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1 /*
2  * Copyright (C) 2012 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 #define LOG_TAG "VelocityTracker"
18 //#define LOG_NDEBUG 0
19 
20 // Log debug messages about velocity tracking.
21 #define DEBUG_VELOCITY 0
22 
23 // Log debug messages about the progress of the algorithm itself.
24 #define DEBUG_STRATEGY 0
25 
26 #include <array>
27 #include <inttypes.h>
28 #include <limits.h>
29 #include <math.h>
30 #include <optional>
31 
32 #include <android-base/stringprintf.h>
33 #include <cutils/properties.h>
34 #include <input/VelocityTracker.h>
35 #include <utils/BitSet.h>
36 #include <utils/Timers.h>
37 
38 namespace android {
39 
40 // Nanoseconds per milliseconds.
41 static const nsecs_t NANOS_PER_MS = 1000000;
42 
43 // Threshold for determining that a pointer has stopped moving.
44 // Some input devices do not send ACTION_MOVE events in the case where a pointer has
45 // stopped.  We need to detect this case so that we can accurately predict the
46 // velocity after the pointer starts moving again.
47 static const nsecs_t ASSUME_POINTER_STOPPED_TIME = 40 * NANOS_PER_MS;
48 
49 
vectorDot(const float * a,const float * b,uint32_t m)50 static float vectorDot(const float* a, const float* b, uint32_t m) {
51     float r = 0;
52     for (size_t i = 0; i < m; i++) {
53         r += *(a++) * *(b++);
54     }
55     return r;
56 }
57 
vectorNorm(const float * a,uint32_t m)58 static float vectorNorm(const float* a, uint32_t m) {
59     float r = 0;
60     for (size_t i = 0; i < m; i++) {
61         float t = *(a++);
62         r += t * t;
63     }
64     return sqrtf(r);
65 }
66 
67 #if DEBUG_STRATEGY || DEBUG_VELOCITY
vectorToString(const float * a,uint32_t m)68 static std::string vectorToString(const float* a, uint32_t m) {
69     std::string str;
70     str += "[";
71     for (size_t i = 0; i < m; i++) {
72         if (i) {
73             str += ",";
74         }
75         str += android::base::StringPrintf(" %f", *(a++));
76     }
77     str += " ]";
78     return str;
79 }
80 #endif
81 
82 #if DEBUG_STRATEGY
matrixToString(const float * a,uint32_t m,uint32_t n,bool rowMajor)83 static std::string matrixToString(const float* a, uint32_t m, uint32_t n, bool rowMajor) {
84     std::string str;
85     str = "[";
86     for (size_t i = 0; i < m; i++) {
87         if (i) {
88             str += ",";
89         }
90         str += " [";
91         for (size_t j = 0; j < n; j++) {
92             if (j) {
93                 str += ",";
94             }
95             str += android::base::StringPrintf(" %f", a[rowMajor ? i * n + j : j * m + i]);
96         }
97         str += " ]";
98     }
99     str += " ]";
100     return str;
101 }
102 #endif
103 
104 
105 // --- VelocityTracker ---
106 
107 // The default velocity tracker strategy.
108 // Although other strategies are available for testing and comparison purposes,
109 // this is the strategy that applications will actually use.  Be very careful
110 // when adjusting the default strategy because it can dramatically affect
111 // (often in a bad way) the user experience.
112 const char* VelocityTracker::DEFAULT_STRATEGY = "lsq2";
113 
VelocityTracker(const char * strategy)114 VelocityTracker::VelocityTracker(const char* strategy) :
115         mLastEventTime(0), mCurrentPointerIdBits(0), mActivePointerId(-1) {
116     char value[PROPERTY_VALUE_MAX];
117 
118     // Allow the default strategy to be overridden using a system property for debugging.
119     if (!strategy) {
120         int length = property_get("persist.input.velocitytracker.strategy", value, nullptr);
121         if (length > 0) {
122             strategy = value;
123         } else {
124             strategy = DEFAULT_STRATEGY;
125         }
126     }
127 
128     // Configure the strategy.
