Home | History | Annotate | Download | only in ui
      1 /*
      2  * Copyright (C) 2010 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 #ifndef _UI_INPUT_H
     18 #define _UI_INPUT_H
     19 
     20 /**
     21  * Native input event structures.
     22  */
     23 
     24 #include <android/input.h>
     25 #include <utils/Vector.h>
     26 #include <utils/KeyedVector.h>
     27 #include <utils/Timers.h>
     28 #include <utils/RefBase.h>
     29 #include <utils/String8.h>
     30 #include <utils/BitSet.h>
     31 
     32 #ifdef HAVE_ANDROID_OS
     33 class SkMatrix;
     34 #endif
     35 
     36 /*
     37  * Additional private constants not defined in ndk/ui/input.h.
     38  */
     39 enum {
     40     /* Private control to determine when an app is tracking a key sequence. */
     41     AKEY_EVENT_FLAG_START_TRACKING = 0x40000000,
     42 
     43     /* Key event is inconsistent with previously sent key events. */
     44     AKEY_EVENT_FLAG_TAINTED = 0x80000000,
     45 };
     46 
     47 enum {
     48     /* Motion event is inconsistent with previously sent motion events. */
     49     AMOTION_EVENT_FLAG_TAINTED = 0x80000000,
     50 };
     51 
     52 enum {
     53     /*
     54      * Indicates that an input device has switches.
     55      * This input source flag is hidden from the API because switches are only used by the system
     56      * and applications have no way to interact with them.
     57      */
     58     AINPUT_SOURCE_SWITCH = 0x80000000,
     59 };
     60 
     61 /*
     62  * SystemUiVisibility constants from View.
     63  */
     64 enum {
     65     ASYSTEM_UI_VISIBILITY_STATUS_BAR_VISIBLE = 0,
     66     ASYSTEM_UI_VISIBILITY_STATUS_BAR_HIDDEN = 0x00000001,
     67 };
     68 
     69 /*
     70  * Maximum number of pointers supported per motion event.
     71  * Smallest number of pointers is 1.
     72  * (We want at least 10 but some touch controllers obstensibly configured for 10 pointers
     73  * will occasionally emit 11.  There is not much harm making this constant bigger.)
     74  */
     75 #define MAX_POINTERS 16
     76 
     77 /*
     78  * Maximum pointer id value supported in a motion event.
     79  * Smallest pointer id is 0.
     80  * (This is limited by our use of BitSet32 to track pointer assignments.)
     81  */
     82 #define MAX_POINTER_ID 31
     83 
     84 /*
     85  * Declare a concrete type for the NDK's input event forward declaration.
     86  */
     87 struct AInputEvent {
     88     virtual ~AInputEvent() { }
     89 };
     90 
     91 /*
     92  * Declare a concrete type for the NDK's input device forward declaration.
     93  */
     94 struct AInputDevice {
     95     virtual ~AInputDevice() { }
     96 };
     97 
     98 
     99 namespace android {
    100 
    101 #ifdef HAVE_ANDROID_OS
    102 class Parcel;
    103 #endif
    104 
    105 /*
    106  * Flags that flow alongside events in the input dispatch system to help with certain
    107  * policy decisions such as waking from device sleep.
    108  *
    109  * These flags are also defined in frameworks/base/core/java/android/view/WindowManagerPolicy.java.
    110  */
    111 enum {
    112     /* These flags originate in RawEvents and are generally set in the key map.
    113      * NOTE: If you edit these flags, also edit labels in KeycodeLabels.h. */
    114 
    115     POLICY_FLAG_WAKE = 0x00000001,
    116     POLICY_FLAG_WAKE_DROPPED = 0x00000002,
    117     POLICY_FLAG_SHIFT = 0x00000004,
    118     POLICY_FLAG_CAPS_LOCK = 0x00000008,
    119     POLICY_FLAG_ALT = 0x00000010,
    120     POLICY_FLAG_ALT_GR = 0x00000020,
    121     POLICY_FLAG_MENU = 0x00000040,
    122     POLICY_FLAG_LAUNCHER = 0x00000080,
    123     POLICY_FLAG_VIRTUAL = 0x00000100,
    124     POLICY_FLAG_FUNCTION = 0x00000200,
    125 
    126     POLICY_FLAG_RAW_MASK = 0x0000ffff,
    127 
    128     /* These flags are set by the input dispatcher. */
    129 
    130     // Indicates that the input event was injected.
