sh2.c

/*
 * Copyright 2015-17 Hillcrest Laboratories, Inc.
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License and 
 * any applicable agreements you may have with Hillcrest Laboratories, Inc.
 * You may obtain a copy of the License at
 *
 *   http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

/*
 * SH-2 API Implementation for Hillcrest BNO080
 */

#include <string.h>
#include <stdio.h>

#include "sh2.h"
#include "shtp.h"
#include "sh2_hal.h"
#include "sh2_err.h"

#include "sh2_util.h"

// Max length of an FRS record, words.
#define MAX_FRS_WORDS (72)

// Max length of sensorhub version string.
#define MAX_VER_LEN (16)

// Max number of report ids supported
#define SH2_MAX_REPORT_IDS (64)

// Tags for sensorhub app advertisements.
#define TAG_SH2_VERSION (0x80)
#define TAG_SH2_REPORT_LENGTHS (0x81)

// executable/device channel responses
#define EXECUTABLE_DEVICE_CMD_RESET (1)
#define EXECUTABLE_DEVICE_CMD_ON    (2)
#define EXECUTABLE_DEVICE_CMD_SLEEP (3)

// executable/device channel responses
#define EXECUTABLE_DEVICE_RESP_RESET_COMPLETE (1)

// --- Private Data Types -------------------------------------------------

typedef int (sh2_OpStart_t)(void);
typedef void (sh2_OpTxDone_t)(void);
typedef void (sh2_OpRx_t)(const uint8_t *payload, uint16_t len);

typedef struct sh2_Op_s {
    sh2_OpStart_t *start;
    sh2_OpTxDone_t *txDone;
    sh2_OpRx_t *rx;
} sh2_Op_t;

// Report definitions
// Bit fields for Feature Report flags
#define FEAT_CHANGE_SENSITIVITY_RELATIVE (1)
#define FEAT_CHANGE_SENSITIVITY_ABSOLUTE (0)
#define FEAT_CHANGE_SENSITIVITY_ENABLED  (2)
#define FEAT_CHANGE_SENSITIVITY_DISABLED (0)
#define FEAT_WAKE_ENABLED                (4)
#define FEAT_WAKE_DISABLED               (0)
#define FEAT_ALWAYS_ON_ENABLED           (8)
#define FEAT_ALWAYS_ON_DISABLED          (0)

#if defined(_MSC_VER)
#define PACKED_STRUCT struct
#pragma pack(push, 1)
#elif defined(__GNUC__)
#define PACKED_STRUCT struct __attribute__((packed))
#else 
#define PACKED_STRUCT __packed struct
#endif

// GET_FEATURE_REQ
#define SENSORHUB_GET_FEATURE_REQ    (0xFE)
typedef PACKED_STRUCT {
    uint8_t reportId;
    uint8_t featureReportId;
} GetFeatureReq_t;

// SENSORHUB_SET_FEATURE_CMD
#define SENSORHUB_SET_FEATURE_CMD    (0xFD)
typedef PACKED_STRUCT {
    uint8_t reportId;             // 0xFD
    uint8_t featureReportId;      // sensor id
    uint8_t flags;                // FEAT_... values
    uint16_t changeSensitivity;
    uint32_t reportInterval_uS;
    uint32_t batchInterval_uS;
    uint32_t sensorSpecific;
} SetFeatureReport_t;

// SENSORHUB_GET_FEATURE_RESP
#define SENSORHUB_GET_FEATURE_RESP   (0xFC)
typedef PACKED_STRUCT {
    uint8_t reportId;
    uint8_t featureReportId;      // sensor id
    uint8_t flags;                // FEAT_... values
    uint16_t changeSensitivity;
    uint32_t reportInterval_uS;
    uint32_t batchInterval_uS;
    uint32_t sensorSpecific;
} GetFeatureResp_t;

#define SENSORHUB_BASE_TIMESTAMP_REF (0xFB)
typedef PACKED_STRUCT {
    uint8_t reportId;
    uint32_t timebase;
} BaseTimestampRef_t;

#define SENSORHUB_TIMESTAMP_REBASE   (0xFA)
typedef PACKED_STRUCT {
    uint8_t reportId;
    int32_t timebase;
} TimestampRebase_t;

// SENSORHUB_PROD_ID_REQ
#define SENSORHUB_PROD_ID_REQ        (0xF9)
typedef PACKED_STRUCT {
    uint8_t reportId;  
    uint8_t reserved;
} ProdIdReq_t;

// SENSORHUB_PROD_ID_RESP
#define SENSORHUB_PROD_ID_RESP       (0xF8)
typedef PACKED_STRUCT {
    uint8_t reportId;
    uint8_t resetCause;
    uint8_t swVerMajor;
    uint8_t swVerMinor;
    uint32_t swPartNumber;
    uint32_t swBuildNumber;
    uint16_t swVerPatch;
    uint8_t reserved0;
    uint8_t reserved1;
} ProdIdResp_t;

// SENSORHUB_FRS_WRITE_REQ
#define SENSORHUB_FRS_WRITE_REQ      (0xF7)
typedef PACKED_STRUCT {
    uint8_t reportId;
    uint8_t reserved;
    uint16_t length;
    uint16_t frsType;
} FrsWriteReq_t;

// SENSORHUB_FRS_WRITE_DATA_REQ
#define SENSORHUB_FRS_WRITE_DATA_REQ (0xF6)
typedef PACKED_STRUCT {
    uint8_t reportId;
    uint8_t reserved;
    uint16_t offset;
    uint32_t data0;
    uint32_t data1;
} FrsWriteDataReq_t;

// FRS write status values
#define FRS_WRITE_STATUS_RECEIVED (0)
#define FRS_WRITE_STATUS_UNRECOGNIZED_FRS_TYPE (1)
#define FRS_WRITE_STATUS_BUSY (2)
#define FRS_WRITE_STATUS_WRITE_COMPLETED (3)
#define FRS_WRITE_STATUS_READY (4)
#define FRS_WRITE_STATUS_FAILED (5)
#define FRS_WRITE_STATUS_NOT_READY (6) // data received when not in write mode
#define FRS_WRITE_STATUS_INVALID_LENGTH (7)
#define FRS_WRITE_STATUS_RECORD_VALID (8)
#define FRS_WRITE_STATUS_INVALID_RECORD (9)
#define FRS_WRITE_STATUS_DEVICE_ERROR (10)
#define FRS_WRITE_STATUS_READ_ONLY (11)

// SENSORHUB_FRS_WRITE_RESP
#define SENSORHUB_FRS_WRITE_RESP     (0xF5)
typedef PACKED_STRUCT {
    uint8_t reportId;
    uint8_t status;
    uint16_t wordOffset;
} FrsWriteResp_t;

// RESP_FRS_READ_REQ
#define SENSORHUB_FRS_READ_REQ       (0xF4)
typedef PACKED_STRUCT {
    uint8_t reportId;
    uint8_t reserved;
    uint16_t readOffset;
    uint16_t frsType;
    uint16_t blockSize;
} FrsReadReq_t;

// Get Datalen portion of len_status field
#define FRS_READ_DATALEN(x) ((x >> 4) & 0x0F)

// Get status portion of len_status field
#define FRS_READ_STATUS(x) ((x) & 0x0F)

// Status values
#define FRS_READ_STATUS_NO_ERROR                        0
#define FRS_READ_STATUS_UNRECOGNIZED_FRS_TYPE           1
#define FRS_READ_STATUS_BUSY                            2
#define FRS_READ_STATUS_READ_RECORD_COMPLETED           3
#define FRS_READ_STATUS_OFFSET_OUT_OF_RANGE             4
#define FRS_READ_STATUS_RECORD_EMPTY                    5
#define FRS_READ_STATUS_READ_BLOCK_COMPLETED            6
#define FRS_READ_STATUS_READ_BLOCK_AND_RECORD_COMPLETED 7
#define FRS_READ_STATUS_DEVICE_ERROR                    8

// SENSORHUB_FRS_READ_RESP
#define SENSORHUB_FRS_READ_RESP      (0xF3)
typedef PACKED_STRUCT {
    uint8_t reportId;
    uint8_t len_status;  // See FRS_READ... macros above
    uint16_t wordOffset;
    uint32_t data0;
    uint32_t data1;
    uint16_t frsType;
    uint8_t reserved0;
    uint8_t reserved1;
} FrsReadResp_t;

// Command and Subcommand values
#define SH2_CMD_ERRORS                 1
#define SH2_CMD_COUNTS                 2
#define     SH2_COUNTS_GET_COUNTS          0
#define     SH2_COUNTS_CLEAR_COUNTS        1
#define SH2_CMD_TARE                   3
#define     SH2_TARE_TARE_NOW              0
#define     SH2_TARE_PERSIST_TARE          1
#define     SH2_TARE_SET_REORIENTATION     2
#define SH2_CMD_INITIALIZE             4
#define     SH2_INIT_SYSTEM                1
#define SH2_INIT_UNSOLICITED           0x80
#define SH2_CMD_FRS                    5
#define SH2_CMD_DCD                    6
#define SH2_CMD_ME_CAL                 7
#define SH2_CMD_SYNC                   8     // Obsolete
#define     SH2_SYNC_SYNC_NOW              0 // Obsolete
#define     SH2_SYNC_ENABLE_EXT_SYNC       1 // Obsolete
#define     SH2_SYNC_DISABLE_EXT_SYNC      2 // Obsolete
#define SH2_CMD_DCD_SAVE               9
#define SH2_CMD_GET_OSC_TYPE           10
#define SH2_CMD_CLEAR_DCD_AND_RESET    11
#define SH2_CMD_CAL                    12
#define     SH2_CAL_START                   0
#define     SH2_CAL_FINISH                  1

