Merge 'staging-next' to Linus's tree
[linux-2.6.git] / drivers / staging / wlags49_h2 / wl_main.c
1 /*******************************************************************************
2  * Agere Systems Inc.
3  * Wireless device driver for Linux (wlags49).
4  *
5  * Copyright (c) 1998-2003 Agere Systems Inc.
6  * All rights reserved.
7  *   http://www.agere.com
8  *
9  * Initially developed by TriplePoint, Inc.
10  *   http://www.triplepoint.com
11  *
12  *------------------------------------------------------------------------------
13  *
14  *   This file contains the main driver entry points and other adapter
15  *   specific routines.
16  *
17  *------------------------------------------------------------------------------
18  *
19  * SOFTWARE LICENSE
20  *
21  * This software is provided subject to the following terms and conditions,
22  * which you should read carefully before using the software.  Using this
23  * software indicates your acceptance of these terms and conditions.  If you do
24  * not agree with these terms and conditions, do not use the software.
25  *
26  * Copyright © 2003 Agere Systems Inc.
27  * All rights reserved.
28  *
29  * Redistribution and use in source or binary forms, with or without
30  * modifications, are permitted provided that the following conditions are met:
31  *
32  * . Redistributions of source code must retain the above copyright notice, this
33  *    list of conditions and the following Disclaimer as comments in the code as
34  *    well as in the documentation and/or other materials provided with the
35  *    distribution.
36  *
37  * . Redistributions in binary form must reproduce the above copyright notice,
38  *    this list of conditions and the following Disclaimer in the documentation
39  *    and/or other materials provided with the distribution.
40  *
41  * . Neither the name of Agere Systems Inc. nor the names of the contributors
42  *    may be used to endorse or promote products derived from this software
43  *    without specific prior written permission.
44  *
45  * Disclaimer
46  *
47  * THIS SOFTWARE IS PROVIDED “AS IS” AND ANY EXPRESS OR IMPLIED WARRANTIES,
48  * INCLUDING, BUT NOT LIMITED TO, INFRINGEMENT AND THE IMPLIED WARRANTIES OF
49  * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.  ANY
50  * USE, MODIFICATION OR DISTRIBUTION OF THIS SOFTWARE IS SOLELY AT THE USERS OWN
51  * RISK. IN NO EVENT SHALL AGERE SYSTEMS INC. OR CONTRIBUTORS BE LIABLE FOR ANY
52  * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
53  * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
54  * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
55  * ON ANY THEORY OF LIABILITY, INCLUDING, BUT NOT LIMITED TO, CONTRACT, STRICT
56  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
57  * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH
58  * DAMAGE.
59  *
60  ******************************************************************************/
61
62 /*******************************************************************************
63  *  constant definitions
64  ******************************************************************************/
65
66 /* Allow support for calling system fcns to access F/W iamge file */
67 #define __KERNEL_SYSCALLS__
68
69 /*******************************************************************************
70  *  include files
71  ******************************************************************************/
72 #include <wl_version.h>
73
74 #include <linux/module.h>
75 #include <linux/proc_fs.h>
76 #include <linux/types.h>
77 #include <linux/kernel.h>
78 // #include <linux/sched.h>
79 // #include <linux/ptrace.h>
80 // #include <linux/slab.h>
81 // #include <linux/ctype.h>
82 // #include <linux/string.h>
83 // #include <linux/timer.h>
84 //#include <linux/interrupt.h>
85 // #include <linux/tqueue.h>
86 // #include <linux/in.h>
87 // #include <linux/delay.h>
88 // #include <asm/io.h>
89 // #include <asm/system.h>
90 // #include <asm/bitops.h>
91 #include <linux/unistd.h>
92 #include <asm/uaccess.h>
93
94 #include <linux/netdevice.h>
95 #include <linux/etherdevice.h>
96 // #include <linux/skbuff.h>
97 // #include <linux/if_arp.h>
98 // #include <linux/ioport.h>
99
100 #define BIN_DL 0
101 #if BIN_DL
102 #include <linux/vmalloc.h>
103 #endif // BIN_DL
104
105
106 #include <debug.h>
107
108 #include <hcf.h>
109 #include <dhf.h>
110 //in order to get around:: wl_main.c:2229: `HREG_EV_RDMAD' undeclared (first use in this function)
111 #include <hcfdef.h>
112
113 #include <wl_if.h>
114 #include <wl_internal.h>
115 #include <wl_util.h>
116 #include <wl_main.h>
117 #include <wl_netdev.h>
118 #include <wl_wext.h>
119
120 #ifdef USE_PROFILE
121 #include <wl_profile.h>
122 #endif  /* USE_PROFILE */
123
124 #ifdef BUS_PCMCIA
125 #include <wl_cs.h>
126 #endif  /* BUS_PCMCIA */
127
128 #ifdef BUS_PCI
129 #include <wl_pci.h>
130 #endif  /* BUS_PCI */
131 /*******************************************************************************
132  *      macro defintions
133  ******************************************************************************/
134 #define VALID_PARAM(C) \
135         { \
136                 if (!(C)) \
137                 { \
138                         printk(KERN_INFO "Wireless, parameter error: \"%s\"\n", #C); \
139                         goto failed; \
140                 } \
141         }
142 /*******************************************************************************
143  *      local functions
144  ******************************************************************************/
145 void wl_isr_handler( unsigned long p );
146
147 #if 0 //SCULL_USE_PROC /* don't waste space if unused */
148 //int scull_read_procmem(char *buf, char **start, off_t offset, int len, int unused);
149 int scull_read_procmem(char *buf, char **start, off_t offset, int len, int *eof, void *data );
150 static int write_int(struct file *file, const char *buffer, unsigned long count, void *data);
151 static void proc_write(const char *name, write_proc_t *w, void *data);
152
153 #endif /* SCULL_USE_PROC */
154
155 /*******************************************************************************
156  * module parameter definitions - set with 'insmod'
157  ******************************************************************************/
158 static p_u16    irq_mask                = 0xdeb8; // IRQ3,4,5,7,9,10,11,12,14,15
159 static p_s8     irq_list[4]             = { -1 };
160
161 #if 0
162 MODULE_PARM(irq_mask,               "h");
163 MODULE_PARM_DESC(irq_mask,               "IRQ mask [0xdeb8]");
164 MODULE_PARM(irq_list,               "1-4b");
165 MODULE_PARM_DESC(irq_list,               "IRQ list [<irq_mask>]");
166 #endif
167
168 static p_u8     PARM_AUTHENTICATION             = PARM_DEFAULT_AUTHENTICATION;
169 static p_u16    PARM_AUTH_KEY_MGMT_SUITE        = PARM_DEFAULT_AUTH_KEY_MGMT_SUITE;
170 static p_u16    PARM_BRSC_2GHZ                  = PARM_DEFAULT_BRSC_2GHZ;
171 static p_u16    PARM_BRSC_5GHZ                  = PARM_DEFAULT_BRSC_5GHZ;
172 static p_u16    PARM_COEXISTENCE                = PARM_DEFAULT_COEXISTENCE;
173 static p_u16    PARM_CONNECTION_CONTROL         = PARM_DEFAULT_CONNECTION_CONTROL;  //;?rename and move
174 static p_char  *PARM_CREATE_IBSS                = PARM_DEFAULT_CREATE_IBSS_STR;
175 static p_char  *PARM_DESIRED_SSID               = PARM_DEFAULT_SSID;
176 static p_char  *PARM_DOWNLOAD_FIRMWARE      = "";
177 static p_u16    PARM_ENABLE_ENCRYPTION          = PARM_DEFAULT_ENABLE_ENCRYPTION;
178 static p_char  *PARM_EXCLUDE_UNENCRYPTED        = PARM_DEFAULT_EXCLUDE_UNENCRYPTED_STR;
179 static p_char  *PARM_INTRA_BSS_RELAY            = PARM_DEFAULT_INTRA_BSS_RELAY_STR;
180 static p_char  *PARM_KEY1                       = "";
181 static p_char  *PARM_KEY2                       = "";
182 static p_char  *PARM_KEY3                       = "";
183 static p_char  *PARM_KEY4                       = "";
184 static p_char  *PARM_LOAD_BALANCING             = PARM_DEFAULT_LOAD_BALANCING_STR;
185 static p_u16    PARM_MAX_SLEEP                  = PARM_DEFAULT_MAX_PM_SLEEP;
186 static p_char  *PARM_MEDIUM_DISTRIBUTION        = PARM_DEFAULT_MEDIUM_DISTRIBUTION_STR;
187 static p_char  *PARM_MICROWAVE_ROBUSTNESS       = PARM_DEFAULT_MICROWAVE_ROBUSTNESS_STR;
188 static p_char  *PARM_MULTICAST_PM_BUFFERING     = PARM_DEFAULT_MULTICAST_PM_BUFFERING_STR;
189 static p_u16    PARM_MULTICAST_RATE             = PARM_DEFAULT_MULTICAST_RATE_2GHZ;
190 static p_char  *PARM_MULTICAST_RX               = PARM_DEFAULT_MULTICAST_RX_STR;
191 static p_u8     PARM_NETWORK_ADDR[ETH_ALEN]     = PARM_DEFAULT_NETWORK_ADDR;
192 static p_u16    PARM_OWN_ATIM_WINDOW            = PARM_DEFAULT_OWN_ATIM_WINDOW;
193 static p_u16    PARM_OWN_BEACON_INTERVAL        = PARM_DEFAULT_OWN_BEACON_INTERVAL;
194 static p_u8     PARM_OWN_CHANNEL                = PARM_DEFAULT_OWN_CHANNEL;
195 static p_u8     PARM_OWN_DTIM_PERIOD            = PARM_DEFAULT_OWN_DTIM_PERIOD;
196 static p_char  *PARM_OWN_NAME                   = PARM_DEFAULT_OWN_NAME;
197 static p_char  *PARM_OWN_SSID                   = PARM_DEFAULT_SSID;
198 static p_u16    PARM_PM_ENABLED                 = WVLAN_PM_STATE_DISABLED;
199 static p_u16    PARM_PM_HOLDOVER_DURATION       = PARM_DEFAULT_PM_HOLDOVER_DURATION;
200 static p_u8     PARM_PORT_TYPE                  = PARM_DEFAULT_PORT_TYPE;
201 static p_char  *PARM_PROMISCUOUS_MODE           = PARM_DEFAULT_PROMISCUOUS_MODE_STR;
202 static p_char  *PARM_REJECT_ANY                 = PARM_DEFAULT_REJECT_ANY_STR;
203 #ifdef USE_WDS
204 static p_u16    PARM_RTS_THRESHOLD1             = PARM_DEFAULT_RTS_THRESHOLD;
205 static p_u16    PARM_RTS_THRESHOLD2             = PARM_DEFAULT_RTS_THRESHOLD;
206 static p_u16    PARM_RTS_THRESHOLD3             = PARM_DEFAULT_RTS_THRESHOLD;
207 static p_u16    PARM_RTS_THRESHOLD4             = PARM_DEFAULT_RTS_THRESHOLD;
208 static p_u16    PARM_RTS_THRESHOLD5             = PARM_DEFAULT_RTS_THRESHOLD;
209 static p_u16    PARM_RTS_THRESHOLD6             = PARM_DEFAULT_RTS_THRESHOLD;
210 #endif // USE_WDS
211 static p_u16    PARM_RTS_THRESHOLD              = PARM_DEFAULT_RTS_THRESHOLD;
212 static p_u16    PARM_SRSC_2GHZ                  = PARM_DEFAULT_SRSC_2GHZ;
213 static p_u16    PARM_SRSC_5GHZ                  = PARM_DEFAULT_SRSC_5GHZ;
214 static p_u8     PARM_SYSTEM_SCALE               = PARM_DEFAULT_SYSTEM_SCALE;
215 static p_u8     PARM_TX_KEY                     = PARM_DEFAULT_TX_KEY;
216 static p_u16    PARM_TX_POW_LEVEL               = PARM_DEFAULT_TX_POW_LEVEL;
217 #ifdef USE_WDS
218 static p_u16    PARM_TX_RATE1                   = PARM_DEFAULT_TX_RATE_2GHZ;
219 static p_u16    PARM_TX_RATE2                   = PARM_DEFAULT_TX_RATE_2GHZ;
220 static p_u16    PARM_TX_RATE3                   = PARM_DEFAULT_TX_RATE_2GHZ;
221 static p_u16    PARM_TX_RATE4                   = PARM_DEFAULT_TX_RATE_2GHZ;
222 static p_u16    PARM_TX_RATE5                   = PARM_DEFAULT_TX_RATE_2GHZ;
223 static p_u16    PARM_TX_RATE6                   = PARM_DEFAULT_TX_RATE_2GHZ;
224 #endif // USE_WDS
225 static p_u16    PARM_TX_RATE                    = PARM_DEFAULT_TX_RATE_2GHZ;
226 #ifdef USE_WDS
227 static p_u8     PARM_WDS_ADDRESS1[ETH_ALEN]     = PARM_DEFAULT_NETWORK_ADDR;
228 static p_u8     PARM_WDS_ADDRESS2[ETH_ALEN]     = PARM_DEFAULT_NETWORK_ADDR;
229 static p_u8     PARM_WDS_ADDRESS3[ETH_ALEN]     = PARM_DEFAULT_NETWORK_ADDR;
230 static p_u8     PARM_WDS_ADDRESS4[ETH_ALEN]     = PARM_DEFAULT_NETWORK_ADDR;
231 static p_u8     PARM_WDS_ADDRESS5[ETH_ALEN]     = PARM_DEFAULT_NETWORK_ADDR;
232 static p_u8     PARM_WDS_ADDRESS6[ETH_ALEN]     = PARM_DEFAULT_NETWORK_ADDR;
233 #endif // USE_WDS
234
235
236 #if 0
237 MODULE_PARM(PARM_DESIRED_SSID,          "s");
238 MODULE_PARM_DESC(PARM_DESIRED_SSID,             "Network Name (<string>) [ANY]");
239 MODULE_PARM(PARM_OWN_SSID,              "s");
240 MODULE_PARM_DESC(PARM_OWN_SSID,                 "Network Name (<string>) [ANY]");
241 MODULE_PARM(PARM_OWN_CHANNEL,           "b");
242 MODULE_PARM_DESC(PARM_OWN_CHANNEL,              "Channel (0 - 14) [0]");
243 MODULE_PARM(PARM_SYSTEM_SCALE,          "b");
244 MODULE_PARM_DESC(PARM_SYSTEM_SCALE,             "Distance Between APs (1 - 3) [1]");
245 MODULE_PARM(PARM_TX_RATE,               "b");
246 MODULE_PARM_DESC(PARM_TX_RATE,                  "Transmit Rate Control");
247 MODULE_PARM(PARM_RTS_THRESHOLD,         "h");
248 MODULE_PARM_DESC(PARM_RTS_THRESHOLD,            "Medium Reservation (RTS/CTS Fragment Length) (256 - 2347) [2347]");
249 MODULE_PARM(PARM_MICROWAVE_ROBUSTNESS,  "s");
250 MODULE_PARM_DESC(PARM_MICROWAVE_ROBUSTNESS,     "Microwave Oven Robustness Enabled (<string> N or Y) [N]");
251 MODULE_PARM(PARM_OWN_NAME,              "s");
252 MODULE_PARM_DESC(PARM_OWN_NAME,                 "Station Name (<string>) [Linux]");
253
254 MODULE_PARM(PARM_ENABLE_ENCRYPTION,     "b");
255 MODULE_PARM_DESC(PARM_ENABLE_ENCRYPTION,        "Encryption Mode (0 - 7) [0]");
256
257 MODULE_PARM(PARM_KEY1,                  "s");
258 MODULE_PARM_DESC(PARM_KEY1,                     "Data Encryption Key 1 (<string>) []");
259 MODULE_PARM(PARM_KEY2,                  "s");
260 MODULE_PARM_DESC(PARM_KEY2,                     "Data Encryption Key 2 (<string>) []");
261 MODULE_PARM(PARM_KEY3,                  "s");
262 MODULE_PARM_DESC(PARM_KEY3,                     "Data Encryption Key 3 (<string>) []");
263 MODULE_PARM(PARM_KEY4,                  "s");
264 MODULE_PARM_DESC(PARM_KEY4,                     "Data Encryption Key 4 (<string>) []");
265 MODULE_PARM(PARM_TX_KEY,                "b");
266 MODULE_PARM_DESC(PARM_TX_KEY,                   "Transmit Key ID (1 - 4) [1]");
267 MODULE_PARM(PARM_MULTICAST_RATE,        "b");
268 MODULE_PARM_DESC(PARM_MULTICAST_RATE,           "Multicast Rate");
269 MODULE_PARM(PARM_DOWNLOAD_FIRMWARE,     "s");
270 MODULE_PARM_DESC(PARM_DOWNLOAD_FIRMWARE,        "filename of firmware image");
271
272 MODULE_PARM(PARM_AUTH_KEY_MGMT_SUITE,   "b");
273 MODULE_PARM_DESC(PARM_AUTH_KEY_MGMT_SUITE,      "Authentication Key Management suite (0-4) [0]");
274
275 MODULE_PARM(PARM_LOAD_BALANCING,        "s");
276 MODULE_PARM_DESC(PARM_LOAD_BALANCING,           "Load Balancing Enabled (<string> N or Y) [Y]");
277 MODULE_PARM(PARM_MEDIUM_DISTRIBUTION,   "s");
278 MODULE_PARM_DESC(PARM_MEDIUM_DISTRIBUTION,      "Medium Distribution Enabled (<string> N or Y) [Y]");
279 MODULE_PARM(PARM_TX_POW_LEVEL,          "b");
280 MODULE_PARM_DESC(PARM_TX_POW_LEVEL,             "Transmit Power (0 - 6) [3]");
281 MODULE_PARM(PARM_SRSC_2GHZ,             "b");
282 MODULE_PARM_DESC(PARM_SRSC_2GHZ,                "Supported Rate Set Control 2.4 GHz");
283 MODULE_PARM(PARM_SRSC_5GHZ,             "b");
284 MODULE_PARM_DESC(PARM_SRSC_5GHZ,                "Supported Rate Set Control 5.0 GHz");
285 MODULE_PARM(PARM_BRSC_2GHZ,             "b");
286 MODULE_PARM_DESC(PARM_BRSC_2GHZ,                "Basic Rate Set Control 2.4 GHz");
287 MODULE_PARM(PARM_BRSC_5GHZ,             "b");
288 MODULE_PARM_DESC(PARM_BRSC_5GHZ,                "Basic Rate Set Control 5.0 GHz");
289 #if 1 //;? (HCF_TYPE) & HCF_TYPE_STA
290 //;?seems reasonable that even an AP-only driver could afford this small additional footprint
291 MODULE_PARM(PARM_PM_ENABLED,            "h");
292 MODULE_PARM_DESC(PARM_PM_ENABLED,               "Power Management State (0 - 2, 8001 - 8002) [0]");
293 MODULE_PARM(PARM_PORT_TYPE,             "b");
294 MODULE_PARM_DESC(PARM_PORT_TYPE,                "Port Type (1 - 3) [1]");
295 //;?MODULE_PARM(PARM_CREATE_IBSS,           "s");
296 //;?MODULE_PARM_DESC(PARM_CREATE_IBSS,              "Create IBSS (<string> N or Y) [N]");
297 //;?MODULE_PARM(PARM_MULTICAST_RX,          "s");
298 //;?MODULE_PARM_DESC(PARM_MULTICAST_RX,             "Multicast Receive Enable (<string> N or Y) [Y]");
299 //;?MODULE_PARM(PARM_MAX_SLEEP,             "h");
300 //;?MODULE_PARM_DESC(PARM_MAX_SLEEP,                "Maximum Power Management Sleep Duration (0 - 65535) [100]");
301 //;?MODULE_PARM(PARM_NETWORK_ADDR,          "6b");
302 //;?MODULE_PARM_DESC(PARM_NETWORK_ADDR,             "Hardware Ethernet Address ([0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff]) [<factory value>]");
303 //;?MODULE_PARM(PARM_AUTHENTICATION,        "b");
304 //
305 //tracker 12448
306 //;?MODULE_PARM_DESC(PARM_AUTHENTICATION,           "Authentication Type (0-2) [0] 0=Open 1=SharedKey 2=LEAP");
307 //;?MODULE_PARM_DESC(authentication,         "Authentication Type (1-2) [1] 1=Open 2=SharedKey");
308 //tracker 12448
309 //
310 //;?MODULE_PARM(PARM_OWN_ATIM_WINDOW,       "b");
311 //;?MODULE_PARM_DESC(PARM_OWN_ATIM_WINDOW,          "ATIM Window time in TU for IBSS creation (0-100) [0]");
312 //;?MODULE_PARM(PARM_PM_HOLDOVER_DURATION,  "b");
313 //;?MODULE_PARM_DESC(PARM_PM_HOLDOVER_DURATION,     "Time station remains awake after MAC frame transfer when PM is on (0-65535) [100]");
314 //;?MODULE_PARM(PARM_PROMISCUOUS_MODE,      "s");
315 //;?MODULE_PARM_DESC(PARM_PROMISCUOUS_MODE,         "Promiscuous Mode Enable (<string> Y or N ) [N]" );
316 //;?
