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1 /*
2  * Copyright (C) 2016 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *      http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 
17 #include <atomic.h>
18 #include <gpio.h>
19 #include <nanohubPacket.h>
20 #include <plat/exti.h>
21 #include <plat/gpio.h>
22 #include <platform.h>
23 #include <plat/syscfg.h>
24 #include <sensors.h>
25 #include <seos.h>
26 #include <i2c.h>
27 #include <timer.h>
28 #include <stdlib.h>
29 #include <string.h>
30 #include <variant/variant.h>
31 #include <variant/sensType.h>
32 
33 #define HTS221_APP_ID              APP_ID_MAKE(NANOHUB_VENDOR_STMICRO, 2)
34 
35 /* Sensor defs */
36 #define HTS221_WAI_REG_ADDR    0x0F
37 #define HTS221_WAI_REG_VAL     0xBC
38 
39 #define HTS221_AV_CONF         0x10
40 
41 #define HTS221_CTRL_REG1       0x20
42 #define HTS221_POWER_ON        0x80
43 #define HTS221_POWER_OFF       0x00
44 #define HTS221_BDU_ON          0x04
45 #define HTS221_ODR_ONE_SHOT    0x00
46 #define HTS221_ODR_1_HZ        0x01
47 #define HTS221_ODR_7_HZ        0x02
48 #define HTS221_ODR_12_5_HZ     0x03
49 
50 #define HTS221_CTRL_REG2       0x21
51 #define HTS221_REBOOT          0x80
52 
53 #define HTS221_CTRL_REG3       0x22
54 #define HTS221_STATUS_REG      0x27
55 
56 #define HTS221_HUMIDITY_OUTL_REG_ADDR    0x28
57 #define HTS221_TEMP_OUTL_REG_ADDR        0x2A
58 
59 #define HTS221_CALIB_DATA      0x30
60 #define HTS221_CALIB_DATA_LEN  16
61 
62 struct hts221_calib_data {
63     uint8_t  h0_x2;
64     uint8_t  h1_x2;
65     uint8_t  unused[4];
66     uint8_t  h0_t0_l;
67     uint8_t  h0_t0_h;
68     uint8_t  unused_2[2];
69     uint8_t  h1_t0_l;
70     uint8_t  h1_t0_h;
71     uint8_t  unused_3[4];
72 };
73 
74 #define INFO_PRINT(fmt, ...) \
75     do { \
76         osLog(LOG_INFO, "%s " fmt, "[HTS221]", ##__VA_ARGS__); \
77     } while (0);
78 
79 #define DEBUG_PRINT(fmt, ...) \
80     do { \
81         if (HTS221_DBG_ENABLED) { \
82             osLog(LOG_DEBUG, "%s " fmt, "[HTS221]", ##__VA_ARGS__); \
83         } \
84     } while (0);
85 
86 #define ERROR_PRINT(fmt, ...) \
87     do { \
88         osLog(LOG_ERROR, "%s " fmt, "[HTS221]", ##__VA_ARGS__); \
89     } while (0);
90 
91 /* DO NOT MODIFY, just to avoid compiler error if not defined using FLAGS */
92 #ifndef HTS221_DBG_ENABLED
93 #define HTS221_DBG_ENABLED                           0
94 #endif /* HTS221_DBG_ENABLED */
95 
96 enum hts221SensorEvents
97 {
98     EVT_COMM_DONE = EVT_APP_START + 1,
99     EVT_INT1_RAISED,
100     EVT_SENSOR_HUMIDITY_TIMER,
101 };
102 
103 enum hts221SensorState {
104     SENSOR_BOOT,
105     SENSOR_VERIFY_ID,
106     SENSOR_INIT,
107     SENSOR_HUMIDITY_POWER_UP,
108     SENSOR_HUMIDITY_POWER_DOWN,
109     SENSOR_READ_SAMPLES,
110 };
111 
112 #ifndef HTS221_I2C_BUS_ID
113 #error "HTS221_I2C_BUS_ID is not defined; please define in variant.h"
114 #endif
115 
116 #ifndef HTS221_I2C_SPEED
117 #error "HTS221_I2C_SPEED is not defined; please define in variant.h"
118 #endif
119 
120 #ifndef HTS221_I2C_ADDR
121 #error "HTS221_I2C_ADDR is not defined; please define in variant.h"
122 #endif
123 
124 enum hts221SensorIndex {
125     HUMIDITY = 0,
126     NUM_OF_SENSOR,
127 };
128 
129 struct hts221Sensor {
130     uint32_t handle;