// SENSORHUB_COMMAND_REQ
#define SENSORHUB_COMMAND_REQ        (0xF2)
typedef PACKED_STRUCT {
    uint8_t reportId;
    uint8_t seq;
    uint8_t command;
    uint8_t p[9];
} CommandReq_t;

// SENSORHUB_COMMAND_RESP
#define SENSORHUB_COMMAND_RESP       (0xF1)
typedef PACKED_STRUCT {
    uint8_t reportId;
    uint8_t seq;
    uint8_t command;
    uint8_t commandSeq;
    uint8_t respSeq;
    uint8_t r[11];
} CommandResp_t;

// SENSORHUB_FORCE_SENSOR_FLUSH
#define SENSORHUB_FORCE_SENSOR_FLUSH (0xF0)
typedef PACKED_STRUCT {
    uint8_t reportId;
    uint8_t sensorId;
} ForceFlushReq_t;

// SENSORHUB_FLUSH_COMPLETED    
#define SENSORHUB_FLUSH_COMPLETED    (0xEF)
typedef PACKED_STRUCT {
    uint8_t reportId;
    uint8_t sensorId;
} ForceFlushResp_t;


#ifdef _MSC_VER
#pragma pack(pop)
#endif

typedef struct sh2_s {
    uint8_t controlChan;

    char version[MAX_VER_LEN+1];
    struct {
        uint8_t id;
        uint8_t len;
    } report[SH2_MAX_REPORT_IDS];

    uint32_t emptyPayloads;
    uint32_t unknownReportIds;
    uint32_t execBadPayload;

	bool advertDone;
	bool gotInitResp;
	bool calledResetCallback;
  
    sh2_EventCallback_t *eventCallback;
    void * eventCallbackCookie;

    sh2_SensorCallback_t *sensorCallback;
    void * sensorCallbackCookie;

    uint8_t nextCmdSeq;

    const sh2_Op_t *pOp;

    int opStatus;

	uint32_t frsData[MAX_FRS_WORDS];
	uint16_t frsDataLen;

	// Parameters and state information for the operation in progress
	union {
		struct {
			CommandReq_t req;
		} sendCmd;
        struct {
            sh2_ProductIds_t *pProdIds;
            uint8_t nextEntry;
            uint8_t expectedEntries;
        } getProdIds;
		struct {
			sh2_SensorConfig_t *pConfig;
			sh2_SensorId_t sensorId;
		} getSensorConfig;
		struct {
			const sh2_SensorConfig_t *pConfig;
			sh2_SensorId_t sensorId;
		} setSensorConfig;
		struct {
			uint16_t frsType;
			uint32_t *pData;
			uint16_t *pWords;
			uint16_t nextOffset;
			sh2_SensorMetadata_t *pMetadata;
		} getFrs;
		struct {
			uint16_t frsType;
			uint32_t *pData;
			uint16_t words;
			uint16_t offset;
		} setFrs;
		struct {
			uint8_t seq;
			uint8_t severity;
			sh2_ErrorRecord_t *pErrors;
			uint16_t *pNumErrors;
			uint16_t errsRead;
		} getErrors;
		struct {
			uint8_t seq;
			sh2_SensorId_t sensorId;
			sh2_Counts_t *pCounts;
		} getCounts;
		struct {
			uint8_t seq;
		} reinit;
		struct {
			uint8_t seq;
		} saveDcdNow;
		struct {
			uint8_t sensors;
			uint8_t seq;
		} calConfig;
		struct {
			uint8_t *pSensors;
			uint8_t seq;
		} getCalConfig;
		struct {
			sh2_SensorId_t sensorId;
		} forceFlush;
        struct {
            uint8_t seq;
            sh2_OscType_t *pOscType;
        } getOscType;
        struct {
            uint32_t interval_us;
            uint8_t seq;
        } startCal;
        struct {
            sh2_CalStatus_t status;
            uint8_t seq;
        } finishCal;
    } opData;

} sh2_t;

// --- Forward Declarations -----------------------------------------------
static int16_t toQ14(double x);
static void setupCmdParams(uint8_t cmd, uint8_t p[9]);
static void setupCmd0(uint8_t cmd);
static void setupCmd1(uint8_t cmd, uint8_t p0);
    
static void executableAdvertHdlr(void *cookie, uint8_t tag, uint8_t len, uint8_t *val);
static void executableDeviceHdlr(void *cookie, uint8_t *payload, uint16_t len, uint32_t timestamp);

static void sensorhubAdvertHdlr(void *cookie, uint8_t tag, uint8_t len, uint8_t *val);
static void sensorhubControlHdlr(void *cookie, uint8_t *payload, uint16_t len, uint32_t timestamp);
static void sensorhubInputNormalHdlr(void *cookie, uint8_t *payload, uint16_t len, uint32_t timestamp);
static void sensorhubInputWakeHdlr(void *cookie, uint8_t *payload, uint16_t len, uint32_t timestamp);
static void sensorhubInputGyroRvHdlr(void *cookie, uint8_t *payload, uint16_t len, uint32_t timestamp);

static uint8_t getReportLen(uint8_t reportId);
    
// SH-2 transaction phases
static int opStart(const sh2_Op_t *pOp);
static void opTxDone(void);
static void opRx(const uint8_t *payload, uint16_t len);
static int opCompleted(int status);

static uint64_t touSTimestamp(uint32_t hostInt, int32_t referenceDelta, uint16_t delay);

// --- Private Data -------------------------------------------------------
static sh2_t sh2;

// SH-2 Transaction handlers

// Operation to Send a Command, No response
static int sendCmdStart(void);
static void sendCmdTxDone(void);
const sh2_Op_t sendCmdOp = {
    .start = sendCmdStart,
    .txDone = sendCmdTxDone,
};

// Operation to get product id
static int getProdIdStart(void);
static void getProdIdRx(const uint8_t *payload, uint16_t len);
const sh2_Op_t getProdIdOp = {
    .start = getProdIdStart,
    .rx = getProdIdRx,
};

// getSensorConfig Operation
static int getSensorConfigStart(void);
static void getSensorConfigRx(const uint8_t *payload, uint16_t len);
const sh2_Op_t getSensorConfigOp = {
    .start = getSensorConfigStart,
    .rx = getSensorConfigRx,
};

// setSensorConfig Operation
static int setSensorConfigStart(void);
static void setSensorConfigTxDone(void);
const sh2_Op_t setSensorConfigOp = {
    .start = setSensorConfigStart,
    .txDone = setSensorConfigTxDone,
};

// get FRS Operation
static int getFrsStart(void);
static void getFrsRx(const uint8_t *payload, uint16_t len);
const sh2_Op_t getFrsOp = {
    .start = getFrsStart,
    .rx = getFrsRx,
};

// set FRS Operation
static int setFrsStart(void);
static void setFrsRx(const uint8_t *payload, uint16_t len);
const sh2_Op_t setFrsOp = {
    .start = setFrsStart,
    .rx = setFrsRx,
};

// get errors operation
static int getErrorsStart(void);
static void getErrorsRx(const uint8_t *payload, uint16_t len);
const sh2_Op_t getErrorsOp = {
    .start = getErrorsStart,
    .rx = getErrorsRx,
};

// get counts operation
static int getCountsStart(void);
static void getCountsRx(const uint8_t *payload, uint16_t len);
const sh2_Op_t getCountsOp = {
    .start = getCountsStart,
    .rx = getCountsRx,
};

// reinitialize operation
static int reinitStart(void);
static void reinitRx(const uint8_t *payload, uint16_t len);
const sh2_Op_t reinitOp = {
    .start = reinitStart,
    .rx = reinitRx,
};

// save dcd now operation
static int saveDcdNowStart(void);
static void saveDcdNowRx(const uint8_t *payload, uint16_t len);
const sh2_Op_t saveDcdNowOp = {
    .start = saveDcdNowStart,
    .rx = saveDcdNowRx,
};

// cal config operation
static int calConfigStart(void);
static void calConfigRx(const uint8_t *payload, uint16_t len);
const sh2_Op_t calConfigOp = {
    .start = calConfigStart,
    .rx = calConfigRx,
};

// get cal config operation
static int getCalConfigStart(void);
static void getCalConfigRx(const uint8_t *payload, uint16_t len);
const sh2_Op_t getCalConfigOp = {
    .start = getCalConfigStart,
    .rx = getCalConfigRx,
};

// force flush operation
static int forceFlushStart(void);
static void forceFlushRx(const uint8_t *payload, uint16_t len);
const sh2_Op_t forceFlushOp = {
    .start = forceFlushStart,
    .rx = forceFlushRx,
};