317 MODULE_PARM(PARM_CONNECTION_CONTROL,    "b");
318 MODULE_PARM_DESC(PARM_CONNECTION_CONTROL,       "Connection Control (0 - 3) [2]");
319 #endif /* HCF_STA */
320 #if 1 //;? (HCF_TYPE) & HCF_TYPE_AP
321                                         //;?should we restore this to allow smaller memory footprint
322 MODULE_PARM(PARM_OWN_DTIM_PERIOD,       "b");
323 MODULE_PARM_DESC(PARM_OWN_DTIM_PERIOD,          "DTIM Period (0 - 255) [1]");
324 MODULE_PARM(PARM_REJECT_ANY,            "s");
325 MODULE_PARM_DESC(PARM_REJECT_ANY,               "Closed System (<string> N or Y) [N]");
326 MODULE_PARM(PARM_EXCLUDE_UNENCRYPTED,   "s");
327 MODULE_PARM_DESC(PARM_EXCLUDE_UNENCRYPTED,      "Deny non-encrypted (<string> N or Y) [Y]");
328 MODULE_PARM(PARM_MULTICAST_PM_BUFFERING,"s");
329 MODULE_PARM_DESC(PARM_MULTICAST_PM_BUFFERING,   "Buffer MAC frames for Tx after DTIM (<string> Y or N) [Y]");
330 MODULE_PARM(PARM_INTRA_BSS_RELAY,       "s");
331 MODULE_PARM_DESC(PARM_INTRA_BSS_RELAY,          "IntraBSS Relay (<string> N or Y) [Y]");
332 MODULE_PARM(PARM_RTS_THRESHOLD1,        "h");
333 MODULE_PARM_DESC(PARM_RTS_THRESHOLD1,           "RTS Threshold, WDS Port 1 (256 - 2347) [2347]");
334 MODULE_PARM(PARM_RTS_THRESHOLD2,        "h");
335 MODULE_PARM_DESC(PARM_RTS_THRESHOLD2,           "RTS Threshold, WDS Port 2 (256 - 2347) [2347]");
336 MODULE_PARM(PARM_RTS_THRESHOLD3,        "h");
337 MODULE_PARM_DESC(PARM_RTS_THRESHOLD3,           "RTS Threshold, WDS Port 3 (256 - 2347) [2347]");
338 MODULE_PARM(PARM_RTS_THRESHOLD4,        "h");
339 MODULE_PARM_DESC(PARM_RTS_THRESHOLD4,           "RTS Threshold, WDS Port 4 (256 - 2347) [2347]");
340 MODULE_PARM(PARM_RTS_THRESHOLD5,        "h");
341 MODULE_PARM_DESC(PARM_RTS_THRESHOLD5,           "RTS Threshold, WDS Port 5 (256 - 2347) [2347]");
342 MODULE_PARM(PARM_RTS_THRESHOLD6,        "h");
343 MODULE_PARM_DESC(PARM_RTS_THRESHOLD6,           "RTS Threshold, WDS Port 6 (256 - 2347) [2347]");
344 MODULE_PARM(PARM_TX_RATE1,              "b");
345 MODULE_PARM_DESC(PARM_TX_RATE1,                 "Transmit Rate Control, WDS Port 1 (1 - 7) [3]");
346 MODULE_PARM(PARM_TX_RATE2,              "b");
347 MODULE_PARM_DESC(PARM_TX_RATE2,                 "Transmit Rate Control, WDS Port 2 (1 - 7) [3]");
348 MODULE_PARM(PARM_TX_RATE3,              "b");
349 MODULE_PARM_DESC(PARM_TX_RATE3,                 "Transmit Rate Control, WDS Port 3 (1 - 7) [3]");
350 MODULE_PARM(PARM_TX_RATE4,              "b");
351 MODULE_PARM_DESC(PARM_TX_RATE4,                 "Transmit Rate Control, WDS Port 4 (1 - 7) [3]");
352 MODULE_PARM(PARM_TX_RATE5,              "b");
353 MODULE_PARM_DESC(PARM_TX_RATE5,                 "Transmit Rate Control, WDS Port 5 (1 - 7) [3]");
354 MODULE_PARM(PARM_TX_RATE6,              "b");
355 MODULE_PARM_DESC(PARM_TX_RATE6,                 "Transmit Rate Control, WDS Port 6 (1 - 7) [3]");
356 MODULE_PARM(PARM_WDS_ADDRESS1,          "6b");
357 MODULE_PARM_DESC(PARM_WDS_ADDRESS1,             "MAC Address, WDS Port 1 ([0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff]) [{0}]");
358 MODULE_PARM(PARM_WDS_ADDRESS2,          "6b");
359 MODULE_PARM_DESC(PARM_WDS_ADDRESS2,             "MAC Address, WDS Port 2 ([0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff]) [{0}]");
360 MODULE_PARM(PARM_WDS_ADDRESS3,          "6b");
361 MODULE_PARM_DESC(PARM_WDS_ADDRESS3,             "MAC Address, WDS Port 3 ([0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff]) [{0}]");
362 MODULE_PARM(PARM_WDS_ADDRESS4,          "6b");
363 MODULE_PARM_DESC(PARM_WDS_ADDRESS4,             "MAC Address, WDS Port 4 ([0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff]) [{0}]");
364 MODULE_PARM(PARM_WDS_ADDRESS5,          "6b");
365 MODULE_PARM_DESC(PARM_WDS_ADDRESS5,             "MAC Address, WDS Port 5 ([0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff]) [{0}]");
366 MODULE_PARM(PARM_WDS_ADDRESS6,          "6b");
367 MODULE_PARM_DESC(PARM_WDS_ADDRESS6,             "MAC Address, WDS Port 6 ([0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff],[0x00-0xff]) [{0}]");
368
369 MODULE_PARM(PARM_OWN_BEACON_INTERVAL,   "b");
370 MODULE_PARM_DESC(PARM_OWN_BEACON_INTERVAL,      "Own Beacon Interval (20 - 200) [100]");
371 MODULE_PARM(PARM_COEXISTENCE,   "b");
372 MODULE_PARM_DESC(PARM_COEXISTENCE,      "Coexistence (0-7) [0]");
373
374 #endif /* HCF_AP */
375 #endif
376
377 /* END NEW PARAMETERS */
378 /*******************************************************************************
379  * debugging specifics
380  ******************************************************************************/
381 #if DBG
382
383 static p_u32    pc_debug = DBG_LVL;
384 //MODULE_PARM(pc_debug, "i");
385 /*static ;?conflicts with my understanding of CL parameters and breaks now I moved
386  * the correspondig logic to wl_profile
387  */ p_u32    DebugFlag = ~0; //recognizable "undefined value" rather then DBG_DEFAULTS;
388 //MODULE_PARM(DebugFlag, "l");
389
390 dbg_info_t   wl_info = { DBG_MOD_NAME, 0, 0 };
391 dbg_info_t  *DbgInfo = &wl_info;
392
393 #endif /* DBG */
394 #ifdef USE_RTS
395
396 static p_char  *useRTS = "N";
397 MODULE_PARM( useRTS, "s" );
398 MODULE_PARM_DESC( useRTS, "Use RTS test interface (<string> N or Y) [N]" );
399
400 #endif  /* USE_RTS */
401 /*******************************************************************************
402  * firmware download specifics
403  ******************************************************************************/
404 extern struct CFG_RANGE2_STRCT BASED
405         cfg_drv_act_ranges_pri;             // describes primary-actor range of HCF
406
407 #if 0 //;? (HCF_TYPE) & HCF_TYPE_AP
408 extern memimage ap;                 // AP firmware image to be downloaded
409 #endif /* HCF_AP */
410
411 #if 1 //;? (HCF_TYPE) & HCF_TYPE_STA
412 //extern memimage station;            // STA firmware image to be downloaded
413 extern memimage fw_image;            // firmware image to be downloaded
414 #endif /* HCF_STA */
415
416
417 int wl_insert( struct net_device *dev )
418 {
419         int                     result = 0;
420         int                     hcf_status = HCF_SUCCESS;
421         int                     i;
422         unsigned long           flags = 0;
423         struct wl_private       *lp = wl_priv(dev);
424         /*------------------------------------------------------------------------*/
425         DBG_FUNC( "wl_insert" );
426         DBG_ENTER( DbgInfo );
427
428         /* Initialize the adapter hardware. */
429         memset( &( lp->hcfCtx ), 0, sizeof( IFB_STRCT ));
430
431         /* Initialize the adapter parameters. */
432         spin_lock_init( &( lp->slock ));
433
434         /* Initialize states */
435         //lp->lockcount = 0; //PE1DNN
436         lp->is_handling_int = WL_NOT_HANDLING_INT;
437         lp->firmware_present = WL_FRIMWARE_NOT_PRESENT;
438
439         lp->dev = dev;
440
441         DBG_PARAM( DbgInfo, "irq_mask", "0x%04x", irq_mask & 0x0FFFF );
442         DBG_PARAM( DbgInfo, "irq_list", "0x%02x 0x%02x 0x%02x 0x%02x",
443                            irq_list[0] & 0x0FF, irq_list[1] & 0x0FF,
444                            irq_list[2] & 0x0FF, irq_list[3] & 0x0FF );
445         DBG_PARAM( DbgInfo, PARM_NAME_DESIRED_SSID, "\"%s\"", PARM_DESIRED_SSID );
446         DBG_PARAM( DbgInfo, PARM_NAME_OWN_SSID, "\"%s\"", PARM_OWN_SSID );
447         DBG_PARAM( DbgInfo, PARM_NAME_OWN_CHANNEL, "%d", PARM_OWN_CHANNEL);
448         DBG_PARAM( DbgInfo, PARM_NAME_SYSTEM_SCALE, "%d", PARM_SYSTEM_SCALE );
449         DBG_PARAM( DbgInfo, PARM_NAME_TX_RATE, "%d", PARM_TX_RATE );
450         DBG_PARAM( DbgInfo, PARM_NAME_RTS_THRESHOLD, "%d", PARM_RTS_THRESHOLD );
451         DBG_PARAM( DbgInfo, PARM_NAME_MICROWAVE_ROBUSTNESS, "\"%s\"", PARM_MICROWAVE_ROBUSTNESS );
452         DBG_PARAM( DbgInfo, PARM_NAME_OWN_NAME, "\"%s\"", PARM_OWN_NAME );
453 //;?            DBG_PARAM( DbgInfo, PARM_NAME_ENABLE_ENCRYPTION, "\"%s\"", PARM_ENABLE_ENCRYPTION );
454         DBG_PARAM( DbgInfo, PARM_NAME_KEY1, "\"%s\"", PARM_KEY1 );
455         DBG_PARAM( DbgInfo, PARM_NAME_KEY2, "\"%s\"", PARM_KEY2 );
456         DBG_PARAM( DbgInfo, PARM_NAME_KEY3, "\"%s\"", PARM_KEY3 );
457         DBG_PARAM( DbgInfo, PARM_NAME_KEY4, "\"%s\"", PARM_KEY4 );
458         DBG_PARAM( DbgInfo, PARM_NAME_TX_KEY, "%d", PARM_TX_KEY );
459         DBG_PARAM( DbgInfo, PARM_NAME_MULTICAST_RATE, "%d", PARM_MULTICAST_RATE );
460         DBG_PARAM( DbgInfo, PARM_NAME_DOWNLOAD_FIRMWARE, "\"%s\"", PARM_DOWNLOAD_FIRMWARE );
461         DBG_PARAM( DbgInfo, PARM_NAME_AUTH_KEY_MGMT_SUITE, "%d", PARM_AUTH_KEY_MGMT_SUITE );
462 //;?#if (HCF_TYPE) & HCF_TYPE_STA
463                                         //;?should we make this code conditional depending on in STA mode
464 //;?        DBG_PARAM( DbgInfo, PARM_NAME_PORT_TYPE, "%d", PARM_PORT_TYPE );
465                 DBG_PARAM( DbgInfo, PARM_NAME_PM_ENABLED, "%04x", PARM_PM_ENABLED );
466 //;?        DBG_PARAM( DbgInfo, PARM_NAME_CREATE_IBSS, "\"%s\"", PARM_CREATE_IBSS );
467 //;?        DBG_PARAM( DbgInfo, PARM_NAME_MULTICAST_RX, "\"%s\"", PARM_MULTICAST_RX );
468 //;?        DBG_PARAM( DbgInfo, PARM_NAME_MAX_SLEEP, "%d", PARM_MAX_SLEEP );
469 /*
470         DBG_PARAM(DbgInfo, PARM_NAME_NETWORK_ADDR, "\"%pM\"",
471                         PARM_NETWORK_ADDR);
472  */
473 //;?        DBG_PARAM( DbgInfo, PARM_NAME_AUTHENTICATION, "%d", PARM_AUTHENTICATION );
474 //;?        DBG_PARAM( DbgInfo, PARM_NAME_OWN_ATIM_WINDOW, "%d", PARM_OWN_ATIM_WINDOW );
475 //;?        DBG_PARAM( DbgInfo, PARM_NAME_PM_HOLDOVER_DURATION, "%d", PARM_PM_HOLDOVER_DURATION );
476 //;?        DBG_PARAM( DbgInfo, PARM_NAME_PROMISCUOUS_MODE, "\"%s\"", PARM_PROMISCUOUS_MODE );
477 //;?#endif /* HCF_STA */
478 #if 1 //;? (HCF_TYPE) & HCF_TYPE_AP
479                 //;?should we restore this to allow smaller memory footprint
480                 //;?I guess: no, since this is Debug mode only
481         DBG_PARAM( DbgInfo, PARM_NAME_OWN_DTIM_PERIOD, "%d", PARM_OWN_DTIM_PERIOD );
482         DBG_PARAM( DbgInfo, PARM_NAME_REJECT_ANY, "\"%s\"", PARM_REJECT_ANY );
483         DBG_PARAM( DbgInfo, PARM_NAME_EXCLUDE_UNENCRYPTED, "\"%s\"", PARM_EXCLUDE_UNENCRYPTED );
484         DBG_PARAM( DbgInfo, PARM_NAME_MULTICAST_PM_BUFFERING, "\"%s\"", PARM_MULTICAST_PM_BUFFERING );
485         DBG_PARAM( DbgInfo, PARM_NAME_INTRA_BSS_RELAY, "\"%s\"", PARM_INTRA_BSS_RELAY );
486 #ifdef USE_WDS
487         DBG_PARAM( DbgInfo, PARM_NAME_RTS_THRESHOLD1, "%d", PARM_RTS_THRESHOLD1 );
488         DBG_PARAM( DbgInfo, PARM_NAME_RTS_THRESHOLD2, "%d", PARM_RTS_THRESHOLD2 );
489         DBG_PARAM( DbgInfo, PARM_NAME_RTS_THRESHOLD3, "%d", PARM_RTS_THRESHOLD3 );
490         DBG_PARAM( DbgInfo, PARM_NAME_RTS_THRESHOLD4, "%d", PARM_RTS_THRESHOLD4 );
491         DBG_PARAM( DbgInfo, PARM_NAME_RTS_THRESHOLD5, "%d", PARM_RTS_THRESHOLD5 );
492         DBG_PARAM( DbgInfo, PARM_NAME_RTS_THRESHOLD6, "%d", PARM_RTS_THRESHOLD6 );
493         DBG_PARAM( DbgInfo, PARM_NAME_TX_RATE1, "%d", PARM_TX_RATE1 );
494         DBG_PARAM( DbgInfo, PARM_NAME_TX_RATE2, "%d", PARM_TX_RATE2 );
495         DBG_PARAM( DbgInfo, PARM_NAME_TX_RATE3, "%d", PARM_TX_RATE3 );
496         DBG_PARAM( DbgInfo, PARM_NAME_TX_RATE4, "%d", PARM_TX_RATE4 );
497         DBG_PARAM( DbgInfo, PARM_NAME_TX_RATE5, "%d", PARM_TX_RATE5 );
498         DBG_PARAM( DbgInfo, PARM_NAME_TX_RATE6, "%d", PARM_TX_RATE6 );
499         DBG_PARAM(DbgInfo, PARM_NAME_WDS_ADDRESS1, "\"%pM\"",
500                         PARM_WDS_ADDRESS1);
501         DBG_PARAM(DbgInfo, PARM_NAME_WDS_ADDRESS2, "\"%pM\"",
502                         PARM_WDS_ADDRESS2);
503         DBG_PARAM(DbgInfo, PARM_NAME_WDS_ADDRESS3, "\"%pM\"",
504                         PARM_WDS_ADDRESS3);
505         DBG_PARAM(DbgInfo, PARM_NAME_WDS_ADDRESS4, "\"%pM\"",
506                         PARM_WDS_ADDRESS4);
507         DBG_PARAM(DbgInfo, PARM_NAME_WDS_ADDRESS5, "\"%pM\"",
508                         PARM_WDS_ADDRESS5);
509         DBG_PARAM(DbgInfo, PARM_NAME_WDS_ADDRESS6, "\"%pM\"",
510                         PARM_WDS_ADDRESS6);
511 #endif /* USE_WDS */
512 #endif /* HCF_AP */
513
514         VALID_PARAM( !PARM_DESIRED_SSID || ( strlen( PARM_DESIRED_SSID ) <= PARM_MAX_NAME_LEN ));
515         VALID_PARAM( !PARM_OWN_SSID || ( strlen( PARM_OWN_SSID ) <= PARM_MAX_NAME_LEN ));
516         VALID_PARAM(( PARM_OWN_CHANNEL <= PARM_MAX_OWN_CHANNEL ));
517         VALID_PARAM(( PARM_SYSTEM_SCALE >= PARM_MIN_SYSTEM_SCALE ) && ( PARM_SYSTEM_SCALE <= PARM_MAX_SYSTEM_SCALE ));
518         VALID_PARAM(( PARM_TX_RATE >= PARM_MIN_TX_RATE ) && ( PARM_TX_RATE <= PARM_MAX_TX_RATE ));
519         VALID_PARAM(( PARM_RTS_THRESHOLD <= PARM_MAX_RTS_THRESHOLD ));
520         VALID_PARAM( !PARM_MICROWAVE_ROBUSTNESS || strchr( "NnYy", PARM_MICROWAVE_ROBUSTNESS[0] ) != NULL );
521         VALID_PARAM( !PARM_OWN_NAME || ( strlen( PARM_NAME_OWN_NAME ) <= PARM_MAX_NAME_LEN ));
522         VALID_PARAM(( PARM_ENABLE_ENCRYPTION <= PARM_MAX_ENABLE_ENCRYPTION ));
523         VALID_PARAM( is_valid_key_string( PARM_KEY1 ));
524         VALID_PARAM( is_valid_key_string( PARM_KEY2 ));
525         VALID_PARAM( is_valid_key_string( PARM_KEY3 ));
526         VALID_PARAM( is_valid_key_string( PARM_KEY4 ));
527         VALID_PARAM(( PARM_TX_KEY >= PARM_MIN_TX_KEY ) && ( PARM_TX_KEY <= PARM_MAX_TX_KEY ));
528
529         VALID_PARAM(( PARM_MULTICAST_RATE >= PARM_MIN_MULTICAST_RATE ) &&
530                                         ( PARM_MULTICAST_RATE <= PARM_MAX_MULTICAST_RATE ));
531
532         VALID_PARAM( !PARM_DOWNLOAD_FIRMWARE || ( strlen( PARM_DOWNLOAD_FIRMWARE ) <= 255 /*;?*/ ));
533         VALID_PARAM(( PARM_AUTH_KEY_MGMT_SUITE < PARM_MAX_AUTH_KEY_MGMT_SUITE ));
534
535         VALID_PARAM( !PARM_LOAD_BALANCING || strchr( "NnYy", PARM_LOAD_BALANCING[0] ) != NULL );
536         VALID_PARAM( !PARM_MEDIUM_DISTRIBUTION || strchr( "NnYy", PARM_MEDIUM_DISTRIBUTION[0] ) != NULL );
537         VALID_PARAM(( PARM_TX_POW_LEVEL <= PARM_MAX_TX_POW_LEVEL ));
538
539         VALID_PARAM(( PARM_PORT_TYPE >= PARM_MIN_PORT_TYPE ) && ( PARM_PORT_TYPE <= PARM_MAX_PORT_TYPE ));
540         VALID_PARAM( PARM_PM_ENABLED <= WVLAN_PM_STATE_STANDARD ||
541                                  ( PARM_PM_ENABLED & 0x7FFF ) <= WVLAN_PM_STATE_STANDARD );
542         VALID_PARAM( !PARM_CREATE_IBSS || strchr( "NnYy", PARM_CREATE_IBSS[0] ) != NULL );
543         VALID_PARAM( !PARM_MULTICAST_RX || strchr( "NnYy", PARM_MULTICAST_RX[0] ) != NULL );
544         VALID_PARAM(( PARM_MAX_SLEEP <= PARM_MAX_MAX_PM_SLEEP ));
545         VALID_PARAM(( PARM_AUTHENTICATION <= PARM_MAX_AUTHENTICATION ));
546         VALID_PARAM(( PARM_OWN_ATIM_WINDOW <= PARM_MAX_OWN_ATIM_WINDOW ));
547         VALID_PARAM(( PARM_PM_HOLDOVER_DURATION <= PARM_MAX_PM_HOLDOVER_DURATION ));
548         VALID_PARAM( !PARM_PROMISCUOUS_MODE || strchr( "NnYy", PARM_PROMISCUOUS_MODE[0] ) != NULL );
549         VALID_PARAM(( PARM_CONNECTION_CONTROL <= PARM_MAX_CONNECTION_CONTROL ));
550
551         VALID_PARAM(( PARM_OWN_DTIM_PERIOD >= PARM_MIN_OWN_DTIM_PERIOD ));
552         VALID_PARAM( !PARM_REJECT_ANY || strchr( "NnYy", PARM_REJECT_ANY[0] ) != NULL );
553         VALID_PARAM( !PARM_EXCLUDE_UNENCRYPTED || strchr( "NnYy", PARM_EXCLUDE_UNENCRYPTED[0] ) != NULL );
554         VALID_PARAM( !PARM_MULTICAST_PM_BUFFERING || strchr( "NnYy", PARM_MULTICAST_PM_BUFFERING[0] ) != NULL );
555         VALID_PARAM( !PARM_INTRA_BSS_RELAY || strchr( "NnYy", PARM_INTRA_BSS_RELAY[0] ) != NULL );
556 #ifdef USE_WDS
557         VALID_PARAM(( PARM_RTS_THRESHOLD1 <= PARM_MAX_RTS_THRESHOLD ));
558         VALID_PARAM(( PARM_RTS_THRESHOLD2 <= PARM_MAX_RTS_THRESHOLD ));
559         VALID_PARAM(( PARM_RTS_THRESHOLD3 <= PARM_MAX_RTS_THRESHOLD ));
560         VALID_PARAM(( PARM_RTS_THRESHOLD4 <= PARM_MAX_RTS_THRESHOLD ));
561         VALID_PARAM(( PARM_RTS_THRESHOLD5 <= PARM_MAX_RTS_THRESHOLD ));
562         VALID_PARAM(( PARM_RTS_THRESHOLD6 <= PARM_MAX_RTS_THRESHOLD ));
563         VALID_PARAM(( PARM_TX_RATE1 >= PARM_MIN_TX_RATE ) && (PARM_TX_RATE1 <= PARM_MAX_TX_RATE ));
564         VALID_PARAM(( PARM_TX_RATE2 >= PARM_MIN_TX_RATE ) && (PARM_TX_RATE2 <= PARM_MAX_TX_RATE ));
565         VALID_PARAM(( PARM_TX_RATE3 >= PARM_MIN_TX_RATE ) && (PARM_TX_RATE3 <= PARM_MAX_TX_RATE ));
566         VALID_PARAM(( PARM_TX_RATE4 >= PARM_MIN_TX_RATE ) && (PARM_TX_RATE4 <= PARM_MAX_TX_RATE ));
567         VALID_PARAM(( PARM_TX_RATE5 >= PARM_MIN_TX_RATE ) && (PARM_TX_RATE5 <= PARM_MAX_TX_RATE ));
568         VALID_PARAM(( PARM_TX_RATE6 >= PARM_MIN_TX_RATE ) && (PARM_TX_RATE6 <= PARM_MAX_TX_RATE ));
569 #endif /* USE_WDS */
570
571         VALID_PARAM(( PARM_OWN_BEACON_INTERVAL >= PARM_MIN_OWN_BEACON_INTERVAL ) && ( PARM_OWN_BEACON_INTERVAL <= PARM_MAX_OWN_BEACON_INTERVAL ));
572         VALID_PARAM(( PARM_COEXISTENCE <= PARM_COEXISTENCE ));
573
574         /* Set the driver parameters from the passed in parameters. */
575
576         /* THESE MODULE PARAMETERS ARE TO BE DEPRECATED IN FAVOR OF A NAMING CONVENTION
577            WHICH IS INLINE WITH THE FORTHCOMING WAVELAN API */
578
579         /* START NEW PARAMETERS */
580
581         lp->Channel             = PARM_OWN_CHANNEL;
582         lp->DistanceBetweenAPs  = PARM_SYSTEM_SCALE;
583
584         /* Need to determine how to handle the new bands for 5GHz */
585         lp->TxRateControl[0]    = PARM_DEFAULT_TX_RATE_2GHZ;
586         lp->TxRateControl[1]    = PARM_DEFAULT_TX_RATE_5GHZ;
587
588         lp->RTSThreshold        = PARM_RTS_THRESHOLD;
589
590         /* Need to determine how to handle the new bands for 5GHz */
591         lp->MulticastRate[0]    = PARM_DEFAULT_MULTICAST_RATE_2GHZ;
592         lp->MulticastRate[1]    = PARM_DEFAULT_MULTICAST_RATE_5GHZ;
593
594         if ( strchr( "Yy", PARM_MICROWAVE_ROBUSTNESS[0] ) != NULL ) {
595                 lp->MicrowaveRobustness = 1;
596         } else {
597                 lp->MicrowaveRobustness = 0;
598         }
599         if ( PARM_DESIRED_SSID && ( strlen( PARM_DESIRED_SSID ) <= HCF_MAX_NAME_LEN )) {
600                 strcpy( lp->NetworkName, PARM_DESIRED_SSID );
601         }
602         if ( PARM_OWN_SSID && ( strlen( PARM_OWN_SSID ) <= HCF_MAX_NAME_LEN )) {
603                 strcpy( lp->NetworkName, PARM_OWN_SSID );
604         }
605         if ( PARM_OWN_NAME && ( strlen( PARM_OWN_NAME ) <= HCF_MAX_NAME_LEN )) {
606                 strcpy( lp->StationName, PARM_OWN_NAME );
607         }
608         lp->EnableEncryption = PARM_ENABLE_ENCRYPTION;
609         if ( PARM_KEY1 && ( strlen( PARM_KEY1 ) <= MAX_KEY_LEN )) {
610                 strcpy( lp->Key1, PARM_KEY1 );
611         }
612         if ( PARM_KEY2 && ( strlen( PARM_KEY2 ) <= MAX_KEY_LEN )) {
613                 strcpy( lp->Key2, PARM_KEY2 );
614         }
615         if ( PARM_KEY3 && ( strlen( PARM_KEY3 ) <= MAX_KEY_LEN )) {
616                 strcpy( lp->Key3, PARM_KEY3 );
617         }
618         if ( PARM_KEY4 && ( strlen( PARM_KEY4 ) <= MAX_KEY_LEN )) {
619                 strcpy( lp->Key4, PARM_KEY4 );
620         }
621
622         lp->TransmitKeyID = PARM_TX_KEY;
623
624         key_string2key( lp->Key1, &(lp->DefaultKeys.key[0] ));
625         key_string2key( lp->Key2, &(lp->DefaultKeys.key[1] ));
626         key_string2key( lp->Key3, &(lp->DefaultKeys.key[2] ));
627         key_string2key( lp->Key4, &(lp->DefaultKeys.key[3] ));
628
629         lp->DownloadFirmware = 1 ; //;?to be upgraded PARM_DOWNLOAD_FIRMWARE;
630         lp->AuthKeyMgmtSuite = PARM_AUTH_KEY_MGMT_SUITE;
631
632         if ( strchr( "Yy", PARM_LOAD_BALANCING[0] ) != NULL ) {
633                 lp->loadBalancing = 1;
634         } else {
635                 lp->loadBalancing = 0;
636         }
637
638         if ( strchr( "Yy", PARM_MEDIUM_DISTRIBUTION[0] ) != NULL ) {
639                 lp->mediumDistribution = 1;
640         } else {
641                 lp->mediumDistribution = 0;
642         }
643
644         lp->txPowLevel = PARM_TX_POW_LEVEL;
645
646         lp->srsc[0] = PARM_SRSC_2GHZ;
647         lp->srsc[1] = PARM_SRSC_5GHZ;
648         lp->brsc[0] = PARM_BRSC_2GHZ;
649         lp->brsc[1] = PARM_BRSC_5GHZ;
650 #if 1 //;? (HCF_TYPE) & HCF_TYPE_STA
651 //;?seems reasonable that even an AP-only driver could afford this small additional footprint
652         lp->PortType            = PARM_PORT_TYPE;
653         lp->MaxSleepDuration    = PARM_MAX_SLEEP;
654         lp->authentication      = PARM_AUTHENTICATION;
655         lp->atimWindow          = PARM_OWN_ATIM_WINDOW;
656         lp->holdoverDuration    = PARM_PM_HOLDOVER_DURATION;
657         lp->PMEnabled           = PARM_PM_ENABLED;  //;?
