1 /*        $NetBSD: dbcool.c,v 1.65 2024/05/18 00:02:04 thorpej Exp $ */
2 
3 /*-
4  * Copyright (c) 2008 The NetBSD Foundation, Inc.
5  * All rights reserved.
6  *
7  * This code is derived from software contributed to The NetBSD Foundation
8  * by Paul Goyette
9  *
10  * Redistribution and use in source and binary forms, with or without
11  * modification, are permitted provided that the following conditions
12  * are met:
13  * 1. Redistributions of source code must retain the above copyright
14  *    notice, this list of conditions and the following disclaimer.
15  * 2. Redistributions in binary form must reproduce the above copyright
16  *    notice, this list of conditions and the following disclaimer in the
17  *    documentation and/or other materials provided with the distribution.
18  *
19  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
20  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
21  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
22  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
23  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
24  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
25  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
26  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
27  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
28  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
29  * POSSIBILITY OF SUCH DAMAGE.
30  */
31 
32 /*
33  * a driver for the dbCool(tm) family of environmental controllers
34  *
35  * Data sheets for the various supported chips are available at
36  *
37  *        http://www.onsemi.com/pub/Collateral/ADM1027-D.PDF
38  *        http://www.onsemi.com/pub/Collateral/ADM1030-D.PDF
39  *        http://www.onsemi.com/pub/Collateral/ADT7463-D.PDF
40  *        http://www.onsemi.com/pub/Collateral/ADT7466.PDF
41  *        http://www.onsemi.com/pub/Collateral/ADT7467-D.PDF
42  *        http://www.onsemi.com/pub/Collateral/ADT7468-D.PDF
43  *        http://www.onsemi.com/pub/Collateral/ADT7473-D.PDF
44  *        http://www.onsemi.com/pub/Collateral/ADT7475-D.PDF
45  *        http://www.onsemi.com/pub/Collateral/ADT7476-D.PDF
46  *        http://www.onsemi.com/pub/Collateral/ADT7490-D.PDF
47  *        http://www.smsc.com/media/Downloads_Public/Data_Sheets/6d103s.pdf
48  *
49  * (URLs are correct as of October 5, 2008)
50  */
51 
52 #include <sys/cdefs.h>
53 __KERNEL_RCSID(0, "$NetBSD: dbcool.c,v 1.65 2024/05/18 00:02:04 thorpej Exp $");
54 
55 #include <sys/param.h>
56 #include <sys/systm.h>
57 #include <sys/kernel.h>
58 #include <sys/device.h>
59 #include <sys/sysctl.h>
60 #include <sys/module.h>
61 
62 #include <dev/i2c/dbcool_var.h>
63 #include <dev/i2c/dbcool_reg.h>
64 
65 /* Config interface */
66 static int dbcool_match(device_t, cfdata_t, void *);
67 static void dbcool_attach(device_t, device_t, void *);
68 static int dbcool_detach(device_t, int);
69 
70 /* Device attributes */
71 static int dbcool_supply_voltage(struct dbcool_softc *);
72 static bool dbcool_islocked(struct dbcool_softc *);
73 
74 /* Sensor read functions */
75 static void dbcool_refresh(struct sysmon_envsys *, envsys_data_t *);
76 static int dbcool_read_rpm(struct dbcool_softc *, uint8_t);
77 static int dbcool_read_temp(struct dbcool_softc *, uint8_t, bool);
78 static int dbcool_read_volt(struct dbcool_softc *, uint8_t, int, bool);
79 
80 /* Sensor get/set limit functions */
81 static void dbcool_get_limits(struct sysmon_envsys *, envsys_data_t *,
82                                     sysmon_envsys_lim_t *, uint32_t *);
83 static void dbcool_get_temp_limits(struct dbcool_softc *, int,
84                                            sysmon_envsys_lim_t *, uint32_t *);
85 static void dbcool_get_volt_limits(struct dbcool_softc *, int,
86                                            sysmon_envsys_lim_t *, uint32_t *);
87 static void dbcool_get_fan_limits(struct dbcool_softc *, int,
88                                           sysmon_envsys_lim_t *, uint32_t *);
89 
90 static void dbcool_set_limits(struct sysmon_envsys *, envsys_data_t *,
91                                     sysmon_envsys_lim_t *, uint32_t *);
92 static void dbcool_set_temp_limits(struct dbcool_softc *, int,
93                                            sysmon_envsys_lim_t *, uint32_t *);
94 static void dbcool_set_volt_limits(struct dbcool_softc *, int,
95                                            sysmon_envsys_lim_t *, uint32_t *);
96 static void dbcool_set_fan_limits(struct dbcool_softc *, int,
97                                           sysmon_envsys_lim_t *, uint32_t *);
98 
99 /* SYSCTL Helpers */
100 SYSCTL_SETUP_PROTO(sysctl_dbcoolsetup);
101 static int sysctl_dbcool_temp(SYSCTLFN_PROTO);
102 static int sysctl_adm1030_temp(SYSCTLFN_PROTO);
103 static int sysctl_adm1030_trange(SYSCTLFN_PROTO);
104 static int sysctl_dbcool_duty(SYSCTLFN_PROTO);
105 static int sysctl_dbcool_behavior(SYSCTLFN_PROTO);
106 static int sysctl_dbcool_slope(SYSCTLFN_PROTO);
107 static int sysctl_dbcool_thyst(SYSCTLFN_PROTO);
108 
109 /* Set-up subroutines */
110 static void dbcool_setup_controllers(struct dbcool_softc *);
111 static int  dbcool_setup_sensors(struct dbcool_softc *);
112 static int  dbcool_attach_sensor(struct dbcool_softc *, int);
113 static int  dbcool_attach_temp_control(struct dbcool_softc *, int,
114           struct chip_id *);
115 
116 #ifdef DBCOOL_DEBUG
117 static int sysctl_dbcool_reg_select(SYSCTLFN_PROTO);
118 static int sysctl_dbcool_reg_access(SYSCTLFN_PROTO);
119 #endif /* DBCOOL_DEBUG */
120 
121 /*
122  * Descriptions for SYSCTL entries
123  */
124 struct dbc_sysctl_info {
125           const char *name;
126           const char *desc;
127           bool lockable;
128           int (*helper)(SYSCTLFN_PROTO);
129 };
130 
131 static struct dbc_sysctl_info dbc_sysctl_table[] = {
132           /*
133            * The first several entries must remain in the same order as the
134            * corresponding entries in enum dbc_pwm_params
135            */
136           { "behavior",                 "operating behavior and temp selector",
137                     true, sysctl_dbcool_behavior },
138           { "min_duty",                 "minimum fan controller PWM duty cycle",
139                     true, sysctl_dbcool_duty },
140           { "max_duty",                 "maximum fan controller PWM duty cycle",
141                     true, sysctl_dbcool_duty },
142           { "cur_duty",                 "current fan controller PWM duty cycle",
143                     false, sysctl_dbcool_duty },
144 
145           /*
146            * The rest of these should be in the order in which they
147            * are to be stored in the sysctl tree;  the table index is
148            * used as the high-order bits of the sysctl_num to maintain
149            * the sequence.
150            *
151            * If you rearrange the order of these items, be sure to
152            * update the sysctl_index in the XXX_sensor_table[] for
153            * the various chips!
154            */
155           { "Trange",                   "temp slope/range to reach 100% duty cycle",
156                     true, sysctl_dbcool_slope },
157           { "Tmin",           "temp at which to start fan controller",
158                     true, sysctl_dbcool_temp },
159           { "Ttherm",                   "temp at which THERM is asserted",
160                     true, sysctl_dbcool_temp },
161           { "Thyst",                    "temp hysteresis for stopping fan controller",
162                     true, sysctl_dbcool_thyst },
163           { "Tmin",           "temp at which to start fan controller",
164                     true, sysctl_adm1030_temp },
165           { "Trange",                   "temp slope/range to reach 100% duty cycle",
166                     true, sysctl_adm1030_trange },
167 };
168 
169 static const char *dbc_sensor_names[] = {
170           "l_temp",  "r1_temp", "r2_temp", "Vccp",   "Vcc",    "fan1",
171           "fan2",    "fan3",    "fan4",    "AIN1",   "AIN2",   "V2dot5",
172           "V5",      "V12",     "Vtt",     "Imon",   "VID"
173 };
174 
175 /*
176  * Following table derived from product data-sheets
177  */
178 static int64_t nominal_voltages[] = {
179           -1,                 /* Vcc can be either 3.3 or 5.0V
180                                  at 3/4 scale                  */
181            2249939, /* Vccp         2.25V 3/4 scale  */
182            2497436, /* 2.5VIN       2.5V  3/4 scale  */
183            5002466, /* 5VIN         5V    3/4 scale  */
184           12000000, /* 12VIN       12V    3/4 scale  */
185            1690809, /* Vtt, Imon    2.25V full scale */
186            1689600, /* AIN1, AIN2   2.25V full scale */
187                  0
188 };
189 
190 /*
191  * Sensor-type, { val-reg, hilim-reg, lolim-reg}, name-idx, sysctl-table-idx,
192  *        nom-voltage-index
193  */
194 struct dbcool_sensor ADT7490_sensor_table[] = {
195           { DBC_TEMP, {       DBCOOL_LOCAL_TEMP,
196                               DBCOOL_LOCAL_HIGHLIM,
197                               DBCOOL_LOCAL_LOWLIM },                  0, 0, 0 },
198           { DBC_TEMP, {       DBCOOL_REMOTE1_TEMP,
199                               DBCOOL_REMOTE1_HIGHLIM,
200                               DBCOOL_REMOTE1_LOWLIM },      1, 0, 0 },
201           { DBC_TEMP, {       DBCOOL_REMOTE2_TEMP,
202                               DBCOOL_REMOTE2_HIGHLIM,
203                               DBCOOL_REMOTE2_LOWLIM },      2, 0, 0 },
204           { DBC_VOLT, {       DBCOOL_VCCP,
205                               DBCOOL_VCCP_HIGHLIM,
206                               DBCOOL_VCCP_LOWLIM },                   3, 0, 1 },
207           { DBC_VOLT, {       DBCOOL_VCC,
208                               DBCOOL_VCC_HIGHLIM,
209                               DBCOOL_VCC_LOWLIM },                    4, 0, 0 },
210           { DBC_VOLT, {       DBCOOL_25VIN,
211                               DBCOOL_25VIN_HIGHLIM,
212                               DBCOOL_25VIN_LOWLIM },                  11, 0, 2 },
213           { DBC_VOLT, {       DBCOOL_5VIN,
214                               DBCOOL_5VIN_HIGHLIM,
215                               DBCOOL_5VIN_LOWLIM },                   12, 0, 3 },
216           { DBC_VOLT, {       DBCOOL_12VIN,
217                               DBCOOL_12VIN_HIGHLIM,
218                               DBCOOL_12VIN_LOWLIM },                  13, 0, 4 },
219           { DBC_VOLT, {       DBCOOL_VTT,
220                               DBCOOL_VTT_HIGHLIM,
221                               DBCOOL_VTT_LOWLIM },                    14, 0, 5 },
222           { DBC_VOLT, {       DBCOOL_IMON,
223                               DBCOOL_IMON_HIGHLIM,
224                               DBCOOL_IMON_LOWLIM },                   15, 0, 5 },
225           { DBC_FAN,  {       DBCOOL_FAN1_TACH_LSB,
226                               DBCOOL_NO_REG,
227                               DBCOOL_TACH1_MIN_LSB },                 5, 0, 0 },
228           { DBC_FAN,  {       DBCOOL_FAN2_TACH_LSB,
229                               DBCOOL_NO_REG,
230                               DBCOOL_TACH2_MIN_LSB },                 6, 0, 0 },
231           { DBC_FAN,  {       DBCOOL_FAN3_TACH_LSB,
232                               DBCOOL_NO_REG,
233                               DBCOOL_TACH3_MIN_LSB },                 7, 0, 0 },
234           { DBC_FAN,  {       DBCOOL_FAN4_TACH_LSB,
235                               DBCOOL_NO_REG,
236                               DBCOOL_TACH4_MIN_LSB },                 8, 0, 0 },
237           { DBC_VID,  {       DBCOOL_VID_REG,
238                               DBCOOL_NO_REG,
239                               DBCOOL_NO_REG },              16, 0, 0 },
240           { DBC_CTL,  {       DBCOOL_LOCAL_TMIN,
241                               DBCOOL_NO_REG,
242                               DBCOOL_NO_REG },              0, 5, 0 },
243           { DBC_CTL,  {       DBCOOL_LOCAL_TTHRESH,
244                               DBCOOL_NO_REG,
245                               DBCOOL_NO_REG },              0, 6, 0 },
246           { DBC_CTL,  {       DBCOOL_R1_LCL_TMIN_HYST | 0x80,
247                               DBCOOL_NO_REG,
248                               DBCOOL_NO_REG },              0, 7, 0 },
249           { DBC_CTL,  {       DBCOOL_REMOTE1_TMIN,
250                               DBCOOL_NO_REG,
251                               DBCOOL_NO_REG },              1, 5, 0 },
252           { DBC_CTL,  {       DBCOOL_REMOTE1_TTHRESH,
253                               DBCOOL_NO_REG,
254                               DBCOOL_NO_REG },              1, 6, 0 },
255           { DBC_CTL,  {       DBCOOL_R1_LCL_TMIN_HYST,
256                               DBCOOL_NO_REG,
257                               DBCOOL_NO_REG },              1, 7, 0 },
258           { DBC_CTL,  {       DBCOOL_REMOTE2_TMIN,
259                               DBCOOL_NO_REG,
260                               DBCOOL_NO_REG },              2, 5, 0 },
261           { DBC_CTL,  {       DBCOOL_REMOTE2_TTHRESH,
262                               DBCOOL_NO_REG,
263                               DBCOOL_NO_REG },              2, 6, 0 },
264           { DBC_CTL,  {       DBCOOL_R2_TMIN_HYST,
265                               DBCOOL_NO_REG,
266                               DBCOOL_NO_REG },              2, 7, 0 },
267           { DBC_EOF,  { 0, 0, 0 }, 0, 0, 0 }
