1 /* $NetBSD: rtwphy.c,v 1.17 2019/11/10 21:16:35 chs Exp $ */
2 /*-
3  * Copyright (c) 2004, 2005 David Young.  All rights reserved.
4  *
5  * Programmed for NetBSD by David Young.
6  *
7  * Redistribution and use in source and binary forms, with or without
8  * modification, are permitted provided that the following conditions
9  * are met:
10  * 1. Redistributions of source code must retain the above copyright
11  *    notice, this list of conditions and the following disclaimer.
12  * 2. Redistributions in binary form must reproduce the above copyright
13  *    notice, this list of conditions and the following disclaimer in the
14  *    documentation and/or other materials provided with the distribution.
15  *
16  * THIS SOFTWARE IS PROVIDED BY David Young ``AS IS'' AND ANY
17  * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
18  * THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
19  * PARTICULAR PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL David
20  * Young BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
21  * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
22  * TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
23  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
24  * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
25  * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
26  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY
27  * OF SUCH DAMAGE.
28  */
29 /*
30  * Control the Philips SA2400 RF front-end and the baseband processor
31  * built into the Realtek RTL8180.
32  */
33 
34 #include <sys/cdefs.h>
35 __KERNEL_RCSID(0, "$NetBSD: rtwphy.c,v 1.17 2019/11/10 21:16:35 chs Exp $");
36 
37 #include <sys/param.h>
38 #include <sys/systm.h>
39 #include <sys/types.h>
40 #include <sys/device.h>
41 
42 #include <sys/bus.h>
43 
44 #include <net/if.h>
45 #include <net/if_media.h>
46 #include <net/if_ether.h>
47 
48 #include <net80211/ieee80211_netbsd.h>
49 #include <net80211/ieee80211_radiotap.h>
50 #include <net80211/ieee80211_var.h>
51 
52 #include <dev/ic/rtwreg.h>
53 #include <dev/ic/max2820reg.h>
54 #include <dev/ic/sa2400reg.h>
55 #include <dev/ic/rtwvar.h>
56 #include <dev/ic/rtwphyio.h>
57 #include <dev/ic/rtwphy.h>
58 
59 static int rtw_max2820_pwrstate(struct rtw_rf *, enum rtw_pwrstate);
60 static int rtw_sa2400_pwrstate(struct rtw_rf *, enum rtw_pwrstate);
61 
62 #define   GCT_WRITE(__gr, __addr, __val, __label)                               \
63           do {                                                                            \
64                     if (rtw_rfbus_write(&(__gr)->gr_bus, RTW_RFCHIPID_GCT,      \
65                         (__addr), (__val)) == -1)                               \
66                               goto __label;                                               \
67           } while(0)
68 
69 static int
rtw_bbp_preinit(struct rtw_regs * regs,u_int antatten0,int dflantb,u_int freq)70 rtw_bbp_preinit(struct rtw_regs *regs, u_int antatten0, int dflantb,
71     u_int freq)
72 {
73           u_int antatten = antatten0;
74           if (dflantb)
75                     antatten |= RTW_BBP_ANTATTEN_DFLANTB;
76           if (freq == 2484) /* channel 14 */
77                     antatten |= RTW_BBP_ANTATTEN_CHAN14;
78           return rtw_bbp_write(regs, RTW_BBP_ANTATTEN, antatten);
79 }
80 
81 static int
rtw_bbp_init(struct rtw_regs * regs,struct rtw_bbpset * bb,int antdiv,int dflantb,uint8_t cs_threshold,u_int freq)82 rtw_bbp_init(struct rtw_regs *regs, struct rtw_bbpset *bb, int antdiv,
83     int dflantb, uint8_t cs_threshold, u_int freq)
84 {
85           int rc;
86           uint32_t sys2, sys3;
87 
88           sys2 = bb->bb_sys2;
89           if (antdiv)
90                     sys2 |= RTW_BBP_SYS2_ANTDIV;
91           sys3 = bb->bb_sys3 |
92               __SHIFTIN(cs_threshold, RTW_BBP_SYS3_CSTHRESH_MASK);
93 
94 #define   RTW_BBP_WRITE_OR_RETURN(reg, val) \
95           if ((rc = rtw_bbp_write(regs, reg, val)) != 0) \
96                     return rc;
97 
98           RTW_BBP_WRITE_OR_RETURN(RTW_BBP_SYS1,             bb->bb_sys1);
99           RTW_BBP_WRITE_OR_RETURN(RTW_BBP_TXAGC,            bb->bb_txagc);