658         if ( strchr( "Yy", PARM_CREATE_IBSS[0] ) != NULL ) {
659                 lp->CreateIBSS = 1;
660         } else {
661                 lp->CreateIBSS = 0;
662         }
663         if ( strchr( "Nn", PARM_MULTICAST_RX[0] ) != NULL ) {
664                 lp->MulticastReceive = 0;
665         } else {
666                 lp->MulticastReceive = 1;
667         }
668         if ( strchr( "Yy", PARM_PROMISCUOUS_MODE[0] ) != NULL ) {
669                 lp->promiscuousMode = 1;
670         } else {
671                 lp->promiscuousMode = 0;
672         }
673         for( i = 0; i < ETH_ALEN; i++ ) {
674            lp->MACAddress[i] = PARM_NETWORK_ADDR[i];
675         }
676
677         lp->connectionControl = PARM_CONNECTION_CONTROL;
678
679 #endif /* HCF_STA */
680 #if 1 //;? (HCF_TYPE) & HCF_TYPE_AP
681         //;?should we restore this to allow smaller memory footprint
682         lp->DTIMPeriod = PARM_OWN_DTIM_PERIOD;
683
684         if ( strchr( "Yy", PARM_REJECT_ANY[0] ) != NULL ) {
685                 lp->RejectAny = 1;
686         } else {
687                 lp->RejectAny = 0;
688         }
689         if ( strchr( "Nn", PARM_EXCLUDE_UNENCRYPTED[0] ) != NULL ) {
690                 lp->ExcludeUnencrypted = 0;
691         } else {
692                 lp->ExcludeUnencrypted = 1;
693         }
694         if ( strchr( "Yy", PARM_MULTICAST_PM_BUFFERING[0] ) != NULL ) {
695                 lp->multicastPMBuffering = 1;
696         } else {
697                 lp->multicastPMBuffering = 0;
698         }
699         if ( strchr( "Yy", PARM_INTRA_BSS_RELAY[0] ) != NULL ) {
700                 lp->intraBSSRelay = 1;
701         } else {
702                 lp->intraBSSRelay = 0;
703         }
704
705         lp->ownBeaconInterval = PARM_OWN_BEACON_INTERVAL;
706         lp->coexistence       = PARM_COEXISTENCE;
707
708 #ifdef USE_WDS
709         lp->wds_port[0].rtsThreshold    = PARM_RTS_THRESHOLD1;
710         lp->wds_port[1].rtsThreshold    = PARM_RTS_THRESHOLD2;
711         lp->wds_port[2].rtsThreshold    = PARM_RTS_THRESHOLD3;
712         lp->wds_port[3].rtsThreshold    = PARM_RTS_THRESHOLD4;
713         lp->wds_port[4].rtsThreshold    = PARM_RTS_THRESHOLD5;
714         lp->wds_port[5].rtsThreshold    = PARM_RTS_THRESHOLD6;
715         lp->wds_port[0].txRateCntl      = PARM_TX_RATE1;
716         lp->wds_port[1].txRateCntl      = PARM_TX_RATE2;
717         lp->wds_port[2].txRateCntl      = PARM_TX_RATE3;
718         lp->wds_port[3].txRateCntl      = PARM_TX_RATE4;
719         lp->wds_port[4].txRateCntl      = PARM_TX_RATE5;
720         lp->wds_port[5].txRateCntl      = PARM_TX_RATE6;
721
722         for( i = 0; i < ETH_ALEN; i++ ) {
723                 lp->wds_port[0].wdsAddress[i] = PARM_WDS_ADDRESS1[i];
724         }
725         for( i = 0; i < ETH_ALEN; i++ ) {
726                 lp->wds_port[1].wdsAddress[i] = PARM_WDS_ADDRESS2[i];
727         }
728         for( i = 0; i < ETH_ALEN; i++ ) {
729                 lp->wds_port[2].wdsAddress[i] = PARM_WDS_ADDRESS3[i];
730         }
731         for( i = 0; i < ETH_ALEN; i++ ) {
732                 lp->wds_port[3].wdsAddress[i] = PARM_WDS_ADDRESS4[i];
733         }
734         for( i = 0; i < ETH_ALEN; i++ ) {
735                 lp->wds_port[4].wdsAddress[i] = PARM_WDS_ADDRESS5[i];
736         }
737         for( i = 0; i < ETH_ALEN; i++ ) {
738                 lp->wds_port[5].wdsAddress[i] = PARM_WDS_ADDRESS6[i];
739         }
740 #endif  /* USE_WDS */
741 #endif  /* HCF_AP */
742 #ifdef USE_RTS
743         if ( strchr( "Yy", useRTS[0] ) != NULL ) {
744                 lp->useRTS = 1;
745         } else {
746                 lp->useRTS = 0;
747         }
748 #endif  /* USE_RTS */
749
750
751         /* END NEW PARAMETERS */
752
753
754         wl_lock( lp, &flags );
755
756         /* Initialize the portState variable */
757         lp->portState = WVLAN_PORT_STATE_DISABLED;
758
759         /* Initialize the ScanResult struct */
760         memset( &( lp->scan_results ), 0, sizeof( lp->scan_results ));
761         lp->scan_results.scan_complete = FALSE;
762
763         /* Initialize the ProbeResult struct */
764         memset( &( lp->probe_results ), 0, sizeof( lp->probe_results ));
765         lp->probe_results.scan_complete = FALSE;
766         lp->probe_num_aps = 0;
767
768
769         /* Initialize Tx queue stuff */
770         memset( lp->txList, 0, sizeof( lp->txList ));
771
772         INIT_LIST_HEAD( &( lp->txFree ));
773
774         lp->txF.skb  = NULL;
775         lp->txF.port = 0;
776
777
778         for( i = 0; i < DEFAULT_NUM_TX_FRAMES; i++ ) {
779                 list_add_tail( &( lp->txList[i].node ), &( lp->txFree ));
780         }
781
782
783         for( i = 0; i < WVLAN_MAX_TX_QUEUES; i++ ) {
784                 INIT_LIST_HEAD( &( lp->txQ[i] ));
785         }
786
787         lp->netif_queue_on = TRUE;
788         lp->txQ_count = 0;
789         /* Initialize the use_dma element in the adapter structure. Not sure if
790            this should be a compile-time or run-time configurable. So for now,
791            implement as run-time and just define here */
792 #ifdef WARP
793 #ifdef ENABLE_DMA
794         DBG_TRACE( DbgInfo, "HERMES 2.5 BUSMASTER DMA MODE\n" );
795         lp->use_dma = 1;
796 #else
797         DBG_TRACE( DbgInfo, "HERMES 2.5 PORT I/O MODE\n" );
798         lp->use_dma = 0;
799 #endif // ENABLE_DMA
800 #endif // WARP
801
802         /* Register the ISR handler information here, so that it's not done
803            repeatedly in the ISR */
804         tasklet_init(&lp->task, wl_isr_handler, (unsigned long)lp);
805
806         /* Connect to the adapter */
807         DBG_TRACE( DbgInfo, "Calling hcf_connect()...\n" );
808         hcf_status = hcf_connect( &lp->hcfCtx, dev->base_addr );
809         //HCF_ERR_INCOMP_FW is acceptable, because download must still take place
810         //HCF_ERR_INCOMP_PRI is not acceptable
811         if ( hcf_status != HCF_SUCCESS && hcf_status != HCF_ERR_INCOMP_FW ) {
812                 DBG_ERROR( DbgInfo, "hcf_connect() failed, status: 0x%x\n", hcf_status );
813                 wl_unlock( lp, &flags );
814                 goto hcf_failed;
815         }
816
817         //;?should set HCF_version and how about driver_stat
818         lp->driverInfo.IO_address       = dev->base_addr;
819         lp->driverInfo.IO_range         = HCF_NUM_IO_PORTS;     //;?conditionally 0x40 or 0x80 seems better
820         lp->driverInfo.IRQ_number       = dev->irq;
821         lp->driverInfo.card_stat        = lp->hcfCtx.IFB_CardStat;
822         //;? what happened to frame_type
823
824         /* Fill in the driver identity structure */
825         lp->driverIdentity.len              = ( sizeof( lp->driverIdentity ) / sizeof( hcf_16 )) - 1;
826         lp->driverIdentity.typ              = CFG_DRV_IDENTITY;
827         lp->driverIdentity.comp_id          = DRV_IDENTITY;
828         lp->driverIdentity.variant          = DRV_VARIANT;
829         lp->driverIdentity.version_major    = DRV_MAJOR_VERSION;
830         lp->driverIdentity.version_minor    = DRV_MINOR_VERSION;
831
832
833         /* Start the card here - This needs to be done in order to get the
834            MAC address for the network layer */
835         DBG_TRACE( DbgInfo, "Calling wvlan_go() to perform a card reset...\n" );
836         hcf_status = wl_go( lp );
837
838         if ( hcf_status != HCF_SUCCESS ) {
839                 DBG_ERROR( DbgInfo, "wl_go() failed\n" );
840                 wl_unlock( lp, &flags );
841                 goto hcf_failed;
842         }
843
844         /* Certain RIDs must be set before enabling the ports */
845         wl_put_ltv_init( lp );
846
847 #if 0 //;?why was this already commented out in wl_lkm_720
848         /* Enable the ports */
849         if ( wl_adapter_is_open( lp->dev )) {
850                 /* Enable the ports */
851                 DBG_TRACE( DbgInfo, "Enabling Port 0\n" );
852                 hcf_status = wl_enable( lp );
853
854                 if ( hcf_status != HCF_SUCCESS ) {
855                         DBG_TRACE( DbgInfo, "Enable port 0 failed: 0x%x\n", hcf_status );
856                 }
857
858 #if (HCF_TYPE) & HCF_TYPE_AP
859                 DBG_TRACE( DbgInfo, "Enabling WDS Ports\n" );
860                 //wl_enable_wds_ports( lp );
861 #endif  /* (HCF_TYPE) & HCF_TYPE_AP */
862
863         }
864 #endif
865
866         /* Fill out the MAC address information in the net_device struct */
867         memcpy( lp->dev->dev_addr, lp->MACAddress, ETH_ALEN );
868         dev->addr_len = ETH_ALEN;
869
870         lp->is_registered = TRUE;
871
872 #ifdef USE_PROFILE
873         /* Parse the config file for the sake of creating WDS ports if WDS is
874            configured there but not in the module options */
875         parse_config( dev );
876 #endif  /* USE_PROFILE */
877
878         /* If we're going into AP Mode, register the "virtual" ethernet devices
879            needed for WDS */
880         WL_WDS_NETDEV_REGISTER( lp );
881
882         /* Reset the DownloadFirmware variable in the private struct. If the
883            config file is not used, this will not matter; if it is used, it
884            will be reparsed in wl_open(). This is done because logic in wl_open
885            used to check if a firmware download is needed is broken by parsing
886            the file here; however, this parsing is needed to register WDS ports
887            in AP mode, if they are configured */
888         lp->DownloadFirmware = WVLAN_DRV_MODE_STA; //;?download_firmware;
889
890 #ifdef USE_RTS
891         if ( lp->useRTS == 1 ) {
892                 DBG_TRACE( DbgInfo, "ENTERING RTS MODE...\n" );
893                 wl_act_int_off( lp );
894                 lp->is_handling_int = WL_NOT_HANDLING_INT; // Not handling interrupts anymore
895
896                 wl_disable( lp );
897
898                 hcf_connect( &lp->hcfCtx, HCF_DISCONNECT);
899         }
900 #endif  /* USE_RTS */
901
902         wl_unlock( lp, &flags );
903
904         DBG_TRACE( DbgInfo, "%s: Wireless, io_addr %#03lx, irq %d, ""mac_address ",
905                            dev->name, dev->base_addr, dev->irq );
906
907         for( i = 0; i < ETH_ALEN; i++ ) {
908                 printk( "%02X%c", dev->dev_addr[i], (( i < ( ETH_ALEN-1 )) ? ':' : '\n' ));
909         }
910
911 #if 0 //SCULL_USE_PROC /* don't waste space if unused */
912         create_proc_read_entry( "wlags", 0, NULL, scull_read_procmem, dev );
913         proc_mkdir("driver/wlags49", 0);
914         proc_write("driver/wlags49/wlags49_type", write_int, &lp->wlags49_type);
915 #endif /* SCULL_USE_PROC */
916
917         DBG_LEAVE( DbgInfo );
918         return result;
919
920 hcf_failed:
921         wl_hcf_error( dev, hcf_status );
922
923 failed:
924
925         DBG_ERROR( DbgInfo, "wl_insert() FAILED\n" );
926
927         if ( lp->is_registered == TRUE ) {
928                 lp->is_registered = FALSE;
929         }
930
931         WL_WDS_NETDEV_DEREGISTER( lp );
932
933         result = -EFAULT;
934
935
936         DBG_LEAVE( DbgInfo );
937         return result;
938 } // wl_insert
939 /*============================================================================*/
940
941
942 /*******************************************************************************
943  *      wl_reset()
944  *******************************************************************************
945  *
946  *  DESCRIPTION:
947  *
948  *      Reset the adapter.
949  *
950  *  PARAMETERS:
951  *
952  *      dev - a pointer to the net_device struct of the wireless device
953  *
954  *  RETURNS:
955  *
956  *      an HCF status code
957  *
958  ******************************************************************************/
959 int wl_reset(struct net_device *dev)
960 {
961         struct wl_private  *lp = wl_priv(dev);
962         int                 hcf_status = HCF_SUCCESS;
963         /*------------------------------------------------------------------------*/
964         DBG_FUNC( "wl_reset" );
965         DBG_ENTER( DbgInfo );
966         DBG_PARAM( DbgInfo, "dev", "%s (0x%p)", dev->name, dev );
967         DBG_PARAM( DbgInfo, "dev->base_addr", "(%#03lx)", dev->base_addr );
968
969         /*
970          * The caller should already have a lock and
971          * disable the interrupts, we do not lock here,
972          * nor do we enable/disable interrupts!
973          */
974
975         DBG_TRACE( DbgInfo, "Device Base Address: %#03lx\n", dev->base_addr );
976         if ( dev->base_addr ) {
977                 /* Shutdown the adapter. */
978                 hcf_connect( &lp->hcfCtx, HCF_DISCONNECT );
979
980                 /* Reset the driver information. */
981                 lp->txBytes = 0;
982
983                 /* Connect to the adapter. */
984                 hcf_status = hcf_connect( &lp->hcfCtx, dev->base_addr );
985                 if ( hcf_status != HCF_SUCCESS && hcf_status != HCF_ERR_INCOMP_FW ) {
986                         DBG_ERROR( DbgInfo, "hcf_connect() failed, status: 0x%x\n", hcf_status );
987                         goto out;
988                 }
989
990                 /* Check if firmware is present, if not change state */
991                 if ( hcf_status == HCF_ERR_INCOMP_FW ) {
992                         lp->firmware_present = WL_FRIMWARE_NOT_PRESENT;
993                 }
994
995                 /* Initialize the portState variable */
996                 lp->portState = WVLAN_PORT_STATE_DISABLED;
997
998                 /* Restart the adapter. */
999                 hcf_status = wl_go( lp );
1000                 if ( hcf_status != HCF_SUCCESS ) {
1001                         DBG_ERROR( DbgInfo, "wl_go() failed, status: 0x%x\n", hcf_status );
1002                         goto out;
1003                 }
1004
1005                 /* Certain RIDs must be set before enabling the ports */
1006                 wl_put_ltv_init( lp );
1007         } else {
1008                 DBG_ERROR( DbgInfo, "Device Base Address INVALID!!!\n" );
1009         }
1010
1011 out:
1012         DBG_LEAVE( DbgInfo );
1013         return hcf_status;
1014 } // wl_reset
1015 /*============================================================================*/
1016
1017
1018 /*******************************************************************************
1019  *      wl_go()
1020  *******************************************************************************
1021  *
1022  *  DESCRIPTION:
1023  *
1024  *      Reset the adapter.
1025  *
1026  *  PARAMETERS:
1027  *
1028  *      dev - a pointer to the net_device struct of the wireless device
1029  *
1030  *  RETURNS:
1031  *
1032  *      an HCF status code
1033  *
1034  ******************************************************************************/
1035 int wl_go( struct wl_private *lp )
1036 {
1037         int     hcf_status = HCF_SUCCESS;
1038         char    *cp = NULL;                     //fw_image
1039         int     retries = 0;
1040         /*------------------------------------------------------------------------*/
1041         DBG_FUNC( "wl_go" );
1042         DBG_ENTER( DbgInfo );
1043
1044         hcf_status = wl_disable( lp );
1045         if ( hcf_status != HCF_SUCCESS ) {
1046                 DBG_TRACE( DbgInfo, "Disable port 0 failed: 0x%x\n", hcf_status );
1047
1048                 while (( hcf_status != HCF_SUCCESS ) && (retries < 10)) {
1049                         retries++;
1050                         hcf_status = wl_disable( lp );
1051                 }
1052                 if ( hcf_status == HCF_SUCCESS ) {
1053                         DBG_TRACE( DbgInfo, "Disable port 0 succes : %d retries\n", retries );
1054                 } else {
1055                         DBG_TRACE( DbgInfo, "Disable port 0 failed after: %d retries\n", retries );
1056                 }
1057         }
1058
1059 #if 1 //;? (HCF_TYPE) & HCF_TYPE_AP
1060         //DBG_TRACE( DbgInfo, "Disabling WDS Ports\n" );
1061         //wl_disable_wds_ports( lp );
1062 #endif  /* (HCF_TYPE) & HCF_TYPE_AP */
1063
1064 //;?what was the purpose of this
1065 //      /* load the appropriate firmware image, depending on driver mode */
1066 //      lp->ltvRecord.len   = ( sizeof( CFG_RANGE20_STRCT ) / sizeof( hcf_16 )) - 1;
1067 //      lp->ltvRecord.typ   = CFG_DRV_ACT_RANGES_PRI;
1068 //      hcf_get_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1069
1070 #if BIN_DL
1071         if ( strlen( lp->fw_image_filename ) ) {
1072 mm_segment_t    fs;
1073 int                     file_desc;
1074 int                     rc;
1075
1076                 DBG_TRACE( DbgInfo, "F/W image:%s:\n", lp->fw_image_filename );
1077                 /* Obtain a user-space process context, storing the original context */
1078                 fs = get_fs( );
1079                 set_fs( get_ds( ));
1080                 file_desc = open( lp->fw_image_filename, O_RDONLY, 0 );
1081                 if ( file_desc == -1 ) {
1082                         DBG_ERROR( DbgInfo, "No image file found\n" );
1083                 } else {
1084                         DBG_TRACE( DbgInfo, "F/W image file found\n" );
1085 #define DHF_ALLOC_SIZE 96000                    //just below 96K, let's hope it suffices for now and for the future
1086                         cp = (char*)vmalloc( DHF_ALLOC_SIZE );
1087                         if ( cp == NULL ) {
1088                                 DBG_ERROR( DbgInfo, "error in vmalloc\n" );
1089                         } else {
1090                                 rc = read( file_desc, cp, DHF_ALLOC_SIZE );
1091                                 if ( rc == DHF_ALLOC_SIZE ) {
1092                                         DBG_ERROR( DbgInfo, "buffer too small, %d\n", DHF_ALLOC_SIZE );
1093                                 } else if ( rc > 0 ) {
1094                                         DBG_TRACE( DbgInfo, "read O.K.: %d bytes  %.12s\n", rc, cp );
1095                                         rc = read( file_desc, &cp[rc], 1 );
1096                                         if ( rc == 0 ) { //;/change to an until-loop at rc<=0
1097                                                 DBG_TRACE( DbgInfo, "no more to read\n" );
1098                                         }
1099                                 }
1100                                 if ( rc != 0 ) {
1101                                         DBG_ERROR( DbgInfo, "file not read in one swoop or other error"\
1102                                                                                 ", give up, too complicated, rc = %0X\n", rc );
1103                                         DBG_ERROR( DbgInfo, "still have to change code to get a real download now !!!!!!!!\n" );
1104                                 } else {
1105                                         DBG_TRACE( DbgInfo, "before dhf_download_binary\n" );
1106                                         hcf_status = dhf_download_binary( (memimage *)cp );
1107                                         DBG_TRACE( DbgInfo, "after dhf_download_binary, before dhf_download_fw\n" );
1108                                         //;?improve error flow/handling
1109                                         hcf_status = dhf_download_fw( &lp->hcfCtx, (memimage *)cp );
1110                                         DBG_TRACE( DbgInfo, "after dhf_download_fw\n" );
1111                                 }
1112                                 vfree( cp );
1113                         }
1114                         close( file_desc );
1115                 }
1116                 set_fs( fs );                   /* Return to the original context */
1117         }
1118 #endif // BIN_DL
1119
1120         /* If firmware is present but the type is unknown then download anyway */
1121         if ( (lp->firmware_present == WL_FRIMWARE_PRESENT)
1122              &&
1123              ( CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.comp_id ) != COMP_ID_FW_STA )
1124              &&
1125              ( CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.comp_id ) != COMP_ID_FW_AP ) ) {
1126                 /* Unknown type, download needed.  */
1127                 lp->firmware_present = WL_FRIMWARE_NOT_PRESENT;
1128         }
1129
1130         if(lp->firmware_present == WL_FRIMWARE_NOT_PRESENT)
1131         {
1132                 if ( cp == NULL ) {
1133                         DBG_TRACE( DbgInfo, "Downloading STA firmware...\n" );
1134 //                      hcf_status = dhf_download_fw( &lp->hcfCtx, &station );
1135                         hcf_status = dhf_download_fw( &lp->hcfCtx, &fw_image );
1136                 }
1137                 if ( hcf_status != HCF_SUCCESS ) {
1138                         DBG_ERROR( DbgInfo, "Firmware Download failed\n" );
1139                         DBG_LEAVE( DbgInfo );
1140                         return hcf_status;
1141                 }
1142         }
1143         /* Report the FW versions */
1144         //;?obsolete, use the available IFB info:: wl_get_pri_records( lp );
1145         if ( CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.comp_id ) == COMP_ID_FW_STA  ) {
1146                 DBG_TRACE( DbgInfo, "downloaded station F/W\n" );
1147         } else if ( CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.comp_id ) == COMP_ID_FW_AP  ) {
1148                 DBG_TRACE( DbgInfo, "downloaded AP F/W\n" );
1149         } else {
1150                 DBG_ERROR( DbgInfo, "unknown F/W type\n" );
1151         }
1152
1153         /*
1154          * Downloaded, no need to repeat this next time, assume the
1155          * contents stays in the card until it is powered off. Note we
1156          * do not switch firmware on the fly, the firmware is fixed in
1157          * the driver for now.