268 };
269 
270 struct dbcool_sensor ADT7476_sensor_table[] = {
271           { DBC_TEMP, {       DBCOOL_LOCAL_TEMP,
272                               DBCOOL_LOCAL_HIGHLIM,
273                               DBCOOL_LOCAL_LOWLIM },                  0, 0, 0 },
274           { DBC_TEMP, {       DBCOOL_REMOTE1_TEMP,
275                               DBCOOL_REMOTE1_HIGHLIM,
276                               DBCOOL_REMOTE1_LOWLIM },      1, 0, 0 },
277           { DBC_TEMP, {       DBCOOL_REMOTE2_TEMP,
278                               DBCOOL_REMOTE2_HIGHLIM,
279                               DBCOOL_REMOTE2_LOWLIM },      2, 0, 0 },
280           { DBC_VOLT, {       DBCOOL_VCCP,
281                               DBCOOL_VCCP_HIGHLIM,
282                               DBCOOL_VCCP_LOWLIM },                   3, 0, 1 },
283           { DBC_VOLT, {       DBCOOL_VCC,
284                               DBCOOL_VCC_HIGHLIM,
285                               DBCOOL_VCC_LOWLIM },                    4, 0, 0 },
286           { DBC_VOLT, {       DBCOOL_25VIN,
287                               DBCOOL_25VIN_HIGHLIM,
288                               DBCOOL_25VIN_LOWLIM },                  11, 0, 2 },
289           { DBC_VOLT, {       DBCOOL_5VIN,
290                               DBCOOL_5VIN_HIGHLIM,
291                               DBCOOL_5VIN_LOWLIM },                   12, 0, 3 },
292           { DBC_VOLT, {       DBCOOL_12VIN,
293                               DBCOOL_12VIN_HIGHLIM,
294                               DBCOOL_12VIN_LOWLIM },                  13, 0, 4 },
295           { DBC_FAN,  {       DBCOOL_FAN1_TACH_LSB,
296                               DBCOOL_NO_REG,
297                               DBCOOL_TACH1_MIN_LSB },                 5, 0, 0 },
298           { DBC_FAN,  {       DBCOOL_FAN2_TACH_LSB,
299                               DBCOOL_NO_REG,
300                               DBCOOL_TACH2_MIN_LSB },                 6, 0, 0 },
301           { DBC_FAN,  {       DBCOOL_FAN3_TACH_LSB,
302                               DBCOOL_NO_REG,
303                               DBCOOL_TACH3_MIN_LSB },                 7, 0, 0 },
304           { DBC_FAN,  {       DBCOOL_FAN4_TACH_LSB,
305                               DBCOOL_NO_REG,
306                               DBCOOL_TACH4_MIN_LSB },                 8, 0, 0 },
307           { DBC_VID,  {       DBCOOL_VID_REG,
308                               DBCOOL_NO_REG,
309                               DBCOOL_NO_REG },              16, 0, 0 },
310           { DBC_CTL,  {       DBCOOL_LOCAL_TMIN,
311                               DBCOOL_NO_REG,
312                               DBCOOL_NO_REG },              0, 5, 0 },
313           { DBC_CTL,  {       DBCOOL_LOCAL_TTHRESH,
314                               DBCOOL_NO_REG,
315                               DBCOOL_NO_REG },              0, 6, 0 },
316           { DBC_CTL,  {       DBCOOL_R1_LCL_TMIN_HYST | 0x80,
317                               DBCOOL_NO_REG,
318                               DBCOOL_NO_REG },              0, 7, 0 },
319           { DBC_CTL,  {       DBCOOL_REMOTE1_TMIN,
320                               DBCOOL_NO_REG,
321                               DBCOOL_NO_REG },              1, 5, 0 },
322           { DBC_CTL,  {       DBCOOL_REMOTE1_TTHRESH,
323                               DBCOOL_NO_REG,
324                               DBCOOL_NO_REG },              1, 6, 0 },
325           { DBC_CTL,  {       DBCOOL_R1_LCL_TMIN_HYST,
326                               DBCOOL_NO_REG,
327                               DBCOOL_NO_REG },              1, 7, 0 },
328           { DBC_CTL,  {       DBCOOL_REMOTE2_TMIN,
329                               DBCOOL_NO_REG,
330                               DBCOOL_NO_REG },              2, 5, 0 },
331           { DBC_CTL,  {       DBCOOL_REMOTE2_TTHRESH,
332                               DBCOOL_NO_REG,
333                               DBCOOL_NO_REG },              2, 6, 0 },
334           { DBC_CTL,  {       DBCOOL_R2_TMIN_HYST,
335                               DBCOOL_NO_REG,
336                               DBCOOL_NO_REG },              2, 7, 0 },
337           { DBC_EOF,  { 0, 0, 0 }, 0, 0, 0 }
338 };
339 
340 struct dbcool_sensor ADT7475_sensor_table[] = {
341           { DBC_TEMP, {       DBCOOL_LOCAL_TEMP,
342                               DBCOOL_LOCAL_HIGHLIM,
343                               DBCOOL_LOCAL_LOWLIM },                  0, 0, 0 },
344           { DBC_TEMP, {       DBCOOL_REMOTE1_TEMP,
345                               DBCOOL_REMOTE1_HIGHLIM,
346                               DBCOOL_REMOTE1_LOWLIM },      1, 0, 0 },
347           { DBC_TEMP, {       DBCOOL_REMOTE2_TEMP,
348                               DBCOOL_REMOTE2_HIGHLIM,
349                               DBCOOL_REMOTE2_LOWLIM },      2, 0, 0 },
350           { DBC_VOLT, {       DBCOOL_VCCP,
351                               DBCOOL_VCCP_HIGHLIM,
352                               DBCOOL_VCCP_LOWLIM },                   3, 0, 1 },
353           { DBC_VOLT, {       DBCOOL_VCC,
354                               DBCOOL_VCC_HIGHLIM,
355                               DBCOOL_VCC_LOWLIM },                    4, 0, 0 },
356           { DBC_FAN,  {       DBCOOL_FAN1_TACH_LSB,
357                               DBCOOL_NO_REG,
358                               DBCOOL_TACH1_MIN_LSB },                 5, 0, 0 },
359           { DBC_FAN,  {       DBCOOL_FAN2_TACH_LSB,
360                               DBCOOL_NO_REG,
361                               DBCOOL_TACH2_MIN_LSB },                 6, 0, 0 },
362           { DBC_FAN,  {       DBCOOL_FAN3_TACH_LSB,
363                               DBCOOL_NO_REG,
364                               DBCOOL_TACH3_MIN_LSB },                 7, 0, 0 },
365           { DBC_FAN,  {       DBCOOL_FAN4_TACH_LSB,
366                               DBCOOL_NO_REG,
367                               DBCOOL_TACH4_MIN_LSB },                 8, 0, 0 },
368           { DBC_CTL,  {       DBCOOL_LOCAL_TMIN,
369                               DBCOOL_NO_REG,
370                               DBCOOL_NO_REG },              0, 5, 0 },
371           { DBC_CTL,  {       DBCOOL_LOCAL_TTHRESH,
372                               DBCOOL_NO_REG,
373                               DBCOOL_NO_REG },              0, 6, 0 },
374           { DBC_CTL,  {       DBCOOL_R1_LCL_TMIN_HYST | 0x80,
375                               DBCOOL_NO_REG,
376                               DBCOOL_NO_REG },              0, 7, 0 },
377           { DBC_CTL,  {       DBCOOL_REMOTE1_TMIN,
378                               DBCOOL_NO_REG,
379                               DBCOOL_NO_REG },              1, 5, 0 },
380           { DBC_CTL,  {       DBCOOL_REMOTE1_TTHRESH,
381                               DBCOOL_NO_REG,
382                               DBCOOL_NO_REG },              1, 6, 0 },
383           { DBC_CTL,  {       DBCOOL_R1_LCL_TMIN_HYST,
384                               DBCOOL_NO_REG,
385                               DBCOOL_NO_REG },              1, 7, 0 },
386           { DBC_CTL,  {       DBCOOL_REMOTE2_TMIN,
387                               DBCOOL_NO_REG,
388                               DBCOOL_NO_REG },              2, 5, 0 },
389           { DBC_CTL,  {       DBCOOL_REMOTE2_TTHRESH,
390                               DBCOOL_NO_REG,
391                               DBCOOL_NO_REG },              2, 6, 0 },
392           { DBC_CTL,  {       DBCOOL_R2_TMIN_HYST,
393                               DBCOOL_NO_REG,
394                               DBCOOL_NO_REG },              2, 7, 0 },
395           { DBC_EOF,  { 0, 0, 0 }, 0, 0, 0 }
396 };
397 
398 /*
399  * The registers of dbcool_power_control must be in the same order as
400  * in enum dbc_pwm_params
401  */
402 struct dbcool_power_control ADT7475_power_table[] = {
403           { { DBCOOL_PWM1_CTL, DBCOOL_PWM1_MINDUTY,
404               DBCOOL_PWM1_MAXDUTY, DBCOOL_PWM1_CURDUTY },
405                     "fan_control_1" },
406           { { DBCOOL_PWM2_CTL, DBCOOL_PWM2_MINDUTY,
407               DBCOOL_PWM2_MAXDUTY, DBCOOL_PWM2_CURDUTY },
408                     "fan_control_2" },
409           { { DBCOOL_PWM3_CTL, DBCOOL_PWM3_MINDUTY,
410               DBCOOL_PWM3_MAXDUTY, DBCOOL_PWM3_CURDUTY },
411                     "fan_control_3" },
412           { { 0, 0, 0, 0 }, NULL }
413 };
414 
415 struct dbcool_sensor ADT7466_sensor_table[] = {
416           { DBC_TEMP, {       DBCOOL_ADT7466_LCL_TEMP_MSB,
417                               DBCOOL_ADT7466_LCL_TEMP_HILIM,
418                               DBCOOL_ADT7466_LCL_TEMP_LOLIM }, 0,  0, 0 },
419           { DBC_TEMP, {       DBCOOL_ADT7466_REM_TEMP_MSB,
420                               DBCOOL_ADT7466_REM_TEMP_HILIM,
421                               DBCOOL_ADT7466_REM_TEMP_LOLIM }, 1,  0, 0 },
422           { DBC_VOLT, {       DBCOOL_ADT7466_VCC,
423                               DBCOOL_ADT7466_VCC_HILIM,
424                               DBCOOL_ADT7466_VCC_LOLIM },   4,  0, 0 },
425           { DBC_VOLT, {       DBCOOL_ADT7466_AIN1,
426                               DBCOOL_ADT7466_AIN1_HILIM,
427                               DBCOOL_ADT7466_AIN1_LOLIM },  9,  0, 6 },
428           { DBC_VOLT, {       DBCOOL_ADT7466_AIN2,
429                               DBCOOL_ADT7466_AIN2_HILIM,
430                               DBCOOL_ADT7466_AIN2_LOLIM },  10, 0, 6 },
431           { DBC_FAN,  {       DBCOOL_ADT7466_FANA_LSB,
432                               DBCOOL_NO_REG,
433                               DBCOOL_ADT7466_FANA_LOLIM_LSB }, 5,  0, 0 },
434           { DBC_FAN,  {       DBCOOL_ADT7466_FANB_LSB,
435                               DBCOOL_NO_REG,
436                               DBCOOL_ADT7466_FANB_LOLIM_LSB }, 6,  0, 0 },
437           { DBC_EOF,  { 0, 0, 0 }, 0, 0, 0 }
438 };
439 
440 struct dbcool_sensor ADM1027_sensor_table[] = {
441           { DBC_TEMP, {       DBCOOL_LOCAL_TEMP,
442                               DBCOOL_LOCAL_HIGHLIM,
443                               DBCOOL_LOCAL_LOWLIM },                  0, 0, 0 },
444           { DBC_TEMP, {       DBCOOL_REMOTE1_TEMP,
445                               DBCOOL_REMOTE1_HIGHLIM,
446                               DBCOOL_REMOTE1_LOWLIM },      1, 0, 0 },
447           { DBC_TEMP, {       DBCOOL_REMOTE2_TEMP,
448                               DBCOOL_REMOTE2_HIGHLIM,
449                               DBCOOL_REMOTE2_LOWLIM },      2, 0, 0 },
450           { DBC_VOLT, {       DBCOOL_VCCP,
451                               DBCOOL_VCCP_HIGHLIM,
452                               DBCOOL_VCCP_LOWLIM },                   3, 0, 1 },
453           { DBC_VOLT, {       DBCOOL_VCC,
454                               DBCOOL_VCC_HIGHLIM,
455                               DBCOOL_VCC_LOWLIM },                    4, 0, 0 },
456           { DBC_VOLT, {       DBCOOL_25VIN,
457                               DBCOOL_25VIN_HIGHLIM,
458                               DBCOOL_25VIN_LOWLIM },                  11, 0, 2 },
459           { DBC_VOLT, {       DBCOOL_5VIN,
460                               DBCOOL_5VIN_HIGHLIM,
461                               DBCOOL_5VIN_LOWLIM },                   12, 0, 3 },
462           { DBC_VOLT, {       DBCOOL_12VIN,
463                               DBCOOL_12VIN_HIGHLIM,
464                               DBCOOL_12VIN_LOWLIM },                  13, 0, 4 },
465           { DBC_FAN,  {       DBCOOL_FAN1_TACH_LSB,
466                               DBCOOL_NO_REG,
467                               DBCOOL_TACH1_MIN_LSB },                 5, 0, 0 },
468           { DBC_FAN,  {       DBCOOL_FAN2_TACH_LSB,
469                               DBCOOL_NO_REG,
470                               DBCOOL_TACH2_MIN_LSB },                 6, 0, 0 },
471           { DBC_FAN,  {       DBCOOL_FAN3_TACH_LSB,
472                               DBCOOL_NO_REG,
473                               DBCOOL_TACH3_MIN_LSB },                 7, 0, 0 },
474           { DBC_FAN,  {       DBCOOL_FAN4_TACH_LSB,
475                               DBCOOL_NO_REG,
476                               DBCOOL_TACH4_MIN_LSB },                 8, 0, 0 },
477           { DBC_VID,  {       DBCOOL_VID_REG,
478                               DBCOOL_NO_REG,
479                               DBCOOL_NO_REG },              16, 0, 0 },
480           { DBC_CTL,  {       DBCOOL_LOCAL_TMIN,
481                               DBCOOL_NO_REG,
482                               DBCOOL_NO_REG },              0, 5, 0 },
483           { DBC_CTL,  {       DBCOOL_LOCAL_TTHRESH,
484                               DBCOOL_NO_REG,
485                               DBCOOL_NO_REG },              0, 6, 0 },
486           { DBC_CTL,  {       DBCOOL_R1_LCL_TMIN_HYST | 0x80,
487                               DBCOOL_NO_REG,
488                               DBCOOL_NO_REG },              0, 7, 0 },
489           { DBC_CTL,  {       DBCOOL_REMOTE1_TMIN,
490                               DBCOOL_NO_REG,
491                               DBCOOL_NO_REG },              1, 5, 0 },
492           { DBC_CTL,  {       DBCOOL_REMOTE1_TTHRESH,
493                               DBCOOL_NO_REG,
494                               DBCOOL_NO_REG },              1, 6, 0 },
495           { DBC_CTL,  {       DBCOOL_R1_LCL_TMIN_HYST,
496                               DBCOOL_NO_REG,
497                               DBCOOL_NO_REG },              1, 7, 0 },
498           { DBC_CTL,  {       DBCOOL_REMOTE2_TMIN,