100           RTW_BBP_WRITE_OR_RETURN(RTW_BBP_LNADET,           bb->bb_lnadet);
101           RTW_BBP_WRITE_OR_RETURN(RTW_BBP_IFAGCINI,         bb->bb_ifagcini);
102           RTW_BBP_WRITE_OR_RETURN(RTW_BBP_IFAGCLIMIT,       bb->bb_ifagclimit);
103           RTW_BBP_WRITE_OR_RETURN(RTW_BBP_IFAGCDET,         bb->bb_ifagcdet);
104 
105           if ((rc = rtw_bbp_preinit(regs, bb->bb_antatten, dflantb, freq)) != 0)
106                     return rc;
107 
108           RTW_BBP_WRITE_OR_RETURN(RTW_BBP_TRL,              bb->bb_trl);
109           RTW_BBP_WRITE_OR_RETURN(RTW_BBP_SYS2,             sys2);
110           RTW_BBP_WRITE_OR_RETURN(RTW_BBP_SYS3,             sys3);
111           RTW_BBP_WRITE_OR_RETURN(RTW_BBP_CHESTLIM,         bb->bb_chestlim);
112           RTW_BBP_WRITE_OR_RETURN(RTW_BBP_CHSQLIM,          bb->bb_chsqlim);
113           return 0;
114 }
115 
116 static int
rtw_sa2400_txpower(struct rtw_rf * rf,uint8_t opaque_txpower)117 rtw_sa2400_txpower(struct rtw_rf *rf, uint8_t opaque_txpower)
118 {
119           struct rtw_sa2400 *sa = (struct rtw_sa2400 *)rf;
120           struct rtw_rfbus *bus = &sa->sa_bus;
121 
122           return rtw_rfbus_write(bus, RTW_RFCHIPID_PHILIPS, SA2400_TX,
123               opaque_txpower);
124 }
125 
126 /* make sure we're using the same settings as the reference driver */
127 static void
verify_syna(u_int freq,uint32_t val)128 verify_syna(u_int freq, uint32_t val)
129 {
130 #ifdef DIAGNOSTIC
131           uint32_t expected_val = ~val;
132 
133           switch (freq) {
134           case 2412:
135                     expected_val = 0x0000096c; /* ch 1 */
136                     break;
137           case 2417:
138                     expected_val = 0x00080970; /* ch 2 */
139                     break;
140           case 2422:
141                     expected_val = 0x00100974; /* ch 3 */
142                     break;
143           case 2427:
144                     expected_val = 0x00180978; /* ch 4 */
145                     break;
146           case 2432:
147                     expected_val = 0x00000980; /* ch 5 */
148                     break;
149           case 2437:
150                     expected_val = 0x00080984; /* ch 6 */
151                     break;
152           case 2442:
153                     expected_val = 0x00100988; /* ch 7 */
154                     break;
155           case 2447:
156                     expected_val = 0x0018098c; /* ch 8 */
157                     break;
158           case 2452:
159                     expected_val = 0x00000994; /* ch 9 */
160                     break;
161           case 2457:
162                     expected_val = 0x00080998; /* ch 10 */
163                     break;
164           case 2462:
165                     expected_val = 0x0010099c; /* ch 11 */
166                     break;
167           case 2467:
168                     expected_val = 0x001809a0; /* ch 12 */
169                     break;
170         case 2472:
171                     expected_val = 0x000009a8; /* ch 13 */
172                     break;
173         case 2484:
174                     expected_val = 0x000009b4; /* ch 14 */
175                     break;
176           }
177           KASSERT(val == expected_val);
178 #endif
179 }
180 
181 /* freq is in MHz */
182 static int
rtw_sa2400_tune(struct rtw_rf * rf,u_int freq)183 rtw_sa2400_tune(struct rtw_rf *rf, u_int freq)
184 {
185           struct rtw_sa2400 *sa = (struct rtw_sa2400 *)rf;
186           struct rtw_rfbus *bus = &sa->sa_bus;
187           int rc;
188           uint32_t syna, synb, sync;
189 
190           /* XO = 44MHz, R = 11, hence N is in units of XO / R = 4MHz.
191            *
192            * The channel spacing (5MHz) is not divisible by 4MHz, so
193            * we set the fractional part of N to compensate.
194            */
195           int n = freq / 4, nf = (freq % 4) * 2;
196 
197           syna = __SHIFTIN(nf, SA2400_SYNA_NF_MASK) | __SHIFTIN(n, SA2400_SYNA_N_MASK);
198           verify_syna(freq, syna);
199 
200           /* Divide the 44MHz crystal down to 4MHz. Set the fractional
201            * compensation charge pump value to agree with the fractional
202            * modulus.