    131     POLICY_FLAG_INJECTED = 0x01000000,
    132 
    133     // Indicates that the input event is from a trusted source such as a directly attached
    134     // input device or an application with system-wide event injection permission.
    135     POLICY_FLAG_TRUSTED = 0x02000000,
    136 
    137     // Indicates that the input event has passed through an input filter.
    138     POLICY_FLAG_FILTERED = 0x04000000,
    139 
    140     // Disables automatic key repeating behavior.
    141     POLICY_FLAG_DISABLE_KEY_REPEAT = 0x08000000,
    142 
    143     /* These flags are set by the input reader policy as it intercepts each event. */
    144 
    145     // Indicates that the screen was off when the event was received and the event
    146     // should wake the device.
    147     POLICY_FLAG_WOKE_HERE = 0x10000000,
    148 
    149     // Indicates that the screen was dim when the event was received and the event
    150     // should brighten the device.
    151     POLICY_FLAG_BRIGHT_HERE = 0x20000000,
    152 
    153     // Indicates that the event should be dispatched to applications.
    154     // The input event should still be sent to the InputDispatcher so that it can see all
    155     // input events received include those that it will not deliver.
    156     POLICY_FLAG_PASS_TO_USER = 0x40000000,
    157 };
    158 
    159 /*
    160  * Describes the basic configuration of input devices that are present.
    161  */
    162 struct InputConfiguration {
    163     enum {
    164         TOUCHSCREEN_UNDEFINED = 0,
    165         TOUCHSCREEN_NOTOUCH = 1,
    166         TOUCHSCREEN_STYLUS = 2,
    167         TOUCHSCREEN_FINGER = 3
    168     };
    169 
    170     enum {
    171         KEYBOARD_UNDEFINED = 0,
    172         KEYBOARD_NOKEYS = 1,
    173         KEYBOARD_QWERTY = 2,
    174         KEYBOARD_12KEY = 3
    175     };
    176 
    177     enum {
    178         NAVIGATION_UNDEFINED = 0,
    179         NAVIGATION_NONAV = 1,
    180         NAVIGATION_DPAD = 2,
    181         NAVIGATION_TRACKBALL = 3,
    182         NAVIGATION_WHEEL = 4
    183     };
    184 
    185     int32_t touchScreen;
    186     int32_t keyboard;
    187     int32_t navigation;
    188 };
    189 
    190 /*
    191  * Pointer coordinate data.
    192  */
    193 struct PointerCoords {
    194     enum { MAX_AXES = 14 }; // 14 so that sizeof(PointerCoords) == 64
    195 
    196     // Bitfield of axes that are present in this structure.
    197     uint64_t bits;
    198 
    199     // Values of axes that are stored in this structure packed in order by axis id
    200     // for each axis that is present in the structure according to 'bits'.
    201     float values[MAX_AXES];
    202 
    203     inline void clear() {
    204         bits = 0;
    205     }
    206 
    207     float getAxisValue(int32_t axis) const;
    208     status_t setAxisValue(int32_t axis, float value);
    209 
    210     void scale(float scale);
    211 
    212     inline float getX() const {
    213         return getAxisValue(AMOTION_EVENT_AXIS_X);
    214     }
    215 
    216     inline float getY() const {
    217         return getAxisValue(AMOTION_EVENT_AXIS_Y);
    218     }
    219 
    220 #ifdef HAVE_ANDROID_OS
    221     status_t readFromParcel(Parcel* parcel);
    222     status_t writeToParcel(Parcel* parcel) const;
    223 #endif
    224 
    225     bool operator==(const PointerCoords& other) const;
    226     inline bool operator!=(const PointerCoords& other) const {
    227         return !(*this == other);
    228     }
    229 
    230     void copyFrom(const PointerCoords& other);
    231 
    232 private:
    233     void tooManyAxes(int axis);
    234 };
    235 
    236 /*
    237  * Pointer property data.
    238  */
    239 struct PointerProperties {
    240     // The id of the pointer.
    241     int32_t id;
    242 
    243     // The pointer tool type.