1158          */
1159         lp->firmware_present = WL_FRIMWARE_PRESENT;
1160
1161         DBG_TRACE( DbgInfo, "ComponentID:%04x variant:%04x major:%04x minor:%04x\n",
1162                                 CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.comp_id ),
1163                                 CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.variant ),
1164                                 CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.version_major ),
1165                                 CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.version_minor ));
1166
1167         /* now we wil get the MAC address of the card */
1168         lp->ltvRecord.len = 4;
1169         if ( CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.comp_id ) == COMP_ID_FW_AP  ) {
1170                 lp->ltvRecord.typ = CFG_NIC_MAC_ADDR;
1171         } else
1172         {
1173                 lp->ltvRecord.typ = CFG_CNF_OWN_MAC_ADDR;
1174         }
1175         hcf_status = hcf_get_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1176         if ( hcf_status != HCF_SUCCESS ) {
1177                 DBG_ERROR( DbgInfo, "Could not retrieve MAC address\n" );
1178                 DBG_LEAVE( DbgInfo );
1179                 return hcf_status;
1180         }
1181         memcpy( lp->MACAddress, &lp->ltvRecord.u.u8[0], ETH_ALEN );
1182         DBG_TRACE(DbgInfo, "Card MAC Address: %pM\n", lp->MACAddress);
1183
1184         /* Write out configuration to the device, enable, and reconnect. However,
1185            only reconnect if in AP mode. For STA mode, need to wait for passive scan
1186            completion before a connect can be issued */
1187         wl_put_ltv( lp );
1188         /* Enable the ports */
1189         hcf_status = wl_enable( lp );
1190
1191         if ( lp->DownloadFirmware == WVLAN_DRV_MODE_AP ) {
1192 #ifdef USE_WDS
1193                 wl_enable_wds_ports( lp );
1194 #endif // USE_WDS
1195                 hcf_status = wl_connect( lp );
1196         }
1197         DBG_LEAVE( DbgInfo );
1198         return hcf_status;
1199 } // wl_go
1200 /*============================================================================*/
1201
1202
1203 /*******************************************************************************
1204  *      wl_set_wep_keys()
1205  *******************************************************************************
1206  *
1207  *  DESCRIPTION:
1208  *
1209  *      Write TxKeyID and WEP keys to the adapter. This is separated from
1210  *  wl_apply() to allow dynamic WEP key updates through the wireless
1211  *  extensions.
1212  *
1213  *  PARAMETERS:
1214  *
1215  *      lp  - a pointer to the wireless adapter's private structure
1216  *
1217  *  RETURNS:
1218  *
1219  *      N/A
1220  *
1221  ******************************************************************************/
1222 void wl_set_wep_keys( struct wl_private *lp )
1223 {
1224         int count = 0;
1225         /*------------------------------------------------------------------------*/
1226         DBG_FUNC( "wl_set_wep_keys" );
1227         DBG_ENTER( DbgInfo );
1228         DBG_PARAM( DbgInfo, "lp", "%s (0x%p)", lp->dev->name, lp );
1229         if ( lp->EnableEncryption ) {
1230                 /* NOTE: CFG_CNF_ENCRYPTION is set in wl_put_ltv() as it's a static
1231                                  RID */
1232
1233                 /* set TxKeyID */
1234                 lp->ltvRecord.len = 2;
1235                 lp->ltvRecord.typ       = CFG_TX_KEY_ID;
1236                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE(lp->TransmitKeyID - 1);
1237
1238                 hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1239
1240                 DBG_TRACE( DbgInfo, "Key 1 len: %d\n", lp->DefaultKeys.key[0].len );
1241                 DBG_TRACE( DbgInfo, "Key 2 len: %d\n", lp->DefaultKeys.key[1].len );
1242                 DBG_TRACE( DbgInfo, "Key 3 len: %d\n", lp->DefaultKeys.key[2].len );
1243                 DBG_TRACE( DbgInfo, "Key 4 len: %d\n", lp->DefaultKeys.key[3].len );
1244
1245                 /* write keys */
1246                 lp->DefaultKeys.len = sizeof( lp->DefaultKeys ) / sizeof( hcf_16 ) - 1;
1247                 lp->DefaultKeys.typ = CFG_DEFAULT_KEYS;
1248
1249                 /* endian translate the appropriate key information */
1250                 for( count = 0; count < MAX_KEYS; count++ ) {
1251                         lp->DefaultKeys.key[count].len = CNV_INT_TO_LITTLE( lp->DefaultKeys.key[count].len );
1252                 }
1253
1254                 hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->DefaultKeys ));
1255
1256                 /* Reverse the above endian translation, since these keys are accessed
1257                    elsewhere */
1258                 for( count = 0; count < MAX_KEYS; count++ ) {
1259                         lp->DefaultKeys.key[count].len = CNV_INT_TO_LITTLE( lp->DefaultKeys.key[count].len );
1260                 }
1261
1262                 DBG_NOTICE( DbgInfo, "encrypt: %d, ID: %d\n", lp->EnableEncryption, lp->TransmitKeyID );
1263                 DBG_NOTICE( DbgInfo, "set key: %s(%d) [%d]\n", lp->DefaultKeys.key[lp->TransmitKeyID-1].key, lp->DefaultKeys.key[lp->TransmitKeyID-1].len, lp->TransmitKeyID-1 );
1264         }
1265
1266         DBG_LEAVE( DbgInfo );
1267 } // wl_set_wep_keys
1268 /*============================================================================*/
1269
1270
1271 /*******************************************************************************
1272  *      wl_apply()
1273  *******************************************************************************
1274  *
1275  *  DESCRIPTION:
1276  *
1277  *      Write the parameters to the adapter. (re-)enables the card if device is
1278  *  open. Returns hcf_status of hcf_enable().
1279  *
1280  *  PARAMETERS:
1281  *
1282  *      lp  - a pointer to the wireless adapter's private structure
1283  *
1284  *  RETURNS:
1285  *
1286  *      an HCF status code
1287  *
1288  ******************************************************************************/
1289 int wl_apply(struct wl_private *lp)
1290 {
1291         int hcf_status = HCF_SUCCESS;
1292         /*------------------------------------------------------------------------*/
1293         DBG_FUNC( "wl_apply" );
1294         DBG_ENTER( DbgInfo );
1295         DBG_ASSERT( lp != NULL);
1296         DBG_PARAM( DbgInfo, "lp", "%s (0x%p)", lp->dev->name, lp );
1297
1298         if ( !( lp->flags & WVLAN2_UIL_BUSY )) {
1299                 /* The adapter parameters have changed:
1300                                 disable card
1301                                 reload parameters
1302                                 enable card
1303                 */
1304
1305                 if ( wl_adapter_is_open( lp->dev )) {
1306                         /* Disconnect and disable if necessary */
1307                         hcf_status = wl_disconnect( lp );
1308                         if ( hcf_status != HCF_SUCCESS ) {
1309                                 DBG_ERROR( DbgInfo, "Disconnect failed\n" );
1310                                 DBG_LEAVE( DbgInfo );
1311                                 return -1;
1312                         }
1313                         hcf_status = wl_disable( lp );
1314                         if ( hcf_status != HCF_SUCCESS ) {
1315                                 DBG_ERROR( DbgInfo, "Disable failed\n" );
1316                                 DBG_LEAVE( DbgInfo );
1317                                 return -1;
1318                         } else {
1319                                 /* Write out configuration to the device, enable, and reconnect.
1320                                    However, only reconnect if in AP mode. For STA mode, need to
1321                                    wait for passive scan completion before a connect can be
1322                                    issued */
1323                                 hcf_status = wl_put_ltv( lp );
1324
1325                                 if ( hcf_status == HCF_SUCCESS ) {
1326                                         hcf_status = wl_enable( lp );
1327
1328                                         if ( CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.comp_id ) == COMP_ID_FW_AP  ) {
1329                                                 hcf_status = wl_connect( lp );
1330                                         }
1331                                 } else {
1332                                         DBG_WARNING( DbgInfo, "wl_put_ltv() failed\n" );
1333                                 }
1334                         }
1335                 }
1336         }
1337
1338         DBG_LEAVE( DbgInfo );
1339         return hcf_status;
1340 } // wl_apply
1341 /*============================================================================*/
1342
1343
1344 /*******************************************************************************
1345  *      wl_put_ltv_init()
1346  *******************************************************************************
1347  *
1348  *  DESCRIPTION:
1349  *
1350  *      Used to set basic parameters for card initialization.
1351  *
1352  *  PARAMETERS:
1353  *
1354  *      lp  - a pointer to the wireless adapter's private structure
1355  *
1356  *  RETURNS:
1357  *
1358  *      an HCF status code
1359  *
1360  ******************************************************************************/
1361 int wl_put_ltv_init( struct wl_private *lp )
1362 {
1363         int i;
1364         int hcf_status;
1365         CFG_RID_LOG_STRCT *RidLog;
1366         /*------------------------------------------------------------------------*/
1367         DBG_FUNC( "wl_put_ltv_init" );
1368         DBG_ENTER( DbgInfo );
1369         if ( lp == NULL ) {
1370                 DBG_ERROR( DbgInfo, "lp pointer is NULL\n" );
1371                 DBG_LEAVE( DbgInfo );
1372                 return -1;
1373         }
1374         /* DMA/IO */
1375         lp->ltvRecord.len = 2;
1376         lp->ltvRecord.typ = CFG_CNTL_OPT;
1377
1378         /* The Card Services build must ALWAYS configure for 16-bit I/O. PCI or
1379            CardBus can be set to either 16/32 bit I/O, or Bus Master DMA, but only
1380            for Hermes-2.5 */
1381 #ifdef BUS_PCMCIA
1382         lp->ltvRecord.u.u16[0] = CNV_INT_TO_LITTLE( USE_16BIT );
1383 #else
1384         if ( lp->use_dma ) {
1385                 lp->ltvRecord.u.u16[0] = CNV_INT_TO_LITTLE( USE_DMA );
1386         } else {
1387                 lp->ltvRecord.u.u16[0] = CNV_INT_TO_LITTLE( 0 );
1388         }
1389
1390 #endif
1391         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1392         DBG_TRACE( DbgInfo, "CFG_CNTL_OPT                      : 0x%04x\n",
1393                            lp->ltvRecord.u.u16[0] );
1394         DBG_TRACE( DbgInfo, "CFG_CNTL_OPT result               : 0x%04x\n",
1395                            hcf_status );
1396
1397         /* Register the list of RIDs on which asynchronous notification is
1398            required. Note that this mechanism replaces the mailbox, so the mailbox
1399            can be queried by the host (if desired) without contention from us */
1400         i=0;
1401
1402         lp->RidList[i].len     = sizeof( lp->ProbeResp );
1403         lp->RidList[i].typ     = CFG_ACS_SCAN;
1404         lp->RidList[i].bufp    = (wci_recordp)&lp->ProbeResp;
1405         //lp->ProbeResp.infoType = 0xFFFF;
1406         i++;
1407
1408         lp->RidList[i].len     = sizeof( lp->assoc_stat );
1409         lp->RidList[i].typ     = CFG_ASSOC_STAT;
1410         lp->RidList[i].bufp    = (wci_recordp)&lp->assoc_stat;
1411         lp->assoc_stat.len     = 0xFFFF;
1412         i++;
1413
1414         lp->RidList[i].len     = 4;
1415         lp->RidList[i].typ     = CFG_UPDATED_INFO_RECORD;
1416         lp->RidList[i].bufp    = (wci_recordp)&lp->updatedRecord;
1417         lp->updatedRecord.len  = 0xFFFF;
1418         i++;
1419
1420         lp->RidList[i].len     = sizeof( lp->sec_stat );
1421         lp->RidList[i].typ     = CFG_SECURITY_STAT;
1422         lp->RidList[i].bufp    = (wci_recordp)&lp->sec_stat;
1423         lp->sec_stat.len       = 0xFFFF;
1424         i++;
1425
1426         lp->RidList[i].typ     = 0;    // Terminate List
1427
1428         RidLog = (CFG_RID_LOG_STRCT *)&lp->ltvRecord;
1429         RidLog->len     = 3;
1430         RidLog->typ     = CFG_REG_INFO_LOG;
1431         RidLog->recordp = (RID_LOGP)&lp->RidList[0];
1432
1433         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1434         DBG_TRACE( DbgInfo, "CFG_REG_INFO_LOG\n" );
1435         DBG_TRACE( DbgInfo, "CFG_REG_INFO_LOG result           : 0x%04x\n",
1436                            hcf_status );
1437         DBG_LEAVE( DbgInfo );
1438         return hcf_status;
1439 } // wl_put_ltv_init
1440 /*============================================================================*/
1441
1442
1443 /*******************************************************************************
1444  *      wl_put_ltv()
1445  *******************************************************************************
1446  *
1447  *  DESCRIPTION:
1448  *
1449  *      Used by wvlan_apply() and wvlan_go to set the card's configuration.
1450  *
1451  *  PARAMETERS:
1452  *
1453  *      lp  - a pointer to the wireless adapter's private structure
1454  *
1455  *  RETURNS:
1456  *
1457  *      an HCF status code
1458  *
1459  ******************************************************************************/
1460 int wl_put_ltv( struct wl_private *lp )
1461 {
1462         int len;
1463         int hcf_status;
1464         /*------------------------------------------------------------------------*/
1465         DBG_FUNC( "wl_put_ltv" );
1466         DBG_ENTER( DbgInfo );
1467
1468         if ( lp == NULL ) {
1469                 DBG_ERROR( DbgInfo, "lp pointer is NULL\n" );
1470                 return -1;
1471         }
1472         if ( CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.comp_id ) == COMP_ID_FW_AP  ) {
1473                 lp->maxPort = 6;                        //;?why set this here and not as part of download process
1474         } else {
1475                 lp->maxPort = 0;
1476         }
1477
1478         /* Send our configuration to the card. Perform any endian translation
1479            necessary */
1480         /* Register the Mailbox; VxWorks does this elsewhere; why;? */
1481         lp->ltvRecord.len       = 4;
1482         lp->ltvRecord.typ       = CFG_REG_MB;
1483         lp->ltvRecord.u.u32[0]  = (u_long)&( lp->mailbox );
1484         lp->ltvRecord.u.u16[2]  = ( MB_SIZE / sizeof( hcf_16 ));
1485         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1486
1487         /* Max Data Length */
1488         lp->ltvRecord.len       = 2;
1489         lp->ltvRecord.typ       = CFG_CNF_MAX_DATA_LEN;
1490         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( HCF_MAX_PACKET_SIZE );
1491         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1492
1493         /* System Scale / Distance between APs */
1494         lp->ltvRecord.len       = 2;
1495         lp->ltvRecord.typ       = CFG_CNF_SYSTEM_SCALE;
1496         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->DistanceBetweenAPs );
1497         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1498
1499         /* Channel */
1500         if ( lp->CreateIBSS && ( lp->Channel == 0 )) {
1501                 DBG_TRACE( DbgInfo, "Create IBSS" );
1502                 lp->Channel = 10;
1503         }
1504         lp->ltvRecord.len       = 2;
1505         lp->ltvRecord.typ       = CFG_CNF_OWN_CHANNEL;
1506         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->Channel );
1507         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1508
1509         /* Microwave Robustness */
1510         lp->ltvRecord.len       = 2;
1511         lp->ltvRecord.typ       = CFG_CNF_MICRO_WAVE;
1512         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->MicrowaveRobustness );
1513         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1514
1515         /* Load Balancing */
1516         lp->ltvRecord.len       = 2;
1517         lp->ltvRecord.typ       = CFG_CNF_LOAD_BALANCING;
1518         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->loadBalancing );
1519         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1520
1521         /* Medium Distribution */
1522         lp->ltvRecord.len       = 2;
1523         lp->ltvRecord.typ       = CFG_CNF_MEDIUM_DISTRIBUTION;
1524         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->mediumDistribution );
1525         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1526         /* Country Code */
1527
1528 #ifdef WARP
1529         /* Tx Power Level (for supported cards) */
1530         lp->ltvRecord.len       = 2;
1531         lp->ltvRecord.typ       = CFG_CNF_TX_POW_LVL;
1532         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->txPowLevel );
1533         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1534
1535         /* Short Retry Limit */
1536         /*lp->ltvRecord.len       = 2;
1537         lp->ltvRecord.typ       = 0xFC32;
1538         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->shortRetryLimit );
1539         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1540         */
1541
1542         /* Long Retry Limit */
1543         /*lp->ltvRecord.len       = 2;
1544         lp->ltvRecord.typ       = 0xFC33;
1545         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->longRetryLimit );
1546         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1547         */
1548
1549         /* Supported Rate Set Control */
1550         lp->ltvRecord.len       = 3;
1551         lp->ltvRecord.typ       = CFG_SUPPORTED_RATE_SET_CNTL; //0xFC88;
1552         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->srsc[0] );
1553         lp->ltvRecord.u.u16[1]  = CNV_INT_TO_LITTLE( lp->srsc[1] );
1554         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1555
1556         /* Basic Rate Set Control */
1557         lp->ltvRecord.len       = 3;
1558         lp->ltvRecord.typ       = CFG_BASIC_RATE_SET_CNTL; //0xFC89;
1559         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->brsc[0] );
1560         lp->ltvRecord.u.u16[1]  = CNV_INT_TO_LITTLE( lp->brsc[1] );
1561         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1562
1563         /* Frame Burst Limit */
1564         /* Defined, but not currently available in Firmware */
1565
1566 #endif // WARP
1567
1568 #ifdef WARP
1569         /* Multicast Rate */
1570         lp->ltvRecord.len       = 3;
1571         lp->ltvRecord.typ       = CFG_CNF_MCAST_RATE;
1572         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->MulticastRate[0] );
1573         lp->ltvRecord.u.u16[1]  = CNV_INT_TO_LITTLE( lp->MulticastRate[1] );
1574 #else
1575         lp->ltvRecord.len       = 2;
1576         lp->ltvRecord.typ       = CFG_CNF_MCAST_RATE;
1577         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->MulticastRate[0] );
1578 #endif // WARP
1579         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1580
1581         /* Own Name (Station Nickname) */
1582         if (( len = ( strlen( lp->StationName ) + 1 ) & ~0x01 ) != 0 ) {
1583                 //DBG_TRACE( DbgInfo, "CFG_CNF_OWN_NAME                  : %s\n",
1584                 //           lp->StationName );
1585
1586                 lp->ltvRecord.len       = 2 + ( len / sizeof( hcf_16 ));
1587                 lp->ltvRecord.typ       = CFG_CNF_OWN_NAME;
1588                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( strlen( lp->StationName ));
1589
1590                 memcpy( &( lp->ltvRecord.u.u8[2] ), lp->StationName, len );
1591         } else {
1592                 //DBG_TRACE( DbgInfo, "CFG_CNF_OWN_NAME                  : EMPTY\n" );
1593
1594                 lp->ltvRecord.len       = 2;
1595                 lp->ltvRecord.typ       = CFG_CNF_OWN_NAME;
1596                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( 0 );
1597         }
1598
1599         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1600
1601         //DBG_TRACE( DbgInfo, "CFG_CNF_OWN_NAME result           : 0x%04x\n",
1602         //           hcf_status );
1603
1604         /* The following are set in STA mode only */
1605         if ( CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.comp_id ) == COMP_ID_FW_STA  ) {
1606
1607                 /* RTS Threshold */
1608                 lp->ltvRecord.len       = 2;
1609                 lp->ltvRecord.typ       = CFG_RTS_THRH;
1610                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->RTSThreshold );
1611                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1612
1613                 /* Port Type */
1614                 lp->ltvRecord.len       = 2;
1615                 lp->ltvRecord.typ       = CFG_CNF_PORT_TYPE;
1616                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->PortType );
1617                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1618
1619                 /* Tx Rate Control */
1620 #ifdef WARP
1621                 lp->ltvRecord.len       = 3;
1622                 lp->ltvRecord.typ       = CFG_TX_RATE_CNTL;
1623                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->TxRateControl[0] );
1624                 lp->ltvRecord.u.u16[1]  = CNV_INT_TO_LITTLE( lp->TxRateControl[1] );
1625 #else
1626                 lp->ltvRecord.len       = 2;
1627                 lp->ltvRecord.typ       = CFG_TX_RATE_CNTL;
1628                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->TxRateControl[0] );
1629 #endif  // WARP
1630
1631 //;?skip temporarily to see whether the RID or something else is the probelm hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1632
1633                 DBG_TRACE( DbgInfo, "CFG_TX_RATE_CNTL 2.4GHz           : 0x%04x\n",
1634                                    lp->TxRateControl[0] );
1635                 DBG_TRACE( DbgInfo, "CFG_TX_RATE_CNTL 5.0GHz           : 0x%04x\n",
1636                                    lp->TxRateControl[1] );
1637                 DBG_TRACE( DbgInfo, "CFG_TX_RATE_CNTL result           : 0x%04x\n",
1638                                    hcf_status );
1639                 /* Power Management */
1640                 lp->ltvRecord.len       = 2;
1641                 lp->ltvRecord.typ       = CFG_CNF_PM_ENABLED;
1642                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->PMEnabled );
1643 //              lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( 0x8001 );
1644                 DBG_TRACE( DbgInfo, "CFG_CNF_PM_ENABLED                : 0x%04x\n", lp->PMEnabled );
1645                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1646                 /* Multicast Receive */
1647                 lp->ltvRecord.len       = 2;
1648                 lp->ltvRecord.typ       = CFG_CNF_MCAST_RX;
1649                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->MulticastReceive );
1650                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1651
1652                 /* Max Sleep Duration */
1653                 lp->ltvRecord.len       = 2;
1654                 lp->ltvRecord.typ       = CFG_CNF_MAX_SLEEP_DURATION;
1655                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->MaxSleepDuration );
1656                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1657
1658                 /* Create IBSS */
1659                 lp->ltvRecord.len       = 2;
1660                 lp->ltvRecord.typ       = CFG_CREATE_IBSS;
1661                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->CreateIBSS );
1662                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1663
1664                 /* Desired SSID */
1665                 if ((( len = ( strlen( lp->NetworkName ) + 1 ) & ~0x01 ) != 0 ) &&
1666                          ( strcmp( lp->NetworkName, "ANY" ) != 0 ) &&
1667                          ( strcmp( lp->NetworkName, "any" ) != 0 )) {
1668                         //DBG_TRACE( DbgInfo, "CFG_DESIRED_SSID                  : %s\n",
1669                         //           lp->NetworkName );
1670
1671                         lp->ltvRecord.len       = 2 + (len / sizeof(hcf_16));
1672                         lp->ltvRecord.typ       = CFG_DESIRED_SSID;
1673                         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( strlen( lp->NetworkName ));
1674
1675                         memcpy( &( lp->ltvRecord.u.u8[2] ), lp->NetworkName, len );
1676                 } else {
1677                         //DBG_TRACE( DbgInfo, "CFG_DESIRED_SSID                  : ANY\n" );
1678
1679                         lp->ltvRecord.len       = 2;
1680                         lp->ltvRecord.typ       = CFG_DESIRED_SSID;
1681                         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( 0 );
1682                 }
1683
1684                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1685
1686                 //DBG_TRACE( DbgInfo, "CFG_DESIRED_SSID result           : 0x%04x\n",
1687                 //           hcf_status );
1688                 /* Own ATIM window */
1689                 lp->ltvRecord.len       = 2;
1690                 lp->ltvRecord.typ       = CFG_CNF_OWN_ATIM_WINDOW;
1691                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->atimWindow );
1692                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1693
1694
1695                 /* Holdover Duration */
1696                 lp->ltvRecord.len       = 2;
1697                 lp->ltvRecord.typ       = CFG_CNF_HOLDOVER_DURATION;
1698                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->holdoverDuration );
1699                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1700
1701                 /* Promiscuous Mode */
1702                 lp->ltvRecord.len       = 2;
1703                 lp->ltvRecord.typ       = CFG_PROMISCUOUS_MODE;
1704                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->promiscuousMode );
1705                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1706
1707                 /* Authentication */
1708                 lp->ltvRecord.len       = 2;
1709                 lp->ltvRecord.typ       = CFG_CNF_AUTHENTICATION;
1710                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->authentication );
1711                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1712 #ifdef WARP
1713                 /* Connection Control */
1714                 lp->ltvRecord.len       = 2;
1715                 lp->ltvRecord.typ       = CFG_CNF_CONNECTION_CNTL;
1716                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->connectionControl );
1717                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1718
1719
1720
1721                 /* Probe data rate */
1722                 /*lp->ltvRecord.len       = 3;
1723                 lp->ltvRecord.typ       = CFG_PROBE_DATA_RATE;