203            */
204           synb = __SHIFTIN(11, SA2400_SYNB_R_MASK) | SA2400_SYNB_L_NORMAL |
205               SA2400_SYNB_ON | SA2400_SYNB_ONE |
206               __SHIFTIN(80, SA2400_SYNB_FC_MASK); /* agrees w/ SA2400_SYNA_FM = 0 */
207 
208           sync = SA2400_SYNC_CP_NORMAL;
209 
210           if ((rc = rtw_rfbus_write(bus, RTW_RFCHIPID_PHILIPS, SA2400_SYNA,
211               syna)) != 0)
212                     return rc;
213           if ((rc = rtw_rfbus_write(bus, RTW_RFCHIPID_PHILIPS, SA2400_SYNB,
214               synb)) != 0)
215                     return rc;
216           if ((rc = rtw_rfbus_write(bus, RTW_RFCHIPID_PHILIPS, SA2400_SYNC,
217               sync)) != 0)
218                     return rc;
219           return rtw_rfbus_write(bus, RTW_RFCHIPID_PHILIPS, SA2400_SYND, 0x0);
220 }
221 
222 static int
rtw_sa2400_pwrstate(struct rtw_rf * rf,enum rtw_pwrstate power)223 rtw_sa2400_pwrstate(struct rtw_rf *rf, enum rtw_pwrstate power)
224 {
225           struct rtw_sa2400 *sa = (struct rtw_sa2400 *)rf;
226           struct rtw_rfbus *bus = &sa->sa_bus;
227           uint32_t opmode;
228           opmode = SA2400_OPMODE_DEFAULTS;
229           switch (power) {
230           case RTW_ON:
231                     opmode |= SA2400_OPMODE_MODE_TXRX;
232                     break;
233           case RTW_SLEEP:
234                     opmode |= SA2400_OPMODE_MODE_WAIT;
235                     break;
236           case RTW_OFF:
237                     opmode |= SA2400_OPMODE_MODE_SLEEP;
238                     break;
239           }
240 
241           if (sa->sa_digphy)
242                     opmode |= SA2400_OPMODE_DIGIN;
243 
244           return rtw_rfbus_write(bus, RTW_RFCHIPID_PHILIPS, SA2400_OPMODE,
245               opmode);
246 }
247 
248 static int
rtw_sa2400_manrx_init(struct rtw_sa2400 * sa)249 rtw_sa2400_manrx_init(struct rtw_sa2400 *sa)
250 {
251           uint32_t manrx;
252 
253           /* XXX we are not supposed to be in RXMGC mode when we do
254            * this?
255            */
256           manrx = SA2400_MANRX_AHSN;
257           manrx |= SA2400_MANRX_TEN;
258           manrx |= __SHIFTIN(1023, SA2400_MANRX_RXGAIN_MASK);
259 
260           return rtw_rfbus_write(&sa->sa_bus, RTW_RFCHIPID_PHILIPS, SA2400_MANRX,
261               manrx);
262 }
263 
264 static int
rtw_sa2400_vcocal_start(struct rtw_sa2400 * sa,int start)265 rtw_sa2400_vcocal_start(struct rtw_sa2400 *sa, int start)
266 {
267           uint32_t opmode;
268 
269           opmode = SA2400_OPMODE_DEFAULTS;
270           if (start)
271                     opmode |= SA2400_OPMODE_MODE_VCOCALIB;
272           else
273                     opmode |= SA2400_OPMODE_MODE_SLEEP;
274 
275           if (sa->sa_digphy)
276                     opmode |= SA2400_OPMODE_DIGIN;
277 
278           return rtw_rfbus_write(&sa->sa_bus, RTW_RFCHIPID_PHILIPS, SA2400_OPMODE,
279               opmode);
280 }
281 
282 static int
rtw_sa2400_vco_calibration(struct rtw_sa2400 * sa)283 rtw_sa2400_vco_calibration(struct rtw_sa2400 *sa)
284 {
285           int rc;
286           /* calibrate VCO */
287           if ((rc = rtw_sa2400_vcocal_start(sa, 1)) != 0)
288                     return rc;
289           DELAY(2200);        /* 2.2 milliseconds */
290           /* XXX superfluous: SA2400 automatically entered SLEEP mode. */
291           return rtw_sa2400_vcocal_start(sa, 0);
292 }
293 
294 static int
rtw_sa2400_filter_calibration(struct rtw_sa2400 * sa)295 rtw_sa2400_filter_calibration(struct rtw_sa2400 *sa)
296 {
297           uint32_t opmode;
