android13/frameworks/native/services/inputflinger/reader/mapper/SensorInputMapper.h

/*
 * Copyright (C) 2020 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.
 */

#ifndef _UI_INPUTREADER_SENSOR_INPUT_MAPPER_H
#define _UI_INPUTREADER_SENSOR_INPUT_MAPPER_H

#include "InputMapper.h"

namespace android {
// sensor data vector length
static constexpr ssize_t SENSOR_VEC_LEN = 3;

class SensorInputMapper : public InputMapper {
public:
    explicit SensorInputMapper(InputDeviceContext& deviceContext);
    ~SensorInputMapper() override;

    uint32_t getSources() const override;
    void populateDeviceInfo(InputDeviceInfo* deviceInfo) override;
    void dump(std::string& dump) override;
    void configure(nsecs_t when, const InputReaderConfiguration* config, uint32_t changes) override;
    void reset(nsecs_t when) override;
    void process(const RawEvent* rawEvent) override;
    bool enableSensor(InputDeviceSensorType sensorType, std::chrono::microseconds samplingPeriod,
                      std::chrono::microseconds maxBatchReportLatency) override;
    void disableSensor(InputDeviceSensorType sensorType) override;
    void flushSensor(InputDeviceSensorType sensorType) override;

private:
    struct Axis {
        explicit Axis(const RawAbsoluteAxisInfo& rawAxisInfo, const AxisInfo& axisInfo, float scale,
                      float offset, float min, float max, float flat, float fuzz, float resolution,
                      float filter)
              : rawAxisInfo(rawAxisInfo),
                axisInfo(axisInfo),
                scale(scale),
                offset(offset),
                min(min),
                max(max),
                flat(flat),
                fuzz(fuzz),
                resolution(resolution),
                filter(filter) {
            resetValue();
        }

        RawAbsoluteAxisInfo rawAxisInfo;
        AxisInfo axisInfo;

        float scale;  // scale factor from raw to normalized values
        float offset; // offset to add after scaling for normalization

        float min;        // normalized inclusive minimum
        float max;        // normalized inclusive maximum
        float flat;       // normalized flat region size
        float fuzz;       // normalized error tolerance
        float resolution; // normalized resolution in units

        float filter;       // filter out small variations of this size
        float currentValue; // current value
        float newValue;     // most recent value

        void resetValue() {
            this->currentValue = 0;
            this->newValue = 0;
        }
    };

    struct Sensor {
        explicit Sensor(const InputDeviceSensorInfo& sensorInfo) : sensorInfo(sensorInfo) {
            resetValue();
        }
        bool enabled;
        InputDeviceSensorAccuracy accuracy;
        std::chrono::nanoseconds samplingPeriod;
        std::chrono::nanoseconds maxBatchReportLatency;
        // last sample time in nano seconds
        std::optional<nsecs_t> lastSampleTimeNs;
        InputDeviceSensorInfo sensorInfo;
        // Sensor X, Y, Z data mapping to abs
        std::array<int32_t, SENSOR_VEC_LEN> dataVec;
        void resetValue() {
            this->enabled = false;
            this->accuracy = InputDeviceSensorAccuracy::ACCURACY_NONE;
            this->samplingPeriod = std::chrono::nanoseconds(0);
            this->maxBatchReportLatency = std::chrono::nanoseconds(0);
            this->lastSampleTimeNs = std::nullopt;
        }
    };

    static Axis createAxis(const AxisInfo& AxisInfo, const RawAbsoluteAxisInfo& rawAxisInfo);

    // Axes indexed by raw ABS_* axis index.
    std::unordered_map<int32_t, Axis> mAxes;

    // hardware timestamp from MSC_TIMESTAMP
    nsecs_t mHardwareTimestamp;
    uint32_t mPrevMscTime;

    bool mDeviceEnabled;
    // Does device support MSC_TIMESTAMP
    bool mHasHardwareTimestamp;

    // Sensor list
    std::unordered_map<InputDeviceSensorType, Sensor> mSensors;

    void sync(nsecs_t when, bool force);

    template <typename T>
    bool tryGetProperty(std::string keyName, T& outValue);

    void parseSensorConfiguration(InputDeviceSensorType sensorType, int32_t absCode,
                                  int32_t sensorDataIndex, const Axis& axis);

    void processHardWareTimestamp(nsecs_t evTime, int32_t evValue);

    Sensor createSensor(InputDeviceSensorType sensorType, const Axis& axis);

    bool setSensorEnabled(InputDeviceSensorType sensorType, bool enabled);
};

} // namespace android

#endif // _UI_INPUTREADER_SENSOR_INPUT_MAPPER_H
initial 2024-06-22 08:45:49 -04:00			`/*`
			`* Copyright (C) 2020 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.`
			`*/`