// getOscType Operation
static int getOscTypeStart(void);
static void getOscTypeRx(const uint8_t *payload, uint16_t len);
const sh2_Op_t getOscTypeOp = {
    .start = getOscTypeStart,
    .rx = getOscTypeRx,
};

// startCalibration Operation
static int startCalStart(void);
static void startCalRx(const uint8_t *payload, uint16_t len);
const sh2_Op_t startCalOp = {
    .start = startCalStart,
    .rx = startCalRx,
};

// finishCalibration Operation
static int finishCalStart(void);
static void finishCalRx(const uint8_t *payload, uint16_t len);
const sh2_Op_t finishCalOp = {
    .start = finishCalStart,
    .rx = finishCalRx,
};

// --- Public API ---------------------------------------------------------

// sh2_init
int sh2_initialize(sh2_EventCallback_t *eventCallback, void *resetCookie)
{
    sh2.controlChan = 0xFF;  // An invalid value since we don't know yet.

    sh2.emptyPayloads = 0;
    sh2.unknownReportIds = 0;

    sh2.advertDone = false;
    sh2.gotInitResp = false;
    sh2.calledResetCallback = false;
  
    sh2.eventCallback = eventCallback;
    sh2.eventCallbackCookie = resetCookie;
    sh2.sensorCallback = 0;
    sh2.sensorCallbackCookie = 0;

    sh2.pOp = 0;
    
    for (int n = 0; n < SH2_MAX_REPORT_IDS; n++) {
        sh2.report[n].id = 0;
        sh2.report[n].len = 0;
    }
  
    sh2.nextCmdSeq = 0;

    // init SHTP layer
    shtp_init();

    // Register SH2 handlers
    shtp_listenAdvert("sensorhub", sensorhubAdvertHdlr, NULL);
    shtp_listenChan("sensorhub", "control", sensorhubControlHdlr, NULL);
    shtp_listenChan("sensorhub", "inputNormal", sensorhubInputNormalHdlr, NULL);
    shtp_listenChan("sensorhub", "inputWake", sensorhubInputWakeHdlr, NULL);
    shtp_listenChan("sensorhub", "inputGyroRv", sensorhubInputGyroRvHdlr, NULL);

    sh2.execBadPayload = 0;

    // Register EXECUTABLE handlers
    shtp_listenAdvert("executable", executableAdvertHdlr, NULL);
    shtp_listenChan("executable", "device", executableDeviceHdlr, NULL);

    // Start SHTP operations (resets sensor hub in non-dfu mode)
    shtp_start(false);

    return SH2_OK;
}

int sh2_setSensorCallback(sh2_SensorCallback_t *callback, void *cookie)
{
    sh2.sensorCallback = callback;
    sh2.sensorCallbackCookie = cookie;

    return SH2_OK;
}

int sh2_getProdIds(sh2_ProductIds_t *pProdIds)
{
	sh2.opData.getProdIds.pProdIds = pProdIds;
	sh2.opData.getProdIds.nextEntry = 0;
    sh2.opData.getProdIds.expectedEntries = 4;  // Most products supply 4 product ids.
                                                // When the first arrives, we'll know if
                                                // we need to adjust this.
	return opStart(&getProdIdOp);
}

int sh2_getSensorConfig(sh2_SensorId_t sensorId, sh2_SensorConfig_t *config)
{
    sh2.opData.getSensorConfig.sensorId = sensorId;
    sh2.opData.getSensorConfig.pConfig = config;
    return opStart(&getSensorConfigOp);
}

int sh2_setSensorConfig(sh2_SensorId_t sensorId, const sh2_SensorConfig_t *pConfig)
{
    // Set up operation
    sh2.opData.setSensorConfig.sensorId = sensorId;
    sh2.opData.setSensorConfig.pConfig = pConfig;

    return opStart(&setSensorConfigOp);
}

const static struct {
    sh2_SensorId_t sensorId;
    uint16_t recordId;
} sensorToRecordMap[] = {
    { SH2_RAW_ACCELEROMETER,            FRS_ID_META_RAW_ACCELEROMETER },
    { SH2_ACCELEROMETER,                FRS_ID_META_ACCELEROMETER },
    { SH2_LINEAR_ACCELERATION,          FRS_ID_META_LINEAR_ACCELERATION },
    { SH2_GRAVITY,                      FRS_ID_META_GRAVITY },
    { SH2_RAW_GYROSCOPE,                FRS_ID_META_RAW_GYROSCOPE },
    { SH2_GYROSCOPE_CALIBRATED,         FRS_ID_META_GYROSCOPE_CALIBRATED },
    { SH2_GYROSCOPE_UNCALIBRATED,       FRS_ID_META_GYROSCOPE_UNCALIBRATED },
    { SH2_RAW_MAGNETOMETER,             FRS_ID_META_RAW_MAGNETOMETER },
    { SH2_MAGNETIC_FIELD_CALIBRATED,    FRS_ID_META_MAGNETIC_FIELD_CALIBRATED },
    { SH2_MAGNETIC_FIELD_UNCALIBRATED,  FRS_ID_META_MAGNETIC_FIELD_UNCALIBRATED },
    { SH2_ROTATION_VECTOR,              FRS_ID_META_ROTATION_VECTOR },
    { SH2_GAME_ROTATION_VECTOR,         FRS_ID_META_GAME_ROTATION_VECTOR },
    { SH2_GEOMAGNETIC_ROTATION_VECTOR,  FRS_ID_META_GEOMAGNETIC_ROTATION_VECTOR },
    { SH2_PRESSURE,                     FRS_ID_META_PRESSURE },
    { SH2_AMBIENT_LIGHT,                FRS_ID_META_AMBIENT_LIGHT },
    { SH2_HUMIDITY,                     FRS_ID_META_HUMIDITY },
    { SH2_PROXIMITY,                    FRS_ID_META_PROXIMITY },
    { SH2_TEMPERATURE,                  FRS_ID_META_TEMPERATURE },
    { SH2_TAP_DETECTOR,                 FRS_ID_META_TAP_DETECTOR },
    { SH2_STEP_DETECTOR,                FRS_ID_META_STEP_DETECTOR },
    { SH2_STEP_COUNTER,                 FRS_ID_META_STEP_COUNTER },
    { SH2_SIGNIFICANT_MOTION,           FRS_ID_META_SIGNIFICANT_MOTION },
    { SH2_STABILITY_CLASSIFIER,         FRS_ID_META_STABILITY_CLASSIFIER },
    { SH2_SHAKE_DETECTOR,               FRS_ID_META_SHAKE_DETECTOR },
    { SH2_FLIP_DETECTOR,                FRS_ID_META_FLIP_DETECTOR },
    { SH2_PICKUP_DETECTOR,              FRS_ID_META_PICKUP_DETECTOR },
    { SH2_STABILITY_DETECTOR,           FRS_ID_META_STABILITY_DETECTOR },
    { SH2_PERSONAL_ACTIVITY_CLASSIFIER, FRS_ID_META_PERSONAL_ACTIVITY_CLASSIFIER },
    { SH2_SLEEP_DETECTOR,               FRS_ID_META_SLEEP_DETECTOR },
    { SH2_TILT_DETECTOR,                FRS_ID_META_TILT_DETECTOR },
    { SH2_POCKET_DETECTOR,              FRS_ID_META_POCKET_DETECTOR },
    { SH2_CIRCLE_DETECTOR,              FRS_ID_META_CIRCLE_DETECTOR },
};

int sh2_getMetadata(sh2_SensorId_t sensorId, sh2_SensorMetadata_t *pData)
{
    // pData must be non-null
    if (pData == 0) return SH2_ERR_BAD_PARAM;
  
	// Convert sensorId to metadata recordId
	int i;
	for (i = 0; i < ARRAY_LEN(sensorToRecordMap); i++) {
		if (sensorToRecordMap[i].sensorId == sensorId) {
			break;
		}
	}
	if (i >= ARRAY_LEN(sensorToRecordMap)) {
		// no match was found
		return SH2_ERR_BAD_PARAM;
	}
	uint16_t recordId = sensorToRecordMap[i].recordId;
	
	// Set up an FRS read operation
	sh2.opData.getFrs.frsType = recordId;
	sh2.opData.getFrs.pData = sh2.frsData;
	sh2.frsDataLen = ARRAY_LEN(sh2.frsData);
	sh2.opData.getFrs.pWords = &sh2.frsDataLen;
	sh2.opData.getFrs.nextOffset = 0;
	sh2.opData.getFrs.pMetadata = pData;

	return opStart(&getFrsOp);
}

int sh2_getFrs(uint16_t recordId, uint32_t *pData, uint16_t *words)
{
    if ((pData == 0) || (words == 0)) {
        return SH2_ERR_BAD_PARAM;
    }
    