    244     int32_t toolType;
    245 
    246     inline void clear() {
    247         id = -1;
    248         toolType = 0;
    249     }
    250 
    251     bool operator==(const PointerProperties& other) const;
    252     inline bool operator!=(const PointerProperties& other) const {
    253         return !(*this == other);
    254     }
    255 
    256     void copyFrom(const PointerProperties& other);
    257 };
    258 
    259 /*
    260  * Input events.
    261  */
    262 class InputEvent : public AInputEvent {
    263 public:
    264     virtual ~InputEvent() { }
    265 
    266     virtual int32_t getType() const = 0;
    267 
    268     inline int32_t getDeviceId() const { return mDeviceId; }
    269 
    270     inline int32_t getSource() const { return mSource; }
    271 
    272     inline void setSource(int32_t source) { mSource = source; }
    273 
    274 protected:
    275     void initialize(int32_t deviceId, int32_t source);
    276     void initialize(const InputEvent& from);
    277 
    278     int32_t mDeviceId;
    279     int32_t mSource;
    280 };
    281 
    282 /*
    283  * Key events.
    284  */
    285 class KeyEvent : public InputEvent {
    286 public:
    287     virtual ~KeyEvent() { }
    288 
    289     virtual int32_t getType() const { return AINPUT_EVENT_TYPE_KEY; }
    290 
    291     inline int32_t getAction() const { return mAction; }
    292 
    293     inline int32_t getFlags() const { return mFlags; }
    294 
    295     inline int32_t getKeyCode() const { return mKeyCode; }
    296 
    297     inline int32_t getScanCode() const { return mScanCode; }
    298 
    299     inline int32_t getMetaState() const { return mMetaState; }
    300 
    301     inline int32_t getRepeatCount() const { return mRepeatCount; }
    302 
    303     inline nsecs_t getDownTime() const { return mDownTime; }
    304 
    305     inline nsecs_t getEventTime() const { return mEventTime; }
    306 
    307     // Return true if this event may have a default action implementation.
    308     static bool hasDefaultAction(int32_t keyCode);
    309     bool hasDefaultAction() const;
    310 
    311     // Return true if this event represents a system key.
    312     static bool isSystemKey(int32_t keyCode);
    313     bool isSystemKey() const;
    314 
    315     void initialize(
    316             int32_t deviceId,
    317             int32_t source,
    318             int32_t action,
    319             int32_t flags,
    320             int32_t keyCode,
    321             int32_t scanCode,
    322             int32_t metaState,
    323             int32_t repeatCount,
    324             nsecs_t downTime,
    325             nsecs_t eventTime);
    326     void initialize(const KeyEvent& from);
    327 
    328 protected:
    329     int32_t mAction;
    330     int32_t mFlags;
    331     int32_t mKeyCode;
    332     int32_t mScanCode;
    333     int32_t mMetaState;
    334     int32_t mRepeatCount;
    335     nsecs_t mDownTime;
    336     nsecs_t mEventTime;
    337 };
    338 
    339 /*
    340  * Motion events.