129     if (!configureStrategy(strategy)) {
130         ALOGD("Unrecognized velocity tracker strategy name '%s'.", strategy);
131         if (!configureStrategy(DEFAULT_STRATEGY)) {
132             LOG_ALWAYS_FATAL("Could not create the default velocity tracker strategy '%s'!",
133                     strategy);
134         }
135     }
136 }
137 
~VelocityTracker()138 VelocityTracker::~VelocityTracker() {
139     delete mStrategy;
140 }
141 
configureStrategy(const char * strategy)142 bool VelocityTracker::configureStrategy(const char* strategy) {
143     mStrategy = createStrategy(strategy);
144     return mStrategy != nullptr;
145 }
146 
createStrategy(const char * strategy)147 VelocityTrackerStrategy* VelocityTracker::createStrategy(const char* strategy) {
148     if (!strcmp("impulse", strategy)) {
149         // Physical model of pushing an object.  Quality: VERY GOOD.
150         // Works with duplicate coordinates, unclean finger liftoff.
151         return new ImpulseVelocityTrackerStrategy();
152     }
153     if (!strcmp("lsq1", strategy)) {
154         // 1st order least squares.  Quality: POOR.
155         // Frequently underfits the touch data especially when the finger accelerates
156         // or changes direction.  Often underestimates velocity.  The direction
157         // is overly influenced by historical touch points.
158         return new LeastSquaresVelocityTrackerStrategy(1);
159     }
160     if (!strcmp("lsq2", strategy)) {
161         // 2nd order least squares.  Quality: VERY GOOD.
162         // Pretty much ideal, but can be confused by certain kinds of touch data,
163         // particularly if the panel has a tendency to generate delayed,
164         // duplicate or jittery touch coordinates when the finger is released.
165         return new LeastSquaresVelocityTrackerStrategy(2);
166     }
167     if (!strcmp("lsq3", strategy)) {
168         // 3rd order least squares.  Quality: UNUSABLE.
169         // Frequently overfits the touch data yielding wildly divergent estimates
170         // of the velocity when the finger is released.
171         return new LeastSquaresVelocityTrackerStrategy(3);
172     }
173     if (!strcmp("wlsq2-delta", strategy)) {
174         // 2nd order weighted least squares, delta weighting.  Quality: EXPERIMENTAL
175         return new LeastSquaresVelocityTrackerStrategy(2,
176                 LeastSquaresVelocityTrackerStrategy::WEIGHTING_DELTA);
177     }
178     if (!strcmp("wlsq2-central", strategy)) {
179         // 2nd order weighted least squares, central weighting.  Quality: EXPERIMENTAL
180         return new LeastSquaresVelocityTrackerStrategy(2,
181                 LeastSquaresVelocityTrackerStrategy::WEIGHTING_CENTRAL);
182     }
183     if (!strcmp("wlsq2-recent", strategy)) {
184         // 2nd order weighted least squares, recent weighting.  Quality: EXPERIMENTAL
185         return new LeastSquaresVelocityTrackerStrategy(2,
186                 LeastSquaresVelocityTrackerStrategy::WEIGHTING_RECENT);
187     }
188     if (!strcmp("int1", strategy)) {
189         // 1st order integrating filter.  Quality: GOOD.
190         // Not as good as 'lsq2' because it cannot estimate acceleration but it is
191         // more tolerant of errors.  Like 'lsq1', this strategy tends to underestimate
192         // the velocity of a fling but this strategy tends to respond to changes in
193         // direction more quickly and accurately.
194         return new IntegratingVelocityTrackerStrategy(1);
195     }
196     if (!strcmp("int2", strategy)) {
197         // 2nd order integrating filter.  Quality: EXPERIMENTAL.
198         // For comparison purposes only.  Unlike 'int1' this strategy can compensate
199         // for acceleration but it typically overestimates the effect.
200         return new IntegratingVelocityTrackerStrategy(2);
201     }
202     if (!strcmp("legacy", strategy)) {
203         // Legacy velocity tracker algorithm.  Quality: POOR.
204         // For comparison purposes only.  This algorithm is strongly influenced by
205         // old data points, consistently underestimates velocity and takes a very long
206         // time to adjust to changes in direction.