1724                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->probeDataRates[0] );
1725                 lp->ltvRecord.u.u16[1]  = CNV_INT_TO_LITTLE( lp->probeDataRates[1] );
1726                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1727
1728                 DBG_TRACE( DbgInfo, "CFG_PROBE_DATA_RATE 2.4GHz        : 0x%04x\n",
1729                                    lp->probeDataRates[0] );
1730                 DBG_TRACE( DbgInfo, "CFG_PROBE_DATA_RATE 5.0GHz        : 0x%04x\n",
1731                                    lp->probeDataRates[1] );
1732                 DBG_TRACE( DbgInfo, "CFG_PROBE_DATA_RATE result        : 0x%04x\n",
1733                                    hcf_status );*/
1734 #endif // WARP
1735         } else {
1736                 /* The following are set in AP mode only */
1737 #if 0 //;? (HCF_TYPE) & HCF_TYPE_AP
1738                 //;?should we restore this to allow smaller memory footprint
1739
1740                 /* DTIM Period */
1741                 lp->ltvRecord.len       = 2;
1742                 lp->ltvRecord.typ       = CFG_CNF_OWN_DTIM_PERIOD;
1743                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->DTIMPeriod );
1744                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1745
1746                 /* Multicast PM Buffering */
1747                 lp->ltvRecord.len       = 2;
1748                 lp->ltvRecord.typ       = CFG_CNF_MCAST_PM_BUF;
1749                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->multicastPMBuffering );
1750                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1751
1752                 /* Reject ANY - Closed System */
1753                 lp->ltvRecord.len       = 2;
1754                 lp->ltvRecord.typ       = CFG_CNF_REJECT_ANY;
1755                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->RejectAny );
1756
1757                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1758
1759                 /* Exclude Unencrypted */
1760                 lp->ltvRecord.len       = 2;
1761                 lp->ltvRecord.typ       = CFG_CNF_EXCL_UNENCRYPTED;
1762                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->ExcludeUnencrypted );
1763
1764                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1765
1766                 /* IntraBSS Relay */
1767                 lp->ltvRecord.len       = 2;
1768                 lp->ltvRecord.typ       = CFG_CNF_INTRA_BSS_RELAY;
1769                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->intraBSSRelay );
1770                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1771
1772                 /* RTS Threshold 0 */
1773                 lp->ltvRecord.len       = 2;
1774                 lp->ltvRecord.typ       = CFG_RTS_THRH0;
1775                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->RTSThreshold );
1776
1777                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1778
1779                 /* Tx Rate Control 0 */
1780 #ifdef WARP
1781                 lp->ltvRecord.len       = 3;
1782                 lp->ltvRecord.typ       = CFG_TX_RATE_CNTL0;
1783                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->TxRateControl[0] );
1784                 lp->ltvRecord.u.u16[1]  = CNV_INT_TO_LITTLE( lp->TxRateControl[1] );
1785 #else
1786                 lp->ltvRecord.len       = 2;
1787                 lp->ltvRecord.typ       = CFG_TX_RATE_CNTL0;
1788                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->TxRateControl[0] );
1789 #endif  // WARP
1790
1791                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1792
1793                 /* Own Beacon Interval */
1794                 lp->ltvRecord.len       = 2;
1795                 lp->ltvRecord.typ       = 0xFC31;
1796                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->ownBeaconInterval );
1797                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1798
1799                 /* Co-Existence Behavior */
1800                 lp->ltvRecord.len       = 2;
1801                 lp->ltvRecord.typ       = 0xFCC7;
1802                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->coexistence );
1803                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1804
1805 #ifdef USE_WDS
1806
1807                 /* RTS Threshold 1 */
1808                 lp->ltvRecord.len       = 2;
1809                 lp->ltvRecord.typ       = CFG_RTS_THRH1;
1810                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->wds_port[0].rtsThreshold );
1811                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1812
1813                 /* RTS Threshold 2 */
1814                 lp->ltvRecord.len       = 2;
1815                 lp->ltvRecord.typ       = CFG_RTS_THRH2;
1816                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->wds_port[1].rtsThreshold );
1817                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1818
1819
1820                 /* RTS Threshold 3 */
1821                 lp->ltvRecord.len       = 2;
1822                 lp->ltvRecord.typ       = CFG_RTS_THRH3;
1823                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->wds_port[2].rtsThreshold );
1824                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1825
1826
1827                 /* RTS Threshold 4 */
1828                 lp->ltvRecord.len       = 2;
1829                 lp->ltvRecord.typ       = CFG_RTS_THRH4;
1830                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->wds_port[3].rtsThreshold );
1831                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1832
1833
1834                 /* RTS Threshold 5 */
1835                 lp->ltvRecord.len       = 2;
1836                 lp->ltvRecord.typ       = CFG_RTS_THRH5;
1837                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->wds_port[4].rtsThreshold );
1838                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1839
1840                 /* RTS Threshold 6 */
1841                 lp->ltvRecord.len       = 2;
1842                 lp->ltvRecord.typ       = CFG_RTS_THRH6;
1843                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->wds_port[5].rtsThreshold );
1844                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1845 #if 0
1846                 /* TX Rate Control 1 */
1847                 lp->ltvRecord.len       = 2;
1848                 lp->ltvRecord.typ       = CFG_TX_RATE_CNTL1;
1849                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->wds_port[0].txRateCntl );
1850                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1851
1852                 /* TX Rate Control 2 */
1853                 lp->ltvRecord.len       = 2;
1854                 lp->ltvRecord.typ       = CFG_TX_RATE_CNTL2;
1855                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->wds_port[1].txRateCntl );
1856                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1857
1858                 /* TX Rate Control 3 */
1859                 lp->ltvRecord.len       = 2;
1860                 lp->ltvRecord.typ       = CFG_TX_RATE_CNTL3;
1861                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->wds_port[2].txRateCntl );
1862                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1863
1864                 /* TX Rate Control 4 */
1865                 lp->ltvRecord.len       = 2;
1866                 lp->ltvRecord.typ       = CFG_TX_RATE_CNTL4;
1867                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->wds_port[3].txRateCntl );
1868                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1869
1870                 /* TX Rate Control 5 */
1871                 lp->ltvRecord.len       = 2;
1872                 lp->ltvRecord.typ       = CFG_TX_RATE_CNTL5;
1873                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->wds_port[4].txRateCntl );
1874                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1875
1876                 /* TX Rate Control 6 */
1877                 lp->ltvRecord.len       = 2;
1878                 lp->ltvRecord.typ       = CFG_TX_RATE_CNTL6;
1879                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->wds_port[5].txRateCntl );
1880                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1881
1882 #endif
1883
1884                 /* WDS addresses.  It's okay to blindly send these parameters, because
1885                    the port needs to be enabled, before anything is done with it. */
1886
1887                 /* WDS Address 1 */
1888                 lp->ltvRecord.len      = 4;
1889                 lp->ltvRecord.typ      = CFG_CNF_WDS_ADDR1;
1890
1891                 memcpy( &lp->ltvRecord.u.u8[0], lp->wds_port[0].wdsAddress, ETH_ALEN );
1892                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1893
1894                 /* WDS Address 2 */
1895                 lp->ltvRecord.len      = 4;
1896                 lp->ltvRecord.typ      = CFG_CNF_WDS_ADDR2;
1897
1898                 memcpy( &lp->ltvRecord.u.u8[0], lp->wds_port[1].wdsAddress, ETH_ALEN );
1899                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1900
1901                 /* WDS Address 3 */
1902                 lp->ltvRecord.len      = 4;
1903                 lp->ltvRecord.typ      = CFG_CNF_WDS_ADDR3;
1904
1905                 memcpy( &lp->ltvRecord.u.u8[0], lp->wds_port[2].wdsAddress, ETH_ALEN );
1906                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1907
1908                 /* WDS Address 4 */
1909                 lp->ltvRecord.len      = 4;
1910                 lp->ltvRecord.typ      = CFG_CNF_WDS_ADDR4;
1911
1912                 memcpy( &lp->ltvRecord.u.u8[0], lp->wds_port[3].wdsAddress, ETH_ALEN );
1913                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1914
1915                 /* WDS Address 5 */
1916                 lp->ltvRecord.len      = 4;
1917                 lp->ltvRecord.typ      = CFG_CNF_WDS_ADDR5;
1918
1919                 memcpy( &lp->ltvRecord.u.u8[0], lp->wds_port[4].wdsAddress, ETH_ALEN );
1920                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1921
1922                 /* WDS Address 6 */
1923                 lp->ltvRecord.len      = 4;
1924                 lp->ltvRecord.typ      = CFG_CNF_WDS_ADDR6;
1925
1926                 memcpy( &lp->ltvRecord.u.u8[0], lp->wds_port[5].wdsAddress, ETH_ALEN );
1927                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1928 #endif  /* USE_WDS */
1929 #endif  /* (HCF_TYPE) & HCF_TYPE_AP */
1930         }
1931
1932         /* Own MAC Address */
1933 /*
1934         DBG_TRACE(DbgInfo, "MAC Address                       : %pM\n",
1935                         lp->MACAddress);
1936  */
1937
1938         if ( WVLAN_VALID_MAC_ADDRESS( lp->MACAddress )) {
1939                 /* Make the MAC address valid by:
1940                                 Clearing the multicast bit
1941                                 Setting the local MAC address bit
1942                 */
1943                 //lp->MACAddress[0] &= ~0x03;  //;?why is this commented out already in 720
1944                 //lp->MACAddress[0] |= 0x02;
1945
1946                 lp->ltvRecord.len = 1 + ( ETH_ALEN / sizeof( hcf_16 ));
1947                 if ( CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.comp_id ) == COMP_ID_FW_AP  ) {
1948                         //DBG_TRACE( DbgInfo, "CFG_NIC_MAC_ADDR\n" );
1949                         lp->ltvRecord.typ = CFG_NIC_MAC_ADDR;
1950                 } else {
1951                         //DBG_TRACE( DbgInfo, "CFG_CNF_OWN_MAC_ADDR\n" );
1952                         lp->ltvRecord.typ = CFG_CNF_OWN_MAC_ADDR;
1953                 }
1954                 /* MAC address is byte aligned, no endian conversion needed */
1955                 memcpy( &( lp->ltvRecord.u.u8[0] ), lp->MACAddress, ETH_ALEN );
1956                 hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1957                 //DBG_TRACE( DbgInfo, "CFG_XXX_MAC_ADDR result           : 0x%04x\n",
1958                 //           hcf_status );
1959
1960                 /* Update the MAC address in the netdevice struct */
1961                 memcpy( lp->dev->dev_addr, lp->MACAddress, ETH_ALEN ); //;?what is the purpose of this seemingly complex logic
1962         }
1963         /* Own SSID */
1964         if ((( len = ( strlen( lp->NetworkName ) + 1 ) & ~0x01 ) != 0 ) &&
1965                                  ( strcmp( lp->NetworkName, "ANY" ) != 0 ) &&
1966                                  ( strcmp( lp->NetworkName, "any" ) != 0 )) {
1967                 //DBG_TRACE( DbgInfo, "CFG_CNF_OWN_SSID                  : %s\n",
1968                 //           lp->NetworkName );
1969                 lp->ltvRecord.len       = 2 + (len / sizeof(hcf_16));
1970                 lp->ltvRecord.typ       = CFG_CNF_OWN_SSID;
1971                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( strlen( lp->NetworkName ));
1972
1973                 memcpy( &( lp->ltvRecord.u.u8[2] ), lp->NetworkName, len );
1974         } else {
1975                 //DBG_TRACE( DbgInfo, "CFG_CNF_OWN_SSID                  : ANY\n" );
1976                 lp->ltvRecord.len       = 2;
1977                 lp->ltvRecord.typ       = CFG_CNF_OWN_SSID;
1978                 lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( 0 );
1979         }
1980
1981         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1982
1983         //DBG_TRACE( DbgInfo, "CFG_CNF_OWN_SSID result           : 0x%04x\n",
1984         //           hcf_status );
1985         /* enable/disable encryption */
1986         lp->ltvRecord.len       = 2;
1987         lp->ltvRecord.typ       = CFG_CNF_ENCRYPTION;
1988         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->EnableEncryption );
1989         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1990
1991         /* Set the Authentication Key Management Suite */
1992         lp->ltvRecord.len       = 2;
1993         lp->ltvRecord.typ       = CFG_SET_WPA_AUTH_KEY_MGMT_SUITE;
1994         lp->ltvRecord.u.u16[0]  = CNV_INT_TO_LITTLE( lp->AuthKeyMgmtSuite );
1995         hcf_status = hcf_put_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
1996         /* WEP Keys */
1997         wl_set_wep_keys( lp );
1998
1999         /* Country Code */
2000         /* countryInfo, ltvCountryInfo, CFG_CNF_COUNTRY_INFO */
2001
2002         DBG_LEAVE( DbgInfo );
2003         return hcf_status;
2004 } // wl_put_ltv
2005 /*============================================================================*/
2006
2007
2008 /*******************************************************************************
2009  *      init_module()
2010  *******************************************************************************
2011  *
2012  *  DESCRIPTION:
2013  *
2014  *      Load the kernel module.
2015  *
2016  *  PARAMETERS:
2017  *
2018  *      N/A
2019  *
2020  *  RETURNS:
2021  *
2022  *      0 on success
2023  *      an errno value otherwise
2024  *
2025  ******************************************************************************/
2026 static int __init wl_module_init( void )
2027 {
2028         int result;
2029         /*------------------------------------------------------------------------*/
2030
2031         DBG_FUNC( "wl_module_init" );
2032
2033 #if DBG
2034         /* Convert "standard" PCMCIA parameter pc_debug to a reasonable DebugFlag value.
2035          * NOTE: The values all fall through to the lower values. */
2036         DbgInfo->DebugFlag = 0;
2037         DbgInfo->DebugFlag = DBG_TRACE_ON;              //;?get this mess resolved one day
2038         if ( pc_debug ) switch( pc_debug ) {
2039           case 8:
2040                 DbgInfo->DebugFlag |= DBG_DS_ON;
2041           case 7:
2042                 DbgInfo->DebugFlag |= DBG_RX_ON | DBG_TX_ON;
2043           case 6:
2044                 DbgInfo->DebugFlag |= DBG_PARAM_ON;
2045           case 5:
2046                 DbgInfo->DebugFlag |= DBG_TRACE_ON;
2047           case 4:
2048                 DbgInfo->DebugFlag |= DBG_VERBOSE_ON;
2049           case 1:
2050                 DbgInfo->DebugFlag |= DBG_DEFAULTS;
2051           default:
2052                 break;
2053         }
2054 #endif /* DBG */
2055
2056         DBG_ENTER( DbgInfo );
2057         printk(KERN_INFO "%s\n", VERSION_INFO);
2058         printk(KERN_INFO "*** Modified for kernel 2.6 by Henk de Groot <pe1dnn@amsat.org>\n");
2059         printk(KERN_INFO "*** Based on 7.18 version by Andrey Borzenkov <arvidjaar@mail.ru> $Revision: 39 $\n");
2060
2061
2062 // ;?#if (HCF_TYPE) & HCF_TYPE_AP
2063 //      DBG_PRINT( "Access Point Mode (AP) Support: YES\n" );
2064 // #else
2065 //      DBG_PRINT( "Access Point Mode (AP) Support: NO\n" );
2066 // #endif /* (HCF_TYPE) & HCF_TYPE_AP */
2067
2068         result = wl_adapter_init_module( );
2069         DBG_LEAVE( DbgInfo );
2070         return result;
2071 } // init_module
2072 /*============================================================================*/
2073
2074
2075 /*******************************************************************************
2076  *      cleanup_module()
2077  *******************************************************************************
2078  *
2079  *  DESCRIPTION:
2080  *
2081  *      Unload the kernel module.
2082  *
2083  *  PARAMETERS:
2084  *
2085  *      N/A
2086  *
2087  *  RETURNS:
2088  *
2089  *      N/A
2090  *
2091  ******************************************************************************/
2092 static void __exit wl_module_exit( void )
2093 {
2094         DBG_FUNC( "wl_module_exit" );
2095         DBG_ENTER(DbgInfo);
2096
2097         wl_adapter_cleanup_module( );
2098 #if 0 //SCULL_USE_PROC /* don't waste space if unused */
2099         remove_proc_entry( "wlags", NULL );             //;?why so a-symmetric compared to location of create_proc_read_entry
2100 #endif
2101
2102         DBG_LEAVE( DbgInfo );
2103         return;
2104 } // cleanup_module
2105 /*============================================================================*/
2106
2107 module_init(wl_module_init);
2108 module_exit(wl_module_exit);
2109
2110 /*******************************************************************************
2111  *      wl_isr()
2112  *******************************************************************************
2113  *
2114  *  DESCRIPTION:
2115  *
2116  *      The Interrupt Service Routine for the driver.
2117  *
2118  *  PARAMETERS:
2119  *
2120  *      irq     -   the irq the interrupt came in on
2121  *      dev_id  -   a buffer containing information about the request
2122  *      regs    -
2123  *
2124  *  RETURNS:
2125  *
2126  *      N/A
2127  *
2128  ******************************************************************************/
2129 irqreturn_t wl_isr( int irq, void *dev_id, struct pt_regs *regs )
2130 {
2131         int                 events;
2132         struct net_device   *dev = (struct net_device *) dev_id;
2133         struct wl_private   *lp = NULL;
2134         /*------------------------------------------------------------------------*/
2135         if (( dev == NULL ) || ( !netif_device_present( dev ))) {
2136                 return IRQ_NONE;
2137         }
2138
2139         /* Set the wl_private pointer (lp), now that we know that dev is non-null */
2140         lp = wl_priv(dev);
2141
2142 #ifdef USE_RTS
2143         if ( lp->useRTS == 1 ) {
2144                 DBG_PRINT( "EXITING ISR, IN RTS MODE...\n" );
2145                 return;
2146                 }
2147 #endif  /* USE_RTS */
2148
2149         /* If we have interrupts pending, then put them on a system task
2150            queue. Otherwise turn interrupts back on */
2151         events = hcf_action( &lp->hcfCtx, HCF_ACT_INT_OFF );
2152
2153         if ( events == HCF_INT_PENDING ) {
2154                 /* Schedule the ISR handler as a bottom-half task in the
2155                    tq_immediate queue */
2156                 tasklet_schedule(&lp->task);
2157         } else {
2158                 //DBG_PRINT( "NOT OUR INTERRUPT\n" );
2159                 hcf_action( &lp->hcfCtx, HCF_ACT_INT_ON );
2160         }
2161
2162         return IRQ_RETVAL(events == HCF_INT_PENDING);
2163 } // wl_isr
2164 /*============================================================================*/
2165
2166
2167 /*******************************************************************************
2168  *      wl_isr_handler()
2169  *******************************************************************************
2170  *
2171  *  DESCRIPTION:
2172  *
2173  *      The ISR handler, scheduled to run in a deferred context by the ISR. This
2174  *      is where the ISR's work actually gets done.
2175  *
2176  *  PARAMETERS:
2177  *
2178  *      lp  - a pointer to the device's private adapter structure
2179  *
2180  *  RETURNS:
2181  *
2182  *      N/A
2183  *
2184  ******************************************************************************/
2185 #define WVLAN_MAX_INT_SERVICES  50
2186
2187 void wl_isr_handler( unsigned long p )
2188 {
2189         struct net_device       *dev;
2190         unsigned long           flags;
2191         bool_t                  stop = TRUE;
2192         int                     count;
2193         int                     result;
2194         struct wl_private       *lp = (struct wl_private *)p;
2195         /*------------------------------------------------------------------------*/
2196
2197         if ( lp == NULL ) {
2198                 DBG_PRINT( "wl_isr_handler  lp adapter pointer is NULL!!!\n" );
2199         } else {
2200                 wl_lock( lp, &flags );
2201
2202                 dev = (struct net_device *)lp->dev;
2203                 if ( dev != NULL && netif_device_present( dev ) ) stop = FALSE;
2204                 for( count = 0; stop == FALSE && count < WVLAN_MAX_INT_SERVICES; count++ ) {
2205                         stop = TRUE;
2206                         result = hcf_service_nic( &lp->hcfCtx,
2207                                                                           (wci_bufp)lp->lookAheadBuf,
2208                                                                           sizeof( lp->lookAheadBuf ));
2209                         if ( result == HCF_ERR_MIC ) {
2210                                 wl_wext_event_mic_failed( dev );        /* Send an event that MIC failed */
2211                                 //;?this seems wrong if HCF_ERR_MIC coincides with another event, stop gets FALSE
2212                                 //so why not do it always ;?
2213                         }
2214
2215 #ifndef USE_MBOX_SYNC
2216                         if ( lp->hcfCtx.IFB_MBInfoLen != 0 ) {  /* anything in the mailbox */
2217                                 wl_mbx( lp );
2218                                 stop = FALSE;
2219                         }
2220 #endif
2221                         /* Check for a Link status event */
2222                         if ( ( lp->hcfCtx.IFB_LinkStat & CFG_LINK_STAT_FW ) != 0 ) {
2223                                 wl_process_link_status( lp );
2224                                 stop = FALSE;
2225                         }
2226                         /* Check for probe response events */
2227                         if ( lp->ProbeResp.infoType != 0 &&
2228                                 lp->ProbeResp.infoType != 0xFFFF ) {
2229                                 wl_process_probe_response( lp );
2230                                 memset( &lp->ProbeResp, 0, sizeof( lp->ProbeResp ));
2231                                 lp->ProbeResp.infoType = 0xFFFF;
2232                                 stop = FALSE;
2233                         }
2234                         /* Check for updated record events */
2235                         if ( lp->updatedRecord.len != 0xFFFF ) {
2236                                 wl_process_updated_record( lp );
2237                                 lp->updatedRecord.len = 0xFFFF;
2238                                 stop = FALSE;
2239                         }
2240                         /* Check for association status events */
2241                         if ( lp->assoc_stat.len != 0xFFFF ) {
2242                                 wl_process_assoc_status( lp );
2243                                 lp->assoc_stat.len = 0xFFFF;
2244                                 stop = FALSE;
2245                         }
2246                         /* Check for security status events */
2247                         if ( lp->sec_stat.len != 0xFFFF ) {
2248                                 wl_process_security_status( lp );
2249                                 lp->sec_stat.len = 0xFFFF;
2250                                 stop = FALSE;
2251                         }
2252
2253 #ifdef ENABLE_DMA
2254                         if ( lp->use_dma ) {
2255                                 /* Check for DMA Rx packets */
2256                                 if ( lp->hcfCtx.IFB_DmaPackets & HREG_EV_RDMAD ) {
2257                                         wl_rx_dma( dev );
2258                                         stop = FALSE;
2259                                 }
2260                                 /* Return Tx DMA descriptors to host */
2261                                 if ( lp->hcfCtx.IFB_DmaPackets & HREG_EV_TDMAD ) {
2262                                         wl_pci_dma_hcf_reclaim_tx( lp );
2263                                         stop = FALSE;
2264                                 }
2265                         }
2266                         else
2267 #endif // ENABLE_DMA
2268                         {
2269                                 /* Check for Rx packets */
2270                                 if ( lp->hcfCtx.IFB_RxLen != 0 ) {
2271                                         wl_rx( dev );
2272                                         stop = FALSE;
2273                                 }
2274                                 /* Make sure that queued frames get sent */
2275                                 if ( wl_send( lp )) {
2276                                         stop = FALSE;
2277                                 }
2278                         }
2279                 }
2280                 /* We're done, so turn interrupts which were turned off in wl_isr, back on */
2281                 hcf_action( &lp->hcfCtx, HCF_ACT_INT_ON );
2282                 wl_unlock( lp, &flags );
2283         }
2284         return;
2285 } // wl_isr_handler
2286 /*============================================================================*/
2287
2288
2289 /*******************************************************************************
2290  *      wl_remove()
2291  *******************************************************************************
2292  *
2293  *  DESCRIPTION:
2294  *
2295  *      Notify the adapter that it has been removed. Since the adapter is gone,
2296  *  we should no longer try to talk to it.