131 };
132 
133 #define HTS221_MAX_PENDING_I2C_REQUESTS   4
134 #define HTS221_MAX_I2C_TRANSFER_SIZE      HTS221_CALIB_DATA_LEN
135 
136 struct I2cTransfer
137 {
138     size_t tx;
139     size_t rx;
140     int err;
141     uint8_t txrxBuf[HTS221_MAX_I2C_TRANSFER_SIZE];
142     uint8_t state;
143     bool inUse;
144 };
145 
146 /* Task structure */
147 struct hts221Task {
148     uint32_t tid;
149 
150     /* timer */
151     uint32_t humidityTimerHandle;
152 
153     /* sensor flags */
154     bool humidityOn;
155     bool humidityReading;
156     bool humidityWantRead;
157 
158     /* calib data */
159     int8_t y0_H;
160     int8_t y1_H;
161     int16_t x0_H;
162     int16_t x1_H;
163 
164     struct I2cTransfer transfers[HTS221_MAX_PENDING_I2C_REQUESTS];
165 
166     /* Communication functions */
167     bool (*comm_tx)(uint8_t addr, uint8_t data, uint32_t delay, uint8_t state);
168     bool (*comm_rx)(uint8_t addr, uint16_t len, uint32_t delay, uint8_t state);
169 
170     /* sensors */
171     struct hts221Sensor sensors[NUM_OF_SENSOR];
172 };
173 
174 static struct hts221Task mTask;
175 
hts221_humidity_percent(int16_t hum)176 static inline float hts221_humidity_percent(int16_t hum)
177 {
178     float percentage = (float) ((mTask.y1_H - mTask.y0_H) * hum + \
179                                ((mTask.x1_H * mTask.y0_H) - (mTask.x0_H * mTask.y1_H))) / \
180                                   (mTask.x1_H - mTask.x0_H);
181 
182     return((percentage > 100) ? 100 : percentage);
183 }
184 
185 /*
186  * Allocate a buffer and mark it as in use with the given state, or return NULL
187  * if no buffers available. Must *not* be called from interrupt context.
188  */
allocXfer(uint8_t state)189 static struct I2cTransfer *allocXfer(uint8_t state)
190 {
191     size_t i;
192 
193     for (i = 0; i < ARRAY_SIZE(mTask.transfers); i++) {
194         if (!mTask.transfers[i].inUse) {
195             mTask.transfers[i].inUse = true;
196             mTask.transfers[i].state = state;
197             return &mTask.transfers[i];
198         }
199     }
200 
201     ERROR_PRINT("Ran out of i2c buffers!");
202     return NULL;
203 }
204 
releaseXfer(struct I2cTransfer * xfer)205 static inline void releaseXfer(struct I2cTransfer *xfer)
206 {
207     xfer->inUse = false;
208 }
209 
210 
i2cCallback(void * cookie,size_t tx,size_t rx,int err)211 static void i2cCallback(void *cookie, size_t tx, size_t rx, int err)
212 {
213     struct I2cTransfer *xfer = cookie;
214 
215     xfer->tx = tx;
216     xfer->rx = rx;
217     xfer->err = err;
218 
219     osEnqueuePrivateEvt(EVT_COMM_DONE, cookie, NULL, mTask.tid);
220     if (err != 0)
221         ERROR_PRINT("i2c error (tx: %d, rx: %d, err: %d)\n", tx, rx, err);
222 }
223 
i2c_read(uint8_t addr,uint16_t len,uint32_t delay,uint8_t state)224 static bool i2c_read(uint8_t addr, uint16_t len, uint32_t delay, uint8_t state)
225 {
226     struct I2cTransfer *xfer = allocXfer(state);
227     int ret = -1;
228 
229     if (xfer != NULL) {
230         if (len > HTS221_MAX_I2C_TRANSFER_SIZE) {
231             DEBUG_PRINT("i2c_read: len too big (len: %d)\n", len);
232             releaseXfer(xfer);
233             return false;
234         }
235 
236         xfer->txrxBuf[0] = 0x80 | addr;