207         return new LegacyVelocityTrackerStrategy();
208     }
209     return nullptr;
210 }
211 
clear()212 void VelocityTracker::clear() {
213     mCurrentPointerIdBits.clear();
214     mActivePointerId = -1;
215 
216     mStrategy->clear();
217 }
218 
clearPointers(BitSet32 idBits)219 void VelocityTracker::clearPointers(BitSet32 idBits) {
220     BitSet32 remainingIdBits(mCurrentPointerIdBits.value & ~idBits.value);
221     mCurrentPointerIdBits = remainingIdBits;
222 
223     if (mActivePointerId >= 0 && idBits.hasBit(mActivePointerId)) {
224         mActivePointerId = !remainingIdBits.isEmpty() ? remainingIdBits.firstMarkedBit() : -1;
225     }
226 
227     mStrategy->clearPointers(idBits);
228 }
229 
addMovement(nsecs_t eventTime,BitSet32 idBits,const Position * positions)230 void VelocityTracker::addMovement(nsecs_t eventTime, BitSet32 idBits, const Position* positions) {
231     while (idBits.count() > MAX_POINTERS) {
232         idBits.clearLastMarkedBit();
233     }
234 
235     if ((mCurrentPointerIdBits.value & idBits.value)
236             && eventTime >= mLastEventTime + ASSUME_POINTER_STOPPED_TIME) {
237 #if DEBUG_VELOCITY
238         ALOGD("VelocityTracker: stopped for %0.3f ms, clearing state.",
239                 (eventTime - mLastEventTime) * 0.000001f);
240 #endif
241         // We have not received any movements for too long.  Assume that all pointers
242         // have stopped.
243         mStrategy->clear();
244     }
245     mLastEventTime = eventTime;
246 
247     mCurrentPointerIdBits = idBits;
248     if (mActivePointerId < 0 || !idBits.hasBit(mActivePointerId)) {
249         mActivePointerId = idBits.isEmpty() ? -1 : idBits.firstMarkedBit();
250     }
251 
252     mStrategy->addMovement(eventTime, idBits, positions);
253 
254 #if DEBUG_VELOCITY
255     ALOGD("VelocityTracker: addMovement eventTime=%" PRId64 ", idBits=0x%08x, activePointerId=%d",
256             eventTime, idBits.value, mActivePointerId);
257     for (BitSet32 iterBits(idBits); !iterBits.isEmpty(); ) {
258         uint32_t id = iterBits.firstMarkedBit();
259         uint32_t index = idBits.getIndexOfBit(id);
260         iterBits.clearBit(id);
261         Estimator estimator;
262         getEstimator(id, &estimator);
263         ALOGD("  %d: position (%0.3f, %0.3f), "
264                 "estimator (degree=%d, xCoeff=%s, yCoeff=%s, confidence=%f)",
265                 id, positions[index].x, positions[index].y,
266                 int(estimator.degree),
267                 vectorToString(estimator.xCoeff, estimator.degree + 1).c_str(),
268                 vectorToString(estimator.yCoeff, estimator.degree + 1).c_str(),
269                 estimator.confidence);
270     }
271 #endif
272 }
273 
addMovement(const MotionEvent * event)274 void VelocityTracker::addMovement(const MotionEvent* event) {
275     int32_t actionMasked = event->getActionMasked();
276 
277     switch (actionMasked) {
278     case AMOTION_EVENT_ACTION_DOWN:
279     case AMOTION_EVENT_ACTION_HOVER_ENTER:
280         // Clear all pointers on down before adding the new movement.
281         clear();
282         break;
283     case AMOTION_EVENT_ACTION_POINTER_DOWN: {
284         // Start a new movement trace for a pointer that just went down.
285         // We do this on down instead of on up because the client may want to query the
286         // final velocity for a pointer that just went up.
287         BitSet32 downIdBits;
288         downIdBits.markBit(event->getPointerId(event->getActionIndex()));
289         clearPointers(downIdBits);
290         break;
291     }
292     case AMOTION_EVENT_ACTION_MOVE:
293     case AMOTION_EVENT_ACTION_HOVER_MOVE:
294         break;
295     default:
296         // Ignore all other actions because they do not convey any new information about
297         // pointer movement.  We also want to preserve the last known velocity of the pointers.