298 
299           opmode = SA2400_OPMODE_DEFAULTS | SA2400_OPMODE_MODE_FCALIB;
300           if (sa->sa_digphy)
301                     opmode |= SA2400_OPMODE_DIGIN;
302 
303           return rtw_rfbus_write(&sa->sa_bus, RTW_RFCHIPID_PHILIPS, SA2400_OPMODE,
304               opmode);
305 }
306 
307 static int
rtw_sa2400_dc_calibration(struct rtw_sa2400 * sa)308 rtw_sa2400_dc_calibration(struct rtw_sa2400 *sa)
309 {
310           struct rtw_rf *rf = &sa->sa_rf;
311           int rc;
312           uint32_t dccal;
313 
314           (*rf->rf_continuous_tx_cb)(rf->rf_continuous_tx_arg, 1);
315 
316           dccal = SA2400_OPMODE_DEFAULTS | SA2400_OPMODE_MODE_TXRX;
317 
318           rc = rtw_rfbus_write(&sa->sa_bus, RTW_RFCHIPID_PHILIPS, SA2400_OPMODE,
319               dccal);
320           if (rc != 0)
321                     return rc;
322 
323           DELAY(5); /* DCALIB after being in Tx mode for 5
324                                * microseconds
325                                */
326 
327           dccal &= ~SA2400_OPMODE_MODE_MASK;
328           dccal |= SA2400_OPMODE_MODE_DCALIB;
329 
330           rc = rtw_rfbus_write(&sa->sa_bus, RTW_RFCHIPID_PHILIPS, SA2400_OPMODE,
331              dccal);
332           if (rc != 0)
333                     return rc;
334 
335           DELAY(20);          /* calibration takes at most 20 microseconds */
336 
337           (*rf->rf_continuous_tx_cb)(rf->rf_continuous_tx_arg, 0);
338 
339           return 0;
340 }
341 
342 static int
rtw_sa2400_agc_init(struct rtw_sa2400 * sa)343 rtw_sa2400_agc_init(struct rtw_sa2400 *sa)
344 {
345           uint32_t agc;
346 
347           agc = __SHIFTIN(25, SA2400_AGC_MAXGAIN_MASK);
348           agc |= __SHIFTIN(7, SA2400_AGC_BBPDELAY_MASK);
349           agc |= __SHIFTIN(15, SA2400_AGC_LNADELAY_MASK);
350           agc |= __SHIFTIN(27, SA2400_AGC_RXONDELAY_MASK);
351 
352           return rtw_rfbus_write(&sa->sa_bus, RTW_RFCHIPID_PHILIPS, SA2400_AGC,
353               agc);
354 }
355 
356 static void
rtw_sa2400_destroy(struct rtw_rf * rf)357 rtw_sa2400_destroy(struct rtw_rf *rf)
358 {
359           struct rtw_sa2400 *sa = (struct rtw_sa2400 *)rf;
360           memset(sa, 0, sizeof(*sa));
361           free(sa, M_DEVBUF);
362 }
363 
364 static int
rtw_sa2400_calibrate(struct rtw_rf * rf,u_int freq)365 rtw_sa2400_calibrate(struct rtw_rf *rf, u_int freq)
366 {
367           struct rtw_sa2400 *sa = (struct rtw_sa2400 *)rf;
368           int i, rc;
369 
370           /* XXX reference driver calibrates VCO twice. Is it a bug? */
371           for (i = 0; i < 2; i++) {
372                     if ((rc = rtw_sa2400_vco_calibration(sa)) != 0)
373                               return rc;
374           }
375           /* VCO calibration erases synthesizer registers, so re-tune */
376           if ((rc = rtw_sa2400_tune(rf, freq)) != 0)
377                     return rc;
378           if ((rc = rtw_sa2400_filter_calibration(sa)) != 0)
379                     return rc;
380           /* analog PHY needs DC calibration */
381           if (!sa->sa_digphy)
382                     return rtw_sa2400_dc_calibration(sa);
383           return 0;
384 }
385 
386 static int
rtw_sa2400_init(struct rtw_rf * rf,u_int freq,uint8_t opaque_txpower,enum rtw_pwrstate power)387 rtw_sa2400_init(struct rtw_rf *rf, u_int freq, uint8_t opaque_txpower,
388     enum rtw_pwrstate power)
389 {
390           struct rtw_sa2400 *sa = (struct rtw_sa2400 *)rf;
391           int rc;
392 
393           if ((rc = rtw_sa2400_txpower(rf, opaque_txpower)) != 0)