2297  *
2298  *  PARAMETERS:
2299  *
2300  *      dev - a pointer to the device's net_device structure
2301  *
2302  *  RETURNS:
2303  *
2304  *      N/A
2305  *
2306  ******************************************************************************/
2307 void wl_remove( struct net_device *dev )
2308 {
2309         struct wl_private   *lp = wl_priv(dev);
2310         unsigned long   flags;
2311         /*------------------------------------------------------------------------*/
2312         DBG_FUNC( "wl_remove" );
2313         DBG_ENTER( DbgInfo );
2314
2315         DBG_PARAM( DbgInfo, "dev", "%s (0x%p)", dev->name, dev );
2316
2317         wl_lock( lp, &flags );
2318
2319         /* stop handling interrupts */
2320         wl_act_int_off( lp );
2321         lp->is_handling_int = WL_NOT_HANDLING_INT;
2322
2323         /*
2324          * Disable the ports: just change state: since the
2325          * card is gone it is useless to talk to it and at
2326          * disconnect all state information is lost anyway.
2327          */
2328         /* Reset portState */
2329         lp->portState = WVLAN_PORT_STATE_DISABLED;
2330
2331 #if 0 //;? (HCF_TYPE) & HCF_TYPE_AP
2332 #ifdef USE_WDS
2333         //wl_disable_wds_ports( lp );
2334 #endif // USE_WDS
2335 #endif  /* (HCF_TYPE) & HCF_TYPE_AP */
2336
2337         /* Mark the device as unregistered */
2338         lp->is_registered = FALSE;
2339
2340         /* Deregister the WDS ports as well */
2341         WL_WDS_NETDEV_DEREGISTER( lp );
2342 #ifdef USE_RTS
2343         if ( lp->useRTS == 1 ) {
2344                 wl_unlock( lp, &flags );
2345
2346                 DBG_LEAVE( DbgInfo );
2347                 return;
2348         }
2349 #endif  /* USE_RTS */
2350
2351         /* Inform the HCF that the card has been removed */
2352         hcf_connect( &lp->hcfCtx, HCF_DISCONNECT );
2353
2354         wl_unlock( lp, &flags );
2355
2356         DBG_LEAVE( DbgInfo );
2357         return;
2358 } // wl_remove
2359 /*============================================================================*/
2360
2361
2362 /*******************************************************************************
2363  *      wl_suspend()
2364  *******************************************************************************
2365  *
2366  *  DESCRIPTION:
2367  *
2368  *      Power-down and halt the adapter.
2369  *
2370  *  PARAMETERS:
2371  *
2372  *      dev - a pointer to the device's net_device structure
2373  *
2374  *  RETURNS:
2375  *
2376  *      N/A
2377  *
2378  ******************************************************************************/
2379 void wl_suspend( struct net_device *dev )
2380 {
2381         struct wl_private  *lp = wl_priv(dev);
2382         unsigned long   flags;
2383         /*------------------------------------------------------------------------*/
2384         DBG_FUNC( "wl_suspend" );
2385         DBG_ENTER( DbgInfo );
2386
2387         DBG_PARAM( DbgInfo, "dev", "%s (0x%p)", dev->name, dev );
2388
2389         /* The adapter is suspended:
2390                         Stop the adapter
2391                         Power down
2392         */
2393         wl_lock( lp, &flags );
2394
2395         /* Disable interrupt handling */
2396         wl_act_int_off( lp );
2397
2398         /* Disconnect */
2399         wl_disconnect( lp );
2400
2401         /* Disable */
2402         wl_disable( lp );
2403
2404         /* Disconnect from the adapter */
2405         hcf_connect( &lp->hcfCtx, HCF_DISCONNECT );
2406
2407         /* Reset portState to be sure (should have been done by wl_disable */
2408         lp->portState = WVLAN_PORT_STATE_DISABLED;
2409
2410         wl_unlock( lp, &flags );
2411
2412         DBG_LEAVE( DbgInfo );
2413         return;
2414 } // wl_suspend
2415 /*============================================================================*/
2416
2417
2418 /*******************************************************************************
2419  *      wl_resume()
2420  *******************************************************************************
2421  *
2422  *  DESCRIPTION:
2423  *
2424  *      Resume a previously suspended adapter.
2425  *
2426  *  PARAMETERS:
2427  *
2428  *      dev - a pointer to the device's net_device structure
2429  *
2430  *  RETURNS:
2431  *
2432  *      N/A
2433  *
2434  ******************************************************************************/
2435 void wl_resume(struct net_device *dev)
2436 {
2437         struct wl_private  *lp = wl_priv(dev);
2438         unsigned long   flags;
2439         /*------------------------------------------------------------------------*/
2440         DBG_FUNC( "wl_resume" );
2441         DBG_ENTER( DbgInfo );
2442
2443         DBG_PARAM( DbgInfo, "dev", "%s (0x%p)", dev->name, dev );
2444
2445         wl_lock( lp, &flags );
2446
2447         /* Connect to the adapter */
2448         hcf_connect( &lp->hcfCtx, dev->base_addr );
2449
2450         /* Reset portState */
2451         lp->portState = WVLAN_PORT_STATE_DISABLED;
2452
2453         /* Power might have been off, assume the card lost the firmware*/
2454         lp->firmware_present = WL_FRIMWARE_NOT_PRESENT;
2455
2456         /* Reload the firmware and restart */
2457         wl_reset( dev );
2458
2459         /* Resume interrupt handling */
2460         wl_act_int_on( lp );
2461
2462         wl_unlock( lp, &flags );
2463
2464         DBG_LEAVE( DbgInfo );
2465         return;
2466 } // wl_resume
2467 /*============================================================================*/
2468
2469
2470 /*******************************************************************************
2471  *      wl_release()
2472  *******************************************************************************
2473  *
2474  *  DESCRIPTION:
2475  *
2476  *      This function perfroms a check on the device and calls wl_remove() if
2477  *  necessary. This function can be used for all bus types, but exists mostly
2478  *  for the benefit of the Card Services driver, as there are times when
2479  *  wl_remove() does not get called.
2480  *
2481  *  PARAMETERS:
2482  *
2483  *      dev - a pointer to the device's net_device structure
2484  *
2485  *  RETURNS:
2486  *
2487  *      N/A
2488  *
2489  ******************************************************************************/
2490 void wl_release( struct net_device *dev )
2491 {
2492         struct wl_private  *lp = wl_priv(dev);
2493         /*------------------------------------------------------------------------*/
2494         DBG_FUNC( "wl_release" );
2495         DBG_ENTER( DbgInfo );
2496
2497         DBG_PARAM( DbgInfo, "dev", "%s (0x%p)", dev->name, dev );
2498         /* If wl_remove() hasn't been called (i.e. when Card Services is shut
2499            down with the card in the slot), then call it */
2500         if ( lp->is_registered == TRUE ) {
2501                 DBG_TRACE( DbgInfo, "Calling unregister_netdev(), as it wasn't called yet\n" );
2502                 wl_remove( dev );
2503
2504                 lp->is_registered = FALSE;
2505         }
2506
2507         DBG_LEAVE( DbgInfo );
2508         return;
2509 } // wl_release
2510 /*============================================================================*/
2511
2512
2513 /*******************************************************************************
2514  *      wl_get_irq_mask()
2515  *******************************************************************************
2516  *
2517  *  DESCRIPTION:
2518  *
2519  *      Accessor function to retrieve the irq_mask module parameter
2520  *
2521  *  PARAMETERS:
2522  *
2523  *      N/A
2524  *
2525  *  RETURNS:
2526  *
2527  *      The irq_mask module parameter
2528  *
2529  ******************************************************************************/
2530 p_u16 wl_get_irq_mask( void )
2531 {
2532         return irq_mask;
2533 } // wl_get_irq_mask
2534 /*============================================================================*/
2535
2536
2537 /*******************************************************************************
2538  *      wl_get_irq_list()
2539  *******************************************************************************
2540  *
2541  *  DESCRIPTION:
2542  *
2543  *      Accessor function to retrieve the irq_list module parameter
2544  *
2545  *  PARAMETERS:
2546  *
2547  *      N/A
2548  *
2549  *  RETURNS:
2550  *
2551  *      The irq_list module parameter
2552  *
2553  ******************************************************************************/
2554 p_s8 * wl_get_irq_list( void )
2555 {
2556         return irq_list;
2557 } // wl_get_irq_list
2558 /*============================================================================*/
2559
2560
2561
2562 /*******************************************************************************
2563  *      wl_enable()
2564  *******************************************************************************
2565  *
2566  *  DESCRIPTION:
2567  *
2568  *      Used to enable MAC ports
2569  *
2570  *  PARAMETERS:
2571  *
2572  *      lp      - pointer to the device's private adapter structure
2573  *
2574  *  RETURNS:
2575  *
2576  *      N/A
2577  *
2578  ******************************************************************************/
2579 int wl_enable( struct wl_private *lp )
2580 {
2581         int hcf_status = HCF_SUCCESS;
2582         /*------------------------------------------------------------------------*/
2583         DBG_FUNC( "wl_enable" );
2584         DBG_ENTER( DbgInfo );
2585
2586         if ( lp->portState == WVLAN_PORT_STATE_ENABLED ) {
2587                 DBG_TRACE( DbgInfo, "No action: Card already enabled\n" );
2588         } else if ( lp->portState == WVLAN_PORT_STATE_CONNECTED ) {
2589                 //;?suspicuous logic, how can you be connected without being enabled so this is probably dead code
2590                 DBG_TRACE( DbgInfo, "No action: Card already connected\n" );
2591         } else {
2592                 hcf_status = hcf_cntl( &lp->hcfCtx, HCF_CNTL_ENABLE );
2593                 if ( hcf_status == HCF_SUCCESS ) {
2594                         /* Set the status of the NIC to enabled */
2595                         lp->portState = WVLAN_PORT_STATE_ENABLED;   //;?bad mnemonic, NIC iso PORT
2596 #ifdef ENABLE_DMA
2597                         if ( lp->use_dma ) {
2598                                 wl_pci_dma_hcf_supply( lp );  //;?always succes?
2599                         }
2600 #endif
2601                 }
2602         }
2603         if ( hcf_status != HCF_SUCCESS ) {  //;?make this an assert
2604                 DBG_TRACE( DbgInfo, "failed: 0x%x\n", hcf_status );
2605         }
2606         DBG_LEAVE( DbgInfo );
2607         return hcf_status;
2608 } // wl_enable
2609 /*============================================================================*/
2610
2611
2612 #ifdef USE_WDS
2613 /*******************************************************************************
2614  *      wl_enable_wds_ports()
2615  *******************************************************************************
2616  *
2617  *  DESCRIPTION:
2618  *
2619  *      Used to enable the WDS MAC ports 1-6
2620  *
2621  *  PARAMETERS:
2622  *
2623  *      lp      - pointer to the device's private adapter structure
2624  *
2625  *  RETURNS:
2626  *
2627  *      N/A
2628  *
2629  ******************************************************************************/
2630 void wl_enable_wds_ports( struct wl_private * lp )
2631 {
2632
2633         DBG_FUNC( "wl_enable_wds_ports" );
2634         DBG_ENTER( DbgInfo );
2635         if ( CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.comp_id ) == COMP_ID_FW_AP  ){
2636                 DBG_ERROR( DbgInfo, "!!!!;? someone misunderstood something !!!!!\n" );
2637         }
2638         DBG_LEAVE( DbgInfo );
2639         return;
2640 } // wl_enable_wds_ports
2641 #endif  /* USE_WDS */
2642 /*============================================================================*/
2643
2644
2645 /*******************************************************************************
2646  *      wl_connect()
2647  *******************************************************************************
2648  *
2649  *  DESCRIPTION:
2650  *
2651  *      Used to connect a MAC port
2652  *
2653  *  PARAMETERS:
2654  *
2655  *      lp      - pointer to the device's private adapter structure
2656  *
2657  *  RETURNS:
2658  *
2659  *      N/A
2660  *
2661  ******************************************************************************/
2662 int wl_connect( struct wl_private *lp )
2663 {
2664         int hcf_status;
2665         /*------------------------------------------------------------------------*/
2666
2667         DBG_FUNC( "wl_connect" );
2668         DBG_ENTER( DbgInfo );
2669
2670         if ( lp->portState != WVLAN_PORT_STATE_ENABLED ) {
2671                 DBG_TRACE( DbgInfo, "No action: Not in enabled state\n" );
2672                 DBG_LEAVE( DbgInfo );
2673                 return HCF_SUCCESS;
2674         }
2675         hcf_status = hcf_cntl( &lp->hcfCtx, HCF_CNTL_CONNECT );
2676         if ( hcf_status == HCF_SUCCESS ) {
2677                 lp->portState = WVLAN_PORT_STATE_CONNECTED;
2678         }
2679         DBG_LEAVE( DbgInfo );
2680         return hcf_status;
2681 } // wl_connect
2682 /*============================================================================*/
2683
2684
2685 /*******************************************************************************
2686  *      wl_disconnect()
2687  *******************************************************************************
2688  *
2689  *  DESCRIPTION:
2690  *
2691  *      Used to disconnect a MAC port
2692  *
2693  *  PARAMETERS:
2694  *
2695  *      lp      - pointer to the device's private adapter structure
2696  *
2697  *  RETURNS:
2698  *
2699  *      N/A
2700  *
2701  ******************************************************************************/
2702 int wl_disconnect( struct wl_private *lp )
2703 {
2704         int hcf_status;
2705         /*------------------------------------------------------------------------*/
2706
2707         DBG_FUNC( "wl_disconnect" );
2708         DBG_ENTER( DbgInfo );
2709
2710         if ( lp->portState != WVLAN_PORT_STATE_CONNECTED ) {
2711                 DBG_TRACE( DbgInfo, "No action: Not in connected state\n" );
2712                 DBG_LEAVE( DbgInfo );
2713                 return HCF_SUCCESS;
2714         }
2715         hcf_status = hcf_cntl( &lp->hcfCtx, HCF_CNTL_DISCONNECT );
2716         if ( hcf_status == HCF_SUCCESS ) {
2717                 lp->portState = WVLAN_PORT_STATE_ENABLED;
2718         }
2719         DBG_LEAVE( DbgInfo );
2720         return hcf_status;
2721 } // wl_disconnect
2722 /*============================================================================*/
2723
2724
2725 /*******************************************************************************
2726  *      wl_disable()
2727  *******************************************************************************
2728  *
2729  *  DESCRIPTION:
2730  *
2731  *      Used to disable MAC ports
2732  *
2733  *  PARAMETERS:
2734  *
2735  *      lp      - pointer to the device's private adapter structure
2736  *      port    - the MAC port to disable
2737  *
2738  *  RETURNS:
2739  *
2740  *      N/A
2741  *
2742  ******************************************************************************/
2743 int wl_disable( struct wl_private *lp )
2744 {
2745         int hcf_status = HCF_SUCCESS;
2746         /*------------------------------------------------------------------------*/
2747         DBG_FUNC( "wl_disable" );
2748         DBG_ENTER( DbgInfo );
2749
2750         if ( lp->portState == WVLAN_PORT_STATE_DISABLED ) {
2751                 DBG_TRACE( DbgInfo, "No action: Port state is disabled\n" );
2752         } else {
2753                 hcf_status = hcf_cntl( &lp->hcfCtx, HCF_CNTL_DISABLE );
2754                 if ( hcf_status == HCF_SUCCESS ) {
2755                         /* Set the status of the port to disabled */ //;?bad mnemonic use NIC iso PORT
2756                         lp->portState = WVLAN_PORT_STATE_DISABLED;
2757
2758 #ifdef ENABLE_DMA
2759                         if ( lp->use_dma ) {
2760                                 wl_pci_dma_hcf_reclaim( lp );
2761                         }
2762 #endif
2763                 }
2764         }
2765         if ( hcf_status != HCF_SUCCESS ) {
2766                 DBG_TRACE( DbgInfo, "failed: 0x%x\n", hcf_status );
2767         }
2768         DBG_LEAVE( DbgInfo );
2769         return hcf_status;
2770 } // wl_disable
2771 /*============================================================================*/
2772
2773
2774 #ifdef USE_WDS
2775 /*******************************************************************************
2776  *      wl_disable_wds_ports()
2777  *******************************************************************************
2778  *
2779  *  DESCRIPTION:
2780  *
2781  *      Used to disable the WDS MAC ports 1-6
2782  *
2783  *  PARAMETERS:
2784  *
2785  *      lp      - pointer to the device's private adapter structure
2786  *
2787  *  RETURNS:
2788  *
2789  *      N/A
2790  *
2791  ******************************************************************************/
2792 void wl_disable_wds_ports( struct wl_private * lp )
2793 {
2794
2795         DBG_FUNC( "wl_disable_wds_ports" );
2796         DBG_ENTER( DbgInfo );
2797
2798         if ( CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.comp_id ) == COMP_ID_FW_AP  ){
2799                 DBG_ERROR( DbgInfo, "!!!!;? someone misunderstood something !!!!!\n" );
2800         }
2801 //      if ( CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.comp_id ) == COMP_ID_FW_AP  ) {
2802 //              wl_disable( lp, HCF_PORT_1 );
2803 //              wl_disable( lp, HCF_PORT_2 );
2804 //              wl_disable( lp, HCF_PORT_3 );
2805 //              wl_disable( lp, HCF_PORT_4 );
2806 //              wl_disable( lp, HCF_PORT_5 );
2807 //              wl_disable( lp, HCF_PORT_6 );
2808 //      }
2809         DBG_LEAVE( DbgInfo );
2810         return;
2811 } // wl_disable_wds_ports
2812 #endif // USE_WDS
2813 /*============================================================================*/
2814
2815
2816 #ifndef USE_MBOX_SYNC
2817 /*******************************************************************************
2818  *      wl_mbx()
2819  *******************************************************************************
2820  *
2821  *  DESCRIPTION:
2822  *      This function is used to read and process a mailbox message.
2823  *
2824  *
2825  *  PARAMETERS:
2826  *
2827  *      lp      - pointer to the device's private adapter structure
2828  *
2829  *  RETURNS:
2830  *
2831  *      an HCF status code
2832  *
2833  ******************************************************************************/
2834 int wl_mbx( struct wl_private *lp )
2835 {
2836         int hcf_status = HCF_SUCCESS;
2837         /*------------------------------------------------------------------------*/
2838         DBG_FUNC( "wl_mbx" );
2839         DBG_ENTER( DbgInfo );
2840         DBG_TRACE( DbgInfo, "Mailbox Info: IFB_MBInfoLen: %d\n",
2841                            lp->hcfCtx.IFB_MBInfoLen );
2842
2843         memset( &( lp->ltvRecord ), 0, sizeof( ltv_t ));
2844
2845         lp->ltvRecord.len = MB_SIZE;
2846         lp->ltvRecord.typ = CFG_MB_INFO;
2847         hcf_status = hcf_get_info( &lp->hcfCtx, (LTVP)&( lp->ltvRecord ));
2848
2849         if ( hcf_status != HCF_SUCCESS ) {
2850                 DBG_ERROR( DbgInfo, "hcf_get_info returned 0x%x\n", hcf_status );
2851
2852                 DBG_LEAVE( DbgInfo );
2853                 return hcf_status;
2854         }
2855
2856         if ( lp->ltvRecord.typ == CFG_MB_INFO ) {
2857                 DBG_LEAVE( DbgInfo );
2858                 return hcf_status;
2859         }
2860         /* Endian translate the mailbox data, then process the message */
2861         wl_endian_translate_mailbox( &( lp->ltvRecord ));
2862         wl_process_mailbox( lp );
2863         DBG_LEAVE( DbgInfo );
2864         return hcf_status;
2865 } // wl_mbx
2866 /*============================================================================*/
2867
2868
2869 /*******************************************************************************
2870  *      wl_endian_translate_mailbox()
2871  *******************************************************************************
2872  *
2873  *  DESCRIPTION:
2874  *
2875  *      This function will perform the tedious task of endian translating all
2876  *  fields withtin a mailbox message which need translating.
2877  *
2878  *  PARAMETERS:
2879  *
2880  *      ltv - pointer to the LTV to endian translate
2881  *
2882  *  RETURNS:
2883  *
2884  *      none
2885  *
2886  ******************************************************************************/
2887 void wl_endian_translate_mailbox( ltv_t *ltv )
2888 {
2889
2890         DBG_FUNC( "wl_endian_translate_mailbox" );
2891         DBG_ENTER( DbgInfo );
2892         switch( ltv->typ ) {
2893           case CFG_TALLIES:
2894                 break;
2895
2896           case CFG_SCAN:
2897                 {
2898                         int num_aps;
2899                         SCAN_RS_STRCT *aps = (SCAN_RS_STRCT *)&ltv->u.u8[0];
2900
2901                         num_aps = (hcf_16)(( (size_t)(ltv->len - 1 ) * 2 ) /
2902                                                                  ( sizeof( SCAN_RS_STRCT )));
2903
2904                         while( num_aps >= 1 ) {
2905                                 num_aps--;
2906
2907                                 aps[num_aps].channel_id =
2908                                         CNV_LITTLE_TO_INT( aps[num_aps].channel_id );
2909
2910                                 aps[num_aps].noise_level =
2911                                         CNV_LITTLE_TO_INT( aps[num_aps].noise_level );
2912
2913                                 aps[num_aps].signal_level =
2914                                         CNV_LITTLE_TO_INT( aps[num_aps].signal_level );
2915
2916                                 aps[num_aps].beacon_interval_time =
2917                                         CNV_LITTLE_TO_INT( aps[num_aps].beacon_interval_time );
2918
2919                                 aps[num_aps].capability =
2920                                         CNV_LITTLE_TO_INT( aps[num_aps].capability );
2921
2922                                 aps[num_aps].ssid_len =
2923                                         CNV_LITTLE_TO_INT( aps[num_aps].ssid_len );
2924
2925                                 aps[num_aps].ssid_val[aps[num_aps].ssid_len] = 0;
2926                         }
2927                 }
2928                 break;
2929
2930           case CFG_ACS_SCAN:
2931                 {
2932                         PROBE_RESP *probe_resp = (PROBE_RESP *)ltv;
2933
2934                         probe_resp->frameControl   = CNV_LITTLE_TO_INT( probe_resp->frameControl );
2935                         probe_resp->durID          = CNV_LITTLE_TO_INT( probe_resp->durID );
2936                         probe_resp->sequence       = CNV_LITTLE_TO_INT( probe_resp->sequence );
2937                         probe_resp->dataLength     = CNV_LITTLE_TO_INT( probe_resp->dataLength );
2938 #ifndef WARP
2939                         probe_resp->lenType        = CNV_LITTLE_TO_INT( probe_resp->lenType );
2940 #endif // WARP
2941                         probe_resp->beaconInterval = CNV_LITTLE_TO_INT( probe_resp->beaconInterval );
2942                         probe_resp->capability     = CNV_LITTLE_TO_INT( probe_resp->capability );
2943                         probe_resp->flags          = CNV_LITTLE_TO_INT( probe_resp->flags );
2944                 }
2945                 break;
2946
2947           case CFG_LINK_STAT:
2948 #define ls ((LINK_STATUS_STRCT *)ltv)
2949                         ls->linkStatus = CNV_LITTLE_TO_INT( ls->linkStatus );
2950                 break;
2951 #undef ls
2952
2953           case CFG_ASSOC_STAT:
2954                 {
2955                         ASSOC_STATUS_STRCT *as = (ASSOC_STATUS_STRCT *)ltv;
2956
2957                         as->assocStatus = CNV_LITTLE_TO_INT( as->assocStatus );
2958                 }
2959                 break;
2960
2961           case CFG_SECURITY_STAT:
2962                 {
2963                         SECURITY_STATUS_STRCT *ss = (SECURITY_STATUS_STRCT *)ltv;
2964
2965                         ss->securityStatus  = CNV_LITTLE_TO_INT( ss->securityStatus );
2966                         ss->reason          = CNV_LITTLE_TO_INT( ss->reason );
2967                 }
2968                 break;
2969
2970           case CFG_WMP:
2971                 break;
2972
2973           case CFG_NULL:
2974                 break;
2975
2976         default:
2977                 break;
2978         }
2979
2980         DBG_LEAVE( DbgInfo );
2981         return;
2982 } // wl_endian_translate_mailbox
2983 /*============================================================================*/
2984
2985 /*******************************************************************************
2986  *      wl_process_mailbox()
2987  *******************************************************************************
2988  *
2989  *  DESCRIPTION:
2990  *
2991  *      This function will process the mailbox data.
