else if (txd_start \| rxd_start) xfer_bit <= 4'h1;`
240			`else if (xfer_done) xfer_bit <= 4'h0;`
241			`else if (xfer_bit_inc) xfer_bit <= xfer_bit+4'h1;`
242
243	107	olivier.gi	`always @ (posedge dbg_clk or posedge dbg_rst)`
244			if (dbg_rst) xfer_cnt <= {`DBG_UART_XFER_CNT_W{1'b0}};
245	136	olivier.gi	else if (rx_active & rxd_edge) xfer_cnt <= {1'b0, bit_cnt_max[`DBG_UART_XFER_CNT_W-1:1]};
246	80	olivier.gi	`else if (txd_start \| xfer_bit_inc) xfer_cnt <= bit_cnt_max;`
247	136	olivier.gi	else if (\|xfer_cnt) xfer_cnt <= xfer_cnt+{`DBG_UART_XFER_CNT_W{1'b1}};
248	80	olivier.gi
249
250			`// Receive/Transmit buffer`
251			`//-------------------------`
252	136	olivier.gi	`assign xfer_buf_nxt = {rxd_s, xfer_buf[19:1]};`
253	80	olivier.gi
254	107	olivier.gi	`always @ (posedge dbg_clk or posedge dbg_rst)`
255			`if (dbg_rst) xfer_buf <= 20'h00000;`
256	80	olivier.gi	`else if (dbg_rd_rdy) xfer_buf <= {1'b1, dbg_dout[15:8], 2'b01, dbg_dout[7:0], 1'b0};`
257			`else if (xfer_bit_inc) xfer_buf <= xfer_buf_nxt;`
258
259
260			`// Generate TXD output`
261			`//------------------------`
262			`reg dbg_uart_txd;`
263	202	olivier.gi
264	107	olivier.gi	`always @ (posedge dbg_clk or posedge dbg_rst)`
265			`if (dbg_rst) dbg_uart_txd <= 1'b1;`
266	80	olivier.gi	`else if (xfer_bit_inc & tx_active) dbg_uart_txd <= xfer_buf[0];`
267
268	202	olivier.gi
269	80	olivier.gi	`//=============================================================================`
270			`// 5) INTERFACE TO DEBUG REGISTERS`
271			`//=============================================================================`
272
273			`reg [5:0] dbg_addr;`
274	107	olivier.gi	`always @ (posedge dbg_clk or posedge dbg_rst)`
275			`if (dbg_rst) dbg_addr <= 6'h00;`
276	136	olivier.gi	else if (cmd_valid) dbg_addr <= xfer_buf_nxt[`DBG_UART_ADDR];
277	80	olivier.gi
278			`reg dbg_bw;`
279	107	olivier.gi	`always @ (posedge dbg_clk or posedge dbg_rst)`
280			`if (dbg_rst) dbg_bw <= 1'b0;`
281	136	olivier.gi	else if (cmd_valid) dbg_bw <= xfer_buf_nxt[`DBG_UART_BW];
282	80	olivier.gi
283			`wire dbg_din_bw = mem_burst ? mem_bw : dbg_bw;`
284
285	136	olivier.gi	`wire [15:0] dbg_din = dbg_din_bw ? {8'h00, xfer_buf_nxt[18:11]} :`
286			`{xfer_buf_nxt[18:11], xfer_buf_nxt[9:2]};`
287	80	olivier.gi	`wire dbg_wr = (xfer_done & (uart_state==RX_DATA2));`
288			`wire dbg_rd = mem_burst ? (xfer_done & (uart_state==TX_DATA2)) :`
289	136	olivier.gi	(cmd_valid & ~xfer_buf_nxt[`DBG_UART_WR]) \| mem_burst_rd;
290	80	olivier.gi
291	202	olivier.gi
292
293	80	olivier.gi	`endmodule // omsp_dbg_uart`
294
295	104	olivier.gi	`ifdef OMSP_NO_INCLUDE
296			`else
297	80	olivier.gi	`include "openMSP430_undefines.v"
298	104	olivier.gi	`endif

Browse

Tools

Subversion Repositories openmsp430

[/] [openmsp430/] [trunk/] [fpga/] [actel_m1a3pl_dev_kit/] [rtl/] [verilog/] [openmsp430/] [omsp_dbg_uart.v] - Blame information for rev 202