    341  */
    342 class MotionEvent : public InputEvent {
    343 public:
    344     virtual ~MotionEvent() { }
    345 
    346     virtual int32_t getType() const { return AINPUT_EVENT_TYPE_MOTION; }
    347 
    348     inline int32_t getAction() const { return mAction; }
    349 
    350     inline int32_t getActionMasked() const { return mAction & AMOTION_EVENT_ACTION_MASK; }
    351 
    352     inline int32_t getActionIndex() const {
    353         return (mAction & AMOTION_EVENT_ACTION_POINTER_INDEX_MASK)
    354                 >> AMOTION_EVENT_ACTION_POINTER_INDEX_SHIFT;
    355     }
    356 
    357     inline void setAction(int32_t action) { mAction = action; }
    358 
    359     inline int32_t getFlags() const { return mFlags; }
    360 
    361     inline void setFlags(int32_t flags) { mFlags = flags; }
    362 
    363     inline int32_t getEdgeFlags() const { return mEdgeFlags; }
    364 
    365     inline void setEdgeFlags(int32_t edgeFlags) { mEdgeFlags = edgeFlags; }
    366 
    367     inline int32_t getMetaState() const { return mMetaState; }
    368 
    369     inline void setMetaState(int32_t metaState) { mMetaState = metaState; }
    370 
    371     inline int32_t getButtonState() const { return mButtonState; }
    372 
    373     inline float getXOffset() const { return mXOffset; }
    374 
    375     inline float getYOffset() const { return mYOffset; }
    376 
    377     inline float getXPrecision() const { return mXPrecision; }
    378 
    379     inline float getYPrecision() const { return mYPrecision; }
    380 
    381     inline nsecs_t getDownTime() const { return mDownTime; }
    382 
    383     inline void setDownTime(nsecs_t downTime) { mDownTime = downTime; }
    384 
    385     inline size_t getPointerCount() const { return mPointerProperties.size(); }
    386 
    387     inline const PointerProperties* getPointerProperties(size_t pointerIndex) const {
    388         return &mPointerProperties[pointerIndex];
    389     }
    390 
    391     inline int32_t getPointerId(size_t pointerIndex) const {
    392         return mPointerProperties[pointerIndex].id;
    393     }
    394 
    395     inline int32_t getToolType(size_t pointerIndex) const {
    396         return mPointerProperties[pointerIndex].toolType;
    397     }
    398 
    399     inline nsecs_t getEventTime() const { return mSampleEventTimes[getHistorySize()]; }
    400 
    401     const PointerCoords* getRawPointerCoords(size_t pointerIndex) const;
    402 
    403     float getRawAxisValue(int32_t axis, size_t pointerIndex) const;
    404 
    405     inline float getRawX(size_t pointerIndex) const {
    406         return getRawAxisValue(AMOTION_EVENT_AXIS_X, pointerIndex);
    407     }
    408 
    409     inline float getRawY(size_t pointerIndex) const {
    410         return getRawAxisValue(AMOTION_EVENT_AXIS_Y, pointerIndex);
    411     }
    412 
    413     float getAxisValue(int32_t axis, size_t pointerIndex) const;
    414 
    415     inline float getX(size_t pointerIndex) const {
    416         return getAxisValue(AMOTION_EVENT_AXIS_X, pointerIndex);
    417     }
    418 
    419     inline float getY(size_t pointerIndex) const {
    420         return getAxisValue(AMOTION_EVENT_AXIS_Y, pointerIndex);
    421     }
    422 
    423     inline float getPressure(size_t pointerIndex) const {
    424         return getAxisValue(AMOTION_EVENT_AXIS_PRESSURE, pointerIndex);
    425     }
    426 
    427     inline float getSize(size_t pointerIndex) const {
    428         return getAxisValue(AMOTION_EVENT_AXIS_SIZE, pointerIndex);
    429     }
    430 
    431     inline float getTouchMajor(size_t pointerIndex) const {
    432         return getAxisValue(AMOTION_EVENT_AXIS_TOUCH_MAJOR, pointerIndex);
    433     }
    434 
    435     inline float getTouchMinor(size_t pointerIndex) const {
    436         return getAxisValue(AMOTION_EVENT_AXIS_TOUCH_MINOR, pointerIndex);
    437     }
    438 
    439     inline float getToolMajor(size_t pointerIndex) const {
    440         return getAxisValue(AMOTION_EVENT_AXIS_TOOL_MAJOR, pointerIndex);
    441     }
    442 
    443     inline float getToolMinor(size_t pointerIndex) const {
    444         return getAxisValue(AMOTION_EVENT_AXIS_TOOL_MINOR, pointerIndex);
    445     }
    446 
    447     inline float getOrientation(size_t pointerIndex) const {
    448         return getAxisValue(AMOTION_EVENT_AXIS_ORIENTATION, pointerIndex);
    449     }
    450 
    451     inline size_t getHistorySize() const { return mSampleEventTimes.size() - 1; }
    452 
    453     inline nsecs_t getHistoricalEventTime(size_t historicalIndex) const {
    454         return mSampleEventTimes[historicalIndex];