	// Store params for this op
	sh2.opData.getFrs.frsType = recordId;
	sh2.opData.getFrs.pData = pData;
	sh2.opData.getFrs.pWords = words;
	sh2.opData.getFrs.nextOffset = 0;
	sh2.opData.getFrs.pMetadata = 0;

    return opStart(&getFrsOp);
}

int sh2_setFrs(uint16_t recordId, uint32_t *pData, uint16_t words)
{
    if ((pData == 0) && (words != 0)) {
        return SH2_ERR_BAD_PARAM;
    }
    
    sh2.opData.setFrs.frsType = recordId;
    sh2.opData.setFrs.pData = pData;
    sh2.opData.setFrs.words = words;

    return opStart(&setFrsOp);
}

int sh2_getErrors(uint8_t severity, sh2_ErrorRecord_t *pErrors, uint16_t *numErrors)
{
    sh2.opData.getErrors.severity = severity;
    sh2.opData.getErrors.pErrors = pErrors;
    sh2.opData.getErrors.pNumErrors = numErrors;
    
    return opStart(&getErrorsOp);
}

int sh2_getCounts(sh2_SensorId_t sensorId, sh2_Counts_t *pCounts)
{
    sh2.opData.getCounts.sensorId = sensorId;
    sh2.opData.getCounts.pCounts = pCounts;
    
    return opStart(&getCountsOp);
}

int sh2_clearCounts(sh2_SensorId_t sensorId)
{
    uint8_t p[9];

    memset(p, 0, sizeof(p));
    p[0] = SH2_COUNTS_CLEAR_COUNTS;
    p[1] = sensorId;
    setupCmdParams(SH2_CMD_COUNTS, p);

    return opStart(&sendCmdOp);
}

int sh2_setTareNow(uint8_t axes,    // SH2_TARE_X | SH2_TARE_Y | SH2_TARE_Z
                   sh2_TareBasis_t basis)
{
    uint8_t p[9];

    memset(p, 0, sizeof(p));
    p[0] = SH2_TARE_TARE_NOW;
    p[1] = axes;
    p[2] = basis;
    setupCmdParams(SH2_CMD_TARE, p);

    return opStart(&sendCmdOp);
}

int sh2_clearTare(void)
{
    uint8_t p[9];

    memset(p, 0, sizeof(p));
    p[0] = SH2_TARE_SET_REORIENTATION;

    setupCmdParams(SH2_CMD_TARE, p);
    return opStart(&sendCmdOp);
}

int sh2_persistTare(void)
{
    setupCmd1(SH2_CMD_TARE, SH2_TARE_PERSIST_TARE);
    return opStart(&sendCmdOp);
}

int sh2_setReorientation(sh2_Quaternion_t *orientation)
{
    uint8_t p[9];

    p[0] = SH2_TARE_SET_REORIENTATION;
    writeu16(&p[1], toQ14(orientation->x));
    writeu16(&p[3], toQ14(orientation->y));
    writeu16(&p[5], toQ14(orientation->z));
    writeu16(&p[7], toQ14(orientation->w));

    setupCmdParams(SH2_CMD_TARE, p);
    return opStart(&sendCmdOp);
}

int sh2_reinitialize(void)
{
    return opStart(&reinitOp);
}

int sh2_saveDcdNow(void)
{
    return opStart(&saveDcdNowOp);
}

int sh2_getOscType(sh2_OscType_t *pOscType)
{
    sh2.opData.getOscType.pOscType = pOscType;
    return opStart(&getOscTypeOp);
}


int sh2_setCalConfig(uint8_t sensors)
{
    sh2.opData.calConfig.sensors = sensors;

    return opStart(&calConfigOp);
}

int sh2_getCalConfig(uint8_t *pSensors)
{
    if (pSensors == 0) {
        return SH2_ERR_BAD_PARAM;
    }
    
    sh2.opData.getCalConfig.pSensors = pSensors;

    return opStart(&getCalConfigOp);
}

int sh2_setDcdAutoSave(bool enabled)
{
    setupCmd1(SH2_CMD_DCD_SAVE, enabled ? 0 : 1);
    return opStart(&sendCmdOp);
}

int sh2_flush(sh2_SensorId_t sensorId)
{
    // Set up flush operation
    sh2.opData.forceFlush.sensorId = sensorId;

    return opStart(&forceFlushOp);
}

int sh2_clearDcdAndReset(void)
{
    setupCmd0(SH2_CMD_CLEAR_DCD_AND_RESET);
    return opStart(&sendCmdOp);
}

int sh2_startCal(uint32_t interval_us)
{
    sh2.opData.startCal.interval_us = interval_us;
    return opStart(&startCalOp);
}

int sh2_finishCal(sh2_CalStatus_t *status)
{
    int retval = opStart(&finishCalOp);
    *status = sh2.opData.finishCal.status;
    return retval;
}

// --- Private utility functions --------------------------------------------------------------

static int16_t toQ14(double x)
{
    int16_t retval = (int16_t)(x * (1<<14));
    
    return retval;
}

// Send a command with parameters from p
static void setupCmdParams(uint8_t cmd, uint8_t p[9])
{
    // Set up request
    sh2.opData.sendCmd.req.reportId = SENSORHUB_COMMAND_REQ;
    sh2.opData.sendCmd.req.seq = sh2.nextCmdSeq++;
    sh2.opData.sendCmd.req.command = cmd;
    memcpy(&sh2.opData.sendCmd.req.p, p,
           sizeof(sh2.opData.sendCmd.req.p));
}

// Set up command with no params
static void setupCmd0(uint8_t cmd)
{
    uint8_t p[9];

    memset(p, 0, sizeof(p));
    setupCmdParams(cmd, p);
}

// Set up command with 1 param
static void setupCmd1(uint8_t cmd, uint8_t p0)
{
    uint8_t p[9];

    memset(p, 0, sizeof(p));
    p[0] = p0;
    setupCmdParams(cmd, p);
}

static void sensorhubAdvertHdlr(void *cookie, uint8_t tag, uint8_t len, uint8_t *val)
{

    switch (tag) {
        case TAG_SH2_VERSION:
            strcpy(sh2.version, (const char *)val);
            break;

        case TAG_SH2_REPORT_LENGTHS:
        {
            uint8_t reports = len/2;
            if (reports > SH2_MAX_REPORT_IDS) {
                // Hub gave us more report lengths than we can store!
                reports = SH2_MAX_REPORT_IDS;
            }
        
            for (int n = 0; n < reports; n++) {
                sh2.report[n].id = val[n*2];
                sh2.report[n].len = val[n*2 + 1];
            }
            break;
        }
    
        case 0:
        {
            // 0 tag indicates end of advertisements for this app
            // At this time, the SHTP layer can give us our channel number.
            sh2.controlChan = shtp_chanNo("sensorhub", "control");

            sh2.advertDone = true;
            break;
        }
        
        default:
            break;
    }
}

static void sensorhubControlHdlr(void *cookie, uint8_t *payload, uint16_t len, uint32_t timestamp)
{
    uint16_t cursor = 0;
    uint32_t count = 0;
    CommandResp_t * pResp = 0;
    sh2_AsyncEvent_t event;
    
    if (len == 0) {
        sh2.emptyPayloads++;
        return;
    }

    while (cursor < len) {
        // Get next report id
        count++;
        uint8_t reportId = payload[cursor];

        // Determine report length
        uint8_t reportLen = 0;
        for (int n = 0; n < SH2_MAX_REPORT_IDS; n++) {
            if (sh2.report[n].id == reportId) {
                reportLen = sh2.report[n].len;
                break;
            }
        }
        if (reportLen == 0) {
            // An unrecognized report id
            sh2.unknownReportIds++;
            return;
        }
        else {
            // Check for unsolicited initialize response or FRS change response
            if (reportId == SENSORHUB_COMMAND_RESP) {
                pResp = (CommandResp_t *)(payload+cursor);
                if ((pResp->command == (SH2_CMD_INITIALIZE | SH2_INIT_UNSOLICITED)) &&
                    (pResp->r[1] == SH2_INIT_SYSTEM)) {
                    // This is an unsolicited INIT message.
                    // Is it time to call reset callback?
                    sh2.gotInitResp = true;
                }
                if (pResp->command == (SH2_CMD_FRS | SH2_INIT_UNSOLICITED))
                {
                    // This is an unsolicited FRS change message
                    event.eventId = SH2_FRS_CHANGE;
                    event.frsType = pResp->r[1] + (pResp->r[2] << 8);
                    if (sh2.eventCallback) {
                        sh2.eventCallback(sh2.eventCallbackCookie, &event);
                    }
				}
			}

            // Hand off to operation in progress, if any
            opRx(payload+cursor, reportLen);
            cursor += reportLen;
        }
    }
}

static void sensorhubInputHdlr(uint8_t *payload, uint16_t len, uint32_t timestamp)
{
    sh2_SensorEvent_t event;
    uint16_t cursor = 0;

    uint32_t referenceDelta;

    referenceDelta = 0;

    while (cursor < len) {
        // Get next report id
        uint8_t reportId = payload[cursor];

        // Determine report length
        uint8_t reportLen = getReportLen(reportId);
        if (reportLen == 0) {
            // An unrecognized report id
            sh2.unknownReportIds++;
            return;
        }
        else {
            if (reportId == SENSORHUB_BASE_TIMESTAMP_REF) {
                const BaseTimestampRef_t *rpt = (const BaseTimestampRef_t *)(payload+cursor);
                