298         // Note that ACTION_UP and ACTION_POINTER_UP always report the last known position
299         // of the pointers that went up.  ACTION_POINTER_UP does include the new position of
300         // pointers that remained down but we will also receive an ACTION_MOVE with this
301         // information if any of them actually moved.  Since we don't know how many pointers
302         // will be going up at once it makes sense to just wait for the following ACTION_MOVE
303         // before adding the movement.
304         return;
305     }
306 
307     size_t pointerCount = event->getPointerCount();
308     if (pointerCount > MAX_POINTERS) {
309         pointerCount = MAX_POINTERS;
310     }
311 
312     BitSet32 idBits;
313     for (size_t i = 0; i < pointerCount; i++) {
314         idBits.markBit(event->getPointerId(i));
315     }
316 
317     uint32_t pointerIndex[MAX_POINTERS];
318     for (size_t i = 0; i < pointerCount; i++) {
319         pointerIndex[i] = idBits.getIndexOfBit(event->getPointerId(i));
320     }
321 
322     nsecs_t eventTime;
323     Position positions[pointerCount];
324 
325     size_t historySize = event->getHistorySize();
326     for (size_t h = 0; h < historySize; h++) {
327         eventTime = event->getHistoricalEventTime(h);
328         for (size_t i = 0; i < pointerCount; i++) {
329             uint32_t index = pointerIndex[i];
330             positions[index].x = event->getHistoricalX(i, h);
331             positions[index].y = event->getHistoricalY(i, h);
332         }
333         addMovement(eventTime, idBits, positions);
334     }
335 
336     eventTime = event->getEventTime();
337     for (size_t i = 0; i < pointerCount; i++) {
338         uint32_t index = pointerIndex[i];
339         positions[index].x = event->getX(i);
340         positions[index].y = event->getY(i);
341     }
342     addMovement(eventTime, idBits, positions);
343 }
344 
getVelocity(uint32_t id,float * outVx,float * outVy) const345 bool VelocityTracker::getVelocity(uint32_t id, float* outVx, float* outVy) const {
346     Estimator estimator;
347     if (getEstimator(id, &estimator) && estimator.degree >= 1) {
348         *outVx = estimator.xCoeff[1];
349         *outVy = estimator.yCoeff[1];
350         return true;
351     }
352     *outVx = 0;
353     *outVy = 0;
354     return false;
355 }
356 
getEstimator(uint32_t id,Estimator * outEstimator) const357 bool VelocityTracker::getEstimator(uint32_t id, Estimator* outEstimator) const {
358     return mStrategy->getEstimator(id, outEstimator);
359 }
360 
361 
362 // --- LeastSquaresVelocityTrackerStrategy ---
363 
LeastSquaresVelocityTrackerStrategy(uint32_t degree,Weighting weighting)364 LeastSquaresVelocityTrackerStrategy::LeastSquaresVelocityTrackerStrategy(
365         uint32_t degree, Weighting weighting) :
366         mDegree(degree), mWeighting(weighting) {
367     clear();
368 }
369 
~LeastSquaresVelocityTrackerStrategy()370 LeastSquaresVelocityTrackerStrategy::~LeastSquaresVelocityTrackerStrategy() {
371 }
372 
clear()373 void LeastSquaresVelocityTrackerStrategy::clear() {
374     mIndex = 0;
375     mMovements[0].idBits.clear();
376 }
377 
clearPointers(BitSet32 idBits)378 void LeastSquaresVelocityTrackerStrategy::clearPointers(BitSet32 idBits) {
379     BitSet32 remainingIdBits(mMovements[mIndex].idBits.value & ~idBits.value);
380     mMovements[mIndex].idBits = remainingIdBits;
381 }
382 
addMovement(nsecs_t eventTime,BitSet32 idBits,const VelocityTracker::Position * positions)383 void LeastSquaresVelocityTrackerStrategy::addMovement(nsecs_t eventTime, BitSet32 idBits,
384         const VelocityTracker::Position* positions) {
385     if (mMovements[mIndex].eventTime != eventTime) {
386         // When ACTION_POINTER_DOWN happens, we will first receive ACTION_MOVE with the coordinates
387         // of the existing pointers, and then ACTION_POINTER_DOWN with the coordinates that include
388         // the new pointer. If the eventtimes for both events are identical, just update the data
389         // for this time.
390         // We only compare against the last value, as it is likely that addMovement is called
391         // in chronological order as events occur.