    455     }
    456 
    457     const PointerCoords* getHistoricalRawPointerCoords(
    458             size_t pointerIndex, size_t historicalIndex) const;
    459 
    460     float getHistoricalRawAxisValue(int32_t axis, size_t pointerIndex,
    461             size_t historicalIndex) const;
    462 
    463     inline float getHistoricalRawX(size_t pointerIndex, size_t historicalIndex) const {
    464         return getHistoricalRawAxisValue(
    465                 AMOTION_EVENT_AXIS_X, pointerIndex, historicalIndex);
    466     }
    467 
    468     inline float getHistoricalRawY(size_t pointerIndex, size_t historicalIndex) const {
    469         return getHistoricalRawAxisValue(
    470                 AMOTION_EVENT_AXIS_Y, pointerIndex, historicalIndex);
    471     }
    472 
    473     float getHistoricalAxisValue(int32_t axis, size_t pointerIndex, size_t historicalIndex) const;
    474 
    475     inline float getHistoricalX(size_t pointerIndex, size_t historicalIndex) const {
    476         return getHistoricalAxisValue(
    477                 AMOTION_EVENT_AXIS_X, pointerIndex, historicalIndex);
    478     }
    479 
    480     inline float getHistoricalY(size_t pointerIndex, size_t historicalIndex) const {
    481         return getHistoricalAxisValue(
    482                 AMOTION_EVENT_AXIS_Y, pointerIndex, historicalIndex);
    483     }
    484 
    485     inline float getHistoricalPressure(size_t pointerIndex, size_t historicalIndex) const {
    486         return getHistoricalAxisValue(
    487                 AMOTION_EVENT_AXIS_PRESSURE, pointerIndex, historicalIndex);
    488     }
    489 
    490     inline float getHistoricalSize(size_t pointerIndex, size_t historicalIndex) const {
    491         return getHistoricalAxisValue(
    492                 AMOTION_EVENT_AXIS_SIZE, pointerIndex, historicalIndex);
    493     }
    494 
    495     inline float getHistoricalTouchMajor(size_t pointerIndex, size_t historicalIndex) const {
    496         return getHistoricalAxisValue(
    497                 AMOTION_EVENT_AXIS_TOUCH_MAJOR, pointerIndex, historicalIndex);
    498     }
    499 
    500     inline float getHistoricalTouchMinor(size_t pointerIndex, size_t historicalIndex) const {
    501         return getHistoricalAxisValue(
    502                 AMOTION_EVENT_AXIS_TOUCH_MINOR, pointerIndex, historicalIndex);
    503     }
    504 
    505     inline float getHistoricalToolMajor(size_t pointerIndex, size_t historicalIndex) const {
    506         return getHistoricalAxisValue(
    507                 AMOTION_EVENT_AXIS_TOOL_MAJOR, pointerIndex, historicalIndex);
    508     }
    509 
    510     inline float getHistoricalToolMinor(size_t pointerIndex, size_t historicalIndex) const {
    511         return getHistoricalAxisValue(
    512                 AMOTION_EVENT_AXIS_TOOL_MINOR, pointerIndex, historicalIndex);
    513     }
    514 
    515     inline float getHistoricalOrientation(size_t pointerIndex, size_t historicalIndex) const {
    516         return getHistoricalAxisValue(
    517                 AMOTION_EVENT_AXIS_ORIENTATION, pointerIndex, historicalIndex);
    518     }
    519 
    520     ssize_t findPointerIndex(int32_t pointerId) const;
    521 
    522     void initialize(
    523             int32_t deviceId,
    524             int32_t source,
    525             int32_t action,
    526             int32_t flags,
    527             int32_t edgeFlags,
    528             int32_t metaState,
    529             int32_t buttonState,
    530             float xOffset,
    531             float yOffset,
    532             float xPrecision,
    533             float yPrecision,
    534             nsecs_t downTime,
    535             nsecs_t eventTime,
    536             size_t pointerCount,
    537             const PointerProperties* pointerProperties,
    538             const PointerCoords* pointerCoords);
    539 
    540     void copyFrom(const MotionEvent* other, bool keepHistory);
    541 
    542     void addSample(
    543             nsecs_t eventTime,
    544             const PointerCoords* pointerCoords);
    545 
    546     void offsetLocation(float xOffset, float yOffset);
    547 
    548     void scale(float scaleFactor);
    549 
    550 #ifdef HAVE_ANDROID_OS
    551     void transform(const SkMatrix* matrix);
    552 
    553     status_t readFromParcel(Parcel* parcel);
    554     status_t writeToParcel(Parcel* parcel) const;
    555 #endif
    556 
    557     static bool isTouchEvent(int32_t source, int32_t action);
    558     inline bool isTouchEvent() const {
    559         return isTouchEvent(mSource, mAction);
    560     }
    561 
    562     // Low-level accessors.
