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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_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: 34 $
// $LastChangedBy: olivier.girard $
// $LastChangedDate: 2009-12-29 20:10:34 +0100 (Tue, 29 Dec 2009) $
//----------------------------------------------------------------------------
`include "timescale.v"
`include "openMSP430_defines.v"
 
module  omsp_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 // omsp_clock_module
 
`include "openMSP430_undefines.v"

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[/] [openmsp430/] [trunk/] [core/] [rtl/] [verilog/] [omsp_clock_module.v] - Blame information for rev 76

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_clock_module.v`
26	2	olivier.gi	`//`
27			`// *Module Description:`
28			`// Basic clock module implementation.`
29			`// Since the openMSP430 mainly targets FPGA and hobby`
30			`// designers. The clock structure has been greatly`
31			`// symplified in order to ease integration.`
32			`// See online wiki for more info.`
33			`//`
34			`// *Author(s):`
35			`// - Olivier Girard, olgirard@gmail.com`
36			`//`
37			`//----------------------------------------------------------------------------`
38	17	olivier.gi	`// $Rev: 34 $`
39			`// $LastChangedBy: olivier.girard $`
40			`// $LastChangedDate: 2009-12-29 20:10:34 +0100 (Tue, 29 Dec 2009) $`
41			`//----------------------------------------------------------------------------`
42	23	olivier.gi	`include "timescale.v"
43			`include "openMSP430_defines.v"
44	2	olivier.gi
45	34	olivier.gi	`module omsp_clock_module (`
46	2	olivier.gi
47			`// OUTPUTs`
48			`aclk_en, // ACLK enable`
49			`mclk, // Main system clock`
50			`per_dout, // Peripheral data output`
51			`por, // Power-on reset`
52			`puc, // Main system reset`
53			`smclk_en, // SMCLK enable`
54
55			`// INPUTs`
56			`dbg_reset, // Reset CPU from debug interface`
57			`dco_clk, // Fast oscillator (fast clock)`
58			`lfxt_clk, // Low frequency oscillator (typ 32kHz)`
59			`oscoff, // Turns off LFXT1 clock input`
60			`per_addr, // Peripheral address`
61			`per_din, // Peripheral data input`
62			`per_en, // Peripheral enable (high active)`
63			`per_wen, // Peripheral write enable (high active)`
64			`reset_n, // Reset Pin (low active)`
65			`scg1, // System clock generator 1. Turns off the SMCLK`
66			`wdt_reset // Watchdog-timer reset`
67			`);`
68
69			`// OUTPUTs`
70			`//=========`
71			`output aclk_en; // ACLK enable`
72			`output mclk; // Main system clock`
73			`output [15:0] per_dout; // Peripheral data output`
74			`output por; // Power-on reset`
75			`output puc; // Main system reset`
76			`output smclk_en; // SMCLK enable`
77
78			`// INPUTs`
79			`//=========`
80			`input dbg_reset; // Reset CPU from debug interface`
81			`input dco_clk; // Fast oscillator (fast clock)`
82			`input lfxt_clk; // Low frequency oscillator (typ 32kHz)`
83			`input oscoff; // Turns off LFXT1 clock input`
84			`input [7:0] per_addr; // Peripheral address`
85			`input [15:0] per_din; // Peripheral data input`
86			`input per_en; // Peripheral enable (high active)`
87			`input [1:0] per_wen; // Peripheral write enable (high active)`
88			`input reset_n; // Reset Pin (low active)`
89			`input scg1; // System clock generator 1. Turns off the SMCLK`
90			`input wdt_reset; // Watchdog-timer reset`
91
92
93			`//=============================================================================`
94			`// 1) PARAMETER DECLARATION`
95			`//=============================================================================`
96
97			`// Register addresses`
98			`parameter BCSCTL1 = 9'h057;`
99			`parameter BCSCTL2 = 9'h058;`
100
101			`// Register one-hot decoder`
102			`parameter BCSCTL1_D = (256'h1 << (BCSCTL1 /2));`
103			`parameter BCSCTL2_D = (256'h1 << (BCSCTL2 /2));`
104
105
106			`//============================================================================`
107			`// 2) REGISTER DECODER`
108			`//============================================================================`
109
110			`// Register address decode`
111			`reg [255:0] reg_dec;`
112			`always @(per_addr)`
113			`case (per_addr)`
114			`(BCSCTL1 /2): reg_dec = BCSCTL1_D;`
115			`(BCSCTL2 /2): reg_dec = BCSCTL2_D;`
116			`default : reg_dec = {256{1'b0}};`
117			`endcase`
118
119			`// Read/Write probes`
120			`wire reg_lo_write = per_wen[0] & per_en;`
121			`wire reg_hi_write = per_wen[1] & per_en;`