392         mIndex++;
393     }
394     if (mIndex == HISTORY_SIZE) {
395         mIndex = 0;
396     }
397 
398     Movement& movement = mMovements[mIndex];
399     movement.eventTime = eventTime;
400     movement.idBits = idBits;
401     uint32_t count = idBits.count();
402     for (uint32_t i = 0; i < count; i++) {
403         movement.positions[i] = positions[i];
404     }
405 }
406 
407 /**
408  * Solves a linear least squares problem to obtain a N degree polynomial that fits
409  * the specified input data as nearly as possible.
410  *
411  * Returns true if a solution is found, false otherwise.
412  *
413  * The input consists of two vectors of data points X and Y with indices 0..m-1
414  * along with a weight vector W of the same size.
415  *
416  * The output is a vector B with indices 0..n that describes a polynomial
417  * that fits the data, such the sum of W[i] * W[i] * abs(Y[i] - (B[0] + B[1] X[i]
418  * + B[2] X[i]^2 ... B[n] X[i]^n)) for all i between 0 and m-1 is minimized.
419  *
420  * Accordingly, the weight vector W should be initialized by the caller with the
421  * reciprocal square root of the variance of the error in each input data point.
422  * In other words, an ideal choice for W would be W[i] = 1 / var(Y[i]) = 1 / stddev(Y[i]).
423  * The weights express the relative importance of each data point.  If the weights are
424  * all 1, then the data points are considered to be of equal importance when fitting
425  * the polynomial.  It is a good idea to choose weights that diminish the importance
426  * of data points that may have higher than usual error margins.
427  *
428  * Errors among data points are assumed to be independent.  W is represented here
429  * as a vector although in the literature it is typically taken to be a diagonal matrix.
430  *
431  * That is to say, the function that generated the input data can be approximated
432  * by y(x) ~= B[0] + B[1] x + B[2] x^2 + ... + B[n] x^n.
433  *
434  * The coefficient of determination (R^2) is also returned to describe the goodness
435  * of fit of the model for the given data.  It is a value between 0 and 1, where 1
436  * indicates perfect correspondence.
437  *
438  * This function first expands the X vector to a m by n matrix A such that
439  * A[i][0] = 1, A[i][1] = X[i], A[i][2] = X[i]^2, ..., A[i][n] = X[i]^n, then
440  * multiplies it by w[i]./
441  *
442  * Then it calculates the QR decomposition of A yielding an m by m orthonormal matrix Q
443  * and an m by n upper triangular matrix R.  Because R is upper triangular (lower
444  * part is all zeroes), we can simplify the decomposition into an m by n matrix
445  * Q1 and a n by n matrix R1 such that A = Q1 R1.
446  *
447  * Finally we solve the system of linear equations given by R1 B = (Qtranspose W Y)
448  * to find B.
449  *
450  * For efficiency, we lay out A and Q column-wise in memory because we frequently
451  * operate on the column vectors.  Conversely, we lay out R row-wise.
452  *
453  * http://en.wikipedia.org/wiki/Numerical_methods_for_linear_least_squares
454  * http://en.wikipedia.org/wiki/Gram-Schmidt
455  */
solveLeastSquares(const float * x,const float * y,const float * w,uint32_t m,uint32_t n,float * outB,float * outDet)456 static bool solveLeastSquares(const float* x, const float* y,
457         const float* w, uint32_t m, uint32_t n, float* outB, float* outDet) {
458 #if DEBUG_STRATEGY
459     ALOGD("solveLeastSquares: m=%d, n=%d, x=%s, y=%s, w=%s", int(m), int(n),
460             vectorToString(x, m).c_str(), vectorToString(y, m).c_str(),
461             vectorToString(w, m).c_str());
462 #endif
463 
464     // Expand the X vector to a matrix A, pre-multiplied by the weights.
465     float a[n][m]; // column-major order
466     for (uint32_t h = 0; h < m; h++) {
467         a[0][h] = w[h];
468         for (uint32_t i = 1; i < n; i++) {
469             a[i][h] = a[i - 1][h] * x[h];
470         }
471     }
472 #if DEBUG_STRATEGY
473     ALOGD("  - a=%s", matrixToString(&a[0][0], m, n, false /*rowMajor*/).c_str());
474 #endif
475 
476     // Apply the Gram-Schmidt process to A to obtain its QR decomposition.