2992  *
2993  *  PARAMETERS:
2994  *
2995  *      ltv - pointer to the LTV to be processed.
2996  *
2997  *  RETURNS:
2998  *
2999  *      none
3000  *
3001  ******************************************************************************/
3002 void wl_process_mailbox( struct wl_private *lp )
3003 {
3004         ltv_t   *ltv;
3005         hcf_16  ltv_val = 0xFFFF;
3006         /*------------------------------------------------------------------------*/
3007         DBG_FUNC( "wl_process_mailbox" );
3008         DBG_ENTER( DbgInfo );
3009         ltv = &( lp->ltvRecord );
3010
3011         switch( ltv->typ ) {
3012
3013           case CFG_TALLIES:
3014                 DBG_TRACE( DbgInfo, "CFG_TALLIES\n" );
3015                 break;
3016           case CFG_SCAN:
3017                 DBG_TRACE( DbgInfo, "CFG_SCAN\n" );
3018
3019                 {
3020                         int num_aps;
3021                         SCAN_RS_STRCT *aps = (SCAN_RS_STRCT *)&ltv->u.u8[0];
3022
3023                         num_aps = (hcf_16)(( (size_t)(ltv->len - 1 ) * 2 ) /
3024                                                                  ( sizeof( SCAN_RS_STRCT )));
3025
3026                         lp->scan_results.num_aps = num_aps;
3027
3028                         DBG_TRACE( DbgInfo, "Number of APs: %d\n", num_aps );
3029
3030                         while( num_aps >= 1 ) {
3031                                 num_aps--;
3032
3033                                 DBG_TRACE( DbgInfo, "AP              : %d\n", num_aps );
3034                                 DBG_TRACE( DbgInfo, "=========================\n" );
3035                                 DBG_TRACE( DbgInfo, "Channel ID      : 0x%04x\n",
3036                                                    aps[num_aps].channel_id );
3037                                 DBG_TRACE( DbgInfo, "Noise Level     : 0x%04x\n",
3038                                                    aps[num_aps].noise_level );
3039                                 DBG_TRACE( DbgInfo, "Signal Level    : 0x%04x\n",
3040                                                    aps[num_aps].signal_level );
3041                                 DBG_TRACE( DbgInfo, "Beacon Interval : 0x%04x\n",
3042                                                    aps[num_aps].beacon_interval_time );
3043                                 DBG_TRACE( DbgInfo, "Capability      : 0x%04x\n",
3044                                                    aps[num_aps].capability );
3045                                 DBG_TRACE( DbgInfo, "SSID Length     : 0x%04x\n",
3046                                                    aps[num_aps].ssid_len );
3047                                 DBG_TRACE(DbgInfo, "BSSID           : %pM\n",
3048                                                    aps[num_aps].bssid);
3049
3050                                 if ( aps[num_aps].ssid_len != 0 ) {
3051                                         DBG_TRACE( DbgInfo, "SSID            : %s.\n",
3052                                                            aps[num_aps].ssid_val );
3053                                 } else {
3054                                         DBG_TRACE( DbgInfo, "SSID            : %s.\n", "ANY" );
3055                                 }
3056
3057                                 DBG_TRACE( DbgInfo, "\n" );
3058
3059                                 /* Copy the info to the ScanResult structure in the private
3060                                    adapter struct */
3061                                 memcpy( &( lp->scan_results.APTable[num_aps]), &( aps[num_aps] ),
3062                                                 sizeof( SCAN_RS_STRCT ));
3063                         }
3064
3065                         /* Set scan result to true so that any scan requests will
3066                            complete */
3067                         lp->scan_results.scan_complete = TRUE;
3068                 }
3069
3070                 break;
3071           case CFG_ACS_SCAN:
3072                 DBG_TRACE( DbgInfo, "CFG_ACS_SCAN\n" );
3073
3074                 {
3075                         PROBE_RESP  *probe_rsp = (PROBE_RESP *)ltv;
3076                         hcf_8       *wpa_ie = NULL;
3077                         hcf_16      wpa_ie_len = 0;
3078
3079                         DBG_TRACE( DbgInfo, "(%s) =========================\n",
3080                                            lp->dev->name );
3081
3082                         DBG_TRACE( DbgInfo, "(%s) length      : 0x%04x.\n",
3083                                            lp->dev->name, probe_rsp->length );
3084
3085                         if ( probe_rsp->length > 1 ) {
3086                                 DBG_TRACE( DbgInfo, "(%s) infoType    : 0x%04x.\n",
3087                                                    lp->dev->name, probe_rsp->infoType );
3088
3089                                 DBG_TRACE( DbgInfo, "(%s) signal      : 0x%02x.\n",
3090                                                    lp->dev->name, probe_rsp->signal );
3091
3092                                 DBG_TRACE( DbgInfo, "(%s) silence     : 0x%02x.\n",
3093                                                    lp->dev->name, probe_rsp->silence );
3094
3095                                 DBG_TRACE( DbgInfo, "(%s) rxFlow      : 0x%02x.\n",
3096                                                    lp->dev->name, probe_rsp->rxFlow );
3097
3098                                 DBG_TRACE( DbgInfo, "(%s) rate        : 0x%02x.\n",
3099                                                    lp->dev->name, probe_rsp->rate );
3100
3101                                 DBG_TRACE( DbgInfo, "(%s) frame cntl  : 0x%04x.\n",
3102                                                    lp->dev->name, probe_rsp->frameControl );
3103
3104                                 DBG_TRACE( DbgInfo, "(%s) durID       : 0x%04x.\n",
3105                                                    lp->dev->name, probe_rsp->durID );
3106
3107                                 DBG_TRACE(DbgInfo, "(%s) address1    : %pM\n",
3108                                         lp->dev->name, probe_rsp->address1);
3109
3110                                 DBG_TRACE(DbgInfo, "(%s) address2    : %pM\n",
3111                                         lp->dev->name, probe_rsp->address2);
3112
3113                                 DBG_TRACE(DbgInfo, "(%s) BSSID       : %pM\n",
3114                                         lp->dev->name, probe_rsp->BSSID);
3115
3116                                 DBG_TRACE( DbgInfo, "(%s) sequence    : 0x%04x.\n",
3117                                                    lp->dev->name, probe_rsp->sequence );
3118
3119                                 DBG_TRACE(DbgInfo, "(%s) address4    : %pM\n",
3120                                         lp->dev->name, probe_rsp->address4);
3121
3122                                 DBG_TRACE( DbgInfo, "(%s) datalength  : 0x%04x.\n",
3123                                                    lp->dev->name, probe_rsp->dataLength );
3124
3125                                 DBG_TRACE(DbgInfo, "(%s) DA          : %pM\n",
3126                                         lp->dev->name, probe_rsp->DA);
3127
3128                                 DBG_TRACE(DbgInfo, "(%s) SA          : %pM\n",
3129                                         lp->dev->name, probe_rsp->SA);
3130
3131                                 //DBG_TRACE( DbgInfo, "(%s) lenType     : 0x%04x.\n",
3132                                 //           lp->dev->name, probe_rsp->lenType );
3133
3134                                 DBG_TRACE(DbgInfo, "(%s) timeStamp   : "
3135                                                 "%d.%d.%d.%d.%d.%d.%d.%d\n",
3136                                                 lp->dev->name,
3137                                                 probe_rsp->timeStamp[0],
3138                                                 probe_rsp->timeStamp[1],
3139                                                 probe_rsp->timeStamp[2],
3140                                                 probe_rsp->timeStamp[3],
3141                                                 probe_rsp->timeStamp[4],
3142                                                 probe_rsp->timeStamp[5],
3143                                                 probe_rsp->timeStamp[6],
3144                                                 probe_rsp->timeStamp[7]);
3145
3146                                 DBG_TRACE( DbgInfo, "(%s) beaconInt   : 0x%04x.\n",
3147                                                    lp->dev->name, probe_rsp->beaconInterval );
3148
3149                                 DBG_TRACE( DbgInfo, "(%s) capability  : 0x%04x.\n",
3150                                                    lp->dev->name, probe_rsp->capability );
3151
3152                                 DBG_TRACE( DbgInfo, "(%s) SSID len    : 0x%04x.\n",
3153                                                    lp->dev->name, probe_rsp->rawData[1] );
3154
3155                                 if ( probe_rsp->rawData[1] > 0 ) {
3156                                         char ssid[HCF_MAX_NAME_LEN];
3157
3158                                         memset( ssid, 0, sizeof( ssid ));
3159                                         strncpy( ssid, &probe_rsp->rawData[2],
3160                                                          probe_rsp->rawData[1] );
3161
3162                                         DBG_TRACE( DbgInfo, "(%s) SSID        : %s\n",
3163                                                            lp->dev->name, ssid );
3164                                 }
3165
3166                                 /* Parse out the WPA-IE, if one exists */
3167                                 wpa_ie = wl_parse_wpa_ie( probe_rsp, &wpa_ie_len );
3168                                 if ( wpa_ie != NULL ) {
3169                                         DBG_TRACE( DbgInfo, "(%s) WPA-IE      : %s\n",
3170                                         lp->dev->name, wl_print_wpa_ie( wpa_ie, wpa_ie_len ));
3171                                 }
3172
3173                                 DBG_TRACE( DbgInfo, "(%s) flags       : 0x%04x.\n",
3174                                                    lp->dev->name, probe_rsp->flags );
3175                         }
3176
3177                         DBG_TRACE( DbgInfo, "\n\n" );
3178                         /* If probe response length is 1, then the scan is complete */
3179                         if ( probe_rsp->length == 1 ) {
3180                                 DBG_TRACE( DbgInfo, "SCAN COMPLETE\n" );
3181                                 lp->probe_results.num_aps = lp->probe_num_aps;
3182                                 lp->probe_results.scan_complete = TRUE;
3183
3184                                 /* Reset the counter for the next scan request */
3185                                 lp->probe_num_aps = 0;
3186
3187                                 /* Send a wireless extensions event that the scan completed */
3188                                 wl_wext_event_scan_complete( lp->dev );
3189                         } else {
3190                                 /* Only copy to the table if the entry is unique; APs sometimes
3191                                    respond more than once to a probe */
3192                                 if ( lp->probe_num_aps == 0 ) {
3193                                         /* Copy the info to the ScanResult structure in the private
3194                                         adapter struct */
3195                                         memcpy( &( lp->probe_results.ProbeTable[lp->probe_num_aps] ),
3196                                                         probe_rsp, sizeof( PROBE_RESP ));
3197
3198                                         /* Increment the number of APs detected */
3199                                         lp->probe_num_aps++;
3200                                 } else {
3201                                         int count;
3202                                         int unique = 1;
3203
3204                                         for( count = 0; count < lp->probe_num_aps; count++ ) {
3205                                                 if ( memcmp( &( probe_rsp->BSSID ),
3206                                                         lp->probe_results.ProbeTable[count].BSSID,
3207                                                         ETH_ALEN ) == 0 ) {
3208                                                         unique = 0;
3209                                                 }
3210                                         }
3211
3212                                         if ( unique ) {
3213                                                 /* Copy the info to the ScanResult structure in the
3214                                                 private adapter struct. Only copy if there's room in the
3215                                                 table */
3216                                                 if ( lp->probe_num_aps < MAX_NAPS )
3217                                                 {
3218                                                         memcpy( &( lp->probe_results.ProbeTable[lp->probe_num_aps] ),
3219                                                                         probe_rsp, sizeof( PROBE_RESP ));
3220                                                 }
3221                                                 else
3222                                                 {
3223                                                         DBG_WARNING( DbgInfo, "Num of scan results exceeds storage, truncating\n" );
3224                                                 }
3225
3226                                                 /* Increment the number of APs detected. Note I do this
3227                                                    here even when I don't copy the probe response to the
3228                                                    buffer in order to detect the overflow condition */
3229                                                 lp->probe_num_aps++;
3230                                         }
3231                                 }
3232                         }
3233                 }
3234
3235                 break;
3236
3237           case CFG_LINK_STAT:
3238 #define ls ((LINK_STATUS_STRCT *)ltv)
3239                 DBG_TRACE( DbgInfo, "CFG_LINK_STAT\n" );
3240
3241                 switch( ls->linkStatus ) {
3242                   case 1:
3243                         DBG_TRACE( DbgInfo, "Link Status : Connected\n" );
3244                         wl_wext_event_ap( lp->dev );
3245                         break;
3246
3247                   case 2:
3248                         DBG_TRACE( DbgInfo, "Link Status : Disconnected\n"  );
3249                         break;
3250
3251                   case 3:
3252                         DBG_TRACE( DbgInfo, "Link Status : Access Point Change\n" );
3253                         break;
3254
3255                   case 4:
3256                         DBG_TRACE( DbgInfo, "Link Status : Access Point Out of Range\n" );
3257                         break;
3258
3259                   case 5:
3260                         DBG_TRACE( DbgInfo, "Link Status : Access Point In Range\n" );
3261                         break;
3262
3263                 default:
3264                         DBG_TRACE( DbgInfo, "Link Status : UNKNOWN (0x%04x)\n",
3265                                            ls->linkStatus );
3266                         break;
3267                 }
3268
3269                 break;
3270 #undef ls
3271
3272           case CFG_ASSOC_STAT:
3273                 DBG_TRACE( DbgInfo, "CFG_ASSOC_STAT\n" );
3274
3275                 {
3276                         ASSOC_STATUS_STRCT *as = (ASSOC_STATUS_STRCT *)ltv;
3277
3278                         switch( as->assocStatus ) {
3279                           case 1:
3280                                 DBG_TRACE( DbgInfo, "Association Status : STA Associated\n" );
3281                                 break;
3282
3283                           case 2:
3284                                 DBG_TRACE( DbgInfo, "Association Status : STA Reassociated\n" );
3285                                 break;
3286
3287                           case 3:
3288                                 DBG_TRACE( DbgInfo, "Association Status : STA Disassociated\n" );
3289                                 break;
3290
3291                         default:
3292                                 DBG_TRACE( DbgInfo, "Association Status : UNKNOWN (0x%04x)\n",
3293                                                    as->assocStatus );
3294                                 break;
3295                         }
3296
3297                         DBG_TRACE(DbgInfo, "STA Address        : %pM\n",
3298                                            as->staAddr);
3299
3300                         if (( as->assocStatus == 2 )  && ( as->len == 8 )) {
3301                                 DBG_TRACE(DbgInfo, "Old AP Address     : %pM\n",
3302                                                    as->oldApAddr);
3303                         }
3304                 }
3305
3306                 break;
3307
3308           case CFG_SECURITY_STAT:
3309                 DBG_TRACE( DbgInfo, "CFG_SECURITY_STAT\n" );
3310
3311                 {
3312                         SECURITY_STATUS_STRCT *ss = (SECURITY_STATUS_STRCT *)ltv;
3313
3314                         switch( ss->securityStatus ) {
3315                           case 1:
3316                                 DBG_TRACE( DbgInfo, "Security Status : Dissassociate [AP]\n" );
3317                                 break;
3318
3319                           case 2:
3320                                 DBG_TRACE( DbgInfo, "Security Status : Deauthenticate [AP]\n" );
3321                                 break;
3322
3323                           case 3:
3324                                 DBG_TRACE( DbgInfo, "Security Status : Authenticate Fail [STA] or [AP]\n" );
3325                                 break;
3326
3327                           case 4:
3328                                 DBG_TRACE( DbgInfo, "Security Status : MIC Fail\n" );
3329                                 break;
3330
3331                           case 5:
3332                                 DBG_TRACE( DbgInfo, "Security Status : Associate Fail\n" );
3333                                 break;
3334
3335                         default:
3336                                 DBG_TRACE( DbgInfo, "Security Status : UNKNOWN %d\n",
3337                                                    ss->securityStatus );
3338                                 break;
3339                         }
3340
3341                         DBG_TRACE(DbgInfo, "STA Address     : %pM\n",
3342                                         ss->staAddr);
3343
3344                         DBG_TRACE(DbgInfo, "Reason          : 0x%04x\n",
3345                                         ss->reason);
3346                 }
3347
3348                 break;
3349
3350           case CFG_WMP:
3351                 DBG_TRACE( DbgInfo, "CFG_WMP, size is %d bytes\n", ltv->len );
3352                 {
3353                         WMP_RSP_STRCT *wmp_rsp = (WMP_RSP_STRCT *)ltv;
3354
3355                         DBG_TRACE( DbgInfo, "CFG_WMP, pdu type is 0x%x\n",
3356                                            wmp_rsp->wmpRsp.wmpHdr.type );
3357
3358                         switch( wmp_rsp->wmpRsp.wmpHdr.type ) {
3359                           case WVLAN_WMP_PDU_TYPE_LT_RSP:
3360                                 {
3361 #if DBG
3362                                         LINKTEST_RSP_STRCT  *lt_rsp = (LINKTEST_RSP_STRCT *)ltv;
3363 #endif // DBG
3364                                         DBG_TRACE( DbgInfo, "LINK TEST RESULT\n" );
3365                                         DBG_TRACE( DbgInfo, "================\n" );
3366                                         DBG_TRACE( DbgInfo, "Length        : %d.\n",     lt_rsp->len );
3367
3368                                         DBG_TRACE( DbgInfo, "Name          : %s.\n",     lt_rsp->ltRsp.ltRsp.name );
3369                                         DBG_TRACE( DbgInfo, "Signal Level  : 0x%02x.\n", lt_rsp->ltRsp.ltRsp.signal );
3370                                         DBG_TRACE( DbgInfo, "Noise  Level  : 0x%02x.\n", lt_rsp->ltRsp.ltRsp.noise );
3371                                         DBG_TRACE( DbgInfo, "Receive Flow  : 0x%02x.\n", lt_rsp->ltRsp.ltRsp.rxFlow );
3372                                         DBG_TRACE( DbgInfo, "Data Rate     : 0x%02x.\n", lt_rsp->ltRsp.ltRsp.dataRate );
3373                                         DBG_TRACE( DbgInfo, "Protocol      : 0x%04x.\n", lt_rsp->ltRsp.ltRsp.protocol );
3374                                         DBG_TRACE( DbgInfo, "Station       : 0x%02x.\n", lt_rsp->ltRsp.ltRsp.station );
3375                                         DBG_TRACE( DbgInfo, "Data Rate Cap : 0x%02x.\n", lt_rsp->ltRsp.ltRsp.dataRateCap );
3376
3377                                         DBG_TRACE( DbgInfo, "Power Mgmt    : 0x%02x 0x%02x 0x%02x 0x%02x.\n",
3378                                                                 lt_rsp->ltRsp.ltRsp.powerMgmt[0],
3379                                                                 lt_rsp->ltRsp.ltRsp.powerMgmt[1],
3380                                                                 lt_rsp->ltRsp.ltRsp.powerMgmt[2],
3381                                                                 lt_rsp->ltRsp.ltRsp.powerMgmt[3] );
3382
3383                                         DBG_TRACE( DbgInfo, "Robustness    : 0x%02x 0x%02x 0x%02x 0x%02x.\n",
3384                                                                 lt_rsp->ltRsp.ltRsp.robustness[0],
3385                                                                 lt_rsp->ltRsp.ltRsp.robustness[1],
3386                                                                 lt_rsp->ltRsp.ltRsp.robustness[2],
3387                                                                 lt_rsp->ltRsp.ltRsp.robustness[3] );
3388
3389                                         DBG_TRACE( DbgInfo, "Scaling       : 0x%02x.\n", lt_rsp->ltRsp.ltRsp.scaling );
3390                                 }
3391
3392                                 break;
3393
3394                         default:
3395                                 break;
3396                         }
3397                 }
3398
3399                 break;
3400
3401           case CFG_NULL:
3402                 DBG_TRACE( DbgInfo, "CFG_NULL\n" );
3403                 break;
3404
3405           case CFG_UPDATED_INFO_RECORD:        // Updated Information Record
3406                 DBG_TRACE( DbgInfo, "UPDATED INFORMATION RECORD\n" );
3407
3408                 ltv_val = CNV_INT_TO_LITTLE( ltv->u.u16[0] );
3409
3410                 /* Check and see which RID was updated */
3411                 switch( ltv_val ) {
3412                   case CFG_CUR_COUNTRY_INFO:  // Indicate Passive Scan Completion
3413                         DBG_TRACE( DbgInfo, "Updated country info\n" );
3414
3415                         /* Do I need to hold off on updating RIDs until the process is
3416                            complete? */
3417                         wl_connect( lp );
3418                         break;
3419
3420                   case CFG_PORT_STAT:    // Wait for Connect Event
3421                         //wl_connect( lp );
3422
3423                         break;
3424
3425                 default:
3426                         DBG_WARNING( DbgInfo, "Unknown RID: 0x%04x\n", ltv_val );
3427                 }
3428
3429                 break;
3430
3431         default:
3432                 DBG_TRACE( DbgInfo, "UNKNOWN MESSAGE: 0x%04x\n", ltv->typ );
3433                 break;
3434         }
3435         DBG_LEAVE( DbgInfo );
3436         return;
3437 } // wl_process_mailbox
3438 /*============================================================================*/
3439 #endif  /* ifndef USE_MBOX_SYNC */
3440
3441 #ifdef USE_WDS
3442 /*******************************************************************************
3443  *      wl_wds_netdev_register()
3444  *******************************************************************************
3445  *
3446  *  DESCRIPTION:
3447  *
3448  *      This function registers net_device structures with the system's network
3449  *      layer for use with the WDS ports.
3450  *
3451  *
3452  *  PARAMETERS:
3453  *
3454  *      lp      - pointer to the device's private adapter structure
3455  *
3456  *  RETURNS:
3457  *
3458  *      N/A
3459  *
3460  ******************************************************************************/
3461 void wl_wds_netdev_register( struct wl_private *lp )
3462 {
3463         int count;
3464         /*------------------------------------------------------------------------*/
3465         DBG_FUNC( "wl_wds_netdev_register" );
3466         DBG_ENTER( DbgInfo );
3467         //;?why is there no USE_WDS clause like in wl_enable_wds_ports
3468         if ( CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.comp_id ) == COMP_ID_FW_AP  ) {
3469                 for( count = 0; count < NUM_WDS_PORTS; count++ ) {
3470                         if ( WVLAN_VALID_MAC_ADDRESS( lp->wds_port[count].wdsAddress )) {
3471                                 if ( register_netdev( lp->wds_port[count].dev ) != 0 ) {
3472                                         DBG_WARNING( DbgInfo, "net device for WDS port %d could not be registered\n",
3473                                                                 ( count + 1 ));
3474                                 }
3475                                 lp->wds_port[count].is_registered = TRUE;
3476
3477                                 /* Fill out the net_device structs with the MAC addr */
3478                                 memcpy( lp->wds_port[count].dev->dev_addr, lp->MACAddress, ETH_ALEN );
3479                                 lp->wds_port[count].dev->addr_len = ETH_ALEN;
3480                         }
3481                 }
3482         }
3483         DBG_LEAVE( DbgInfo );
3484         return;
3485 } // wl_wds_netdev_register
3486 /*============================================================================*/
3487
3488
3489 /*******************************************************************************
3490  *      wl_wds_netdev_deregister()
3491  *******************************************************************************
3492  *
3493  *  DESCRIPTION:
3494  *
3495  *      This function deregisters the WDS net_device structures used by the
3496  *      system's network layer.