                // store base timestamp reference
                referenceDelta = -rpt->timebase;
            }
            else if (reportId == SENSORHUB_TIMESTAMP_REBASE) {
                const TimestampRebase_t *rpt = (const TimestampRebase_t *)(payload+cursor);

                referenceDelta += rpt->timebase;
            }
            else if (reportId == SENSORHUB_FLUSH_COMPLETED) {
                // Route this as if it arrived on command channel.
                opRx(payload+cursor, reportLen);
            }
            else {
                uint8_t *pReport = payload+cursor;
                uint16_t delay = ((pReport[2] & 0xFC) << 6) + pReport[3];
                event.timestamp_uS = touSTimestamp(timestamp, referenceDelta, delay);
                event.reportId = reportId;
                memcpy(event.report, pReport, reportLen);
                /// event.pReport = pReport;
                event.len = reportLen;
                if (sh2.sensorCallback != 0) {
                    sh2.sensorCallback(sh2.sensorCallbackCookie, &event);
                }
            }
            cursor += reportLen;
        }
    }
}

static void sensorhubInputNormalHdlr(void *cookie, uint8_t *payload, uint16_t len, uint32_t timestamp)
{
    
    sensorhubInputHdlr(payload, len, timestamp);
}

static void sensorhubInputWakeHdlr(void *cookie, uint8_t *payload, uint16_t len, uint32_t timestamp)
{
    
    sensorhubInputHdlr(payload, len, timestamp);
}

static void sensorhubInputGyroRvHdlr(void *cookie, uint8_t *payload, uint16_t len, uint32_t timestamp)
{

    sh2_SensorEvent_t event;
    uint16_t cursor = 0;

    uint8_t reportId = SH2_GYRO_INTEGRATED_RV;
    uint8_t reportLen = getReportLen(reportId);

    while (cursor < len) {
        event.timestamp_uS = timestamp;
        event.reportId = reportId;
        memcpy(event.report, payload+cursor, reportLen);
        /// event.pReport = payload+cursor;
        event.len = reportLen;

        if (sh2.sensorCallback != 0) {
            sh2.sensorCallback(sh2.sensorCallbackCookie, &event);
        }

        cursor += reportLen;
    }
}

static uint8_t getReportLen(uint8_t reportId)
{
    for (int n = 0; n < SH2_MAX_REPORT_IDS; n++) {
        if (sh2.report[n].id == reportId) {
            return sh2.report[n].len;
        }
    }

    return 0;
}

// SH-2 transaction phases
static int opStart(const sh2_Op_t *pOp)
{
    // return error if another operation already in progress
    if (sh2.pOp) return SH2_ERR_OP_IN_PROGRESS;

    // Establish this operation as the new operation in progress
    sh2.pOp = pOp;
    int rc = pOp->start();  // Call start method
    if (rc != SH2_OK) {
        // Operation failed to start
        
        // Unregister this operation
        sh2.pOp = 0;
    }

    // Block the calling thread until the operation completes.
    sh2_hal_block();

    // Clear operation in progress
    sh2.pOp = 0;

    // Get return status from opStatus
    rc = sh2.opStatus;
    
    return rc;
}

static void opTxDone(void)
{
    if ((sh2.pOp != 0) && (sh2.pOp->txDone != 0)) {
        sh2.pOp->txDone();  // Call txDone method
    }
}

static void opRx(const uint8_t *payload, uint16_t len)
{ 
	if ((sh2.pOp != 0) &&                      // An operation is in progress
        (sh2.pOp->rx != 0)) {                  // and it has an rx method
		sh2.pOp->rx(payload, len);  // Call receive method
	}
}

static int opCompleted(int status)
{
    // Record status
    sh2.opStatus = status;

    // Block the calling thread until the operation completes.
    sh2_hal_unblock();

    return SH2_OK;
}

// Produce 64-bit microsecond timestamp for a sensor event
static uint64_t touSTimestamp(uint32_t hostInt, int32_t referenceDelta, uint16_t delay)
{
    static uint32_t lastHostInt = 0;
    static uint32_t rollovers = 0;
    uint64_t timestamp;

    // Count times hostInt timestamps rolled over to produce upper bits
    if (hostInt < lastHostInt) {
        rollovers++;
    }
    lastHostInt = hostInt;
    
    timestamp = ((uint64_t)rollovers << 32);
    timestamp += hostInt + (referenceDelta + delay) * 100;

    return timestamp;
}

// --- Operation: Send Command (no response expected.) ----------------------

static int sendCmdStart(void)
{
    int rc = SH2_OK;

    // Send request
    rc = shtp_send(sh2.controlChan,
                   (uint8_t *)&sh2.opData.sendCmd.req,
                   sizeof(sh2.opData.sendCmd.req));
    opTxDone();

    return rc;
}

static void sendCmdTxDone(void)
{
    opCompleted(SH2_OK);
}
    
// --- Operation: Get Product Id ----------------------

// Get Product ID Op handler
static int getProdIdStart(void)
{
    int rc = SH2_OK;
    ProdIdReq_t req;
    
    // Set up request to issue
    memset(&req, 0, sizeof(req));
    req.reportId = SENSORHUB_PROD_ID_REQ;
    rc = shtp_send(sh2.controlChan, (uint8_t *)&req, sizeof(req));
    opTxDone();

    return rc;
}

static void getProdIdRx(const uint8_t *payload, uint16_t len)
{
	ProdIdResp_t *resp = (ProdIdResp_t *)payload;
	
	// skip this if it isn't the product id response.
	if (resp->reportId != SENSORHUB_PROD_ID_RESP) return;

	// Store this product id, if we can
	sh2_ProductIds_t *pProdIds = sh2.opData.getProdIds.pProdIds;
	
	if (pProdIds) {
		// Store the product id response
		if (sh2.opData.getProdIds.nextEntry < sh2.opData.getProdIds.expectedEntries) {
			sh2_ProductId_t *pProdId = &pProdIds->entry[sh2.opData.getProdIds.nextEntry];
			
			pProdId->resetCause = resp->resetCause;
			pProdId->swVersionMajor = resp->swVerMajor;
			pProdId->swVersionMinor = resp->swVerMinor;
			pProdId->swPartNumber = resp->swPartNumber;
			pProdId->swBuildNumber = resp->swBuildNumber;
			pProdId->swVersionPatch = resp->swVerPatch;
			pProdId->reserved0 = resp->reserved0;
			pProdId->reserved1 = resp->reserved1;

            if (pProdId->swPartNumber == 10004095) {
                // FSP200 has 5 product id entries
                sh2.opData.getProdIds.expectedEntries = 5;
            }


			sh2.opData.getProdIds.nextEntry++;
		}
	}

	// Complete this operation if there is no storage for more product ids
	if ((sh2.opData.getProdIds.pProdIds == 0) ||
	    (sh2.opData.getProdIds.nextEntry >= sh2.opData.getProdIds.expectedEntries)) {
        sh2.opData.getProdIds.pProdIds->numEntries = sh2.opData.getProdIds.nextEntry;
		opCompleted(SH2_OK);
	}

	return;
}

// --- Operation: Get Sensor Config ----------------------

static int getSensorConfigStart(void)
{
    int rc = SH2_OK;
    GetFeatureReq_t req;
    
    // set up request to issue
    memset(&req, 0, sizeof(req));
    req.reportId = SENSORHUB_GET_FEATURE_REQ;
    req.featureReportId = sh2.opData.getSensorConfig.sensorId;
    rc = shtp_send(sh2.controlChan, (uint8_t *)&req, sizeof(req));
    opTxDone();

    return rc;
}

static void getSensorConfigRx(const uint8_t *payload, uint16_t len)
{
    GetFeatureResp_t *resp = (GetFeatureResp_t *)payload;
    sh2_SensorConfig_t *pConfig;
    
    // skip this if it isn't the response we're waiting for.
    if (resp->reportId != SENSORHUB_GET_FEATURE_RESP) return;
    if (resp->featureReportId != sh2.opData.getSensorConfig.sensorId) return;

    // Copy out data
    pConfig = sh2.opData.getSensorConfig.pConfig;
    
    pConfig->changeSensitivityEnabled = ((resp->flags & FEAT_CHANGE_SENSITIVITY_ENABLED) != 0);
    pConfig->changeSensitivityRelative = ((resp->flags & FEAT_CHANGE_SENSITIVITY_RELATIVE) != 0);
    pConfig->wakeupEnabled = ((resp->flags & FEAT_WAKE_ENABLED) != 0);
    pConfig->alwaysOnEnabled = ((resp->flags & FEAT_ALWAYS_ON_ENABLED) != 0);
    pConfig->changeSensitivity = resp->changeSensitivity;
    pConfig->reportInterval_us = resp->reportInterval_uS;
    pConfig->batchInterval_us = resp->batchInterval_uS;
    pConfig->sensorSpecific = resp->sensorSpecific;