    563     inline const PointerProperties* getPointerProperties() const {
    564         return mPointerProperties.array();
    565     }
    566     inline const nsecs_t* getSampleEventTimes() const { return mSampleEventTimes.array(); }
    567     inline const PointerCoords* getSamplePointerCoords() const {
    568             return mSamplePointerCoords.array();
    569     }
    570 
    571 protected:
    572     int32_t mAction;
    573     int32_t mFlags;
    574     int32_t mEdgeFlags;
    575     int32_t mMetaState;
    576     int32_t mButtonState;
    577     float mXOffset;
    578     float mYOffset;
    579     float mXPrecision;
    580     float mYPrecision;
    581     nsecs_t mDownTime;
    582     Vector<PointerProperties> mPointerProperties;
    583     Vector<nsecs_t> mSampleEventTimes;
    584     Vector<PointerCoords> mSamplePointerCoords;
    585 };
    586 
    587 /*
    588  * Input event factory.
    589  */
    590 class InputEventFactoryInterface {
    591 protected:
    592     virtual ~InputEventFactoryInterface() { }
    593 
    594 public:
    595     InputEventFactoryInterface() { }
    596 
    597     virtual KeyEvent* createKeyEvent() = 0;
    598     virtual MotionEvent* createMotionEvent() = 0;
    599 };
    600 
    601 /*
    602  * A simple input event factory implementation that uses a single preallocated instance
    603  * of each type of input event that are reused for each request.
    604  */
    605 class PreallocatedInputEventFactory : public InputEventFactoryInterface {
    606 public:
    607     PreallocatedInputEventFactory() { }
    608     virtual ~PreallocatedInputEventFactory() { }
    609 
    610     virtual KeyEvent* createKeyEvent() { return & mKeyEvent; }
    611     virtual MotionEvent* createMotionEvent() { return & mMotionEvent; }
    612 
    613 private:
    614     KeyEvent mKeyEvent;
    615     MotionEvent mMotionEvent;
    616 };
    617 
    618 /*
    619  * Calculates the velocity of pointer movements over time.
    620  */
    621 class VelocityTracker {
    622 public:
    623     // Default polynomial degree.  (used by getVelocity)
    624     static const uint32_t DEFAULT_DEGREE = 2;
    625 
    626     // Default sample horizon.  (used by getVelocity)
    627     // We don't use too much history by default since we want to react to quick
    628     // changes in direction.
    629     static const nsecs_t DEFAULT_HORIZON = 100 * 1000000; // 100 ms
    630 
    631     struct Position {
    632         float x, y;
    633     };
    634 
    635     struct Estimator {
    636         static const size_t MAX_DEGREE = 2;
    637 
    638         // Polynomial coefficients describing motion in X and Y.
    639         float xCoeff[MAX_DEGREE + 1], yCoeff[MAX_DEGREE + 1];
    640 
    641         // Polynomial degree (number of coefficients), or zero if no information is
    642         // available.
    643         uint32_t degree;
    644 
    645         // Confidence (coefficient of determination), between 0 (no fit) and 1 (perfect fit).
    646         float confidence;
    647 
    648         inline void clear() {
    649             degree = 0;
    650             confidence = 0;
    651             for (size_t i = 0; i <= MAX_DEGREE; i++) {
    652                 xCoeff[i] = 0;
    653                 yCoeff[i] = 0;
    654             }
    655         }
    656     };
    657 
    658     VelocityTracker();
    659 
    660     // Resets the velocity tracker state.
    661     void clear();
    662 
    663     // Resets the velocity tracker state for specific pointers.
    664     // Call this method when some pointers have changed and may be reusing
    665     // an id that was assigned to a different pointer earlier.
    666     void clearPointers(BitSet32 idBits);
    667 
    668     // Adds movement information for a set of pointers.
    669     // The idBits bitfield specifies the pointer ids of the pointers whose positions
    670     // are included in the movement.
    671     // The positions array contains position information for each pointer in order by
    672     // increasing id.  Its size should be equal to the number of one bits in idBits.