499                               DBCOOL_NO_REG,
500                               DBCOOL_NO_REG },              2, 5, 0 },
501           { DBC_CTL,  {       DBCOOL_REMOTE2_TTHRESH,
502                               DBCOOL_NO_REG,
503                               DBCOOL_NO_REG },              2, 6, 0 },
504           { DBC_CTL,  {       DBCOOL_R2_TMIN_HYST,
505                               DBCOOL_NO_REG,
506                               DBCOOL_NO_REG },              2, 7, 0 },
507           { DBC_EOF,  { 0, 0, 0 }, 0, 0, 0 }
508 };
509 
510 struct dbcool_sensor ADM1030_sensor_table[] = {
511           { DBC_TEMP, {       DBCOOL_ADM1030_L_TEMP,
512                               DBCOOL_ADM1030_L_HI_LIM,
513                               DBCOOL_ADM1030_L_LO_LIM },    0,  0, 0 },
514           { DBC_TEMP, {       DBCOOL_ADM1030_R_TEMP,
515                               DBCOOL_ADM1030_R_HI_LIM,
516                               DBCOOL_ADM1030_R_LO_LIM },    1,  0, 0 },
517           { DBC_FAN,  {       DBCOOL_ADM1030_FAN_TACH,
518                               DBCOOL_NO_REG,
519                               DBCOOL_ADM1030_FAN_LO_LIM },  5,  0, 0 },
520           { DBC_CTL,  {       DBCOOL_ADM1030_L_TMIN,
521                               DBCOOL_NO_REG,
522                               DBCOOL_NO_REG },              0,  8, 0 },
523           { DBC_CTL,  {       DBCOOL_ADM1030_L_TTHRESH,
524                               DBCOOL_NO_REG,
525                               DBCOOL_NO_REG },              0,  9, 0 },
526           { DBC_CTL,  {       DBCOOL_ADM1030_L_TTHRESH,
527                               DBCOOL_NO_REG,
528                               DBCOOL_NO_REG },              0,  6, 0 },
529           { DBC_CTL,  {       DBCOOL_ADM1030_R_TMIN,
530                               DBCOOL_NO_REG,
531                               DBCOOL_NO_REG },              1,  8, 0 },
532           { DBC_CTL,  {       DBCOOL_ADM1030_R_TTHRESH,
533                               DBCOOL_NO_REG,
534                               DBCOOL_NO_REG },              1,  9, 0 },
535           { DBC_CTL,  {       DBCOOL_ADM1030_R_TTHRESH,
536                               DBCOOL_NO_REG,
537                               DBCOOL_NO_REG },              1,  6, 0 },
538           { DBC_EOF,  {0, 0, 0 }, 0, 0, 0 }
539 };
540 
541 struct dbcool_power_control ADM1030_power_table[] = {
542           { { DBCOOL_ADM1030_CFG1,  DBCOOL_NO_REG, DBCOOL_NO_REG,
543               DBCOOL_ADM1030_FAN_SPEED_CFG },
544             "fan_control_1" },
545           { { 0, 0, 0, 0 }, NULL }
546 };
547 
548 struct dbcool_sensor ADM1031_sensor_table[] = {
549           { DBC_TEMP, {       DBCOOL_ADM1030_L_TEMP,
550                               DBCOOL_ADM1030_L_HI_LIM,
551                               DBCOOL_ADM1030_L_LO_LIM },    0,  0, 0 },
552           { DBC_TEMP, {       DBCOOL_ADM1030_R_TEMP,
553                               DBCOOL_ADM1030_R_HI_LIM,
554                               DBCOOL_ADM1030_R_LO_LIM },    1,  0, 0 },
555           { DBC_TEMP, {       DBCOOL_ADM1031_R2_TEMP,
556                               DBCOOL_ADM1031_R2_HI_LIM,
557                               DBCOOL_ADM1031_R2_LO_LIM },   2,  0, 0 },
558           { DBC_FAN,  {       DBCOOL_ADM1030_FAN_TACH,
559                               DBCOOL_NO_REG,
560                               DBCOOL_ADM1030_FAN_LO_LIM },  5,  0, 0 },
561           { DBC_FAN,  {       DBCOOL_ADM1031_FAN2_TACH,
562                               DBCOOL_NO_REG,
563                               DBCOOL_ADM1031_FAN2_LO_LIM }, 6,  0, 0 },
564           { DBC_CTL,  {       DBCOOL_ADM1030_L_TMIN,
565                               DBCOOL_NO_REG,
566                               DBCOOL_NO_REG },              0,  8, 0 },
567           { DBC_CTL,  {       DBCOOL_ADM1030_L_TTHRESH,
568                               DBCOOL_NO_REG,
569                               DBCOOL_NO_REG },              0,  9, 0 },
570           { DBC_CTL,  {       DBCOOL_ADM1030_L_TTHRESH,
571                               DBCOOL_NO_REG,
572                               DBCOOL_NO_REG },              0,  6, 0 },
573           { DBC_CTL,  {       DBCOOL_ADM1030_R_TMIN,
574                               DBCOOL_NO_REG,
575                               DBCOOL_NO_REG },              1,  8, 0 },
576           { DBC_CTL,  {       DBCOOL_ADM1030_R_TTHRESH,
577                               DBCOOL_NO_REG,
578                               DBCOOL_NO_REG },              1,  9, 0 },
579           { DBC_CTL,  {       DBCOOL_ADM1030_R_TTHRESH,
580                               DBCOOL_NO_REG,
581                               DBCOOL_NO_REG },              1,  6, 0 },
582           { DBC_CTL,  {       DBCOOL_ADM1031_R2_TMIN,
583                               DBCOOL_NO_REG,
584                               DBCOOL_NO_REG },              2,  8, 0 },
585           { DBC_CTL,  {       DBCOOL_ADM1031_R2_TTHRESH,
586                               DBCOOL_NO_REG,
587                               DBCOOL_NO_REG },              2,  9, 0 },
588           { DBC_CTL,  {       DBCOOL_ADM1031_R2_TTHRESH,
589                               DBCOOL_NO_REG,
590                               DBCOOL_NO_REG },              2,  6, 0 },
591           { DBC_EOF,  {0, 0, 0 }, 0, 0, 0 }
592 };
593 
594 struct dbcool_power_control ADM1031_power_table[] = {
595           { { DBCOOL_ADM1030_CFG1,  DBCOOL_NO_REG, DBCOOL_NO_REG,
596               DBCOOL_ADM1030_FAN_SPEED_CFG },
597             "fan_control_1" },
598           { { DBCOOL_ADM1030_CFG1,  DBCOOL_NO_REG, DBCOOL_NO_REG,
599               DBCOOL_ADM1030_FAN_SPEED_CFG },
600             "fan_control_2" },
601           { { 0, 0, 0, 0 }, NULL }
602 };
603 
604 struct dbcool_sensor EMC6D103S_sensor_table[] = {
605           { DBC_TEMP, {       DBCOOL_LOCAL_TEMP,
606                               DBCOOL_LOCAL_HIGHLIM,
607                               DBCOOL_LOCAL_LOWLIM },                  0, 0, 0 },
608           { DBC_TEMP, {       DBCOOL_REMOTE1_TEMP,
609                               DBCOOL_REMOTE1_HIGHLIM,
610                               DBCOOL_REMOTE1_LOWLIM },      1, 0, 0 },
611           { DBC_TEMP, {       DBCOOL_REMOTE2_TEMP,
612                               DBCOOL_REMOTE2_HIGHLIM,
613                               DBCOOL_REMOTE2_LOWLIM },      2, 0, 0 },
614           { DBC_VOLT, {       DBCOOL_VCCP,
615                               DBCOOL_VCCP_HIGHLIM,
616                               DBCOOL_VCCP_LOWLIM },                   3, 0, 1 },
617           { DBC_VOLT, {       DBCOOL_VCC,
618                               DBCOOL_VCC_HIGHLIM,
619                               DBCOOL_VCC_LOWLIM },                    4, 0, 0 },
620           { DBC_VOLT, {       DBCOOL_25VIN,
621                               DBCOOL_25VIN_HIGHLIM,
622                               DBCOOL_25VIN_LOWLIM },                  11, 0, 2 },
623           { DBC_VOLT, {       DBCOOL_5VIN,
624                               DBCOOL_5VIN_HIGHLIM,
625                               DBCOOL_5VIN_LOWLIM },                   12, 0, 3 },
626           { DBC_VOLT, {       DBCOOL_12VIN,
627                               DBCOOL_12VIN_HIGHLIM,
628                               DBCOOL_12VIN_LOWLIM },                  13, 0, 4 },
629           { DBC_FAN,  {       DBCOOL_FAN1_TACH_LSB,
630                               DBCOOL_NO_REG,
631                               DBCOOL_TACH1_MIN_LSB },                 5, 0, 0 },
632           { DBC_FAN,  {       DBCOOL_FAN2_TACH_LSB,
633                               DBCOOL_NO_REG,
634                               DBCOOL_TACH2_MIN_LSB },                 6, 0, 0 },
635           { DBC_FAN,  {       DBCOOL_FAN3_TACH_LSB,
636                               DBCOOL_NO_REG,
637                               DBCOOL_TACH3_MIN_LSB },                 7, 0, 0 },
638           { DBC_FAN,  {       DBCOOL_FAN4_TACH_LSB,
639                               DBCOOL_NO_REG,
640                               DBCOOL_TACH4_MIN_LSB },                 8, 0, 0 },
641           { DBC_VID,  {       DBCOOL_VID_REG,
642                               DBCOOL_NO_REG,
643                               DBCOOL_NO_REG },              16, 0, 0 },
644           { DBC_CTL,  {       DBCOOL_LOCAL_TMIN,
645                               DBCOOL_NO_REG,
646                               DBCOOL_NO_REG },              0, 5, 0 },
647           { DBC_CTL,  {       DBCOOL_LOCAL_TTHRESH,
648                               DBCOOL_NO_REG,
649                               DBCOOL_NO_REG },              0, 6, 0 },
650           { DBC_CTL,  {       DBCOOL_REMOTE1_TMIN,
651                               DBCOOL_NO_REG,
652                               DBCOOL_NO_REG },              1, 5, 0 },
653           { DBC_CTL,  {       DBCOOL_REMOTE1_TTHRESH,
654                               DBCOOL_NO_REG,
655                               DBCOOL_NO_REG },              1, 6, 0 },
656           { DBC_CTL,  {       DBCOOL_REMOTE2_TMIN,
657                               DBCOOL_NO_REG,
658                               DBCOOL_NO_REG },              2, 5, 0 },
659           { DBC_CTL,  {       DBCOOL_REMOTE2_TTHRESH,
660                               DBCOOL_NO_REG,
661                               DBCOOL_NO_REG },              2, 6, 0 },
662           { DBC_EOF,  { 0, 0, 0 }, 0, 0, 0 }
663 };
664 
665 struct chip_id chip_table[] = {
666           { DBCOOL_COMPANYID, ADT7490_DEVICEID, ADT7490_REV_ID,
667                     ADT7490_sensor_table, ADT7475_power_table,
668                     DBCFLAG_TEMPOFFSET | DBCFLAG_HAS_MAXDUTY | DBCFLAG_HAS_PECI,
669                     90000 * 60, "ADT7490" },
670           { DBCOOL_COMPANYID, ADT7476_DEVICEID, 0xff,
671                     ADT7476_sensor_table, ADT7475_power_table,
672                     DBCFLAG_TEMPOFFSET | DBCFLAG_HAS_MAXDUTY,
673                     90000 * 60, "ADT7476" },
674           { DBCOOL_COMPANYID, ADT7475_DEVICEID, 0xff,
675                     ADT7475_sensor_table, ADT7475_power_table,
676                     DBCFLAG_TEMPOFFSET | DBCFLAG_HAS_MAXDUTY | DBCFLAG_HAS_SHDN,
677                     90000 * 60, "ADT7475" },
678           { DBCOOL_COMPANYID, ADT7473_DEVICEID, ADT7473_REV_ID1,
679                     ADT7475_sensor_table, ADT7475_power_table,
680                     DBCFLAG_TEMPOFFSET | DBCFLAG_HAS_MAXDUTY | DBCFLAG_HAS_SHDN,
681                     90000 * 60, "ADT7460/ADT7463" },
682           { DBCOOL_COMPANYID, ADT7473_DEVICEID, ADT7473_REV_ID2,
683                     ADT7475_sensor_table, ADT7475_power_table,
684                     DBCFLAG_TEMPOFFSET | DBCFLAG_HAS_MAXDUTY | DBCFLAG_HAS_SHDN,
685                     90000 * 60, "ADT7463-1" },
686           { DBCOOL_COMPANYID, ADT7468_DEVICEID, 0xff,
687                     ADT7476_sensor_table, ADT7475_power_table,
688                     DBCFLAG_TEMPOFFSET  | DBCFLAG_MULTI_VCC | DBCFLAG_HAS_MAXDUTY |
689                         DBCFLAG_4BIT_VER | DBCFLAG_HAS_SHDN,
690                     90000 * 60, "ADT7467/ADT7468" },
691           { DBCOOL_COMPANYID, ADT7466_DEVICEID, 0xff,
692                     ADT7466_sensor_table, NULL,
693                     DBCFLAG_ADT7466 | DBCFLAG_TEMPOFFSET | DBCFLAG_HAS_SHDN,
694                     82000 * 60, "ADT7466" },
695           { DBCOOL_COMPANYID, ADT7463_DEVICEID, ADT7463_REV_ID1,
696                     ADM1027_sensor_table, ADT7475_power_table,
697                     DBCFLAG_MULTI_VCC | DBCFLAG_4BIT_VER | DBCFLAG_HAS_SHDN,
698                     90000 * 60, "ADT7463" },
699           { DBCOOL_COMPANYID, ADT7463_DEVICEID, ADT7463_REV_ID2,
700                     ADM1027_sensor_table, ADT7475_power_table,
701                     DBCFLAG_MULTI_VCC | DBCFLAG_4BIT_VER | DBCFLAG_HAS_SHDN |
702                         DBCFLAG_HAS_VID_SEL,
703                     90000 * 60, "ADT7463" },
704           { DBCOOL_COMPANYID, ADM1027_DEVICEID, ADM1027_REV_ID,
705                     ADM1027_sensor_table, ADT7475_power_table,
706                     DBCFLAG_MULTI_VCC | DBCFLAG_4BIT_VER,
707                     90000 * 60, "ADM1027" },
708           { DBCOOL_COMPANYID, ADM1030_DEVICEID, 0xff,
709                     ADM1030_sensor_table, ADM1030_power_table,
710                     DBCFLAG_ADM1030 | DBCFLAG_NO_READBYTE,
711                     11250 * 60, "ADM1030" },
712           { DBCOOL_COMPANYID, ADM1031_DEVICEID, 0xff,
713                     ADM1031_sensor_table, ADM1030_power_table,
714                     DBCFLAG_ADM1030 | DBCFLAG_NO_READBYTE,
715                     11250 * 60, "ADM1031" },
716           { SMSC_COMPANYID, EMC6D103S_DEVICEID, EMC6D103S_REV_ID,
717                     EMC6D103S_sensor_table, ADT7475_power_table,
718                     DBCFLAG_4BIT_VER,
719                     90000 * 60, "EMC6D103S" },
720           { 0, 0, 0, NULL, NULL, 0, 0, NULL }
721 };
722 
723 static const char *behavior[] = {
724           "remote1",          "local",  "remote2",          "full-speed",
725           "disabled",         "local+remote2","all-temps",  "manual"
726 };
727 
728 static char dbcool_cur_behav[16];
729 
730 CFATTACH_DECL_NEW(dbcool, sizeof(struct dbcool_softc),
731     dbcool_match, dbcool_attach, dbcool_detach, NULL);
732 
733 static const struct device_compatible_entry compat_data[] = {
734           { .compat = "i2c-adm1031" },
735           { .compat = "adt7467" },
736           { .compat = "adt7460" },
737           { .compat = "adm1030" },