237         if ((ret = i2cMasterTxRx(HTS221_I2C_BUS_ID, HTS221_I2C_ADDR,
238                     xfer->txrxBuf, 1, xfer->txrxBuf, len, i2cCallback, xfer)) < 0) {
239             DEBUG_PRINT("i2c_read: i2cMasterTxRx operation failed (ret: %d)\n", ret);
240             releaseXfer(xfer);
241             return false;
242         }
243     }
244 
245     return (ret == -1) ? false : true;
246 }
247 
i2c_write(uint8_t addr,uint8_t data,uint32_t delay,uint8_t state)248 static bool i2c_write(uint8_t addr, uint8_t data, uint32_t delay, uint8_t state)
249 {
250     struct I2cTransfer *xfer = allocXfer(state);
251     int ret = -1;
252 
253     if (xfer != NULL) {
254         xfer->txrxBuf[0] = addr;
255         xfer->txrxBuf[1] = data;
256         if ((ret = i2cMasterTx(HTS221_I2C_BUS_ID, HTS221_I2C_ADDR, xfer->txrxBuf, 2, i2cCallback, xfer)) < 0) {
257             releaseXfer(xfer);
258             DEBUG_PRINT("i2c_write: i2cMasterTx operation failed (ret: %d)\n", ret);
259             return false;
260         }
261     }
262 
263     return (ret == -1) ? false : true;
264 }
265 
266 /* Sensor Info */
sensorHumidityTimerCallback(uint32_t timerId,void * data)267 static void sensorHumidityTimerCallback(uint32_t timerId, void *data)
268 {
269     osEnqueuePrivateEvt(EVT_SENSOR_HUMIDITY_TIMER, data, NULL, mTask.tid);
270 }
271 
272 #define DEC_INFO(name, type, axis, inter, samples, rates) \
273     .sensorName = name, \
274     .sensorType = type, \
275     .numAxis = axis, \
276     .interrupt = inter, \
277     .minSamples = samples, \
278     .supportedRates = rates
279 
280 static uint32_t hts221Rates[] = {
281     SENSOR_HZ(1.0f),
282     SENSOR_HZ(7.0f),
283     SENSOR_HZ(12.5f),
284     0
285 };
286 
287 /* should match "supported rates in length" and be the timer length for that rate in nanosecs */
288 static const uint64_t hts221RatesRateVals[] =
289 {
290     1 * 1000000000ULL,    /* 1 Hz */
291     1000000000ULL / 7,    /* 7 Hz */
292     2000000000ULL / 25,   /* 12.5 Hz */
293 };
294 
295 
296 static const struct SensorInfo hts221SensorInfo[NUM_OF_SENSOR] =
297 {
298     { DEC_INFO("Humidity", SENS_TYPE_HUMIDITY, NUM_AXIS_EMBEDDED, NANOHUB_INT_NONWAKEUP,
299         300, hts221Rates) },
300 };
301 
302 /* Sensor Operations */
humidityPower(bool on,void * cookie)303 static bool humidityPower(bool on, void *cookie)
304 {
305     bool oldMode = mTask.humidityOn;
306     bool newMode = on;
307     uint32_t state = on ? SENSOR_HUMIDITY_POWER_UP : SENSOR_HUMIDITY_POWER_DOWN;
308     bool ret = true;
309 
310     INFO_PRINT("humidityPower %s\n", on ? "enable" : "disable");
311 
312     if (!on && mTask.humidityTimerHandle) {
313         timTimerCancel(mTask.humidityTimerHandle);
314         mTask.humidityTimerHandle = 0;
315         mTask.humidityReading = false;
316     }
317 
318     if (oldMode != newMode) {
319         if (on)
320             ret = mTask.comm_tx(HTS221_CTRL_REG1, HTS221_POWER_ON | HTS221_ODR_12_5_HZ, 0, state);
321         else
322             ret = mTask.comm_tx(HTS221_CTRL_REG1, HTS221_POWER_OFF, 0, state);
323     } else
324         sensorSignalInternalEvt(mTask.sensors[HUMIDITY].handle,
325                     SENSOR_INTERNAL_EVT_POWER_STATE_CHG, on, 0);
326 
327     if (!ret) {