    673     void addMovement(nsecs_t eventTime, BitSet32 idBits, const Position* positions);
    674 
    675     // Adds movement information for all pointers in a MotionEvent, including historical samples.
    676     void addMovement(const MotionEvent* event);
    677 
    678     // Gets the velocity of the specified pointer id in position units per second.
    679     // Returns false and sets the velocity components to zero if there is
    680     // insufficient movement information for the pointer.
    681     bool getVelocity(uint32_t id, float* outVx, float* outVy) const;
    682 
    683     // Gets a quadratic estimator for the movements of the specified pointer id.
    684     // Returns false and clears the estimator if there is no information available
    685     // about the pointer.
    686     bool getEstimator(uint32_t id, uint32_t degree, nsecs_t horizon,
    687             Estimator* outEstimator) const;
    688 
    689     // Gets the active pointer id, or -1 if none.
    690     inline int32_t getActivePointerId() const { return mActivePointerId; }
    691 
    692     // Gets a bitset containing all pointer ids from the most recent movement.
    693     inline BitSet32 getCurrentPointerIdBits() const { return mMovements[mIndex].idBits; }
    694 
    695 private:
    696     // Number of samples to keep.
    697     static const uint32_t HISTORY_SIZE = 20;
    698 
    699     struct Movement {
    700         nsecs_t eventTime;
    701         BitSet32 idBits;
    702         Position positions[MAX_POINTERS];
    703 
    704         inline const Position& getPosition(uint32_t id) const {
    705             return positions[idBits.getIndexOfBit(id)];
    706         }
    707     };
    708 
    709     uint32_t mIndex;
    710     Movement mMovements[HISTORY_SIZE];
    711     int32_t mActivePointerId;
    712 };
    713 
    714 
    715 /*
    716  * Specifies parameters that govern pointer or wheel acceleration.
    717  */
    718 struct VelocityControlParameters {
    719     // A scale factor that is multiplied with the raw velocity deltas
    720     // prior to applying any other velocity control factors.  The scale
    721     // factor should be used to adapt the input device resolution
    722     // (eg. counts per inch) to the output device resolution (eg. pixels per inch).
    723     //
    724     // Must be a positive value.
    725     // Default is 1.0 (no scaling).
    726     float scale;
    727 
    728     // The scaled speed at which acceleration begins to be applied.
    729     // This value establishes the upper bound of a low speed regime for
    730     // small precise motions that are performed without any acceleration.
    731     //
    732     // Must be a non-negative value.
    733     // Default is 0.0 (no low threshold).
    734     float lowThreshold;
    735 
    736     // The scaled speed at which maximum acceleration is applied.
    737     // The difference between highThreshold and lowThreshold controls
    738     // the range of speeds over which the acceleration factor is interpolated.
    739     // The wider the range, the smoother the acceleration.
    740     //
    741     // Must be a non-negative value greater than or equal to lowThreshold.
    742     // Default is 0.0 (no high threshold).
    743     float highThreshold;
    744 
    745     // The acceleration factor.
    746     // When the speed is above the low speed threshold, the velocity will scaled
    747     // by an interpolated value between 1.0 and this amount.
    748     //
    749     // Must be a positive greater than or equal to 1.0.
    750     // Default is 1.0 (no acceleration).
    751     float acceleration;
    752 
    753     VelocityControlParameters() :
    754             scale(1.0f), lowThreshold(0.0f), highThreshold(0.0f), acceleration(1.0f) {
    755     }
    756 
    757     VelocityControlParameters(float scale, float lowThreshold,
    758             float highThreshold, float acceleration) :
    759             scale(scale), lowThreshold(lowThreshold),
    760             highThreshold(highThreshold), acceleration(acceleration) {
    761     }
    762 };
    763 
    764 /*
    765  * Implements mouse pointer and wheel speed control and acceleration.
    766  */
    767 class VelocityControl {
    768 public:
    769     VelocityControl();
    770 
    771     /* Sets the various parameters. */
    772     void setParameters(const VelocityControlParameters& parameters);
    773 
    774     /* Resets the current movement counters to zero.
    775      * This has the effect of nullifying any acceleration. */
    776     void reset();
    777 
    778     /* Translates a raw movement delta into an appropriately
    779      * scaled / accelerated delta based on the current velocity. */
    780     void move(nsecs_t eventTime, float* deltaX, float* deltaY);
    781 
    782 private:
    783     // If no movements are received within this amount of time,
    784     // we assume the movement has stopped and reset the movement counters.