122			`wire reg_read = ~\|per_wen & per_en;`
123
124			`// Read/Write vectors`
125			`wire [255:0] reg_hi_wr = reg_dec & {256{reg_hi_write}};`
126			`wire [255:0] reg_lo_wr = reg_dec & {256{reg_lo_write}};`
127			`wire [255:0] reg_rd = reg_dec & {256{reg_read}};`
128
129
130			`//============================================================================`
131			`// 3) REGISTERS`
132			`//============================================================================`
133
134			`// BCSCTL1 Register`
135			`//--------------`
136			`reg [7:0] bcsctl1;`
137			`wire bcsctl1_wr = BCSCTL1[0] ? reg_hi_wr[BCSCTL1/2] : reg_lo_wr[BCSCTL1/2];`
138			`wire [7:0] bcsctl1_nxt = BCSCTL1[0] ? per_din[15:8] : per_din[7:0];`
139
140			`always @ (posedge mclk or posedge puc)`
141			`if (puc) bcsctl1 <= 8'h00;`
142			`else if (bcsctl1_wr) bcsctl1 <= bcsctl1_nxt & 8'h30; // Mask unused bits`
143
144
145			`// BCSCTL2 Register`
146			`//--------------`
147			`reg [7:0] bcsctl2;`
148			`wire bcsctl2_wr = BCSCTL2[0] ? reg_hi_wr[BCSCTL2/2] : reg_lo_wr[BCSCTL2/2];`
149			`wire [7:0] bcsctl2_nxt = BCSCTL2[0] ? per_din[15:8] : per_din[7:0];`
150
151			`always @ (posedge mclk or posedge puc)`
152			`if (puc) bcsctl2 <= 8'h00;`
153			`else if (bcsctl2_wr) bcsctl2 <= bcsctl2_nxt & 8'h0e; // Mask unused bits`
154
155
156			`//============================================================================`
157			`// 4) DATA OUTPUT GENERATION`
158			`//============================================================================`
159
160			`// Data output mux`
161			`wire [15:0] bcsctl1_rd = (bcsctl1 & {8{reg_rd[BCSCTL1/2]}}) << (8 & {4{BCSCTL1[0]}});`
162			`wire [15:0] bcsctl2_rd = (bcsctl2 & {8{reg_rd[BCSCTL2/2]}}) << (8 & {4{BCSCTL2[0]}});`
163
164			`wire [15:0] per_dout = bcsctl1_rd \|`
165			`bcsctl2_rd;`
166
167
168			`//=============================================================================`
169			`// 5) CLOCK GENERATION`
170			`//=============================================================================`
171
172			`// Synchronize LFXT_CLK & edge detection`
173			`//---------------------------------------`
174			`reg [2:0] lfxt_clk_s;`
175
176			`always @ (posedge mclk or posedge puc)`
177			`if (puc) lfxt_clk_s <= 3'b000;`
178			`else lfxt_clk_s <= {lfxt_clk_s[1:0], lfxt_clk};`
179
180			wire lfxt_clk_en = (lfxt_clk_s[1] & ~lfxt_clk_s[2]) & ~(oscoff & ~bcsctl2[`SELS]);
181
182
183			`// Generate main system clock`
184			`//----------------------------`
185
186			`wire mclk = dco_clk;`
187			`wire mclk_n = !dco_clk;`
188
189
190			`// Generate ACLK`
191			`//----------------------------`
192
193			`reg [2:0] aclk_div;`
194
195			wire aclk_en = lfxt_clk_en & ((bcsctl1[`DIVAx]==2'b00) ? 1'b1 :
196			(bcsctl1[`DIVAx]==2'b01) ? aclk_div[0] :
197			(bcsctl1[`DIVAx]==2'b10) ? &aclk_div[1:0] :
198			`&aclk_div[2:0]);`
199
200			`always @ (posedge mclk or posedge puc)`
201			`if (puc) aclk_div <= 3'h0;`
202			else if ((bcsctl1[`DIVAx]!=2'b00) & lfxt_clk_en) aclk_div <= aclk_div+3'h1;
203
204
205			`// Generate SMCLK`
206			`//----------------------------`
207
208			`reg [2:0] smclk_div;`
209
210			wire smclk_in = ~scg1 & (bcsctl2[`SELS] ? lfxt_clk_en : 1'b1);
211
212			wire smclk_en = smclk_in & ((bcsctl2[`DIVSx]==2'b00) ? 1'b1 :
213			(bcsctl2[`DIVSx]==2'b01) ? smclk_div[0] :
214			(bcsctl2[`DIVSx]==2'b10) ? &smclk_div[1:0] :
215			`&smclk_div[2:0]);`
216
217			`always @ (posedge mclk or posedge puc)`
218			`if (puc) smclk_div <= 3'h0;`
219			else if ((bcsctl2[`DIVSx]!=2'b00) & smclk_in) smclk_div <= smclk_div+3'h1;
220
221
222			`//=============================================================================`
223			`// 6) RESET GENERATION`
224			`//=============================================================================`
225
226			`// Generate synchronized POR`
227			`wire por_reset = !reset_n;`
228
229			`reg [1:0] por_s;`
230			`always @(posedge mclk_n or posedge por_reset)`
231			`if (por_reset) por_s <= 2'b11;`
232			`else por_s <= {por_s[0], 1'b0};`
233			`wire por = por_s[1];`
234
235			`// Generate main system reset`
236			`wire puc_reset = por_reset \| wdt_reset \| dbg_reset;`
237
238			`reg [1:0] puc_s;`
239			`always @(posedge mclk_n or posedge puc_reset)`
240			`if (puc_reset) puc_s <= 2'b11;`
241			`else puc_s <= {puc_s[0], 1'b0};`
242			`wire puc = puc_s[1];`
243
244
245	34	olivier.gi	`endmodule // omsp_clock_module`
246	2	olivier.gi
247	33	olivier.gi	`include "openMSP430_undefines.v"