			`#ifndef _UI_INPUTREADER_SENSOR_INPUT_MAPPER_H`
			`#define _UI_INPUTREADER_SENSOR_INPUT_MAPPER_H`

			`#include "InputMapper.h"`

			`namespace android {`
			`// sensor data vector length`
			`static constexpr ssize_t SENSOR_VEC_LEN = 3;`

			`class SensorInputMapper : public InputMapper {`
			`public:`
			`explicit SensorInputMapper(InputDeviceContext& deviceContext);`
			`~SensorInputMapper() override;`

			`uint32_t getSources() const override;`
			`void populateDeviceInfo(InputDeviceInfo* deviceInfo) override;`
			`void dump(std::string& dump) override;`
			`void configure(nsecs_t when, const InputReaderConfiguration* config, uint32_t changes) override;`
			`void reset(nsecs_t when) override;`
			`void process(const RawEvent* rawEvent) override;`
			`bool enableSensor(InputDeviceSensorType sensorType, std::chrono::microseconds samplingPeriod,`
			`std::chrono::microseconds maxBatchReportLatency) override;`
			`void disableSensor(InputDeviceSensorType sensorType) override;`
			`void flushSensor(InputDeviceSensorType sensorType) override;`

			`private:`
			`struct Axis {`
			`explicit Axis(const RawAbsoluteAxisInfo& rawAxisInfo, const AxisInfo& axisInfo, float scale,`
			`float offset, float min, float max, float flat, float fuzz, float resolution,`
			`float filter)`
			`: rawAxisInfo(rawAxisInfo),`
			`axisInfo(axisInfo),`
			`scale(scale),`
			`offset(offset),`
			`min(min),`
			`max(max),`
			`flat(flat),`
			`fuzz(fuzz),`
			`resolution(resolution),`
			`filter(filter) {`
			`resetValue();`
			`}`

			`RawAbsoluteAxisInfo rawAxisInfo;`
			`AxisInfo axisInfo;`

			`float scale; // scale factor from raw to normalized values`
			`float offset; // offset to add after scaling for normalization`

			`float min; // normalized inclusive minimum`
			`float max; // normalized inclusive maximum`
			`float flat; // normalized flat region size`
			`float fuzz; // normalized error tolerance`
			`float resolution; // normalized resolution in units`

			`float filter; // filter out small variations of this size`
			`float currentValue; // current value`
			`float newValue; // most recent value`

			`void resetValue() {`
			`this->currentValue = 0;`
			`this->newValue = 0;`
			`}`
			`};`

			`struct Sensor {`
			`explicit Sensor(const InputDeviceSensorInfo& sensorInfo) : sensorInfo(sensorInfo) {`
			`resetValue();`
			`}`
			`bool enabled;`
			`InputDeviceSensorAccuracy accuracy;`
			`std::chrono::nanoseconds samplingPeriod;`
			`std::chrono::nanoseconds maxBatchReportLatency;`
			`// last sample time in nano seconds`
			`std::optional<nsecs_t> lastSampleTimeNs;`
			`InputDeviceSensorInfo sensorInfo;`
			`// Sensor X, Y, Z data mapping to abs`
			`std::array<int32_t, SENSOR_VEC_LEN> dataVec;`
			`void resetValue() {`
			`this->enabled = false;`
			`this->accuracy = InputDeviceSensorAccuracy::ACCURACY_NONE;`
			`this->samplingPeriod = std::chrono::nanoseconds(0);`
			`this->maxBatchReportLatency = std::chrono::nanoseconds(0);`
			`this->lastSampleTimeNs = std::nullopt;`
			`}`
			`};`

			`static Axis createAxis(const AxisInfo& AxisInfo, const RawAbsoluteAxisInfo& rawAxisInfo);`

			`// Axes indexed by raw ABS_* axis index.`
			`std::unordered_map<int32_t, Axis> mAxes;`

			`// hardware timestamp from MSC_TIMESTAMP`
			`nsecs_t mHardwareTimestamp;`
			`uint32_t mPrevMscTime;`

			`bool mDeviceEnabled;`
			`// Does device support MSC_TIMESTAMP`
			`bool mHasHardwareTimestamp;`

			`// Sensor list`
			`std::unordered_map<InputDeviceSensorType, Sensor> mSensors;`

			`void sync(nsecs_t when, bool force);`

			`template <typename T>`
			`bool tryGetProperty(std::string keyName, T& outValue);`

			`void parseSensorConfiguration(InputDeviceSensorType sensorType, int32_t absCode,`
			`int32_t sensorDataIndex, const Axis& axis);`

			`void processHardWareTimestamp(nsecs_t evTime, int32_t evValue);`

			`Sensor createSensor(InputDeviceSensorType sensorType, const Axis& axis);`

			`bool setSensorEnabled(InputDeviceSensorType sensorType, bool enabled);`
			`};`

			`} // namespace android`

			`#endif // _UI_INPUTREADER_SENSOR_INPUT_MAPPER_H`