    785     static const nsecs_t STOP_TIME = 500 * 1000000; // 500 ms
    786 
    787     VelocityControlParameters mParameters;
    788 
    789     nsecs_t mLastMovementTime;
    790     VelocityTracker::Position mRawPosition;
    791     VelocityTracker mVelocityTracker;
    792 };
    793 
    794 
    795 /*
    796  * Describes the characteristics and capabilities of an input device.
    797  */
    798 class InputDeviceInfo {
    799 public:
    800     InputDeviceInfo();
    801     InputDeviceInfo(const InputDeviceInfo& other);
    802     ~InputDeviceInfo();
    803 
    804     struct MotionRange {
    805         int32_t axis;
    806         uint32_t source;
    807         float min;
    808         float max;
    809         float flat;
    810         float fuzz;
    811     };
    812 
    813     void initialize(int32_t id, const String8& name);
    814 
    815     inline int32_t getId() const { return mId; }
    816     inline const String8 getName() const { return mName; }
    817     inline uint32_t getSources() const { return mSources; }
    818 
    819     const MotionRange* getMotionRange(int32_t axis, uint32_t source) const;
    820 
    821     void addSource(uint32_t source);
    822     void addMotionRange(int32_t axis, uint32_t source,
    823             float min, float max, float flat, float fuzz);
    824     void addMotionRange(const MotionRange& range);
    825 
    826     inline void setKeyboardType(int32_t keyboardType) { mKeyboardType = keyboardType; }
    827     inline int32_t getKeyboardType() const { return mKeyboardType; }
    828 
    829     inline const Vector<MotionRange>& getMotionRanges() const {
    830         return mMotionRanges;
    831     }
    832 
    833 private:
    834     int32_t mId;
    835     String8 mName;
    836     uint32_t mSources;
    837     int32_t mKeyboardType;
    838 
    839     Vector<MotionRange> mMotionRanges;
    840 };
    841 
    842 /*
    843  * Identifies a device.
    844  */
    845 struct InputDeviceIdentifier {
    846     inline InputDeviceIdentifier() :
    847             bus(0), vendor(0), product(0), version(0) {
    848     }
    849 
    850     String8 name;
    851     String8 location;
    852     String8 uniqueId;
    853     uint16_t bus;
    854     uint16_t vendor;
    855     uint16_t product;
    856     uint16_t version;
    857 };
    858 
    859 /* Types of input device configuration files. */
    860 enum InputDeviceConfigurationFileType {
    861     INPUT_DEVICE_CONFIGURATION_FILE_TYPE_CONFIGURATION = 0,     /* .idc file */
    862     INPUT_DEVICE_CONFIGURATION_FILE_TYPE_KEY_LAYOUT = 1,        /* .kl file */
    863     INPUT_DEVICE_CONFIGURATION_FILE_TYPE_KEY_CHARACTER_MAP = 2, /* .kcm file */
    864 };
    865 
    866 /*
    867  * Gets the path of an input device configuration file, if one is available.
    868  * Considers both system provided and user installed configuration files.
    869  *
    870  * The device identifier is used to construct several default configuration file
    871  * names to try based on the device name, vendor, product, and version.
    872  *
    873  * Returns an empty string if not found.
    874  */
    875 extern String8 getInputDeviceConfigurationFilePathByDeviceIdentifier(
    876         const InputDeviceIdentifier& deviceIdentifier,
    877         InputDeviceConfigurationFileType type);
    878 
    879 /*
    880  * Gets the path of an input device configuration file, if one is available.
    881  * Considers both system provided and user installed configuration files.
    882  *
    883  * The name is case-sensitive and is used to construct the filename to resolve.
    884  * All characters except 'a'-'z', 'A'-'Z', '0'-'9', '-', and '_' are replaced by underscores.
    885  *
    886  * Returns an empty string if not found.
    887  */
    888 extern String8 getInputDeviceConfigurationFilePathByName(
    889         const String8& name, InputDeviceConfigurationFileType type);
    890 
    891 } // namespace android
    892 
    893 #endif // _UI_INPUT_H
    894