477     float q[n][m]; // orthonormal basis, column-major order
478     float r[n][n]; // upper triangular matrix, row-major order
479     for (uint32_t j = 0; j < n; j++) {
480         for (uint32_t h = 0; h < m; h++) {
481             q[j][h] = a[j][h];
482         }
483         for (uint32_t i = 0; i < j; i++) {
484             float dot = vectorDot(&q[j][0], &q[i][0], m);
485             for (uint32_t h = 0; h < m; h++) {
486                 q[j][h] -= dot * q[i][h];
487             }
488         }
489 
490         float norm = vectorNorm(&q[j][0], m);
491         if (norm < 0.000001f) {
492             // vectors are linearly dependent or zero so no solution
493 #if DEBUG_STRATEGY
494             ALOGD("  - no solution, norm=%f", norm);
495 #endif
496             return false;
497         }
498 
499         float invNorm = 1.0f / norm;
500         for (uint32_t h = 0; h < m; h++) {
501             q[j][h] *= invNorm;
502         }
503         for (uint32_t i = 0; i < n; i++) {
504             r[j][i] = i < j ? 0 : vectorDot(&q[j][0], &a[i][0], m);
505         }
506     }
507 #if DEBUG_STRATEGY
508     ALOGD("  - q=%s", matrixToString(&q[0][0], m, n, false /*rowMajor*/).c_str());
509     ALOGD("  - r=%s", matrixToString(&r[0][0], n, n, true /*rowMajor*/).c_str());
510 
511     // calculate QR, if we factored A correctly then QR should equal A
512     float qr[n][m];
513     for (uint32_t h = 0; h < m; h++) {
514         for (uint32_t i = 0; i < n; i++) {
515             qr[i][h] = 0;
516             for (uint32_t j = 0; j < n; j++) {
517                 qr[i][h] += q[j][h] * r[j][i];
518             }
519         }
520     }
521     ALOGD("  - qr=%s", matrixToString(&qr[0][0], m, n, false /*rowMajor*/).c_str());
522 #endif
523 
524     // Solve R B = Qt W Y to find B.  This is easy because R is upper triangular.
525     // We just work from bottom-right to top-left calculating B's coefficients.
526     float wy[m];
527     for (uint32_t h = 0; h < m; h++) {
528         wy[h] = y[h] * w[h];
529     }
530     for (uint32_t i = n; i != 0; ) {
531         i--;
532         outB[i] = vectorDot(&q[i][0], wy, m);
533         for (uint32_t j = n - 1; j > i; j--) {
534             outB[i] -= r[i][j] * outB[j];
535         }
536         outB[i] /= r[i][i];
537     }
538 #if DEBUG_STRATEGY
539     ALOGD("  - b=%s", vectorToString(outB, n).c_str());
540 #endif
541 
542     // Calculate the coefficient of determination as 1 - (SSerr / SStot) where
543     // SSerr is the residual sum of squares (variance of the error),
544     // and SStot is the total sum of squares (variance of the data) where each
545     // has been weighted.