738           DEVICE_COMPAT_EOL
739 };
740 
741 int
dbcool_match(device_t parent,cfdata_t cf,void * aux)742 dbcool_match(device_t parent, cfdata_t cf, void *aux)
743 {
744           struct i2c_attach_args *ia = aux;
745           struct dbcool_chipset dc;
746           dc.dc_tag = ia->ia_tag;
747           dc.dc_addr = ia->ia_addr;
748           dc.dc_chip = NULL;
749           dc.dc_readreg = dbcool_readreg;
750           dc.dc_writereg = dbcool_writereg;
751           int match_result;
752 
753           if (iic_use_direct_match(ia, cf, compat_data, &match_result))
754                     return match_result;
755 
756           if ((ia->ia_addr & DBCOOL_ADDRMASK) != DBCOOL_ADDR)
757                     return 0;
758           if (dbcool_chip_ident(&dc) >= 0)
759                     return I2C_MATCH_ADDRESS_AND_PROBE;
760 
761           return 0;
762 }
763 
764 void
dbcool_attach(device_t parent,device_t self,void * aux)765 dbcool_attach(device_t parent, device_t self, void *aux)
766 {
767           struct dbcool_softc *sc = device_private(self);
768           struct i2c_attach_args *args = aux;
769           uint8_t ver;
770 
771           sc->sc_dc.dc_addr = args->ia_addr;
772           sc->sc_dc.dc_tag = args->ia_tag;
773           sc->sc_dc.dc_chip = NULL;
774           sc->sc_dc.dc_readreg = dbcool_readreg;
775           sc->sc_dc.dc_writereg = dbcool_writereg;
776           sc->sc_dev = self;
777           sc->sc_prop = args->ia_prop;
778           prop_object_retain(sc->sc_prop);
779 
780           if (dbcool_chip_ident(&sc->sc_dc) < 0 || sc->sc_dc.dc_chip == NULL)
781                     panic("could not identify chip at addr %d", args->ia_addr);
782 
783           aprint_naive("\n");
784           aprint_normal("\n");
785 
786           ver = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_REVISION_REG);
787           if (sc->sc_dc.dc_chip->flags & DBCFLAG_4BIT_VER)
788                   if (sc->sc_dc.dc_chip->company == SMSC_COMPANYID)
789                   {
790                             aprint_normal_dev(self, "SMSC %s Controller "
791                                   "(rev 0x%02x, stepping 0x%02x)\n",
792                                   sc->sc_dc.dc_chip->name, ver >> 4, ver & 0x0f);
793                   } else {
794                             aprint_normal_dev(self, "%s dBCool(tm) Controller "
795                                   "(rev 0x%02x, stepping 0x%02x)\n",
796                                   sc->sc_dc.dc_chip->name, ver >> 4, ver & 0x0f);
797                 }
798           else
799                     aprint_normal_dev(self, "%s dBCool(tm) Controller "
800                               "(rev 0x%04x)\n", sc->sc_dc.dc_chip->name, ver);
801 
802           sc->sc_sysctl_log = NULL;
803 
804 #ifdef _MODULE
805           sysctl_dbcoolsetup(&sc->sc_sysctl_log);
806 #endif
807 
808           dbcool_setup(self);
809 
810           if (!pmf_device_register(self, dbcool_pmf_suspend, dbcool_pmf_resume))
811                     aprint_error_dev(self, "couldn't establish power handler\n");
812 }
813 
814 static int
dbcool_detach(device_t self,int flags)815 dbcool_detach(device_t self, int flags)
816 {
817           struct dbcool_softc *sc = device_private(self);
818 
819           pmf_device_deregister(self);
820 
821           if (sc->sc_sme != NULL)
822                     sysmon_envsys_unregister(sc->sc_sme);
823 
824           sysctl_teardown(&sc->sc_sysctl_log);
825 
826           return 0;
827 }
828 
829 /*
830  * On suspend, we save the state of the SHDN bit, then set it
831  * On resume, we restore the previous state of the SHDN bit (which
832  * we saved in sc_suspend)
833  */
834 static bool
dbcool_do_pmf(device_t dev,const pmf_qual_t * qual,bool suspend)835 dbcool_do_pmf(device_t dev, const pmf_qual_t *qual, bool suspend)
836 {
837           struct dbcool_softc *sc = device_private(dev);
838           uint8_t reg, bit, cfg;
839 
840           if ((sc->sc_dc.dc_chip->flags & DBCFLAG_HAS_SHDN) == 0)
841                     return true;
842 
843           if (sc->sc_dc.dc_chip->flags & DBCFLAG_ADT7466) {
844                     reg = DBCOOL_ADT7466_CONFIG2;
845                     bit = DBCOOL_ADT7466_CFG2_SHDN;
846           } else {
847                     reg = DBCOOL_CONFIG2_REG;
848                     bit = DBCOOL_CFG2_SHDN;
849           }
850           cfg = sc->sc_dc.dc_readreg(&sc->sc_dc, reg);
851           if (suspend) {
852                     sc->sc_suspend = (cfg & bit) != 0;
853                     cfg |= bit;
854           } else {
855                     cfg &= sc->sc_suspend ? bit : 0;
856           }
857           sc->sc_dc.dc_writereg(&sc->sc_dc, reg, cfg);
858 
859           return true;
860 }
861 
862 bool
dbcool_pmf_suspend(device_t dev,const pmf_qual_t * qual)863 dbcool_pmf_suspend(device_t dev, const pmf_qual_t *qual)
864 {
865 
866           return dbcool_do_pmf(dev, qual, true);
867 }
868 
869 bool
dbcool_pmf_resume(device_t dev,const pmf_qual_t * qual)870 dbcool_pmf_resume(device_t dev, const pmf_qual_t *qual)
871 {
872 
873           return dbcool_do_pmf(dev, qual, false);
874 }
875 
876 uint8_t
dbcool_readreg(struct dbcool_chipset * dc,uint8_t reg)877 dbcool_readreg(struct dbcool_chipset *dc, uint8_t reg)
878 {
879           uint8_t data = 0;
880 
881           if (iic_acquire_bus(dc->dc_tag, 0) != 0)
882                     return data;
883 
884           if (dc->dc_chip == NULL || dc->dc_chip->flags & DBCFLAG_NO_READBYTE) {
885                     /* ADM1027 doesn't support i2c read_byte protocol */
886                     if (iic_smbus_send_byte(dc->dc_tag, dc->dc_addr, reg, 0) != 0)
887                               goto bad;
888                     (void)iic_smbus_receive_byte(dc->dc_tag, dc->dc_addr, &data, 0);
889           } else
890                     (void)iic_smbus_read_byte(dc->dc_tag, dc->dc_addr, reg, &data,
891                                                     0);
892 
893 bad:
894           iic_release_bus(dc->dc_tag, 0);
895           return data;
896 }
897 
898 void
dbcool_writereg(struct dbcool_chipset * dc,uint8_t reg,uint8_t val)899 dbcool_writereg(struct dbcool_chipset *dc, uint8_t reg, uint8_t val)
900 {
901           if (iic_acquire_bus(dc->dc_tag, 0) != 0)
902                     return;
903 
904           (void)iic_smbus_write_byte(dc->dc_tag, dc->dc_addr, reg, val, 0);
905 
906           iic_release_bus(dc->dc_tag, 0);
907 }
908 
909 static bool
dbcool_islocked(struct dbcool_softc * sc)910 dbcool_islocked(struct dbcool_softc *sc)
911 {
912           uint8_t cfg_reg;
913 
914           if (sc->sc_dc.dc_chip->flags & DBCFLAG_ADM1030)
915                     return 0;
916 
917           if (sc->sc_dc.dc_chip->flags & DBCFLAG_ADT7466)
918                     cfg_reg = DBCOOL_ADT7466_CONFIG1;
919           else
920                     cfg_reg = DBCOOL_CONFIG1_REG;
921 
922           if (sc->sc_dc.dc_readreg(&sc->sc_dc, cfg_reg) & DBCOOL_CFG1_LOCK)
923                     return 1;
924           else
925                     return 0;
926 }
927 
928 static int
dbcool_read_temp(struct dbcool_softc * sc,uint8_t reg,bool extres)929 dbcool_read_temp(struct dbcool_softc *sc, uint8_t reg, bool extres)
930 {
931           uint8_t   t1, t2, t3, val, ext = 0;
932           int temp;
933 
934           if (sc->sc_dc.dc_chip->flags & DBCFLAG_ADT7466) {
935                     /*
936                      * ADT7466 temps are in strange location
937                      */
938                     ext = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_ADT7466_CONFIG1);
939                     val = sc->sc_dc.dc_readreg(&sc->sc_dc, reg);
940                     if (extres)
941                               ext = sc->sc_dc.dc_readreg(&sc->sc_dc, reg + 1);
942           } else if (sc->sc_dc.dc_chip->flags & DBCFLAG_ADM1030) {
943                     /*
944                      * ADM1030 temps are in their own special place, too
945                      */
946                     if (extres) {
947                               ext = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_ADM1030_TEMP_EXTRES);
948                               if (reg == DBCOOL_ADM1030_L_TEMP)
949                                         ext >>= 6;
950                               else if (reg == DBCOOL_ADM1031_R2_TEMP)
951                                         ext >>= 4;
952                               else
953                                         ext >>= 1;
954                               ext &= 0x03;
955                     }
956                     val = sc->sc_dc.dc_readreg(&sc->sc_dc, reg);
957           } else if (extres) {
958                     ext = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_EXTRES2_REG);
959 
960                     /* Read all msb regs to unlatch them */
961                     t1 = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_12VIN);
962                     t1 = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_REMOTE1_TEMP);
963                     t2 = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_REMOTE2_TEMP);
964                     t3 = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_LOCAL_TEMP);
965                     switch (reg) {
966                     case DBCOOL_REMOTE1_TEMP:
967                               val = t1;
968                               ext >>= 2;
969                               break;
970                     case DBCOOL_LOCAL_TEMP:
971                               val = t3;
972                               ext >>= 4;
973                               break;
974                     case DBCOOL_REMOTE2_TEMP:
975                               val = t2;
976                               ext >>= 6;
977                               break;
978                     default:
979                               val = 0;
980                               break;
981                     }
982                     ext &= 0x03;
983           }
984           else
985                     val = sc->sc_dc.dc_readreg(&sc->sc_dc, reg);
986 
987           /* Check for invalid temp values */
988           if ((sc->sc_temp_offset == 0 && val == 0x80) ||
989               (sc->sc_temp_offset != 0 && val == 0))
990                     return 0;
991 
992           /* If using offset mode, adjust, else treat as signed */
993           if (sc->sc_temp_offset) {
994                     temp = val;
995                     temp -= sc->sc_temp_offset;
996           } else
997                     temp = (int8_t)val;
998 
999           /* Convert degC to uK and include extended precision bits */
1000           temp *= 1000000;
1001           temp +=  250000 * (int)ext;
1002           temp += 273150000U;
1003 
1004           return temp;
1005 }
1006 
1007 static int
dbcool_read_rpm(struct dbcool_softc * sc,uint8_t reg)1008 dbcool_read_rpm(struct dbcool_softc *sc, uint8_t reg)
1009 {
1010           int rpm;
1011           uint8_t rpm_lo, rpm_hi;
1012 
1013           rpm_lo = sc->sc_dc.dc_readreg(&sc->sc_dc, reg);
1014           if (sc->sc_dc.dc_chip->flags & DBCFLAG_ADM1030)
1015                     rpm_hi = (rpm_lo == 0xff)?0xff:0x0;
1016           else
1017                     rpm_hi = sc->sc_dc.dc_readreg(&sc->sc_dc, reg + 1);
1018 
1019           rpm = (rpm_hi << 8) | rpm_lo;
1020           if (rpm == 0xffff)
1021                     return 0; /* 0xffff indicates stalled/failed fan */
1022 
1023           /* don't divide by zero */
1024           return (rpm == 0)? 0 : (sc->sc_dc.dc_chip->rpm_dividend / rpm);
1025 }
1026 
1027 /* Provide chip's supply voltage, in microvolts */
1028 static int
dbcool_supply_voltage(struct dbcool_softc * sc)1029 dbcool_supply_voltage(struct dbcool_softc *sc)
1030 {
1031           if (sc->sc_dc.dc_chip->flags & DBCFLAG_MULTI_VCC) {
1032                     if (sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_CONFIG1_REG) & DBCOOL_CFG1_Vcc)
1033                               return 5002500;
1034                     else
1035                               return 3300000;
1036           } else if (sc->sc_dc.dc_chip->flags & DBCFLAG_ADT7466) {
1037                     if (sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_ADT7466_CONFIG1) &
1038                                   DBCOOL_ADT7466_CFG1_Vcc)
1039                               return 5000000;
1040                     else
1041                               return 3300000;
1042           } else
1043                     return 3300000;
1044 }
1045 
1046 /*
1047  * Nominal voltages are calculated in microvolts
1048  */
1049 static int
dbcool_read_volt(struct dbcool_softc * sc,uint8_t reg,int nom_idx,bool extres)1050 dbcool_read_volt(struct dbcool_softc *sc, uint8_t reg, int nom_idx, bool extres)
1051 {
1052           uint8_t ext = 0, v1, v2, v3, v4, val;
1053           int64_t ret;
1054           int64_t nom;
1055 
1056           nom = nominal_voltages[nom_idx];
1057           if (nom < 0)
1058                     nom = sc->sc_supply_voltage;
1059 
1060           /* ADT7466 voltages are in strange locations with only 8-bits */
1061           if (sc->sc_dc.dc_chip->flags & DBCFLAG_ADT7466)
1062                     val = sc->sc_dc.dc_readreg(&sc->sc_dc, reg);
1063           else
1064           /*
1065            * It's a "normal" dbCool chip - check for regs that
1066            * share extended resolution bits since we have to
1067            * read all the MSB registers to unlatch them.
