/*
* Copyright (C) 2016 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* 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.
*/
#include <stdlib.h>
#include <string.h>
#include <float.h>
#include <eventnums.h>
#include <gpio.h>
#include <heap.h>
#include <hostIntf.h>
#include <isr.h>
#include <nanohubPacket.h>
#include <sensors.h>
#include <seos.h>
#include <timer.h>
#include <plat/gpio.h>
#include <plat/exti.h>
#include <plat/syscfg.h>
#include <variant/variant.h>
#define APP_VERSION 2
#define HALL_REPORT_OPENED_VALUE 0
#define HALL_REPORT_CLOSED_VALUE 1
#define HALL_DEBOUNCE_TIMER_DELAY 25000000ULL // 25 milliseconds
#ifndef HALL_PIN
#error "HALL_PIN is not defined; please define in variant.h"
#endif
#ifndef HALL_IRQ
#error "HALL_IRQ is not defined; please define in variant.h"
#endif
static struct SensorTask
{
struct Gpio *pin;
struct ChainedIsr isr;
uint32_t id;
uint32_t sensorHandle;
uint32_t debounceTimerHandle;
int32_t prevReportedValue;
bool on;
} mTask;
static void debounceTimerCallback(uint32_t timerId, void *cookie)
{
union EmbeddedDataPoint sample;
bool prevPinState = (bool)cookie;
bool pinState = gpioGet(mTask.pin);
if (mTask.on) {
if (pinState == prevPinState) {
sample.idata = pinState ? HALL_REPORT_OPENED_VALUE :
HALL_REPORT_CLOSED_VALUE;
if (sample.idata != mTask.prevReportedValue) {
mTask.prevReportedValue = sample.idata;
osEnqueueEvt(sensorGetMyEventType(SENS_TYPE_HALL), sample.vptr, NULL);
}
}
}
}
static bool hallIsr(struct ChainedIsr *localIsr)
{
struct SensorTask *data = container_of(localIsr, struct SensorTask, isr);
bool pinState = gpioGet(data->pin);
if (!extiIsPendingGpio(data->pin)) {
return false;
}
if (data->on) {
if (mTask.debounceTimerHandle)
timTimerCancel(mTask.debounceTimerHandle);
mTask.debounceTimerHandle = timTimerSet(HALL_DEBOUNCE_TIMER_DELAY, 0, 50, debounceTimerCallback, (void*)pinState, true /* oneShot */);
}
extiClearPendingGpio(data->pin);
return true;
}
static bool enableInterrupt(struct Gpio *pin, struct ChainedIsr *isr)
{
gpioConfigInput(pin, GPIO_SPEED_LOW, GPIO_PULL_NONE);
syscfgSetExtiPort(pin);
extiEnableIntGpio(pin, EXTI_TRIGGER_BOTH);
extiChainIsr(HALL_IRQ, isr);
return true;
}
static bool disableInterrupt(struct Gpio *pin, struct ChainedIsr *isr)
{
extiUnchainIsr(HALL_IRQ, isr);
extiDisableIntGpio(pin);
return true;
}
static const uint32_t supportedRates[] =
{
SENSOR_RATE_ONCHANGE,
0
};
static const struct SensorInfo mSensorInfo =
{
.sensorName = "Hall",
.supportedRates = supportedRates,
.sensorType = SENS_TYPE_HALL,
.numAxis = NUM_AXIS_EMBEDDED,
.interrupt = NANOHUB_INT_WAKEUP,
.minSamples = 20
};
static bool hallPower(bool on, void *cookie)
{
if (on) {
extiClearPendingGpio(mTask.pin);
enableInterrupt(mTask.pin, &mTask.isr);
} else {
disableInterrupt(mTask.pin, &mTask.isr);
extiClearPendingGpio(mTask.pin);
}
mTask.on = on;
mTask.prevReportedValue = -1;
if (mTask.debounceTimerHandle) {
timTimerCancel(mTask.debounceTimerHandle);
mTask.debounceTimerHandle = 0;
}
return sensorSignalInternalEvt(mTask.sensorHandle, SENSOR_INTERNAL_EVT_POWER_STATE_CHG, on, 0);
}
static bool hallFirmwareUpload(void *cookie)
{
return sensorSignalInternalEvt(mTask.sensorHandle, SENSOR_INTERNAL_EVT_FW_STATE_CHG, 1, 0);
}
static bool hallSetRate(uint32_t rate, uint64_t latency, void *cookie)
{
// report initial state of hall interrupt pin
if (mTask.on) {
union EmbeddedDataPoint sample;
bool pinState = gpioGet(mTask.pin);
sample.idata = pinState ? HALL_REPORT_OPENED_VALUE :
HALL_REPORT_CLOSED_VALUE;
osEnqueueEvt(sensorGetMyEventType(SENS_TYPE_HALL), sample.vptr, NULL);
}
return sensorSignalInternalEvt(mTask.sensorHandle, SENSOR_INTERNAL_EVT_RATE_CHG, rate, latency);
}
static bool hallFlush(void *cookie)
{
return osEnqueueEvt(sensorGetMyEventType(SENS_TYPE_HALL), SENSOR_DATA_EVENT_FLUSH, NULL);
}
static bool hallSendLastSample(void *cookie, uint32_t tid)
{
union EmbeddedDataPoint sample;
bool result = true;
if (mTask.prevReportedValue != -1) {
sample.idata = mTask.prevReportedValue;
result = osEnqueuePrivateEvt(sensorGetMyEventType(SENS_TYPE_HALL), sample.vptr, NULL, tid);
}
return result;
}
static const struct SensorOps mSensorOps =
{
.sensorPower = hallPower,
.sensorFirmwareUpload = hallFirmwareUpload,
.sensorSetRate = hallSetRate,
.sensorFlush = hallFlush,
.sensorSendOneDirectEvt = hallSendLastSample
};
static void handleEvent(uint32_t evtType, const void* evtData)
{
}
static bool startTask(uint32_t taskId)
{
mTask.id = taskId;
mTask.sensorHandle = sensorRegister(&mSensorInfo, &mSensorOps, NULL, true);
mTask.prevReportedValue = -1;
mTask.pin = gpioRequest(HALL_PIN);
mTask.isr.func = hallIsr;
return true;
}
static void endTask(void)
{
disableInterrupt(mTask.pin, &mTask.isr);
extiUnchainIsr(HALL_IRQ, &mTask.isr);
extiClearPendingGpio(mTask.pin);
gpioRelease(mTask.pin);
sensorUnregister(mTask.sensorHandle);
}
INTERNAL_APP_INIT(APP_ID_MAKE(NANOHUB_VENDOR_GOOGLE, 6), APP_VERSION, startTask, endTask, handleEvent);