    // Complete this operation
    opCompleted(SH2_OK);

    return;
}

static int setSensorConfigStart(void)
{
    SetFeatureReport_t req;
    uint8_t flags = 0;
    int rc;
    sh2_SensorConfig_t *pConfig = sh2.opData.getSensorConfig.pConfig;
    
    if (pConfig->changeSensitivityEnabled)  flags |= FEAT_CHANGE_SENSITIVITY_ENABLED;
    if (pConfig->changeSensitivityRelative) flags |= FEAT_CHANGE_SENSITIVITY_RELATIVE;
    if (pConfig->wakeupEnabled)             flags |= FEAT_WAKE_ENABLED;
    if (pConfig->alwaysOnEnabled)           flags |= FEAT_ALWAYS_ON_ENABLED;

    memset(&req, 0, sizeof(req));
    req.reportId = SENSORHUB_SET_FEATURE_CMD;
    req.featureReportId = sh2.opData.setSensorConfig.sensorId;
    req.flags = flags;
    req.changeSensitivity = pConfig->changeSensitivity;
    req.reportInterval_uS = pConfig->reportInterval_us;
    req.batchInterval_uS = pConfig->batchInterval_us;
    req.sensorSpecific = pConfig->sensorSpecific;

    rc = shtp_send(sh2.controlChan, (uint8_t *)&req, sizeof(req));
    opTxDone();

    return rc;
}

static void setSensorConfigTxDone(void)
{
    // complete immediately
    opCompleted(SH2_OK);
}

// --- get frs operation ------------------------------------

static int getFrsStart(void)
{
    int rc = SH2_OK;
    FrsReadReq_t req;

	// set up request to issue
	memset(&req, 0, sizeof(req));
	req.reportId = SENSORHUB_FRS_READ_REQ;
	req.reserved = 0;
	req.readOffset = 0; // read from start
	req.frsType = sh2.opData.getFrs.frsType;
	req.blockSize = 0;  // read all avail data

    rc = shtp_send(sh2.controlChan, (uint8_t *)&req, sizeof(req));
    opTxDone();

    return rc;
}

static void stuffMetadata(sh2_SensorMetadata_t *pData, uint32_t *frsData)
{
    // Populate the sensorMetadata structure with results
    pData->meVersion        = (frsData[0] >> 0) & 0xFF;
    pData->mhVersion        = (frsData[0] >> 8) & 0xFF;
    pData->shVersion        = (frsData[0] >> 16) & 0xFF;
    pData->range            = frsData[1];
    pData->resolution       = frsData[2];
    pData->power_mA         = (frsData[3] >> 0) & 0xFFFF;    // 16.10 format
    pData->revision         = (frsData[3] >> 16) & 0xFFFF;
    pData->minPeriod_uS     = frsData[4];
    pData->maxPeriod_uS     = 0;  // ...unless reading format 4 metadata below
    pData->fifoMax          = (frsData[5] >> 0) & 0xFFFF;
    pData->fifoReserved     = (frsData[5] >> 16) & 0xFFFF;
    pData->batchBufferBytes = (frsData[6] >> 0) & 0xFFFF;;
    pData->vendorIdLen      = (frsData[6] >> 16) & 0xFFFF;

    // Init fields that may not be present, depending on metadata revision
    pData->qPoint1           = 0;
    pData->qPoint2           = 0;
    pData->qPoint3           = 0;
    pData->sensorSpecificLen = 0;
    strcpy(pData->vendorId, ""); // init with empty string in case vendorIdLen == 0
    
    int vendorIdOffset = 8;
    // Get revision-specific fields
    if (pData->revision == 0) {
        // No fixed fields, vendor id copied after if-else block
    }
    else if (pData->revision == 1) {
        pData->qPoint1        = (frsData[7] >> 0) & 0xFFFF;
        pData->qPoint2        = (frsData[7] >> 16) & 0xFFFF;
    }
    else if (pData->revision == 2) {
        pData->qPoint1        = (frsData[7] >> 0) & 0xFFFF;
        pData->qPoint2        = (frsData[7] >> 16) & 0xFFFF;
        pData->sensorSpecificLen = (frsData[8] >> 0) & 0xFFFF;
        memcpy(pData->sensorSpecific, (uint8_t *)&frsData[9], pData->sensorSpecificLen);
        vendorIdOffset = 9 + ((pData->sensorSpecificLen+3)/4); // 9 + one word for every 4 bytes of SS data
    }
    else if (pData->revision == 3) {
        pData->qPoint1        = (frsData[7] >> 0) & 0xFFFF;
        pData->qPoint2        = (frsData[7] >> 16) & 0xFFFF;
        pData->sensorSpecificLen = (frsData[8] >> 0) & 0xFFFF;
        pData->qPoint3        = (frsData[8] >> 16) & 0xFFFF;
        memcpy(pData->sensorSpecific, (uint8_t *)&frsData[9], pData->sensorSpecificLen);
        vendorIdOffset = 9 + ((pData->sensorSpecificLen+3)/4); // 9 + one word for every 4 bytes of SS data
    }
    else if (pData->revision == 4) {
        pData->qPoint1        = (frsData[7] >> 0) & 0xFFFF;
        pData->qPoint2        = (frsData[7] >> 16) & 0xFFFF;
        pData->sensorSpecificLen = (frsData[8] >> 0) & 0xFFFF;
        pData->qPoint3        = (frsData[8] >> 16) & 0xFFFF;
        pData->maxPeriod_uS   = frsData[9];
        memcpy(pData->sensorSpecific, (uint8_t *)&frsData[10], pData->sensorSpecificLen);
        vendorIdOffset = 10 + ((pData->sensorSpecificLen+3)/4); // 9 + one word for every 4 bytes of SS data
    }
    else {
        // Unrecognized revision!
    }

    // Copy vendor id
    memcpy(pData->vendorId, (uint8_t *)&frsData[vendorIdOffset],
           pData->vendorIdLen);
}

static void getFrsRx(const uint8_t *payload, uint16_t len)
{
	FrsReadResp_t *resp = (FrsReadResp_t *)payload;
	uint8_t status;

	// skip this if it isn't the response we're looking for
	if (resp->reportId != SENSORHUB_FRS_READ_RESP) return;

	// Check for errors: Unrecognized FRS type, Busy, Out of range, Device error
	status = FRS_READ_STATUS(resp->len_status);
	if ((status == FRS_READ_STATUS_UNRECOGNIZED_FRS_TYPE) ||
	    (status == FRS_READ_STATUS_BUSY) ||
	    (status == FRS_READ_STATUS_OFFSET_OUT_OF_RANGE) ||
	    (status == FRS_READ_STATUS_DEVICE_ERROR)
		) {
		// Operation failed
		opCompleted(SH2_ERR_HUB);
		return;
	}

	if (status == FRS_READ_STATUS_RECORD_EMPTY) {
		// Empty record, return zero length.
		*(sh2.opData.getFrs.pWords) = 0;
		opCompleted(SH2_OK);
	}

	// Store the contents from this response
	uint16_t offset = resp->wordOffset;

    // check for missed offsets, resulting in error.
    if (offset != sh2.opData.getFrs.nextOffset) {
        // Some data was dropped.
        *(sh2.opData.getFrs.pWords) = 0;
        opCompleted(SH2_ERR_IO);
    }
	
	// store first word, if we have room
	if ((*(sh2.opData.getFrs.pWords) == 0) ||
        (offset <= *(sh2.opData.getFrs.pWords))) {
		sh2.opData.getFrs.pData[offset] = resp->data0;
		sh2.opData.getFrs.nextOffset = offset+1;
	}

    // store second word if there is one and we have room
    if ((FRS_READ_DATALEN(resp->len_status) == 2)  &&
        ((*(sh2.opData.getFrs.pWords) == 0) ||
         (offset <= *(sh2.opData.getFrs.pWords)))) {
		sh2.opData.getFrs.pData[offset+1] = resp->data1;
		sh2.opData.getFrs.nextOffset = offset+2;
	}

	// If read is done, complete the operation
	if ((status == FRS_READ_STATUS_READ_RECORD_COMPLETED) ||
	    (status == FRS_READ_STATUS_READ_BLOCK_COMPLETED) ||
	    (status == FRS_READ_STATUS_READ_BLOCK_AND_RECORD_COMPLETED)) {
		*(sh2.opData.getFrs.pWords) = sh2.opData.getFrs.nextOffset;

        // If this was performed from getMetadata, copy the results into pMetadata.
        if (sh2.opData.getFrs.pMetadata != 0) {
            stuffMetadata(sh2.opData.getFrs.pMetadata, sh2.opData.getFrs.pData);
        }

        opCompleted(SH2_OK);
    }

    return;
}

// --- set frs operation ------------------------------------

static int setFrsStart(void)
{
    int rc = SH2_OK;
    FrsWriteReq_t req;

    sh2.opData.setFrs.offset = 0;
    
    // set up request to issue
    memset(&req, 0, sizeof(req));
    req.reportId = SENSORHUB_FRS_WRITE_REQ;
    req.reserved = 0;
    req.length = sh2.opData.setFrs.words;
    req.frsType = sh2.opData.getFrs.frsType;

    rc = shtp_send(sh2.controlChan, (uint8_t *)&req, sizeof(req));
    opTxDone();

    return rc;
}

static void setFrsRx(const uint8_t *payload, uint16_t len)
{
    FrsWriteResp_t *resp = (FrsWriteResp_t *)payload;
    FrsWriteDataReq_t req;
    uint8_t status;
    bool sendMoreData = false;
    bool completed = false;
    int rc = SH2_OK;