3497  *
3498  *
3499  *  PARAMETERS:
3500  *
3501  *      lp      - pointer to the device's private adapter structure
3502  *
3503  *  RETURNS:
3504  *
3505  *      N/A
3506  *
3507  ******************************************************************************/
3508 void wl_wds_netdev_deregister( struct wl_private *lp )
3509 {
3510         int count;
3511         /*------------------------------------------------------------------------*/
3512         DBG_FUNC( "wl_wds_netdev_deregister" );
3513         DBG_ENTER( DbgInfo );
3514         if ( CNV_INT_TO_LITTLE( lp->hcfCtx.IFB_FWIdentity.comp_id ) == COMP_ID_FW_AP  ) {
3515                 for( count = 0; count < NUM_WDS_PORTS; count++ ) {
3516                         if ( WVLAN_VALID_MAC_ADDRESS( lp->wds_port[count].wdsAddress )) {
3517                                 unregister_netdev( lp->wds_port[count].dev );
3518                         }
3519                         lp->wds_port[count].is_registered = FALSE;
3520                 }
3521         }
3522         DBG_LEAVE( DbgInfo );
3523         return;
3524 } // wl_wds_netdev_deregister
3525 /*============================================================================*/
3526 #endif  /* USE_WDS */
3527
3528
3529 #if 0 //SCULL_USE_PROC /* don't waste space if unused */
3530 /*
3531  * The proc filesystem: function to read and entry
3532  */
3533 int printf_hcf_16( char *s, char *buf, hcf_16* p, int n );
3534 int printf_hcf_16( char *s, char *buf, hcf_16* p, int n ) {
3535
3536 int i, len;
3537
3538         len = sprintf(buf, "%s", s );
3539         while ( len < 20 ) len += sprintf(buf+len, " " );
3540         len += sprintf(buf+len,": " );
3541         for ( i = 0; i < n; i++ ) {
3542                 if ( len % 80 > 75 ) {
3543                         len += sprintf(buf+len,"\n" );
3544                 }
3545                 len += sprintf(buf+len,"%04X ", p[i] );
3546         }
3547         len += sprintf(buf+len,"\n" );
3548         return len;
3549 } // printf_hcf_16
3550
3551 int printf_hcf_8( char *s, char *buf, hcf_8* p, int n );
3552 int printf_hcf_8( char *s, char *buf, hcf_8* p, int n ) {
3553
3554 int i, len;
3555
3556         len = sprintf(buf, "%s", s );
3557         while ( len < 20 ) len += sprintf(buf+len, " " );
3558         len += sprintf(buf+len,": " );
3559         for ( i = 0; i <= n; i++ ) {
3560                 if ( len % 80 > 77 ) {
3561                         len += sprintf(buf+len,"\n" );
3562                 }
3563                 len += sprintf(buf+len,"%02X ", p[i] );
3564         }
3565         len += sprintf(buf+len,"\n" );
3566         return len;
3567 } // printf_hcf8
3568
3569 int printf_strct( char *s, char *buf, hcf_16* p );
3570 int printf_strct( char *s, char *buf, hcf_16* p ) {
3571
3572 int i, len;
3573
3574         len = sprintf(buf, "%s", s );
3575         while ( len < 20 ) len += sprintf(buf+len, " " );
3576         len += sprintf(buf+len,": " );
3577         for ( i = 0; i <= *p; i++ ) {
3578                 if ( len % 80 > 75 ) {
3579                         len += sprintf(buf+len,"\n" );
3580                 }
3581                 len += sprintf(buf+len,"%04X ", p[i] );
3582         }
3583         len += sprintf(buf+len,"\n" );
3584         return len;
3585 } // printf_strct
3586
3587 int scull_read_procmem(char *buf, char **start, off_t offset, int len, int *eof, void *data )
3588 {
3589         struct wl_private       *lp = NULL;
3590         IFBP                            ifbp;
3591         CFG_HERMES_TALLIES_STRCT *p;
3592
3593     #define LIMIT (PAGE_SIZE-80) /* don't print any more after this size */
3594
3595     len=0;
3596
3597         lp = ((struct net_device *)data)->priv;
3598         if (lp == NULL) {
3599         len += sprintf(buf+len,"No wl_private in scull_read_procmem\n" );
3600         } else if ( lp->wlags49_type == 0 ){
3601             ifbp = &lp->hcfCtx;
3602             len += sprintf(buf+len,"Magic:               0x%04X\n", ifbp->IFB_Magic );
3603             len += sprintf(buf+len,"IOBase:              0x%04X\n", ifbp->IFB_IOBase );
3604             len += sprintf(buf+len,"LinkStat:            0x%04X\n", ifbp->IFB_LinkStat );
3605             len += sprintf(buf+len,"DSLinkStat:          0x%04X\n", ifbp->IFB_DSLinkStat );
3606             len += sprintf(buf+len,"TickIni:         0x%08lX\n", ifbp->IFB_TickIni );
3607             len += sprintf(buf+len,"TickCnt:             0x%04X\n", ifbp->IFB_TickCnt );
3608             len += sprintf(buf+len,"IntOffCnt:           0x%04X\n", ifbp->IFB_IntOffCnt );
3609                 len += printf_hcf_16( "IFB_FWIdentity", &buf[len],
3610                                                           &ifbp->IFB_FWIdentity.len, ifbp->IFB_FWIdentity.len + 1 );
3611         } else if ( lp->wlags49_type == 1 ) {
3612             len += sprintf(buf+len,"Channel:              0x%04X\n", lp->Channel );
3613 /****** len += sprintf(buf+len,"slock:                  %d\n", lp->slock );             */
3614 //x             struct tq_struct            "task:               0x%04X\n", lp->task );
3615 //x             struct net_device_stats     "stats:              0x%04X\n", lp->stats );
3616 #ifdef WIRELESS_EXT
3617 //x             struct iw_statistics        "wstats:             0x%04X\n", lp->wstats );
3618 //x         len += sprintf(buf+len,"spy_number:           0x%04X\n", lp->spy_number );
3619 //x             u_char                      spy_address[IW_MAX_SPY][ETH_ALEN];
3620 //x             struct iw_quality           spy_stat[IW_MAX_SPY];
3621 #endif // WIRELESS_EXT
3622             len += sprintf(buf+len,"IFB:                  0x%p\n", &lp->hcfCtx );
3623             len += sprintf(buf+len,"flags:                %#.8lX\n", lp->flags );  //;?use this format from now on
3624             len += sprintf(buf+len,"DebugFlag(wl_private) 0x%04X\n", lp->DebugFlag );
3625 #if DBG
3626             len += sprintf(buf+len,"DebugFlag (DbgInfo):   0x%08lX\n", DbgInfo->DebugFlag );
3627 #endif // DBG
3628             len += sprintf(buf+len,"is_registered:        0x%04X\n", lp->is_registered );
3629 //x             CFG_DRV_INFO_STRCT          "driverInfo:         0x%04X\n", lp->driverInfo );
3630                 len += printf_strct( "driverInfo", &buf[len], (hcf_16*)&lp->driverInfo );
3631 //x             CFG_IDENTITY_STRCT          "driverIdentity:     0x%04X\n", lp->driverIdentity );
3632                 len += printf_strct( "driverIdentity", &buf[len], (hcf_16*)&lp->driverIdentity );
3633 //x             CFG_FW_IDENTITY_STRCT       "StationIdentity:    0x%04X\n", lp->StationIdentity );
3634                 len += printf_strct( "StationIdentity", &buf[len], (hcf_16*)&lp->StationIdentity );
3635 //x             CFG_PRI_IDENTITY_STRCT      "PrimaryIdentity:    0x%04X\n", lp->PrimaryIdentity );
3636                 len += printf_strct( "PrimaryIdentity", &buf[len], (hcf_16*)&lp->hcfCtx.IFB_PRIIdentity );
3637                 len += printf_strct( "PrimarySupplier", &buf[len], (hcf_16*)&lp->hcfCtx.IFB_PRISup );
3638 //x             CFG_PRI_IDENTITY_STRCT      "NICIdentity:        0x%04X\n", lp->NICIdentity );
3639                 len += printf_strct( "NICIdentity", &buf[len], (hcf_16*)&lp->NICIdentity );
3640 //x             ltv_t                       "ltvRecord:          0x%04X\n", lp->ltvRecord );
3641             len += sprintf(buf+len,"txBytes:              0x%08lX\n", lp->txBytes );
3642             len += sprintf(buf+len,"maxPort:              0x%04X\n", lp->maxPort );        /* 0 for STA, 6 for AP */
3643         /* Elements used for async notification from hardware */
3644 //x             RID_LOG_STRCT                           RidList[10];
3645 //x             ltv_t                       "updatedRecord:      0x%04X\n", lp->updatedRecord );
3646 //x             PROBE_RESP                                  "ProbeResp:                    0x%04X\n", lp->ProbeResp );
3647 //x             ASSOC_STATUS_STRCT          "assoc_stat:         0x%04X\n", lp->assoc_stat );
3648 //x             SECURITY_STATUS_STRCT       "sec_stat:           0x%04X\n", lp->sec_stat );
3649 //x             u_char                      lookAheadBuf[WVLAN_MAX_LOOKAHEAD];
3650             len += sprintf(buf+len,"PortType:             0x%04X\n", lp->PortType );           // 1 - 3 (1 [Normal] | 3 [AdHoc])
3651             len += sprintf(buf+len,"Channel:              0x%04X\n", lp->Channel );            // 0 - 14 (0)
3652 //x             hcf_16                      TxRateControl[2];
3653             len += sprintf(buf+len,"TxRateControl[2]:     0x%04X 0x%04X\n",
3654                                                 lp->TxRateControl[0], lp->TxRateControl[1] );
3655             len += sprintf(buf+len,"DistanceBetweenAPs:   0x%04X\n", lp->DistanceBetweenAPs ); // 1 - 3 (1)
3656             len += sprintf(buf+len,"RTSThreshold:         0x%04X\n", lp->RTSThreshold );       // 0 - 2347 (2347)
3657             len += sprintf(buf+len,"PMEnabled:            0x%04X\n", lp->PMEnabled );          // 0 - 2, 8001 - 8002 (0)
3658             len += sprintf(buf+len,"MicrowaveRobustness:  0x%04X\n", lp->MicrowaveRobustness );// 0 - 1 (0)
3659             len += sprintf(buf+len,"CreateIBSS:           0x%04X\n", lp->CreateIBSS );         // 0 - 1 (0)
3660             len += sprintf(buf+len,"MulticastReceive:     0x%04X\n", lp->MulticastReceive );   // 0 - 1 (1)
3661             len += sprintf(buf+len,"MaxSleepDuration:     0x%04X\n", lp->MaxSleepDuration );   // 0 - 65535 (100)
3662 //x             hcf_8                       MACAddress[ETH_ALEN];
3663                 len += printf_hcf_8( "MACAddress", &buf[len], lp->MACAddress, ETH_ALEN );
3664 //x             char                        NetworkName[HCF_MAX_NAME_LEN+1];
3665             len += sprintf(buf+len,"NetworkName:          %.32s\n", lp->NetworkName );
3666 //x             char                        StationName[HCF_MAX_NAME_LEN+1];
3667             len += sprintf(buf+len,"EnableEncryption:     0x%04X\n", lp->EnableEncryption );   // 0 - 1 (0)
3668 //x             char                        Key1[MAX_KEY_LEN+1];
3669                 len += printf_hcf_8( "Key1", &buf[len], lp->Key1, MAX_KEY_LEN );
3670 //x             char                        Key2[MAX_KEY_LEN+1];
3671 //x             char                        Key3[MAX_KEY_LEN+1];
3672 //x             char                        Key4[MAX_KEY_LEN+1];
3673             len += sprintf(buf+len,"TransmitKeyID:        0x%04X\n", lp->TransmitKeyID );      // 1 - 4 (1)
3674 //x             CFG_DEFAULT_KEYS_STRCT      "DefaultKeys:         0x%04X\n", lp->DefaultKeys );
3675 //x             u_char                      mailbox[MB_SIZE];
3676 //x             char                        szEncryption[MAX_ENC_LEN];
3677             len += sprintf(buf+len,"driverEnable:         0x%04X\n", lp->driverEnable );
3678             len += sprintf(buf+len,"wolasEnable:          0x%04X\n", lp->wolasEnable );
3679             len += sprintf(buf+len,"atimWindow:           0x%04X\n", lp->atimWindow );
3680             len += sprintf(buf+len,"holdoverDuration:     0x%04X\n", lp->holdoverDuration );
3681 //x             hcf_16                      MulticastRate[2];
3682             len += sprintf(buf+len,"authentication:       0x%04X\n", lp->authentication ); // is this AP specific?
3683             len += sprintf(buf+len,"promiscuousMode:      0x%04X\n", lp->promiscuousMode );
3684             len += sprintf(buf+len,"DownloadFirmware:     0x%04X\n", lp->DownloadFirmware );   // 0 - 2 (0 [None] | 1 [STA] | 2 [AP])
3685             len += sprintf(buf+len,"AuthKeyMgmtSuite:     0x%04X\n", lp->AuthKeyMgmtSuite );
3686             len += sprintf(buf+len,"loadBalancing:        0x%04X\n", lp->loadBalancing );
3687             len += sprintf(buf+len,"mediumDistribution:   0x%04X\n", lp->mediumDistribution );
3688             len += sprintf(buf+len,"txPowLevel:           0x%04X\n", lp->txPowLevel );
3689 //          len += sprintf(buf+len,"shortRetryLimit:    0x%04X\n", lp->shortRetryLimit );
3690 //          len += sprintf(buf+len,"longRetryLimit:     0x%04X\n", lp->longRetryLimit );
3691 //x             hcf_16                      srsc[2];
3692 //x             hcf_16                      brsc[2];
3693             len += sprintf(buf+len,"connectionControl:    0x%04X\n", lp->connectionControl );
3694 //x             //hcf_16                      probeDataRates[2];
3695             len += sprintf(buf+len,"ownBeaconInterval:    0x%04X\n", lp->ownBeaconInterval );
3696             len += sprintf(buf+len,"coexistence:          0x%04X\n", lp->coexistence );
3697 //x             WVLAN_FRAME                 "txF:                0x%04X\n", lp->txF );
3698 //x             WVLAN_LFRAME                txList[DEFAULT_NUM_TX_FRAMES];
3699 //x             struct list_head            "txFree:             0x%04X\n", lp->txFree );
3700 //x             struct list_head            txQ[WVLAN_MAX_TX_QUEUES];
3701             len += sprintf(buf+len,"netif_queue_on:       0x%04X\n", lp->netif_queue_on );
3702             len += sprintf(buf+len,"txQ_count:            0x%04X\n", lp->txQ_count );
3703 //x             DESC_STRCT                  "desc_rx:            0x%04X\n", lp->desc_rx );
3704 //x             DESC_STRCT                  "desc_tx:            0x%04X\n", lp->desc_tx );
3705 //x             WVLAN_PORT_STATE            "portState:          0x%04X\n", lp->portState );
3706 //x             ScanResult                  "scan_results:       0x%04X\n", lp->scan_results );
3707 //x             ProbeResult                 "probe_results:      0x%04X\n", lp->probe_results );
3708             len += sprintf(buf+len,"probe_num_aps:        0x%04X\n", lp->probe_num_aps );
3709             len += sprintf(buf+len,"use_dma:              0x%04X\n", lp->use_dma );
3710 //x             DMA_STRCT                   "dma:                0x%04X\n", lp->dma );
3711 #ifdef USE_RTS
3712             len += sprintf(buf+len,"useRTS:               0x%04X\n", lp->useRTS );
3713 #endif  // USE_RTS
3714 #if 1 //;? (HCF_TYPE) & HCF_TYPE_AP
3715                 //;?should we restore this to allow smaller memory footprint
3716                 //;?I guess not. This should be brought under Debug mode only
3717             len += sprintf(buf+len,"DTIMPeriod:           0x%04X\n", lp->DTIMPeriod );         // 1 - 255 (1)
3718             len += sprintf(buf+len,"multicastPMBuffering: 0x%04X\n", lp->multicastPMBuffering );
3719             len += sprintf(buf+len,"RejectAny:            0x%04X\n", lp->RejectAny );          // 0 - 1 (0)
3720             len += sprintf(buf+len,"ExcludeUnencrypted:   0x%04X\n", lp->ExcludeUnencrypted ); // 0 - 1 (1)
3721             len += sprintf(buf+len,"intraBSSRelay:        0x%04X\n", lp->intraBSSRelay );
3722             len += sprintf(buf+len,"wlags49_type:             0x%08lX\n", lp->wlags49_type );
3723 #ifdef USE_WDS
3724 //x             WVLAN_WDS_IF                wds_port[NUM_WDS_PORTS];
3725 #endif // USE_WDS
3726 #endif // HCF_AP
3727         } else if ( lp->wlags49_type == 2 ){
3728         len += sprintf(buf+len,"tallies to be added\n" );
3729 //Hermes Tallies (IFB substructure) {
3730             p = &lp->hcfCtx.IFB_NIC_Tallies;
3731         len += sprintf(buf+len,"TxUnicastFrames:          %08lX\n", p->TxUnicastFrames );
3732         len += sprintf(buf+len,"TxMulticastFrames:        %08lX\n", p->TxMulticastFrames );
3733         len += sprintf(buf+len,"TxFragments:              %08lX\n", p->TxFragments );
3734         len += sprintf(buf+len,"TxUnicastOctets:          %08lX\n", p->TxUnicastOctets );
3735         len += sprintf(buf+len,"TxMulticastOctets:        %08lX\n", p->TxMulticastOctets );
3736         len += sprintf(buf+len,"TxDeferredTransmissions:  %08lX\n", p->TxDeferredTransmissions );
3737         len += sprintf(buf+len,"TxSingleRetryFrames:      %08lX\n", p->TxSingleRetryFrames );
3738         len += sprintf(buf+len,"TxMultipleRetryFrames:    %08lX\n", p->TxMultipleRetryFrames );
3739         len += sprintf(buf+len,"TxRetryLimitExceeded:     %08lX\n", p->TxRetryLimitExceeded );
3740         len += sprintf(buf+len,"TxDiscards:               %08lX\n", p->TxDiscards );
3741         len += sprintf(buf+len,"RxUnicastFrames:          %08lX\n", p->RxUnicastFrames );
3742         len += sprintf(buf+len,"RxMulticastFrames:        %08lX\n", p->RxMulticastFrames );
3743         len += sprintf(buf+len,"RxFragments:              %08lX\n", p->RxFragments );
3744         len += sprintf(buf+len,"RxUnicastOctets:          %08lX\n", p->RxUnicastOctets );
3745         len += sprintf(buf+len,"RxMulticastOctets:        %08lX\n", p->RxMulticastOctets );
3746         len += sprintf(buf+len,"RxFCSErrors:              %08lX\n", p->RxFCSErrors );
3747         len += sprintf(buf+len,"RxDiscardsNoBuffer:       %08lX\n", p->RxDiscardsNoBuffer );
3748         len += sprintf(buf+len,"TxDiscardsWrongSA:        %08lX\n", p->TxDiscardsWrongSA );
3749         len += sprintf(buf+len,"RxWEPUndecryptable:       %08lX\n", p->RxWEPUndecryptable );
3750         len += sprintf(buf+len,"RxMsgInMsgFragments:      %08lX\n", p->RxMsgInMsgFragments );
3751         len += sprintf(buf+len,"RxMsgInBadMsgFragments:   %08lX\n", p->RxMsgInBadMsgFragments );
3752         len += sprintf(buf+len,"RxDiscardsWEPICVError:    %08lX\n", p->RxDiscardsWEPICVError );
3753         len += sprintf(buf+len,"RxDiscardsWEPExcluded:    %08lX\n", p->RxDiscardsWEPExcluded );
3754 #if (HCF_EXT) & HCF_EXT_TALLIES_FW
3755         //to be added ;?
3756 #endif // HCF_EXT_TALLIES_FW
3757         } else if ( lp->wlags49_type & 0x8000 ) {       //;?kludgy but it is unclear to me were else to place this
3758 #if DBG
3759                 DbgInfo->DebugFlag = lp->wlags49_type & 0x7FFF;
3760 #endif // DBG
3761                 lp->wlags49_type = 0;                           //default to IFB again ;?
3762         } else {
3763         len += sprintf(buf+len,"unknown value for wlags49_type: 0x%08lX\n", lp->wlags49_type );
3764         len += sprintf(buf+len,"0x0000 - IFB\n" );
3765         len += sprintf(buf+len,"0x0001 - wl_private\n" );
3766         len += sprintf(buf+len,"0x0002 - Tallies\n" );
3767         len += sprintf(buf+len,"0x8xxx - Change debufflag\n" );
3768         len += sprintf(buf+len,"ERROR    0001\nWARNING  0002\nNOTICE   0004\nTRACE    0008\n" );
3769         len += sprintf(buf+len,"VERBOSE  0010\nPARAM    0020\nBREAK    0040\nRX       0100\n" );
3770         len += sprintf(buf+len,"TX       0200\nDS       0400\n" );
3771         }
3772     return len;
3773 } // scull_read_procmem
3774
3775 static void proc_write(const char *name, write_proc_t *w, void *data)
3776 {
3777         struct proc_dir_entry * entry = create_proc_entry(name, S_IFREG | S_IWUSR, NULL);
3778         if (entry) {
3779                 entry->write_proc = w;
3780                 entry->data = data;
3781         }
3782 } // proc_write
3783
3784 static int write_int(struct file *file, const char *buffer, unsigned long count, void *data)
3785 {
3786         static char             proc_number[11];
3787         unsigned int    nr = 0;
3788
3789         DBG_FUNC( "write_int" );
3790         DBG_ENTER( DbgInfo );
3791
3792         if (count > 9) {
3793                 count = -EINVAL;
3794         } else if ( copy_from_user(proc_number, buffer, count) ) {
3795                 count = -EFAULT;
3796         }
3797         if  (count > 0 ) {
3798                 proc_number[count] = 0;
3799                 nr = simple_strtoul(proc_number , NULL, 0);
3800                 *(unsigned int *)data = nr;
3801                 if ( nr & 0x8000 ) {    //;?kludgy but it is unclear to me were else to place this
3802 #if DBG
3803                         DbgInfo->DebugFlag = nr & 0x7FFF;
3804 #endif // DBG
3805                 }
3806         }
3807         DBG_PRINT( "value: %08X\n", nr );
3808         DBG_LEAVE( DbgInfo );
3809         return count;
3810 } // write_int
3811
3812 #endif /* SCULL_USE_PROC */
3813
3814 #ifdef DN554
3815 #define RUN_AT(x)               (jiffies+(x))           //"borrowed" from include/pcmcia/k_compat.h
3816 #define DS_OOR  0x8000          //Deepsleep OutOfRange Status
3817
3818                 lp->timer_oor_cnt = DS_OOR;
3819                 init_timer( &lp->timer_oor );
3820                 lp->timer_oor.function = timer_oor;
3821                 lp->timer_oor.data = (unsigned long)lp;
3822                 lp->timer_oor.expires = RUN_AT( 3 * HZ );
3823                 add_timer( &lp->timer_oor );
3824                 printk( "<5>wl_enable: %ld\n", jiffies );               //;?remove me 1 day
3825 #endif //DN554
3826 #ifdef DN554
3827 /*******************************************************************************
3828  *      timer_oor()
3829  *******************************************************************************
3830  *
3831  *  DESCRIPTION:
3832  *
3833  *
3834  *  PARAMETERS:
3835  *
3836  *      arg - a u_long representing a pointer to a dev_link_t structure for the
3837  *            device to be released.
3838  *
3839  *  RETURNS:
3840  *
3841  *      N/A
3842  *
3843  ******************************************************************************/
3844 void timer_oor( u_long arg )
3845 {
3846         struct wl_private       *lp = (struct wl_private *)arg;
3847
3848     /*------------------------------------------------------------------------*/
3849
3850     DBG_FUNC( "timer_oor" );
3851     DBG_ENTER( DbgInfo );
3852     DBG_PARAM( DbgInfo, "arg", "0x%08lx", arg );
3853
3854         printk( "<5>timer_oor: %ld 0x%04X\n", jiffies, lp->timer_oor_cnt );             //;?remove me 1 day
3855         lp->timer_oor_cnt += 10;
3856     if ( (lp->timer_oor_cnt & ~DS_OOR) > 300 ) {
3857                 lp->timer_oor_cnt = 300;
3858         }
3859         lp->timer_oor_cnt |= DS_OOR;
3860         init_timer( &lp->timer_oor );
3861         lp->timer_oor.function = timer_oor;
3862         lp->timer_oor.data = (unsigned long)lp;
3863         lp->timer_oor.expires = RUN_AT( (lp->timer_oor_cnt & ~DS_OOR) * HZ );
3864         add_timer( &lp->timer_oor );
3865
3866     DBG_LEAVE( DbgInfo );
3867 } // timer_oor
3868 #endif //DN554
3869
3870 MODULE_LICENSE("Dual BSD/GPL");