394                     return rc;
395 
396           /* skip configuration if it's time to sleep or to power-down. */
397           if (power == RTW_SLEEP || power == RTW_OFF)
398                     return rtw_sa2400_pwrstate(rf, power);
399 
400           /* go to sleep for configuration */
401           if ((rc = rtw_sa2400_pwrstate(rf, RTW_SLEEP)) != 0)
402                     return rc;
403 
404           if ((rc = rtw_sa2400_tune(rf, freq)) != 0)
405                     return rc;
406           if ((rc = rtw_sa2400_agc_init(sa)) != 0)
407                     return rc;
408           if ((rc = rtw_sa2400_manrx_init(sa)) != 0)
409                     return rc;
410           if ((rc = rtw_sa2400_calibrate(rf, freq)) != 0)
411                     return rc;
412 
413           /* enter Tx/Rx mode */
414           return rtw_sa2400_pwrstate(rf, power);
415 }
416 
417 struct rtw_rf *
rtw_sa2400_create(struct rtw_regs * regs,rtw_rf_write_t rf_write,int digphy)418 rtw_sa2400_create(struct rtw_regs *regs, rtw_rf_write_t rf_write, int digphy)
419 {
420           struct rtw_sa2400 *sa;
421           struct rtw_rfbus *bus;
422           struct rtw_rf *rf;
423           struct rtw_bbpset *bb;
424 
425           sa = malloc(sizeof(*sa), M_DEVBUF, M_WAITOK | M_ZERO);
426           sa->sa_digphy = digphy;
427 
428           rf = &sa->sa_rf;
429           bus = &sa->sa_bus;
430 
431           rf->rf_init = rtw_sa2400_init;
432           rf->rf_destroy = rtw_sa2400_destroy;
433           rf->rf_txpower = rtw_sa2400_txpower;
434           rf->rf_tune = rtw_sa2400_tune;
435           rf->rf_pwrstate = rtw_sa2400_pwrstate;
436           bb = &rf->rf_bbpset;
437 
438           /* XXX magic */
439           bb->bb_antatten = RTW_BBP_ANTATTEN_PHILIPS_MAGIC;
440           bb->bb_chestlim =   0x00;
441           bb->bb_chsqlim =    0xa0;
442           bb->bb_ifagcdet =   0x64;
443           bb->bb_ifagcini =   0x90;
444           bb->bb_ifagclimit = 0x1a;
445           bb->bb_lnadet =               0xe0;
446           bb->bb_sys1 =                 0x98;
447           bb->bb_sys2 =                 0x47;
448           bb->bb_sys3 =                 0x90;
449           bb->bb_trl =                  0x88;
450           bb->bb_txagc =                0x38;
451 
452           bus->b_regs = regs;
453           bus->b_write = rf_write;
454 
455           return &sa->sa_rf;
456 }
457 
458 static int
rtw_grf5101_txpower(struct rtw_rf * rf,uint8_t opaque_txpower)459 rtw_grf5101_txpower(struct rtw_rf *rf, uint8_t opaque_txpower)
460 {
461           struct rtw_grf5101 *gr = (struct rtw_grf5101 *)rf;
462 
463           GCT_WRITE(gr, 0x15, 0, err);
464           GCT_WRITE(gr, 0x06, opaque_txpower, err);
465           GCT_WRITE(gr, 0x15, 0x10, err);
466           GCT_WRITE(gr, 0x15, 0x00, err);
467           return 0;
468 err:
469           return -1;
470 }
471 
472 static int
rtw_grf5101_pwrstate(struct rtw_rf * rf,enum rtw_pwrstate power)473 rtw_grf5101_pwrstate(struct rtw_rf *rf, enum rtw_pwrstate power)
474 {
475           struct rtw_grf5101 *gr = (struct rtw_grf5101 *)rf;
476           switch (power) {
477           case RTW_OFF:
478           case RTW_SLEEP:
479                     GCT_WRITE(gr, 0x07, 0x0000, err);
480                     GCT_WRITE(gr, 0x1f, 0x0045, err);
481                     GCT_WRITE(gr, 0x1f, 0x0005, err);
482                     GCT_WRITE(gr, 0x00, 0x08e4, err);
483           default:
484                     break;
485           case RTW_ON:
486                     GCT_WRITE(gr, 0x1f, 0x0001, err);
487                     DELAY(10);