    // skip this if it isn't the response we're looking for.
    if (resp->reportId != SENSORHUB_FRS_WRITE_RESP) return;

    // Check for errors: Unrecognized FRS type, Busy, Out of range, Device error
    status = resp->status;
    switch(status) {
        case FRS_WRITE_STATUS_RECEIVED:
        case FRS_WRITE_STATUS_READY:
            sendMoreData = true;
            break;
        case FRS_WRITE_STATUS_UNRECOGNIZED_FRS_TYPE:
        case FRS_WRITE_STATUS_BUSY:
        case FRS_WRITE_STATUS_FAILED:
        case FRS_WRITE_STATUS_NOT_READY:
        case FRS_WRITE_STATUS_INVALID_LENGTH:
        case FRS_WRITE_STATUS_INVALID_RECORD:
        case FRS_WRITE_STATUS_DEVICE_ERROR:
        case FRS_WRITE_STATUS_READ_ONLY:
            rc = SH2_ERR_HUB;
            completed = true;
            break;
        case FRS_WRITE_STATUS_WRITE_COMPLETED:
            // Successful completion
            rc = SH2_OK;
            completed = true;
            break;
        case FRS_WRITE_STATUS_RECORD_VALID:
            // That's nice, keep waiting
            break;
    }

    // if we should send more data, do it.
    if (sendMoreData &&
        (sh2.opData.setFrs.offset < sh2.opData.setFrs.words)) {
        uint16_t offset = sh2.opData.setFrs.offset;
        
        memset(&req, 0, sizeof(req));
        req.reportId = SENSORHUB_FRS_WRITE_DATA_REQ;
        req.reserved = 0;
        req.offset = offset;
        req.data0 = sh2.opData.setFrs.pData[offset++];
        if (offset < sh2.opData.setFrs.words) {
            req.data1 = sh2.opData.setFrs.pData[offset++];
        } else {
            req.data1 = 0;
        }
        sh2.opData.setFrs.offset = offset;
        
        rc = shtp_send(sh2.controlChan, (uint8_t *)&req, sizeof(req));
        opTxDone();

    }

    // if the operation is done or has to be aborted, complete it
    if (completed) {
        opCompleted(rc);
    }

    return;
}

// --- Operation: get errors --------------

static int getErrorsStart(void)
{
    int rc = SH2_OK;
    CommandReq_t req;
    
    // Create a command sequence number for this command
    sh2.opData.getErrors.seq = sh2.nextCmdSeq++;
    sh2.opData.getErrors.errsRead = 0;
    
    // set up request to issue
    memset(&req, 0, sizeof(req));
    req.reportId = SENSORHUB_COMMAND_REQ;
    req.seq = sh2.opData.getErrors.seq;
    req.command = SH2_CMD_ERRORS;
    req.p[0] = sh2.opData.getErrors.severity;
    
    rc = shtp_send(sh2.controlChan, (uint8_t *)&req, sizeof(req));
    opTxDone();
    
    return rc;
}

static void getErrorsRx(const uint8_t *payload, uint16_t len)
{
    CommandResp_t *resp = (CommandResp_t *)payload;
    
    // skip this if it isn't the right response
    if (resp->reportId != SENSORHUB_COMMAND_RESP) return;
    if (resp->command != SH2_CMD_ERRORS) return;
    if (resp->commandSeq != sh2.opData.getErrors.seq) return;


    if (resp->r[2] == 255) {
        // No error to report, operation is complete
        *(sh2.opData.getErrors.pNumErrors) = sh2.opData.getErrors.errsRead;
        opCompleted(SH2_OK);
    } else {
        // Copy data for invoker.
        unsigned int index = sh2.opData.getErrors.errsRead;
        if (index < *(sh2.opData.getErrors.pNumErrors)) {
            // We have room for this one.
            sh2.opData.getErrors.pErrors[index].severity = resp->r[0];
            sh2.opData.getErrors.pErrors[index].sequence = resp->r[1];
            sh2.opData.getErrors.pErrors[index].source = resp->r[2];
            sh2.opData.getErrors.pErrors[index].error = resp->r[3];
            sh2.opData.getErrors.pErrors[index].module = resp->r[4];
            sh2.opData.getErrors.pErrors[index].code = resp->r[5];

            sh2.opData.getErrors.errsRead++;
        }
    }

    return;
}

// --- Operation: get counts --------------

static int getCountsStart(void)
{
    int rc = SH2_OK;
    CommandReq_t req;
    
    // Create a command sequence number for this command
    sh2.opData.getCounts.seq = sh2.nextCmdSeq++;
    
    // set up request to issue
    memset(&req, 0, sizeof(req));
    req.reportId = SENSORHUB_COMMAND_REQ;
    req.seq = sh2.opData.getCounts.seq;
    req.command = SH2_CMD_COUNTS;
    req.p[0] = SH2_COUNTS_GET_COUNTS;
    req.p[1] = sh2.opData.getCounts.sensorId;
    
    rc = shtp_send(sh2.controlChan, (uint8_t *)&req, sizeof(req));
    opTxDone();

    return rc;
}

static void getCountsRx(const uint8_t *payload, uint16_t len)
{
    CommandResp_t *resp = (CommandResp_t *)payload;
    
    // skip this if it isn't the right response
    if (resp->reportId != SENSORHUB_COMMAND_RESP) return;
    if (resp->command != SH2_CMD_COUNTS) return;
    if (resp->commandSeq != sh2.opData.getCounts.seq) return;

    // Store results
    if (resp->respSeq == 0) {
        sh2.opData.getCounts.pCounts->offered = readu32(&resp->r[3]);
        sh2.opData.getCounts.pCounts->accepted = readu32(&resp->r[7]);
    }
    else {
        sh2.opData.getCounts.pCounts->on = readu32(&resp->r[3]);
        sh2.opData.getCounts.pCounts->attempted = readu32(&resp->r[7]);
    }
    
    // Complete this operation if we've received last response
    if (resp->respSeq == 1) {
        opCompleted(SH2_OK);
    }

    return;
}

// --- Operation: reinitialize --------------

static int reinitStart(void)
{
    int rc = SH2_OK;
    CommandReq_t req;
    
    // Create a command sequence number for this command
    sh2.opData.reinit.seq = sh2.nextCmdSeq++;
    
    // set up request to issue
    memset(&req, 0, sizeof(req));
    req.reportId = SENSORHUB_COMMAND_REQ;
    req.seq = sh2.opData.reinit.seq;
    req.command = SH2_CMD_INITIALIZE;
    req.p[0] = SH2_INIT_SYSTEM;
    
    rc = shtp_send(sh2.controlChan, (uint8_t *)&req, sizeof(req));
    opTxDone();

    return rc;
}

static void reinitRx(const uint8_t *payload, uint16_t len)
{
    CommandResp_t *resp = (CommandResp_t *)payload;
    
    // skip this if it isn't the right response
    if (resp->reportId != SENSORHUB_COMMAND_RESP) return;
    if (resp->command != SH2_CMD_INITIALIZE) return;
    if (resp->commandSeq != sh2.opData.reinit.seq) return;

    // If return status is error, return error to invoker
    int rc = SH2_OK;
    if (resp->r[0] != 0) {
        rc = SH2_ERR_HUB;
    }
    
    // Complete this operation
    opCompleted(rc);

    return;
}

// --- Operation: save dcd now --------------

static int saveDcdNowStart(void)
{
    int rc = SH2_OK;
    CommandReq_t req;
    
    // Create a command sequence number for this command
    sh2.opData.saveDcdNow.seq = sh2.nextCmdSeq++;
    
    // set up request to issue
    memset(&req, 0, sizeof(req));
    req.reportId = SENSORHUB_COMMAND_REQ;
    req.seq = sh2.opData.saveDcdNow.seq;
    req.command = SH2_CMD_DCD;
    
    rc = shtp_send(sh2.controlChan, (uint8_t *)&req, sizeof(req));
    opTxDone();

    return rc;
}

static void saveDcdNowRx(const uint8_t *payload, uint16_t len)
{
    CommandResp_t *resp = (CommandResp_t *)payload;
    
    // skip this if it isn't the right response
    if (resp->reportId != SENSORHUB_COMMAND_RESP) return;
    if (resp->command != SH2_CMD_DCD) return;
    if (resp->commandSeq != sh2.opData.saveDcdNow.seq) return;

    // If return status is error, return error to invoker
    int rc = SH2_OK;
    if (resp->r[0] != 0) {
        rc = SH2_ERR_HUB;
    }
    
    // Complete this operation
    opCompleted(rc);

    return;
}

// --- Operation: cal config --------------

static int calConfigStart(void)
{
    int rc = SH2_OK;
    CommandReq_t req;
    
    // Create a command sequence number for this command
    sh2.opData.calConfig.seq = sh2.nextCmdSeq++;
    