1068            */
1069           if (!extres)
1070                     val = sc->sc_dc.dc_readreg(&sc->sc_dc, reg);
1071           else if (reg == DBCOOL_12VIN) {
1072                     ext = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_EXTRES2_REG) & 0x03;
1073                     val = sc->sc_dc.dc_readreg(&sc->sc_dc, reg);
1074                     (void)dbcool_read_temp(sc, DBCOOL_LOCAL_TEMP, true);
1075           } else if (reg == DBCOOL_VTT || reg == DBCOOL_IMON) {
1076                     ext = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_EXTRES_VTT_IMON);
1077                     v1 = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_IMON);
1078                     v2 = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_VTT);
1079                     if (reg == DBCOOL_IMON) {
1080                               val = v1;
1081                               ext >>= 6;
1082                     } else {
1083                               val = v2;
1084                               ext >>= 4;
1085                     }
1086                     ext &= 0x0f;
1087           } else {
1088                     ext = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_EXTRES1_REG);
1089                     v1 = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_25VIN);
1090                     v2 = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_VCCP);
1091                     v3 = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_VCC);
1092                     v4 = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_5VIN);
1093 
1094                     switch (reg) {
1095                     case DBCOOL_25VIN:
1096                               val = v1;
1097                               break;
1098                     case DBCOOL_VCCP:
1099                               val = v2;
1100                               ext >>= 2;
1101                               break;
1102                     case DBCOOL_VCC:
1103                               val = v3;
1104                               ext >>= 4;
1105                               break;
1106                     case DBCOOL_5VIN:
1107                               val = v4;
1108                               ext >>= 6;
1109                               break;
1110                     default:
1111                               val = nom = 0;
1112                     }
1113                     ext &= 0x03;
1114           }
1115 
1116           /*
1117            * Scale the nominal value by the 10-bit fraction
1118            *
1119            * Returned value is in microvolts.
1120            */
1121           ret = val;
1122           ret <<= 2;
1123           ret |= ext;
1124           ret = (ret * nom) / 0x300;
1125 
1126           return ret;
1127 }
1128 
1129 static int
sysctl_dbcool_temp(SYSCTLFN_ARGS)1130 sysctl_dbcool_temp(SYSCTLFN_ARGS)
1131 {
1132           struct sysctlnode node;
1133           struct dbcool_softc *sc;
1134           int reg, error;
1135           uint8_t chipreg;
1136           uint8_t newreg;
1137 
1138           node = *rnode;
1139           sc = (struct dbcool_softc *)node.sysctl_data;
1140           chipreg = node.sysctl_num & 0xff;
1141 
1142           if (sc->sc_temp_offset) {
1143                     reg = sc->sc_dc.dc_readreg(&sc->sc_dc, chipreg);
1144                     reg -= sc->sc_temp_offset;
1145           } else
1146                     reg = (int8_t)sc->sc_dc.dc_readreg(&sc->sc_dc, chipreg);
1147 
1148           node.sysctl_data = &reg;
1149           error = sysctl_lookup(SYSCTLFN_CALL(&node));
1150 
1151           if (error || newp == NULL)
1152                     return error;
1153 
1154           /* We were asked to update the value - sanity check before writing */
1155           if (*(int *)node.sysctl_data < -64 ||
1156               *(int *)node.sysctl_data > 127 + sc->sc_temp_offset)
1157                     return EINVAL;
1158 
1159           newreg = *(int *)node.sysctl_data;
1160           newreg += sc->sc_temp_offset;
1161           sc->sc_dc.dc_writereg(&sc->sc_dc, chipreg, newreg);
1162           return 0;
1163 }
1164 
1165 static int
sysctl_adm1030_temp(SYSCTLFN_ARGS)1166 sysctl_adm1030_temp(SYSCTLFN_ARGS)
1167 {
1168           struct sysctlnode node;
1169           struct dbcool_softc *sc;
1170           int reg, error;
1171           uint8_t chipreg, oldreg, newreg;
1172 
1173           node = *rnode;
1174           sc = (struct dbcool_softc *)node.sysctl_data;
1175           chipreg = node.sysctl_num & 0xff;
1176 
1177           oldreg = (int8_t)sc->sc_dc.dc_readreg(&sc->sc_dc, chipreg);
1178           reg = (oldreg >> 1) & ~0x03;
1179 
1180           node.sysctl_data = &reg;
1181           error = sysctl_lookup(SYSCTLFN_CALL(&node));
1182 
1183           if (error || newp == NULL)
1184                     return error;
1185 
1186           /* We were asked to update the value - sanity check before writing */
1187           if (*(int *)node.sysctl_data < 0 || *(int *)node.sysctl_data > 127)
1188                     return EINVAL;
1189 
1190           newreg = *(int *)node.sysctl_data;
1191           newreg &= ~0x03;
1192           newreg <<= 1;
1193           newreg |= (oldreg & 0x07);
1194           sc->sc_dc.dc_writereg(&sc->sc_dc, chipreg, newreg);
1195           return 0;
1196 }
1197 
1198 static int
sysctl_adm1030_trange(SYSCTLFN_ARGS)1199 sysctl_adm1030_trange(SYSCTLFN_ARGS)
1200 {
1201           struct sysctlnode node;
1202           struct dbcool_softc *sc;
1203           int reg, error, newval;
1204           uint8_t chipreg, oldreg, newreg;
1205 
1206           node = *rnode;
1207           sc = (struct dbcool_softc *)node.sysctl_data;
1208           chipreg = node.sysctl_num & 0xff;
1209 
1210           oldreg = (int8_t)sc->sc_dc.dc_readreg(&sc->sc_dc, chipreg);
1211           reg = oldreg & 0x07;
1212 
1213           node.sysctl_data = &reg;
1214           error = sysctl_lookup(SYSCTLFN_CALL(&node));
1215 
1216           if (error || newp == NULL)
1217                     return error;
1218 
1219           /* We were asked to update the value - sanity check before writing */
1220           newval = *(int *)node.sysctl_data;
1221 
1222           if (newval == 5)
1223                     newreg = 0;
1224           else if (newval == 10)
1225                     newreg = 1;
1226           else if (newval == 20)
1227                     newreg = 2;
1228           else if (newval == 40)
1229                     newreg = 3;
1230           else if (newval == 80)
1231                     newreg = 4;
1232           else
1233                     return EINVAL;
1234 
1235           newreg |= (oldreg & ~0x07);
1236           sc->sc_dc.dc_writereg(&sc->sc_dc, chipreg, newreg);
1237           return 0;
1238 }
1239 
1240 static int
sysctl_dbcool_duty(SYSCTLFN_ARGS)1241 sysctl_dbcool_duty(SYSCTLFN_ARGS)
1242 {
1243           struct sysctlnode node;
1244           struct dbcool_softc *sc;
1245           int reg, error;
1246           uint8_t chipreg, oldreg, newreg;
1247 
1248           node = *rnode;
1249           sc = (struct dbcool_softc *)node.sysctl_data;
1250           chipreg = node.sysctl_num & 0xff;
1251 
1252           oldreg = sc->sc_dc.dc_readreg(&sc->sc_dc, chipreg);
1253           reg = (uint32_t)oldreg;
1254           if (sc->sc_dc.dc_chip->flags & DBCFLAG_ADM1030)
1255                     reg = ((reg & 0x0f) * 100) / 15;
1256           else
1257                     reg = (reg * 100) / 255;
1258           node.sysctl_data = &reg;
1259           error = sysctl_lookup(SYSCTLFN_CALL(&node));
1260 
1261           if (error || newp == NULL)
1262                     return error;
1263 
1264           /* We were asked to update the value - sanity check before writing */
1265           if (*(int *)node.sysctl_data < 0 || *(int *)node.sysctl_data > 100)
1266                     return EINVAL;
1267 
1268           if (sc->sc_dc.dc_chip->flags & DBCFLAG_ADM1030) {
1269                     newreg = *(uint8_t *)(node.sysctl_data) * 15 / 100;
1270                     newreg |= oldreg & 0xf0;
1271           } else
1272                     newreg = *(uint8_t *)(node.sysctl_data) * 255 / 100;
1273           sc->sc_dc.dc_writereg(&sc->sc_dc, chipreg, newreg);
1274           return 0;
1275 }
1276 
1277 static int
sysctl_dbcool_behavior(SYSCTLFN_ARGS)1278 sysctl_dbcool_behavior(SYSCTLFN_ARGS)
1279 {
1280           struct sysctlnode node;
1281           struct dbcool_softc *sc;
1282           int i, reg, error;
1283           uint8_t chipreg, oldreg, newreg;
1284 
1285           node = *rnode;
1286           sc = (struct dbcool_softc *)node.sysctl_data;
1287           chipreg = node.sysctl_num & 0xff;
1288 
1289           oldreg = sc->sc_dc.dc_readreg(&sc->sc_dc, chipreg);
1290 
1291           if (sc->sc_dc.dc_chip->flags & DBCFLAG_ADM1030) {
1292                     if ((sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_ADM1030_CFG2) & 1) == 0)
1293                               reg = 4;
1294                     else if ((oldreg & 0x80) == 0)
1295                               reg = 7;
1296                     else if ((oldreg & 0x60) == 0)
1297                               reg = 4;
1298                     else
1299                               reg = 6;
1300           } else
1301                     reg = (oldreg >> 5) & 0x07;
1302 
1303           strlcpy(dbcool_cur_behav, behavior[reg], sizeof(dbcool_cur_behav));
1304           node.sysctl_data = dbcool_cur_behav;
1305           error = sysctl_lookup(SYSCTLFN_CALL(&node));
1306 
1307           if (error || newp == NULL)
1308                     return error;
1309 
1310           /* We were asked to update the value - convert string to value */
1311           newreg = __arraycount(behavior);
1312           for (i = 0; i < __arraycount(behavior); i++)
1313                     if (strcmp(node.sysctl_data, behavior[i]) == 0)
1314                               break;
1315           if (i >= __arraycount(behavior))
1316                     return EINVAL;
1317           newreg = i;
1318           if (sc->sc_dc.dc_chip->flags & DBCFLAG_ADM1030) {
1319                     /*
1320                      * ADM1030 splits fan controller behavior across two
1321                      * registers.  We also do not support Auto-Filter mode
1322                      * nor do we support Manual-RPM-feedback.