328         DEBUG_PRINT("humidityPower comm_tx failed\n");
329         return(false);
330     }
331 
332     mTask.humidityReading = false;
333     mTask.humidityOn = on;
334     return true;
335 }
336 
humidityFwUpload(void * cookie)337 static bool humidityFwUpload(void *cookie)
338 {
339     return sensorSignalInternalEvt(mTask.sensors[HUMIDITY].handle, SENSOR_INTERNAL_EVT_FW_STATE_CHG, 1, 0);
340 }
341 
humiditySetRate(uint32_t rate,uint64_t latency,void * cookie)342 static bool humiditySetRate(uint32_t rate, uint64_t latency, void *cookie)
343 {
344     INFO_PRINT("humiditySetRate %lu Hz - %llu ns\n", rate, latency);
345 
346     if (mTask.humidityTimerHandle)
347         timTimerCancel(mTask.humidityTimerHandle);
348 
349     mTask.humidityTimerHandle = timTimerSet(sensorTimerLookupCommon(hts221Rates,
350                 hts221RatesRateVals, rate), 0, 50, sensorHumidityTimerCallback, NULL, false);
351 
352     return sensorSignalInternalEvt(mTask.sensors[HUMIDITY].handle,
353                 SENSOR_INTERNAL_EVT_RATE_CHG, rate, latency);
354 }
355 
humidityFlush(void * cookie)356 static bool humidityFlush(void *cookie)
357 {
358     return osEnqueueEvt(sensorGetMyEventType(SENS_TYPE_HUMIDITY), SENSOR_DATA_EVENT_FLUSH, NULL);
359 }
360 
361 #define DEC_OPS(power, firmware, rate, flush, cal, cfg) \
362     .sensorPower = power, \
363     .sensorFirmwareUpload = firmware, \
364     .sensorSetRate = rate, \
365     .sensorFlush = flush, \
366     .sensorCalibrate = cal, \
367     .sensorCfgData = cfg
368 
369 static const struct SensorOps hts221SensorOps[NUM_OF_SENSOR] =
370 {
371     { DEC_OPS(humidityPower, humidityFwUpload, humiditySetRate, humidityFlush, NULL, NULL) },
372 };
373 
hts221_save_calib_data(uint8_t * buf)374 static void hts221_save_calib_data(uint8_t *buf)
375 {
376     struct hts221_calib_data *calib = (struct hts221_calib_data *) buf;
377 
378     mTask.y0_H = (int8_t) (calib->h0_x2 / 2);
379     mTask.y1_H = (int8_t) (calib->h1_x2 / 2);
380     mTask.x0_H = (int16_t) (calib->h0_t0_h << 8) |
381                            calib->h0_t0_l;
382     mTask.x1_H = (int16_t) (calib->h1_t0_h << 8) |
383                            calib->h1_t0_l;
384     DEBUG_PRINT("y0_H: %d - y1_H: %d\n", mTask.y0_H, mTask.y1_H);
385     DEBUG_PRINT("x0_H: %d - x1_H: %d\n", mTask.x0_H, mTask.x1_H);
386 }
387 
388 static uint8_t *humidity_samples;
handleCommDoneEvt(const void * evtData)389 static int handleCommDoneEvt(const void* evtData)
390 {
391     uint8_t i;
392     int16_t humidity_val;
393     union EmbeddedDataPoint sample;
394     struct I2cTransfer *xfer = (struct I2cTransfer *)evtData;
395 
396     switch (xfer->state) {
397     case SENSOR_BOOT:
398         hts221_save_calib_data(xfer->txrxBuf);
399         if (!mTask.comm_rx(HTS221_WAI_REG_ADDR, 1, 1, SENSOR_VERIFY_ID)) {
400             DEBUG_PRINT("Not able to read WAI\n");
401             return -1;
402         }
403         break;
404 
405     case SENSOR_VERIFY_ID:
406         /* Check the sensor ID */
407         if (xfer->err != 0 || xfer->txrxBuf[0] != HTS221_WAI_REG_VAL) {
408             DEBUG_PRINT("WAI returned is: %02x\n", xfer->txrxBuf[0]);
409             break;
410         }
411 
412         INFO_PRINT( "Device ID is correct! (%02x)\n", xfer->txrxBuf[0]);