488                     GCT_WRITE(gr, 0x1f, 0x0001, err);
489                     DELAY(10);
490                     GCT_WRITE(gr, 0x1f, 0x0041, err);
491                     DELAY(10);
492                     GCT_WRITE(gr, 0x1f, 0x0061, err);
493                     DELAY(10);
494                     GCT_WRITE(gr, 0x00, 0x0ae4, err);
495                     DELAY(10);
496                     GCT_WRITE(gr, 0x07, 0x1000, err);
497                     DELAY(100);
498                     break;
499           }
500 
501           return 0;
502 err:
503           return -1;
504 }
505 
506 static int
rtw_grf5101_tune(struct rtw_rf * rf,u_int freq)507 rtw_grf5101_tune(struct rtw_rf *rf, u_int freq)
508 {
509           int channel;
510           struct rtw_grf5101 *gr = (struct rtw_grf5101 *)rf;
511 
512           if (freq == 2484)
513                     channel = 14;
514           else if ((channel = (freq - 2412) / 5 + 1) < 1 || channel > 13) {
515                     RTW_DPRINTF(RTW_DEBUG_PHY,
516                         ("%s: invalid channel %d (freq %d)\n", __func__, channel,
517                          freq));
518                     return -1;
519           }
520 
521           GCT_WRITE(gr, 0x07, 0, err);
522           GCT_WRITE(gr, 0x0b, channel - 1, err);
523           GCT_WRITE(gr, 0x07, 0x1000, err);
524           return 0;
525 err:
526           return -1;
527 }
528 
529 static int
rtw_grf5101_init(struct rtw_rf * rf,u_int freq,uint8_t opaque_txpower,enum rtw_pwrstate power)530 rtw_grf5101_init(struct rtw_rf *rf, u_int freq, uint8_t opaque_txpower,
531     enum rtw_pwrstate power)
532 {
533           int rc;
534           struct rtw_grf5101 *gr = (struct rtw_grf5101 *)rf;
535 
536           /*
537          * These values have been derived from the rtl8180-sa2400
538          * Linux driver.  It is unknown what they all do, GCT refuse
539          * to release any documentation so these are more than
540          * likely sub optimal settings
541            */
542 
543           GCT_WRITE(gr, 0x01, 0x1a23, err);
544           GCT_WRITE(gr, 0x02, 0x4971, err);
545           GCT_WRITE(gr, 0x03, 0x41de, err);
546           GCT_WRITE(gr, 0x04, 0x2d80, err);
547 
548           GCT_WRITE(gr, 0x05, 0x61ff, err);
549 
550           GCT_WRITE(gr, 0x06, 0x0, err);
551 
552           GCT_WRITE(gr, 0x08, 0x7533, err);
553           GCT_WRITE(gr, 0x09, 0xc401, err);
554           GCT_WRITE(gr, 0x0a, 0x0, err);
555           GCT_WRITE(gr, 0x0c, 0x1c7, err);
556           GCT_WRITE(gr, 0x0d, 0x29d3, err);
557           GCT_WRITE(gr, 0x0e, 0x2e8, err);
558           GCT_WRITE(gr, 0x10, 0x192, err);
559           GCT_WRITE(gr, 0x11, 0x248, err);
560           GCT_WRITE(gr, 0x12, 0x0, err);
561           GCT_WRITE(gr, 0x13, 0x20c4, err);
562           GCT_WRITE(gr, 0x14, 0xf4fc, err);
563           GCT_WRITE(gr, 0x15, 0x0, err);
564           GCT_WRITE(gr, 0x16, 0x1500, err);
565 
566           if ((rc = rtw_grf5101_txpower(rf, opaque_txpower)) != 0)
567                     return rc;
568 
569           if ((rc = rtw_grf5101_tune(rf, freq)) != 0)
570                     return rc;
571 
572           return 0;
573 err:
574           return -1;
575 }
576 
577 static void
rtw_grf5101_destroy(struct rtw_rf * rf)578 rtw_grf5101_destroy(struct rtw_rf *rf)
579 {
580           struct rtw_grf5101 *gr = (struct rtw_grf5101 *)rf;
581           memset(gr, 0, sizeof(*gr));
582           free(gr, M_DEVBUF);
583 }
584 
585 struct rtw_rf *
rtw_grf5101_create(struct rtw_regs * regs,rtw_rf_write_t rf_write,int digphy)586 rtw_grf5101_create(struct rtw_regs *regs, rtw_rf_write_t rf_write,