1323                      */
1324                     if (newreg == 4) {
1325                               oldreg = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_ADM1030_CFG2);
1326                               oldreg &= ~0x01;
1327                               sc->sc_dc.dc_writereg(&sc->sc_dc, DBCOOL_ADM1030_CFG2, oldreg);
1328                     } else {
1329                               if (newreg == 0)
1330                                         newreg = 4;
1331                               else if (newreg == 6)
1332                                         newreg = 7;
1333                               else if (newreg == 7)
1334                                         newreg = 0;
1335                               else
1336                                         return EINVAL;
1337                               newreg <<= 5;
1338                               newreg |= (oldreg & 0x1f);
1339                               sc->sc_dc.dc_writereg(&sc->sc_dc, chipreg, newreg);
1340                               oldreg = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_ADM1030_CFG2) | 1;
1341                               sc->sc_dc.dc_writereg(&sc->sc_dc, DBCOOL_ADM1030_CFG2, oldreg);
1342                     }
1343           } else {
1344                     newreg = (sc->sc_dc.dc_readreg(&sc->sc_dc, chipreg) & 0x1f) | (i << 5);
1345                     sc->sc_dc.dc_writereg(&sc->sc_dc, chipreg, newreg);
1346           }
1347           return 0;
1348 }
1349 
1350 static int
sysctl_dbcool_slope(SYSCTLFN_ARGS)1351 sysctl_dbcool_slope(SYSCTLFN_ARGS)
1352 {
1353           struct sysctlnode node;
1354           struct dbcool_softc *sc;
1355           int reg, error;
1356           uint8_t chipreg;
1357           uint8_t newreg;
1358 
1359           node = *rnode;
1360           sc = (struct dbcool_softc *)node.sysctl_data;
1361           chipreg = node.sysctl_num & 0xff;
1362 
1363           reg = (sc->sc_dc.dc_readreg(&sc->sc_dc, chipreg) >> 4) & 0x0f;
1364           node.sysctl_data = &reg;
1365           error = sysctl_lookup(SYSCTLFN_CALL(&node));
1366 
1367           if (error || newp == NULL)
1368                     return error;
1369 
1370           /* We were asked to update the value - sanity check before writing */
1371           if (*(int *)node.sysctl_data < 0 || *(int *)node.sysctl_data > 0x0f)
1372                     return EINVAL;
1373 
1374           newreg = (sc->sc_dc.dc_readreg(&sc->sc_dc, chipreg) & 0x0f) |
1375                       (*(int *)node.sysctl_data << 4);
1376           sc->sc_dc.dc_writereg(&sc->sc_dc, chipreg, newreg);
1377           return 0;
1378 }
1379 
1380 static int
sysctl_dbcool_thyst(SYSCTLFN_ARGS)1381 sysctl_dbcool_thyst(SYSCTLFN_ARGS)
1382 {
1383           struct sysctlnode node;
1384           struct dbcool_softc *sc;
1385           int reg, error;
1386           uint8_t chipreg;
1387           uint8_t newreg, newhyst;
1388 
1389           node = *rnode;
1390           sc = (struct dbcool_softc *)node.sysctl_data;
1391           chipreg = node.sysctl_num & 0x7f;
1392 
1393           /* retrieve 4-bit value */
1394           newreg = sc->sc_dc.dc_readreg(&sc->sc_dc, chipreg);
1395           if ((node.sysctl_num & 0x80) == 0)
1396                     reg = newreg >> 4;
1397           else
1398                     reg = newreg;
1399           reg = reg & 0x0f;
1400 
1401           node.sysctl_data = &reg;
1402           error = sysctl_lookup(SYSCTLFN_CALL(&node));
1403 
1404           if (error || newp == NULL)
1405                     return error;
1406 
1407           /* We were asked to update the value - sanity check before writing */
1408           newhyst = *(int *)node.sysctl_data;
1409           if (newhyst > 0x0f)
1410                     return EINVAL;
1411 
1412           /* Insert new value into field and update register */
1413           if ((node.sysctl_num & 0x80) == 0) {
1414                     newreg &= 0x0f;
1415                     newreg |= (newhyst << 4);
1416           } else {
1417                     newreg &= 0xf0;
1418                     newreg |= newhyst;
1419           }
1420           sc->sc_dc.dc_writereg(&sc->sc_dc, chipreg, newreg);
1421           return 0;
1422 }
1423 
1424 #ifdef DBCOOL_DEBUG
1425 
1426 /*
1427  * These routines can be used for debugging.  reg_select is used to
1428  * select any arbitrary register in the device.  reg_access is used
1429  * to read (and optionally update) the selected register.
1430  *
1431  * No attempt is made to validate the data passed.  If you use these
1432  * routines, you are assumed to know what you're doing!
1433  *
1434  * Caveat user
1435  */
1436 static int
sysctl_dbcool_reg_select(SYSCTLFN_ARGS)1437 sysctl_dbcool_reg_select(SYSCTLFN_ARGS)
1438 {
1439           struct sysctlnode node;
1440           struct dbcool_softc *sc;
1441           int reg, error;
1442 
1443           node = *rnode;
1444           sc = (struct dbcool_softc *)node.sysctl_data;
1445 
1446           reg = sc->sc_user_reg;
1447           node.sysctl_data = &reg;
1448           error = sysctl_lookup(SYSCTLFN_CALL(&node));
1449 
1450           if (error || newp == NULL)
1451                     return error;
1452 
1453           sc->sc_user_reg = *(int *)node.sysctl_data;
1454           return 0;
1455 }
1456 
1457 static int
sysctl_dbcool_reg_access(SYSCTLFN_ARGS)1458 sysctl_dbcool_reg_access(SYSCTLFN_ARGS)
1459 {
1460           struct sysctlnode node;
1461           struct dbcool_softc *sc;
1462           int reg, error;
1463           uint8_t chipreg;
1464           uint8_t newreg;
1465 
1466           node = *rnode;
1467           sc = (struct dbcool_softc *)node.sysctl_data;
1468           chipreg = sc->sc_user_reg;
1469 
1470           reg = sc->sc_dc.dc_readreg(&sc->sc_dc, chipreg);
1471           node.sysctl_data = &reg;
1472           error = sysctl_lookup(SYSCTLFN_CALL(&node));
1473 
1474           if (error || newp == NULL)
1475                     return error;
1476 
1477           newreg = *(int *)node.sysctl_data;
1478           sc->sc_dc.dc_writereg(&sc->sc_dc, chipreg, newreg);
1479           return 0;
1480 }
1481 #endif /* DBCOOL_DEBUG */
1482 
1483 /*
1484  * Encode an index number and register number for use as a sysctl_num
1485  * so we can select the correct device register later.
1486  */
1487 #define   DBC_PWM_SYSCTL(seq, reg)      ((seq << 8) | reg)
1488 
1489 void
dbcool_setup(device_t self)1490 dbcool_setup(device_t self)
1491 {
1492           struct dbcool_softc *sc = device_private(self);
1493           const struct sysctlnode *me = NULL;
1494 #ifdef DBCOOL_DEBUG
1495           struct sysctlnode *node = NULL;
1496 #endif
1497           uint8_t cfg_val, cfg_reg;
1498           int ret, error;
1499 
1500           /*
1501            * Some chips are capable of reporting an extended temperature range
1502            * by default.  On these models, config register 5 bit 0 can be set
1503            * to 1 for compatibility with other chips that report 2s complement.
1504            */
1505           if (sc->sc_dc.dc_chip->flags & DBCFLAG_ADT7466) {
1506                     if (sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_ADT7466_CONFIG1) & 0x80)
1507                               sc->sc_temp_offset = 64;
1508                     else
1509                               sc->sc_temp_offset = 0;
1510           } else if (sc->sc_dc.dc_chip->flags & DBCFLAG_TEMPOFFSET) {
1511                     if (sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_CONFIG5_REG) &
1512                                   DBCOOL_CFG5_TWOSCOMP)
1513                               sc->sc_temp_offset = 0;
1514                     else
1515                               sc->sc_temp_offset = 64;
1516           } else
1517                     sc->sc_temp_offset = 0;
1518 
1519           /* Determine Vcc for this chip */
1520           sc->sc_supply_voltage = dbcool_supply_voltage(sc);
1521 
1522           ret = sysctl_createv(&sc->sc_sysctl_log, 0, NULL, &me,
1523                  CTLFLAG_READWRITE,
1524                  CTLTYPE_NODE, device_xname(self), NULL,
1525                  NULL, 0, NULL, 0,
1526                  CTL_HW, CTL_CREATE, CTL_EOL);
1527           if (ret == 0)
1528                     sc->sc_root_sysctl_num = me->sysctl_num;
1529           else
1530                     sc->sc_root_sysctl_num = 0;
1531 
1532           aprint_debug_dev(self,
1533                     "Supply voltage %"PRId64".%06"PRId64"V, %s temp range\n",
1534                     sc->sc_supply_voltage / 1000000,
1535                     sc->sc_supply_voltage % 1000000,
1536                     sc->sc_temp_offset ? "extended" : "normal");
1537 
1538           /* Create the sensors for this device */
1539           sc->sc_sme = sysmon_envsys_create();
1540           if (dbcool_setup_sensors(sc))
1541                     goto out;
1542 
1543           if (sc->sc_root_sysctl_num != 0) {
1544                     /* If supported, create sysctl tree for fan PWM controllers */
1545                     if (sc->sc_dc.dc_chip->power != NULL)
1546                               dbcool_setup_controllers(sc);
1547 
1548 #ifdef DBCOOL_DEBUG
1549                     ret = sysctl_createv(&sc->sc_sysctl_log, 0, NULL,
1550                               (void *)&node,
1551                               CTLFLAG_READWRITE, CTLTYPE_INT, "reg_select", NULL,
1552                               sysctl_dbcool_reg_select,
1553                               0, (void *)sc, sizeof(int),
1554                               CTL_HW, me->sysctl_num, CTL_CREATE, CTL_EOL);
1555                     if (node != NULL)
1556                               node->sysctl_data = sc;
1557 
1558                     ret = sysctl_createv(&sc->sc_sysctl_log, 0, NULL,
1559                               (void *)&node,
1560                               CTLFLAG_READWRITE, CTLTYPE_INT, "reg_access", NULL,
1561                               sysctl_dbcool_reg_access,
1562                               0, (void *)sc, sizeof(int),
1563                               CTL_HW, me->sysctl_num, CTL_CREATE, CTL_EOL);
1564                     if (node != NULL)
1565                               node->sysctl_data = sc;
1566 #endif /* DBCOOL_DEBUG */
1567           }
1568 
1569           /*
1570            * Read and rewrite config register to activate device
1571            */
1572           if (sc->sc_dc.dc_chip->flags & DBCFLAG_ADM1030)
1573                     cfg_reg = DBCOOL_ADM1030_CFG1;
1574           else if (sc->sc_dc.dc_chip->flags & DBCFLAG_ADT7466)
1575                     cfg_reg = DBCOOL_ADT7466_CONFIG1;
1576           else
1577                     cfg_reg = DBCOOL_CONFIG1_REG;
1578           cfg_val = sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_CONFIG1_REG);
1579           if ((cfg_val & DBCOOL_CFG1_START) == 0) {
1580                     cfg_val |= DBCOOL_CFG1_START;
1581                     sc->sc_dc.dc_writereg(&sc->sc_dc, cfg_reg, cfg_val);
1582           }
1583           if (dbcool_islocked(sc))
1584                     aprint_normal_dev(self, "configuration locked\n");
1585 
1586           sc->sc_sme->sme_name = device_xname(self);
1587           sc->sc_sme->sme_cookie = sc;
1588           sc->sc_sme->sme_refresh = dbcool_refresh;
1589           sc->sc_sme->sme_set_limits = dbcool_set_limits;
1590           sc->sc_sme->sme_get_limits = dbcool_get_limits;
1591 
1592           if ((error = sysmon_envsys_register(sc->sc_sme)) != 0) {
1593                     aprint_error_dev(self,
1594                         "unable to register with sysmon (%d)\n", error);
1595                     goto out;
1596           }
1597 
1598           return;
1599 
1600 out:
1601           sysmon_envsys_destroy(sc->sc_sme);
1602           sc->sc_sme = NULL;
1603 }
1604 
1605 static int
dbcool_setup_sensors(struct dbcool_softc * sc)1606 dbcool_setup_sensors(struct dbcool_softc *sc)
1607 {
1608           int i;
1609           int error = 0;
1610           uint8_t   vid_reg, vid_val;
1611           struct chip_id *chip = sc->sc_dc.dc_chip;
1612 
1613           for (i=0; chip->table[i].type != DBC_EOF; i++) {
1614                     if (i < DBCOOL_MAXSENSORS)
1615                               sc->sc_sysctl_num[i] = -1;
1616                     else if (chip->table[i].type != DBC_CTL) {
1617                               aprint_normal_dev(sc->sc_dev, "chip table too big!\n");
1618                               break;
1619                     }
1620                     switch (chip->table[i].type) {
1621                     case DBC_TEMP:
1622                               sc->sc_sensor[i].units = ENVSYS_STEMP;
1623                               sc->sc_sensor[i].state = ENVSYS_SINVALID;
1624                               sc->sc_sensor[i].flags |= ENVSYS_FMONLIMITS;
1625                               sc->sc_sensor[i].flags |= ENVSYS_FHAS_ENTROPY;
1626                               error = dbcool_attach_sensor(sc, i);
1627                               break;
1628                     case DBC_VOLT:
1629                               /*
1630                                * If 12V-In pin has been reconfigured as 6th bit
1631                                * of VID code, don't create a 12V-In sensor
1632                                */
1633                               if ((chip->flags & DBCFLAG_HAS_VID_SEL) &&
1634                                   (chip->table[i].reg.val_reg == DBCOOL_12VIN) &&
1635                                   (sc->sc_dc.dc_readreg(&sc->sc_dc, DBCOOL_VID_REG) &
1636                                                   0x80))
1637                                         break;
1638 
1639                               sc->sc_sensor[i].units = ENVSYS_SVOLTS_DC;
1640                               sc->sc_sensor[i].state = ENVSYS_SINVALID;
1641                               sc->sc_sensor[i].flags |= ENVSYS_FMONLIMITS;
1642                               sc->sc_sensor[i].flags |= ENVSYS_FHAS_ENTROPY;
1643                               error = dbcool_attach_sensor(sc, i);
1644                               break;
1645                     case DBC_FAN:
1646                               sc->sc_sensor[i].units = ENVSYS_SFANRPM;
1647                               sc->sc_sensor[i].state = ENVSYS_SINVALID;
1648                               sc->sc_sensor[i].flags |= ENVSYS_FMONLIMITS;
1649                               sc->sc_sensor[i].flags |= ENVSYS_FHAS_ENTROPY;
1650                               error = dbcool_attach_sensor(sc, i);
1651                               break;
1652                     case DBC_VID:
1653                               sc->sc_sensor[i].units = ENVSYS_INTEGER;