413         for (i = 0; i < NUM_OF_SENSOR; i++)
414             sensorRegisterInitComplete(mTask.sensors[i].handle);
415 
416         break;
417 
418     case SENSOR_INIT:
419         for (i = 0; i < NUM_OF_SENSOR; i++)
420             sensorRegisterInitComplete(mTask.sensors[i].handle);
421         break;
422 
423     case SENSOR_HUMIDITY_POWER_UP:
424         sensorSignalInternalEvt(mTask.sensors[HUMIDITY].handle,
425                     SENSOR_INTERNAL_EVT_POWER_STATE_CHG, true, 0);
426         break;
427 
428     case SENSOR_HUMIDITY_POWER_DOWN:
429         sensorSignalInternalEvt(mTask.sensors[HUMIDITY].handle,
430                     SENSOR_INTERNAL_EVT_POWER_STATE_CHG, false, 0);
431         break;
432 
433     case SENSOR_READ_SAMPLES:
434         if (mTask.humidityOn && mTask.humidityWantRead) {
435             mTask.humidityWantRead = false;
436             humidity_samples = xfer->txrxBuf;
437 
438             humidity_val = (int16_t)(((humidity_samples[1] << 8) & 0xff00) | humidity_samples[0]);
439             DEBUG_PRINT("humidity raw data %d\n", humidity_val);
440 
441             mTask.humidityReading = false;
442             sample.fdata = hts221_humidity_percent(humidity_val);
443             osEnqueueEvt(sensorGetMyEventType(SENS_TYPE_HUMIDITY), sample.vptr, NULL);
444         }
445 
446         break;
447 
448     default:
449         break;
450     }
451 
452     releaseXfer(xfer);
453     return (0);
454 }
455 
handleEvent(uint32_t evtType,const void * evtData)456 static void handleEvent(uint32_t evtType, const void* evtData)
457 {
458     switch (evtType) {
459     case EVT_APP_START:
460         INFO_PRINT( "EVT_APP_START\n");
461         osEventUnsubscribe(mTask.tid, EVT_APP_START);
462 
463         mTask.comm_rx(HTS221_CALIB_DATA, sizeof(struct hts221_calib_data), 0, SENSOR_BOOT);
464         break;
465 
466     case EVT_COMM_DONE:
467         handleCommDoneEvt(evtData);
468         break;
469 
470     case EVT_SENSOR_HUMIDITY_TIMER:
471         mTask.humidityWantRead = true;
472 
473         /* Start sampling for a value */
474         if (!mTask.humidityReading) {
475             mTask.humidityReading = true;
476 
477             mTask.comm_rx(HTS221_HUMIDITY_OUTL_REG_ADDR, 2, 1, SENSOR_READ_SAMPLES);
478         }
479         break;
480 
481     default:
482         break;
483     }
484 
485 }
486 
startTask(uint32_t task_id)487 static bool startTask(uint32_t task_id)
488 {
489     uint8_t i;
490 
491     mTask.tid = task_id;
492 
493     INFO_PRINT( "started\n");
494 
495     mTask.humidityOn = false;
496     mTask.humidityReading = false;
497 
498     /* Init the communication part */
499     i2cMasterRequest(HTS221_I2C_BUS_ID, HTS221_I2C_SPEED);
500 
501     mTask.comm_tx = i2c_write;
502     mTask.comm_rx = i2c_read;
503 
504     for (i = 0; i < NUM_OF_SENSOR; i++) {
505         mTask.sensors[i].handle =
506             sensorRegister(&hts221SensorInfo[i], &hts221SensorOps[i], NULL, false);
507     }
508 
509     osEventSubscribe(mTask.tid, EVT_APP_START);
510 
511     return true;
512 }
513 
endTask(void)514 static void endTask(void)
515 {
516     INFO_PRINT( "ended\n");
517 }
518 
519 INTERNAL_APP_INIT(HTS221_APP_ID, 0, startTask, endTask, handleEvent);
520