546     float ymean = 0;
547     for (uint32_t h = 0; h < m; h++) {
548         ymean += y[h];
549     }
550     ymean /= m;
551 
552     float sserr = 0;
553     float sstot = 0;
554     for (uint32_t h = 0; h < m; h++) {
555         float err = y[h] - outB[0];
556         float term = 1;
557         for (uint32_t i = 1; i < n; i++) {
558             term *= x[h];
559             err -= term * outB[i];
560         }
561         sserr += w[h] * w[h] * err * err;
562         float var = y[h] - ymean;
563         sstot += w[h] * w[h] * var * var;
564     }
565     *outDet = sstot > 0.000001f ? 1.0f - (sserr / sstot) : 1;
566 #if DEBUG_STRATEGY
567     ALOGD("  - sserr=%f", sserr);
568     ALOGD("  - sstot=%f", sstot);
569     ALOGD("  - det=%f", *outDet);
570 #endif
571     return true;
572 }
573 
574 /*
575  * Optimized unweighted second-order least squares fit. About 2x speed improvement compared to
576  * the default implementation
577  */
solveUnweightedLeastSquaresDeg2(const float * x,const float * y,size_t count)578 static std::optional<std::array<float, 3>> solveUnweightedLeastSquaresDeg2(
579         const float* x, const float* y, size_t count) {
580     // Solving y = a*x^2 + b*x + c
581     float sxi = 0, sxiyi = 0, syi = 0, sxi2 = 0, sxi3 = 0, sxi2yi = 0, sxi4 = 0;
582 
583     for (size_t i = 0; i < count; i++) {
584         float xi = x[i];
585         float yi = y[i];
586         float xi2 = xi*xi;
587         float xi3 = xi2*xi;
588         float xi4 = xi3*xi;
589         float xiyi = xi*yi;
590         float xi2yi = xi2*yi;
591 
592         sxi += xi;
593         sxi2 += xi2;
594         sxiyi += xiyi;
595         sxi2yi += xi2yi;
596         syi += yi;
597         sxi3 += xi3;
598         sxi4 += xi4;
599     }
600 
601     float Sxx = sxi2 - sxi*sxi / count;
602     float Sxy = sxiyi - sxi*syi / count;
603     float Sxx2 = sxi3 - sxi*sxi2 / count;
604     float Sx2y = sxi2yi - sxi2*syi / count;
605     float Sx2x2 = sxi4 - sxi2*sxi2 / count;
606 
607     float denominator = Sxx*Sx2x2 - Sxx2*Sxx2;
608     if (denominator == 0) {
609         ALOGW("division by 0 when computing velocity, Sxx=%f, Sx2x2=%f, Sxx2=%f", Sxx, Sx2x2, Sxx2);
610         return std::nullopt;
611     }
612     // Compute a
613     float numerator = Sx2y*Sxx - Sxy*Sxx2;
614     float a = numerator / denominator;
615 
616     // Compute b
617     numerator = Sxy*Sx2x2 - Sx2y*Sxx2;
618     float b = numerator / denominator;
619 
620     // Compute c
621     float c = syi/count - b * sxi/count - a * sxi2/count;
622 
623     return std::make_optional(std::array<float, 3>({c, b, a}));
624 }
625 
getEstimator(uint32_t id,VelocityTracker::Estimator * outEstimator) const626 bool LeastSquaresVelocityTrackerStrategy::getEstimator(uint32_t id,
627         VelocityTracker::Estimator* outEstimator) const {
628     outEstimator->clear();
629 
630     // Iterate over movement samples in reverse time order and collect samples.
631     float x[HISTORY_SIZE];
632     float y[HISTORY_SIZE];
633     float w[HISTORY_SIZE];
634     float time[HISTORY_SIZE];
635     uint32_t m = 0;
636     uint32_t index = mIndex;
637     const Movement& newestMovement = mMovements[mIndex];
638     do {
639         const Movement& movement = mMovements[index];
640         if (!movement.idBits.hasBit(id)) {
641             break;
642         }
643 
644         nsecs_t age = newestMovement.eventTime - movement.eventTime;
645         if (age > HORIZON) {
646             break;
647         }
648 
649         const VelocityTracker::Position& position = movement.getPosition(id);
650         x[m] = position.x;
651         y[m] = position.y;
652         w[m] = chooseWeight(index);
653         time[m] = -age * 0.000000001f;
654         index = (index == 0 ? HISTORY_SIZE : index) - 1;
655     } while (++m < HISTORY_SIZE);
656 
657     if (m == 0) {
658         return false; // no data
659     }
660 
661     // Calculate a least squares polynomial fit.