    // set up request to issue
    memset(&req, 0, sizeof(req));
    req.reportId = SENSORHUB_COMMAND_REQ;
    req.seq = sh2.opData.calConfig.seq;
    req.command = SH2_CMD_ME_CAL;
    req.p[0] = (sh2.opData.calConfig.sensors & SH2_CAL_ACCEL) ? 1 : 0; // accel cal
    req.p[1] = (sh2.opData.calConfig.sensors & SH2_CAL_GYRO)  ? 1 : 0; // gyro cal
    req.p[2] = (sh2.opData.calConfig.sensors & SH2_CAL_MAG)   ? 1 : 0; // mag cal
    req.p[4] = (sh2.opData.calConfig.sensors & SH2_CAL_PLANAR) ? 1 : 0; // planar cal
    
    rc = shtp_send(sh2.controlChan, (uint8_t *)&req, sizeof(req));
    opTxDone();

    return rc;
}

static void calConfigRx(const uint8_t *payload, uint16_t len)
{
    int rc = SH2_OK;
    CommandResp_t *resp = (CommandResp_t *)payload;
    
    // skip this if it isn't the right response
    if (resp->reportId != SENSORHUB_COMMAND_RESP) return;
    if (resp->command != SH2_CMD_ME_CAL) return;
    if (resp->commandSeq != sh2.opData.calConfig.seq) return;

    // If return status is error, return error to invoker
    if (resp->r[0] != 0) {
        rc = SH2_ERR_HUB;
    }
    
    // Complete this operation
    opCompleted(rc);

    return;
}

// --- Operation: cal config --------------

static int getCalConfigStart(void)
{
    int rc = SH2_OK;
    CommandReq_t req;
    
    // Create a command sequence number for this command
    sh2.opData.getCalConfig.seq = sh2.nextCmdSeq++;
    
    // set up request to issue
    memset(&req, 0, sizeof(req));
    req.reportId = SENSORHUB_COMMAND_REQ;
    req.seq = sh2.opData.getCalConfig.seq;
    req.command = SH2_CMD_ME_CAL;
    req.p[3] = 0x01;  // Get ME Cal settings
    
    rc = shtp_send(sh2.controlChan, (uint8_t *)&req, sizeof(req));
    opTxDone();

    return rc;
}

static void getCalConfigRx(const uint8_t *payload, uint16_t len)
{
    int rc = SH2_OK;
    CommandResp_t *resp = (CommandResp_t *)payload;
    
    // skip this if it isn't the right response
    if (resp->reportId != SENSORHUB_COMMAND_RESP) return;
    if (resp->command != SH2_CMD_ME_CAL) return;
    if (resp->commandSeq != sh2.opData.getCalConfig.seq) return;

    // If return status is error, return error to invoker
    if (resp->r[0] != 0) {
        rc = SH2_ERR_HUB;
    }

    // Unload results into pSensors
    uint8_t sensors = 0;
    if (resp->r[1]) sensors |= SH2_CAL_ACCEL;
    if (resp->r[2]) sensors |= SH2_CAL_GYRO;
    if (resp->r[3]) sensors |= SH2_CAL_MAG;
    if (resp->r[4]) sensors |= SH2_CAL_PLANAR;
    *(sh2.opData.getCalConfig.pSensors) = sensors;
    
    // Complete this operation
    opCompleted(rc);

    return;
}

// --- Operation: force flush --------------

static int forceFlushStart(void)
{
    int rc = SH2_OK;
    ForceFlushReq_t req;
    
    // set up request to issue
    memset(&req, 0, sizeof(req));
    req.reportId = SENSORHUB_FORCE_SENSOR_FLUSH;
    req.sensorId = sh2.opData.forceFlush.sensorId;
    rc = shtp_send(sh2.controlChan, (uint8_t *)&req, sizeof(req));
    opTxDone();

    return rc;
}

static void forceFlushRx(const uint8_t *payload, uint16_t len)
{
    ForceFlushResp_t *resp = (ForceFlushResp_t *)payload;
    
    // skip this if it isn't the flush completed response for this sensor
    if (resp->reportId != SENSORHUB_FLUSH_COMPLETED) return;
    if (resp->sensorId != sh2.opData.forceFlush.sensorId) return;

    // Complete this operation
    opCompleted(SH2_OK);

    return;
}

// --- Operation: get oscillator type --------------

static int getOscTypeStart(void)
{
    int rc = SH2_OK;
    CommandReq_t req;
    
    // Create a command sequence number for this command
    sh2.opData.getOscType.seq = sh2.nextCmdSeq++;
    
    // set up request to issue
    memset(&req, 0, sizeof(req));
    req.reportId = SENSORHUB_COMMAND_REQ;
    req.seq = sh2.opData.getOscType.seq;
    req.command = SH2_CMD_GET_OSC_TYPE;
    
    rc = shtp_send(sh2.controlChan, (uint8_t *)&req, sizeof(req));
    opTxDone();

    return rc;
}

static void getOscTypeRx(const uint8_t *payload, uint16_t len)
{
    CommandResp_t *resp = (CommandResp_t *)payload;
    sh2_OscType_t *pOscType;
    
    // skip this if it isn't the response we're waiting for.
    if (resp->reportId != SENSORHUB_COMMAND_RESP) return;
    if (resp->command != SH2_CMD_GET_OSC_TYPE) return;
    if (resp->commandSeq != sh2.opData.getOscType.seq) return;

    // Read out data
    pOscType = sh2.opData.getOscType.pOscType;
    *pOscType = (sh2_OscType_t)resp->r[0];

    // Complete this operation
    opCompleted(SH2_OK);

    return;
}

// --- Operation: start calibration --------------

static int startCalStart(void)
{
    int rc = SH2_OK;
    CommandReq_t req;
    
    // Create a command sequence number for this command
    sh2.opData.getOscType.seq = sh2.nextCmdSeq++;
    
    // set up request to issue
    memset(&req, 0, sizeof(req));
    req.reportId = SENSORHUB_COMMAND_REQ;
    req.seq = sh2.opData.startCal.seq;
    req.command = SH2_CMD_CAL;
    req.p[0] = SH2_CAL_START;
    req.p[1] = sh2.opData.startCal.interval_us & 0xFF;          // LSB
    req.p[2] = (sh2.opData.startCal.interval_us >> 8) & 0xFF;
    req.p[3] = (sh2.opData.startCal.interval_us >> 16) & 0xFF;
    req.p[4] = (sh2.opData.startCal.interval_us >> 24) & 0xFF;  // MSB
    
    rc = shtp_send(sh2.controlChan, (uint8_t *)&req, sizeof(req));
    opTxDone();

    return rc;
}

static void startCalRx(const uint8_t *payload, uint16_t len)
{
    CommandResp_t *resp = (CommandResp_t *)payload;
    
    // skip this if it isn't the response we're waiting for.
    if (resp->reportId != SENSORHUB_COMMAND_RESP) return;
    if (resp->command != SH2_CMD_CAL) return;
    if (resp->commandSeq != sh2.opData.startCal.seq) return;

    // Complete this operation
    opCompleted(SH2_OK);

    return;
}

// --- Operation: stop calibration --------------

static int finishCalStart(void)
{
    int rc = SH2_OK;
    CommandReq_t req;
    
    // Create a command sequence number for this command
    sh2.opData.getOscType.seq = sh2.nextCmdSeq++;
    
    // set up request to issue
    memset(&req, 0, sizeof(req));
    req.reportId = SENSORHUB_COMMAND_REQ;
    req.seq = sh2.opData.finishCal.seq;
    req.command = SH2_CMD_CAL;
    req.p[0] = SH2_CAL_FINISH;
    
    rc = shtp_send(sh2.controlChan, (uint8_t *)&req, sizeof(req));
    opTxDone();

    return rc;
}

static void finishCalRx(const uint8_t *payload, uint16_t len)
{
    CommandResp_t *resp = (CommandResp_t *)payload;
    
    // skip this if it isn't the response we're waiting for.
    if (resp->reportId != SENSORHUB_COMMAND_RESP) return;
    if (resp->command != SH2_CMD_CAL) return;
    if (resp->commandSeq != sh2.opData.finishCal.seq) return;

    sh2.opData.finishCal.status = (sh2_CalStatus_t)resp->r[1];

    // Complete this operation
    if (sh2.opData.finishCal.status == SH2_CAL_SUCCESS) {
        opCompleted(SH2_OK);
    }
    else {
        opCompleted(SH2_ERR_HUB);
    }

    return;
}

static void executableAdvertHdlr(void *cookie, uint8_t tag, uint8_t len, uint8_t *val)
{
    switch (tag) {
        default:
            // Ignore unknown tags
            // (And there are no known tags for this app.)
            break;
    }
}

static void executableDeviceHdlr(void *cookie, uint8_t *payload, uint16_t len, uint32_t timestamp)
{
    sh2_AsyncEvent_t event;

    // Discard if length is bad
    if (len != 1) {
        sh2.execBadPayload++;
        return;
    }
    
    switch (payload[0]) {
        case EXECUTABLE_DEVICE_RESP_RESET_COMPLETE:
            // Notify client that reset is complete.
            event.eventId = SH2_RESET;
            if (sh2.eventCallback) {
                sh2.eventCallback(sh2.eventCallbackCookie, &event);
            }
            break;
        default:
            sh2.execBadPayload++;
            break;
    }
}