587     int digphy)
588 {
589           struct rtw_grf5101 *gr;
590           struct rtw_rfbus *bus;
591           struct rtw_rf *rf;
592           struct rtw_bbpset *bb;
593 
594           gr = malloc(sizeof(*gr), M_DEVBUF, M_WAITOK | M_ZERO);
595 
596           rf = &gr->gr_rf;
597           bus = &gr->gr_bus;
598 
599           rf->rf_init = rtw_grf5101_init;
600           rf->rf_destroy = rtw_grf5101_destroy;
601           rf->rf_txpower = rtw_grf5101_txpower;
602           rf->rf_tune = rtw_grf5101_tune;
603           rf->rf_pwrstate = rtw_grf5101_pwrstate;
604           bb = &rf->rf_bbpset;
605 
606           /* XXX magic */
607           bb->bb_antatten = RTW_BBP_ANTATTEN_GCT_MAGIC;
608           bb->bb_chestlim =       0x00;
609           bb->bb_chsqlim =        0xa0;
610           bb->bb_ifagcdet =       0x64;
611           bb->bb_ifagcini =       0x90;
612           bb->bb_ifagclimit =     0x1e;
613           bb->bb_lnadet =         0xc0;
614           bb->bb_sys1 =           0xa8;
615           bb->bb_sys2 =           0x47;
616           bb->bb_sys3 =           0x9b;
617           bb->bb_trl =            0x88;
618           bb->bb_txagc =          0x08;
619 
620           bus->b_regs = regs;
621           bus->b_write = rf_write;
622 
623           return &gr->gr_rf;
624 }
625 
626 /* freq is in MHz */
627 static int
rtw_max2820_tune(struct rtw_rf * rf,u_int freq)628 rtw_max2820_tune(struct rtw_rf *rf, u_int freq)
629 {
630           struct rtw_max2820 *mx = (struct rtw_max2820 *)rf;
631           struct rtw_rfbus *bus = &mx->mx_bus;
632 
633           if (freq < 2400 || freq > 2499)
634                     return -1;
635 
636           return rtw_rfbus_write(bus, RTW_RFCHIPID_MAXIM, MAX2820_CHANNEL,
637               __SHIFTIN(freq - 2400, MAX2820_CHANNEL_CF_MASK));
638 }
639 
640 static void
rtw_max2820_destroy(struct rtw_rf * rf)641 rtw_max2820_destroy(struct rtw_rf *rf)
642 {
643           struct rtw_max2820 *mx = (struct rtw_max2820 *)rf;
644           memset(mx, 0, sizeof(*mx));
645           free(mx, M_DEVBUF);
646 }
647 
648 static int
rtw_max2820_init(struct rtw_rf * rf,u_int freq,uint8_t opaque_txpower,enum rtw_pwrstate power)649 rtw_max2820_init(struct rtw_rf *rf, u_int freq, uint8_t opaque_txpower,
650     enum rtw_pwrstate power)
651 {
652           struct rtw_max2820 *mx = (struct rtw_max2820 *)rf;
653           struct rtw_rfbus *bus = &mx->mx_bus;
654           int rc;
655 
656           if ((rc = rtw_rfbus_write(bus, RTW_RFCHIPID_MAXIM, MAX2820_TEST,
657               MAX2820_TEST_DEFAULT)) != 0)
658                     return rc;
659 
660           if ((rc = rtw_rfbus_write(bus, RTW_RFCHIPID_MAXIM, MAX2820_ENABLE,
661               MAX2820_ENABLE_DEFAULT)) != 0)
662                     return rc;
663 
664           /* skip configuration if it's time to sleep or to power-down. */
665           if ((rc = rtw_max2820_pwrstate(rf, power)) != 0)
666                     return rc;
667           else if (power == RTW_OFF || power == RTW_SLEEP)
668                     return 0;
669 
670           if ((rc = rtw_rfbus_write(bus, RTW_RFCHIPID_MAXIM, MAX2820_SYNTH,
671               MAX2820_SYNTH_R_44MHZ)) != 0)
672                     return rc;
673 
674           if ((rc = rtw_max2820_tune(rf, freq)) != 0)
675                     return rc;
676 
677           /* XXX The MAX2820 datasheet indicates that 1C and 2C should not
678            * be changed from 7, however, the reference driver sets them
679            * to 4 and 1, respectively.