1654                               sc->sc_sensor[i].state = ENVSYS_SINVALID;
1655                               sc->sc_sensor[i].flags |= ENVSYS_FMONNOTSUPP;
1656 
1657                               /* retrieve 5- or 6-bit value */
1658                               vid_reg = chip->table[i].reg.val_reg;
1659                               vid_val = sc->sc_dc.dc_readreg(&sc->sc_dc, vid_reg);
1660                               if (chip->flags & DBCFLAG_HAS_VID_SEL)
1661                                         vid_val &= 0x3f;
1662                               else
1663                                         vid_val &= 0x1f;
1664                               sc->sc_sensor[i].value_cur = vid_val;
1665 
1666                               error = dbcool_attach_sensor(sc, i);
1667                               break;
1668                     case DBC_CTL:
1669                               error = dbcool_attach_temp_control(sc, i, chip);
1670                               if (error) {
1671                                         aprint_error_dev(sc->sc_dev,
1672                                                             "attach index %d failed %d\n",
1673                                                             i, error);
1674                                         error = 0;
1675                               }
1676                               break;
1677                     default:
1678                               aprint_error_dev(sc->sc_dev,
1679                                         "sensor_table index %d has bad type %d\n",
1680                                         i, chip->table[i].type);
1681                               break;
1682                     }
1683                     if (error)
1684                               break;
1685           }
1686           return error;
1687 }
1688 
1689 static int
dbcool_attach_sensor(struct dbcool_softc * sc,int idx)1690 dbcool_attach_sensor(struct dbcool_softc *sc, int idx)
1691 {
1692           int name_index;
1693           int error = 0;
1694           char name[8];
1695           const char *desc;
1696 
1697           name_index = sc->sc_dc.dc_chip->table[idx].name_index;
1698           snprintf(name, 7, "s%02x", sc->sc_dc.dc_chip->table[idx].reg.val_reg);
1699           if (prop_dictionary_get_string(sc->sc_prop, name, &desc)) {
1700                      strlcpy(sc->sc_sensor[idx].desc, desc,
1701                               sizeof(sc->sc_sensor[idx].desc));
1702           } else {
1703                     strlcpy(sc->sc_sensor[idx].desc, dbc_sensor_names[name_index],
1704                               sizeof(sc->sc_sensor[idx].desc));
1705           }
1706           sc->sc_regs[idx] = &sc->sc_dc.dc_chip->table[idx].reg;
1707           sc->sc_nom_volt[idx] = sc->sc_dc.dc_chip->table[idx].nom_volt_index;
1708 
1709           error = sysmon_envsys_sensor_attach(sc->sc_sme, &sc->sc_sensor[idx]);
1710           return error;
1711 }
1712 
1713 static int
dbcool_attach_temp_control(struct dbcool_softc * sc,int idx,struct chip_id * chip)1714 dbcool_attach_temp_control(struct dbcool_softc *sc, int idx,
1715                                  struct chip_id *chip)
1716 {
1717           const struct sysctlnode *me2 = NULL, *node;
1718           int j, ret, sysctl_index, rw_flag;
1719           uint8_t   sysctl_reg;
1720           char name[SYSCTL_NAMELEN];
1721 
1722           /* Search for the corresponding temp sensor */
1723           for (j = 0; j < idx; j++) {
1724                     if (j >= DBCOOL_MAXSENSORS || chip->table[j].type != DBC_TEMP)
1725                               continue;
1726                     if (chip->table[j].name_index == chip->table[idx].name_index)
1727                               break;
1728           }
1729           if (j >= idx)       /* Temp sensor not found */
1730                     return ENOENT;
1731 
1732           /* create sysctl node for the sensor if not one already there */
1733           if (sc->sc_sysctl_num[j] == -1) {
1734                     int name_index = sc->sc_dc.dc_chip->table[idx].name_index;
1735 
1736                     ret = sysctl_createv(&sc->sc_sysctl_log, 0, NULL, &me2,
1737                                              CTLFLAG_READWRITE,
1738                                              CTLTYPE_NODE, dbc_sensor_names[name_index],
1739                                              sc->sc_sensor[j].desc,
1740                                              NULL, 0, NULL, 0,
1741                                              CTL_HW, sc->sc_root_sysctl_num, CTL_CREATE,
1742                                                   CTL_EOL);
1743                     if (me2 != NULL)
1744                               sc->sc_sysctl_num[j] = me2->sysctl_num;
1745                     else
1746                               return ret;
1747           }
1748           /* add sysctl leaf node for this control variable */
1749           sysctl_index = chip->table[idx].sysctl_index;
1750           sysctl_reg = chip->table[idx].reg.val_reg;
1751           strlcpy(name, dbc_sysctl_table[sysctl_index].name, sizeof(name));
1752           if (dbc_sysctl_table[sysctl_index].lockable && dbcool_islocked(sc))
1753                     rw_flag = CTLFLAG_READONLY | CTLFLAG_OWNDESC;
1754           else
1755                     rw_flag = CTLFLAG_READWRITE | CTLFLAG_OWNDESC;
1756           ret = sysctl_createv(&sc->sc_sysctl_log, 0, NULL, &node, rw_flag,
1757                                    CTLTYPE_INT, name,
1758                                    SYSCTL_DESCR(dbc_sysctl_table[sysctl_index].desc),
1759                                    dbc_sysctl_table[sysctl_index].helper,
1760                                    0, (void *)sc, sizeof(int),
1761                                    CTL_HW, sc->sc_root_sysctl_num,
1762                                         sc->sc_sysctl_num[j],
1763                                         DBC_PWM_SYSCTL(idx, sysctl_reg), CTL_EOL);
1764 
1765           return ret;
1766 }
1767 
1768 static void
dbcool_setup_controllers(struct dbcool_softc * sc)1769 dbcool_setup_controllers(struct dbcool_softc *sc)
1770 {
1771           int i, j, rw_flag;
1772           uint8_t sysctl_reg;
1773           struct chip_id *chip = sc->sc_dc.dc_chip;
1774           const struct sysctlnode *me2 = NULL;
1775           const struct sysctlnode *node = NULL;
1776           char name[SYSCTL_NAMELEN];
1777 
1778           for (i = 0; chip->power[i].desc != NULL; i++) {
1779                     snprintf(name, sizeof(name), "fan_ctl_%d", i);
1780                     sysctl_createv(&sc->sc_sysctl_log, 0, NULL, &me2,
1781                            CTLFLAG_READWRITE | CTLFLAG_OWNDESC,
1782                            CTLTYPE_NODE, name, NULL,
1783                            NULL, 0, NULL, 0,
1784                            CTL_HW, sc->sc_root_sysctl_num, CTL_CREATE, CTL_EOL);
1785 
1786                     for (j = DBC_PWM_BEHAVIOR; j < DBC_PWM_LAST_PARAM; j++) {
1787                               if (j == DBC_PWM_MAX_DUTY &&
1788                                   (chip->flags & DBCFLAG_HAS_MAXDUTY) == 0)
1789                                         continue;
1790                               sysctl_reg = chip->power[i].power_regs[j];
1791                               if (sysctl_reg == DBCOOL_NO_REG)
1792                                         continue;
1793                               strlcpy(name, dbc_sysctl_table[j].name, sizeof(name));
1794                               if (dbc_sysctl_table[j].lockable && dbcool_islocked(sc))
1795                                         rw_flag = CTLFLAG_READONLY | CTLFLAG_OWNDESC;
1796                               else
1797                                         rw_flag = CTLFLAG_READWRITE | CTLFLAG_OWNDESC;
1798                               (sysctl_createv)(&sc->sc_sysctl_log, 0, NULL,
1799                                         &node, rw_flag,
1800                                         (j == DBC_PWM_BEHAVIOR)?
1801                                                   CTLTYPE_STRING:CTLTYPE_INT,
1802                                         name,
1803                                         SYSCTL_DESCR(dbc_sysctl_table[j].desc),
1804                                         dbc_sysctl_table[j].helper,
1805                                         0, sc,
1806                                         ( j == DBC_PWM_BEHAVIOR)?
1807                                                   sizeof(dbcool_cur_behav): sizeof(int),
1808                                         CTL_HW, sc->sc_root_sysctl_num, me2->sysctl_num,
1809                                         DBC_PWM_SYSCTL(j, sysctl_reg), CTL_EOL);
1810                     }
1811           }
1812 }
1813 
1814 static void
dbcool_refresh(struct sysmon_envsys * sme,envsys_data_t * edata)1815 dbcool_refresh(struct sysmon_envsys *sme, envsys_data_t *edata)
1816 {
1817           struct dbcool_softc *sc=sme->sme_cookie;
1818           int i, nom_volt_idx, cur;
1819           struct reg_list *reg;
1820 
1821           i = edata->sensor;
1822           reg = sc->sc_regs[i];
1823 
1824           edata->state = ENVSYS_SVALID;
1825           switch (edata->units)
1826           {
1827                     case ENVSYS_STEMP:
1828                               cur = dbcool_read_temp(sc, reg->val_reg, true);
1829                               break;
1830                     case ENVSYS_SVOLTS_DC:
1831                               nom_volt_idx = sc->sc_nom_volt[i];
1832                               cur = dbcool_read_volt(sc, reg->val_reg, nom_volt_idx,
1833                                                             true);
1834                               break;
1835                     case ENVSYS_SFANRPM:
1836                               cur = dbcool_read_rpm(sc, reg->val_reg);
1837                               break;
1838                     case ENVSYS_INTEGER:
1839                               return;
1840                     default:
1841                               edata->state = ENVSYS_SINVALID;
1842                               return;
1843           }
1844 
1845           if (cur == 0 && (edata->units != ENVSYS_SFANRPM))
1846                     edata->state = ENVSYS_SINVALID;
1847 
1848           /*
1849            * If fan is "stalled" but has no low limit, treat
1850            * it as though the fan is not installed.
1851            */
1852           else if (edata->units == ENVSYS_SFANRPM && cur == 0 &&
1853                               !(edata->upropset & (PROP_CRITMIN | PROP_WARNMIN)))
1854                     edata->state = ENVSYS_SINVALID;
1855 
1856           edata->value_cur = cur;
1857 }
1858 
1859 int
dbcool_chip_ident(struct dbcool_chipset * dc)1860 dbcool_chip_ident(struct dbcool_chipset *dc)
1861 {
1862           /* verify this is a supported dbCool chip */
1863           uint8_t c_id, d_id, r_id;
1864           int i;
1865 
1866           c_id = dc->dc_readreg(dc, DBCOOL_COMPANYID_REG);
1867           d_id = dc->dc_readreg(dc, DBCOOL_DEVICEID_REG);
1868           r_id = dc->dc_readreg(dc, DBCOOL_REVISION_REG);
1869 
1870           /* The EMC6D103S only supports read_byte and since dc->dc_chip is
1871            * NULL when we call dc->dc_readreg above we use
1872            * send_byte/receive_byte which doesn't work.
1873            *
1874            * So if we only get 0's back then try again with dc->dc_chip
1875            * set to the EMC6D103S_DEVICEID and which doesn't have
1876            * DBCFLAG_NO_READBYTE set so read_byte will be used
1877            */
1878           if ((c_id == 0) && (d_id == 0) && (r_id == 0)) {
1879                     for (i = 0; chip_table[i].company != 0; i++)
1880                               if ((SMSC_COMPANYID == chip_table[i].company) &&
1881                                   (EMC6D103S_DEVICEID == chip_table[i].device)) {
1882                                         dc->dc_chip = &chip_table[i];
1883                                         break;
1884                               }
1885                     c_id = dc->dc_readreg(dc, DBCOOL_COMPANYID_REG);
1886                     d_id = dc->dc_readreg(dc, DBCOOL_DEVICEID_REG);
1887                     r_id = dc->dc_readreg(dc, DBCOOL_REVISION_REG);
1888           }
1889 
1890           for (i = 0; chip_table[i].company != 0; i++)
1891                     if ((c_id == chip_table[i].company) &&
1892                         (d_id == chip_table[i].device ||
1893                         chip_table[i].device == 0xff) &&
1894                         (r_id == chip_table[i].rev ||
1895                         chip_table[i].rev == 0xff)) {
1896                               dc->dc_chip = &chip_table[i];
1897                               return i;
1898                     }
1899 
1900           aprint_debug("dbcool_chip_ident: addr 0x%02x c_id 0x%02x d_id 0x%02x"
1901                               " r_id 0x%02x: No match.\n", dc->dc_addr, c_id, d_id,
1902                               r_id);
1903 
1904           return -1;
1905 }
1906 
1907 /*
1908  * Retrieve sensor limits from the chip registers
1909  */
1910 static void
dbcool_get_limits(struct sysmon_envsys * sme,envsys_data_t * edata,sysmon_envsys_lim_t * limits,uint32_t * props)1911 dbcool_get_limits(struct sysmon_envsys *sme, envsys_data_t *edata,
1912                       sysmon_envsys_lim_t *limits, uint32_t *props)
1913 {
1914           int index = edata->sensor;
1915           struct dbcool_softc *sc = sme->sme_cookie;
1916 
1917           *props &= ~(PROP_CRITMIN | PROP_CRITMAX);
1918           switch (edata->units) {
1919               case ENVSYS_STEMP:
1920                     dbcool_get_temp_limits(sc, index, limits, props);
1921                     break;
1922               case ENVSYS_SVOLTS_DC:
1923                     dbcool_get_volt_limits(sc, index, limits, props);
1924                     break;
1925               case ENVSYS_SFANRPM:
1926                     dbcool_get_fan_limits(sc, index, limits, props);
1927 
1928               /* FALLTHROUGH */
1929               default:
1930                     break;
1931           }
1932           *props &= ~PROP_DRIVER_LIMITS;
1933 
1934           /* If both limits provided, make sure they're sane */
1935           if ((*props & PROP_CRITMIN) &&
1936               (*props & PROP_CRITMAX) &&
1937               (limits->sel_critmin >= limits->sel_critmax))
1938                     *props &= ~(PROP_CRITMIN | PROP_CRITMAX);
1939 
1940           /*
1941            * If this is the first time through, save these values
1942            * in case user overrides them and then requests a reset.