680            */
681           if ((rc = rtw_rfbus_write(bus, RTW_RFCHIPID_MAXIM, MAX2820_RECEIVE,
682               MAX2820_RECEIVE_DL_DEFAULT |
683               __SHIFTIN(4, MAX2820A_RECEIVE_1C_MASK) |
684               __SHIFTIN(1, MAX2820A_RECEIVE_2C_MASK))) != 0)
685                     return rc;
686 
687           return rtw_rfbus_write(bus, RTW_RFCHIPID_MAXIM, MAX2820_TRANSMIT,
688               MAX2820_TRANSMIT_PA_DEFAULT);
689 }
690 
691 static int
rtw_max2820_txpower(struct rtw_rf * rf,uint8_t opaque_txpower)692 rtw_max2820_txpower(struct rtw_rf *rf, uint8_t opaque_txpower)
693 {
694           /* TBD */
695           return 0;
696 }
697 
698 static int
rtw_max2820_pwrstate(struct rtw_rf * rf,enum rtw_pwrstate power)699 rtw_max2820_pwrstate(struct rtw_rf *rf, enum rtw_pwrstate power)
700 {
701           uint32_t enable;
702           struct rtw_max2820 *mx;
703           struct rtw_rfbus *bus;
704 
705           mx = (struct rtw_max2820 *)rf;
706           bus = &mx->mx_bus;
707 
708           switch (power) {
709           case RTW_OFF:
710           case RTW_SLEEP:
711           default:
712                     enable = 0x0;
713                     break;
714           case RTW_ON:
715                     enable = MAX2820_ENABLE_DEFAULT;
716                     break;
717           }
718           return rtw_rfbus_write(bus, RTW_RFCHIPID_MAXIM, MAX2820_ENABLE, enable);
719 }
720 
721 struct rtw_rf *
rtw_max2820_create(struct rtw_regs * regs,rtw_rf_write_t rf_write,int is_a)722 rtw_max2820_create(struct rtw_regs *regs, rtw_rf_write_t rf_write, int is_a)
723 {
724           struct rtw_max2820 *mx;
725           struct rtw_rfbus *bus;
726           struct rtw_rf *rf;
727           struct rtw_bbpset *bb;
728 
729           mx = malloc(sizeof(*mx), M_DEVBUF, M_WAITOK | M_ZERO);
730           mx->mx_is_a = is_a;
731 
732           rf = &mx->mx_rf;
733           bus = &mx->mx_bus;
734 
735           rf->rf_init = rtw_max2820_init;
736           rf->rf_destroy = rtw_max2820_destroy;
737           rf->rf_txpower = rtw_max2820_txpower;
738           rf->rf_tune = rtw_max2820_tune;
739           rf->rf_pwrstate = rtw_max2820_pwrstate;
740           bb = &rf->rf_bbpset;
741 
742           /* XXX magic */
743           bb->bb_antatten = RTW_BBP_ANTATTEN_MAXIM_MAGIC;
744           bb->bb_chestlim =   0;
745           bb->bb_chsqlim =    159;
746           bb->bb_ifagcdet =   100;
747           bb->bb_ifagcini =   144;
748           bb->bb_ifagclimit = 26;
749           bb->bb_lnadet =               248;
750           bb->bb_sys1 =                 136;
751           bb->bb_sys2 =                 71;
752           bb->bb_sys3 =                 155;
753           bb->bb_trl =                  136;
754           bb->bb_txagc =                8;
755 
756           bus->b_regs = regs;
757           bus->b_write = rf_write;
758 
759           return &mx->mx_rf;
760 }
761 
762 /* freq is in MHz */
763 int
rtw_phy_init(struct rtw_regs * regs,struct rtw_rf * rf,uint8_t opaque_txpower,uint8_t cs_threshold,u_int freq,int antdiv,int dflantb,enum rtw_pwrstate power)764 rtw_phy_init(struct rtw_regs *regs, struct rtw_rf *rf, uint8_t opaque_txpower,
765     uint8_t cs_threshold, u_int freq, int antdiv, int dflantb,
766     enum rtw_pwrstate power)
767 {
768           int rc;
769           RTW_DPRINTF(RTW_DEBUG_PHY,
770               ("%s: txpower %u csthresh %u freq %u antdiv %u dflantb %u "
771                "pwrstate %s\n", __func__, opaque_txpower, cs_threshold, freq,
772                antdiv, dflantb, rtw_pwrstate_string(power)));
773 
774           /* XXX is this really necessary? */
775           if ((rc = rtw_rf_txpower(rf, opaque_txpower)) != 0)
776                     return rc;
777           if ((rc = rtw_bbp_preinit(regs, rf->rf_bbpset.bb_antatten, dflantb,
778               freq)) != 0)
779                     return rc;
780           if ((rc = rtw_rf_tune(rf, freq)) != 0)
781                     return rc;
782           /* initialize RF  */
783           if ((rc = rtw_rf_init(rf, freq, opaque_txpower, power)) != 0)
784                     return rc;
785 #if 0     /* what is this redundant tx power setting here for? */
786           if ((rc = rtw_rf_txpower(rf, opaque_txpower)) != 0)
787                     return rc;
788 #endif
789           return rtw_bbp_init(regs, &rf->rf_bbpset, antdiv, dflantb,
790               cs_threshold, freq);
791 }
792