1943            */
1944           if (sc->sc_defprops[index] == 0) {
1945                     sc->sc_defprops[index] = *props | PROP_DRIVER_LIMITS;
1946                     sc->sc_deflims[index]  = *limits;
1947           }
1948 }
1949 
1950 static void
dbcool_get_temp_limits(struct dbcool_softc * sc,int idx,sysmon_envsys_lim_t * lims,uint32_t * props)1951 dbcool_get_temp_limits(struct dbcool_softc *sc, int idx,
1952                            sysmon_envsys_lim_t *lims, uint32_t *props)
1953 {
1954           struct reg_list *reg = sc->sc_regs[idx];
1955           uint8_t   lo_lim, hi_lim;
1956 
1957           lo_lim = sc->sc_dc.dc_readreg(&sc->sc_dc, reg->lo_lim_reg);
1958           hi_lim = sc->sc_dc.dc_readreg(&sc->sc_dc, reg->hi_lim_reg);
1959 
1960           if (sc->sc_temp_offset) {
1961                     if (lo_lim > 0x01) {
1962                               lims->sel_critmin = lo_lim - sc->sc_temp_offset;
1963                               *props |= PROP_CRITMIN;
1964                     }
1965                     if (hi_lim != 0xff) {
1966                               lims->sel_critmax = hi_lim - sc->sc_temp_offset;
1967                               *props |= PROP_CRITMAX;
1968                     }
1969           } else {
1970                     if (lo_lim != 0x80 && lo_lim != 0x81) {
1971                               lims->sel_critmin = (int8_t)lo_lim;
1972                               *props |= PROP_CRITMIN;
1973                     }
1974 
1975                     if (hi_lim != 0x7f) {
1976                               lims->sel_critmax = (int8_t)hi_lim;
1977                               *props |= PROP_CRITMAX;
1978                     }
1979           }
1980 
1981           /* Convert temp limits to microKelvin */
1982           lims->sel_critmin *= 1000000;
1983           lims->sel_critmin += 273150000;
1984           lims->sel_critmax *= 1000000;
1985           lims->sel_critmax += 273150000;
1986 }
1987 
1988 static void
dbcool_get_volt_limits(struct dbcool_softc * sc,int idx,sysmon_envsys_lim_t * lims,uint32_t * props)1989 dbcool_get_volt_limits(struct dbcool_softc *sc, int idx,
1990                            sysmon_envsys_lim_t *lims, uint32_t *props)
1991 {
1992           struct reg_list *reg = sc->sc_regs[idx];
1993           int64_t limit;
1994           int nom;
1995 
1996           nom = nominal_voltages[sc->sc_dc.dc_chip->table[idx].nom_volt_index];
1997           if (nom < 0)
1998                     nom = dbcool_supply_voltage(sc);
1999           nom *= 1000000;               /* scale for microvolts */
2000 
2001           limit = sc->sc_dc.dc_readreg(&sc->sc_dc, reg->lo_lim_reg);
2002           if (limit != 0x00 && limit != 0xff) {
2003                     limit *= nom;
2004                     limit /= 0xc0;
2005                     lims->sel_critmin = limit;
2006                     *props |= PROP_CRITMIN;
2007           }
2008           limit = sc->sc_dc.dc_readreg(&sc->sc_dc, reg->hi_lim_reg);
2009           if (limit != 0x00 && limit != 0xff) {
2010                     limit *= nom;
2011                     limit /= 0xc0;
2012                     lims->sel_critmax = limit;
2013                     *props |= PROP_CRITMAX;
2014           }
2015 }
2016 
2017 static void
dbcool_get_fan_limits(struct dbcool_softc * sc,int idx,sysmon_envsys_lim_t * lims,uint32_t * props)2018 dbcool_get_fan_limits(struct dbcool_softc *sc, int idx,
2019                           sysmon_envsys_lim_t *lims, uint32_t *props)
2020 {
2021           struct reg_list *reg = sc->sc_regs[idx];
2022           int32_t   limit;
2023 
2024           limit = dbcool_read_rpm(sc, reg->lo_lim_reg);
2025           if (limit) {
2026                     lims->sel_critmin = limit;
2027                     *props |= PROP_CRITMIN;
2028           }
2029 }
2030 
2031 /*
2032  * Update sensor limits in the chip registers
2033  */
2034 static void
dbcool_set_limits(struct sysmon_envsys * sme,envsys_data_t * edata,sysmon_envsys_lim_t * limits,uint32_t * props)2035 dbcool_set_limits(struct sysmon_envsys *sme, envsys_data_t *edata,
2036                       sysmon_envsys_lim_t *limits, uint32_t *props)
2037 {
2038           int index = edata->sensor;
2039           struct dbcool_softc *sc = sme->sme_cookie;
2040 
2041           if (limits == NULL) {
2042                     limits = &sc->sc_deflims[index];
2043                     props  = &sc->sc_defprops[index];
2044           }
2045           switch (edata->units) {
2046               case ENVSYS_STEMP:
2047                     dbcool_set_temp_limits(sc, index, limits, props);
2048                     break;
2049               case ENVSYS_SVOLTS_DC:
2050                     dbcool_set_volt_limits(sc, index, limits, props);
2051                     break;
2052               case ENVSYS_SFANRPM:
2053                     dbcool_set_fan_limits(sc, index, limits, props);
2054 
2055               /* FALLTHROUGH */
2056               default:
2057                     break;
2058           }
2059           *props &= ~PROP_DRIVER_LIMITS;
2060 }
2061 
2062 static void
dbcool_set_temp_limits(struct dbcool_softc * sc,int idx,sysmon_envsys_lim_t * lims,uint32_t * props)2063 dbcool_set_temp_limits(struct dbcool_softc *sc, int idx,
2064                            sysmon_envsys_lim_t *lims, uint32_t *props)
2065 {
2066           struct reg_list *reg = sc->sc_regs[idx];
2067           int32_t   limit;
2068 
2069           if (*props & PROP_CRITMIN) {
2070                     limit = lims->sel_critmin - 273150000;
2071                     limit /= 1000000;
2072                     if (sc->sc_temp_offset) {
2073                               limit += sc->sc_temp_offset;
2074                               if (limit < 0)
2075                                         limit = 0;
2076                               else if (limit > 255)
2077                                         limit = 255;
2078                     } else {
2079                               if (limit < -127)
2080                                         limit = -127;
2081                               else if (limit > 127)
2082                                         limit = 127;
2083                     }
2084                     sc->sc_dc.dc_writereg(&sc->sc_dc, reg->lo_lim_reg,
2085                                               (uint8_t)limit);
2086           } else if (*props & PROP_DRIVER_LIMITS) {
2087                     if (sc->sc_temp_offset)
2088                               limit = 0x00;
2089                     else
2090                               limit = 0x80;
2091                     sc->sc_dc.dc_writereg(&sc->sc_dc, reg->lo_lim_reg,
2092                                               (uint8_t)limit);
2093           }
2094 
2095           if (*props & PROP_CRITMAX) {
2096                     limit = lims->sel_critmax - 273150000;
2097                     limit /= 1000000;
2098                     if (sc->sc_temp_offset) {
2099                               limit += sc->sc_temp_offset;
2100                               if (limit < 0)
2101                                         limit = 0;
2102                               else if (limit > 255)
2103                                         limit = 255;
2104                     } else {
2105                               if (limit < -127)
2106                                         limit = -127;
2107                               else if (limit > 127)
2108                                         limit = 127;
2109                     }
2110                     sc->sc_dc.dc_writereg(&sc->sc_dc, reg->hi_lim_reg,
2111                                               (uint8_t)limit);
2112           } else if (*props & PROP_DRIVER_LIMITS) {
2113                     if (sc->sc_temp_offset)
2114                               limit = 0xff;
2115                     else
2116                               limit = 0x7f;
2117                     sc->sc_dc.dc_writereg(&sc->sc_dc, reg->hi_lim_reg,
2118                                               (uint8_t)limit);
2119           }
2120 }
2121 
2122 static void
dbcool_set_volt_limits(struct dbcool_softc * sc,int idx,sysmon_envsys_lim_t * lims,uint32_t * props)2123 dbcool_set_volt_limits(struct dbcool_softc *sc, int idx,
2124                            sysmon_envsys_lim_t *lims, uint32_t *props)
2125 {
2126           struct reg_list *reg = sc->sc_regs[idx];
2127           int64_t limit;
2128           int nom;
2129 
2130           nom = nominal_voltages[sc->sc_dc.dc_chip->table[idx].nom_volt_index];
2131           if (nom < 0)
2132                     nom = dbcool_supply_voltage(sc);
2133           nom *= 1000000;               /* scale for microvolts */
2134 
2135           if (*props & PROP_CRITMIN) {
2136                     limit = lims->sel_critmin;
2137                     limit *= 0xc0;
2138                     limit /= nom;
2139                     if (limit > 0xff)
2140                               limit = 0xff;
2141                     else if (limit < 0)
2142                               limit = 0;
2143                     sc->sc_dc.dc_writereg(&sc->sc_dc, reg->lo_lim_reg, limit);
2144           } else if (*props & PROP_DRIVER_LIMITS)
2145                     sc->sc_dc.dc_writereg(&sc->sc_dc, reg->lo_lim_reg, 0);
2146 
2147           if (*props & PROP_CRITMAX) {
2148                     limit = lims->sel_critmax;
2149                     limit *= 0xc0;
2150                     limit /= nom;
2151                     if (limit > 0xff)
2152                               limit = 0xff;
2153                     else if (limit < 0)
2154                               limit = 0;
2155                     sc->sc_dc.dc_writereg(&sc->sc_dc, reg->hi_lim_reg, limit);
2156           } else if (*props & PROP_DRIVER_LIMITS)
2157                     sc->sc_dc.dc_writereg(&sc->sc_dc, reg->hi_lim_reg, 0xff);
2158 }
2159 
2160 static void
dbcool_set_fan_limits(struct dbcool_softc * sc,int idx,sysmon_envsys_lim_t * lims,uint32_t * props)2161 dbcool_set_fan_limits(struct dbcool_softc *sc, int idx,
2162                           sysmon_envsys_lim_t *lims, uint32_t *props)
2163 {
2164           struct reg_list *reg = sc->sc_regs[idx];
2165           int32_t   limit, dividend;
2166 
2167           if (*props & PROP_CRITMIN) {
2168                     limit = lims->sel_critmin;
2169                     if (limit == 0)
2170                               limit = 0xffff;
2171                     else {
2172                               if (sc->sc_dc.dc_chip->flags & DBCFLAG_ADM1030)
2173                                         dividend = 11250 * 60;
2174                               else
2175                                         dividend = 90000 * 60;
2176                               limit = limit / dividend;
2177                               if (limit > 0xffff)
2178                                         limit = 0xffff;
2179                     }
2180                     sc->sc_dc.dc_writereg(&sc->sc_dc, reg->lo_lim_reg,
2181                                               limit & 0xff);
2182                     limit >>= 8;
2183                     sc->sc_dc.dc_writereg(&sc->sc_dc, reg->lo_lim_reg + 1,
2184                                               limit & 0xff);
2185           } else if (*props & PROP_DRIVER_LIMITS) {
2186                     sc->sc_dc.dc_writereg(&sc->sc_dc, reg->lo_lim_reg, 0xff);
2187                     sc->sc_dc.dc_writereg(&sc->sc_dc, reg->lo_lim_reg + 1, 0xff);
2188           }
2189 }
2190 
2191 MODULE(MODULE_CLASS_DRIVER, dbcool, "iic,sysmon_envsys");
2192 
2193 #ifdef _MODULE
2194 #include "ioconf.c"
2195 #endif
2196 
2197 static int
dbcool_modcmd(modcmd_t cmd,void * opaque)2198 dbcool_modcmd(modcmd_t cmd, void *opaque)
2199 {
2200           int error = 0;
2201 #ifdef _MODULE
2202           static struct sysctllog *dbcool_sysctl_clog;
2203 #endif
2204 
2205           switch (cmd) {
2206           case MODULE_CMD_INIT:
2207 #ifdef _MODULE
2208                     error = config_init_component(cfdriver_ioconf_dbcool,
2209                         cfattach_ioconf_dbcool, cfdata_ioconf_dbcool);
2210                     sysctl_dbcoolsetup(&dbcool_sysctl_clog);
2211 #endif
2212                     return error;
2213           case MODULE_CMD_FINI:
2214 #ifdef _MODULE
2215                     error = config_fini_component(cfdriver_ioconf_dbcool,
2216                         cfattach_ioconf_dbcool, cfdata_ioconf_dbcool);
2217                     sysctl_teardown(&dbcool_sysctl_clog);
2218 #endif
2219                     return error;
2220           default:
2221                     return ENOTTY;
2222           }
2223 }
2224