662     uint32_t degree = mDegree;
663     if (degree > m - 1) {
664         degree = m - 1;
665     }
666 
667     if (degree == 2 && mWeighting == WEIGHTING_NONE) {
668         // Optimize unweighted, quadratic polynomial fit
669         std::optional<std::array<float, 3>> xCoeff = solveUnweightedLeastSquaresDeg2(time, x, m);
670         std::optional<std::array<float, 3>> yCoeff = solveUnweightedLeastSquaresDeg2(time, y, m);
671         if (xCoeff && yCoeff) {
672             outEstimator->time = newestMovement.eventTime;
673             outEstimator->degree = 2;
674             outEstimator->confidence = 1;
675             for (size_t i = 0; i <= outEstimator->degree; i++) {
676                 outEstimator->xCoeff[i] = (*xCoeff)[i];
677                 outEstimator->yCoeff[i] = (*yCoeff)[i];
678             }
679             return true;
680         }
681     } else if (degree >= 1) {
682         // General case for an Nth degree polynomial fit
683         float xdet, ydet;
684         uint32_t n = degree + 1;
685         if (solveLeastSquares(time, x, w, m, n, outEstimator->xCoeff, &xdet)
686                 && solveLeastSquares(time, y, w, m, n, outEstimator->yCoeff, &ydet)) {
687             outEstimator->time = newestMovement.eventTime;
688             outEstimator->degree = degree;
689             outEstimator->confidence = xdet * ydet;
690 #if DEBUG_STRATEGY
691             ALOGD("estimate: degree=%d, xCoeff=%s, yCoeff=%s, confidence=%f",
692                     int(outEstimator->degree),
693                     vectorToString(outEstimator->xCoeff, n).c_str(),
694                     vectorToString(outEstimator->yCoeff, n).c_str(),
695                     outEstimator->confidence);
696 #endif
697             return true;
698         }
699     }
700 
701     // No velocity data available for this pointer, but we do have its current position.
702     outEstimator->xCoeff[0] = x[0];
703     outEstimator->yCoeff[0] = y[0];
704     outEstimator->time = newestMovement.eventTime;
705     outEstimator->degree = 0;
706     outEstimator->confidence = 1;
707     return true;
708 }
709 
chooseWeight(uint32_t index) const710 float LeastSquaresVelocityTrackerStrategy::chooseWeight(uint32_t index) const {
711     switch (mWeighting) {
712     case WEIGHTING_DELTA: {
713         // Weight points based on how much time elapsed between them and the next
714         // point so that points that "cover" a shorter time span are weighed less.
715         //   delta  0ms: 0.5
716         //   delta 10ms: 1.0
717         if (index == mIndex) {
718             return 1.0f;
719         }
720         uint32_t nextIndex = (index + 1) % HISTORY_SIZE;
721         float deltaMillis = (mMovements[nextIndex].eventTime- mMovements[index].eventTime)
722                 * 0.000001f;
723         if (deltaMillis < 0) {
724             return 0.5f;
725         }
726         if (deltaMillis < 10) {
727             return 0.5f + deltaMillis * 0.05;
728         }
729         return 1.0f;
730     }
731 
732     case WEIGHTING_CENTRAL: {
733         // Weight points based on their age, weighing very recent and very old points less.
734         //   age  0ms: 0.5
735         //   age 10ms: 1.0
736         //   age 50ms: 1.0
737         //   age 60ms: 0.5
738         float ageMillis = (mMovements[mIndex].eventTime - mMovements[index].eventTime)
739                 * 0.000001f;
740         if (ageMillis < 0) {
741             return 0.5f;
742         }
743         if (ageMillis < 10) {
744             return 0.5f + ageMillis * 0.05;
745         }
746         if (ageMillis < 50) {
747             return 1.0f;
748         }
749         if (ageMillis < 60) {
750             return 0.5f + (60 - ageMillis) * 0.05;
751         }
752         return 0.5f;
753     }
754 
755     case WEIGHTING_RECENT: {
756         // Weight points based on their age, weighing older points less.
757         //   age   0ms: 1.0
758         //   age  50ms: 1.0
759         //   age 100ms: 0.5
760         float ageMillis = (mMovements[mIndex].eventTime - mMovements[index].eventTime)
761                 * 0.000001f;
762         if (ageMillis < 50) {
763             return 1.0f;
764         }
765         if (ageMillis < 100) {
766             return 0.5f + (100 - ageMillis) * 0.01f;
767         }
768         return 0.5f;
769     }
770 
771     case WEIGHTING_NONE:
772     default:
773         return 1.0f;
774     }
775 }
776 
777 
778 // --- IntegratingVelocityTrackerStrategy ---
779 
IntegratingVelocityTrackerStrategy(uint32_t degree)780 IntegratingVelocityTrackerStrategy::IntegratingVelocityTrackerStrategy(uint32_t degree) :
781         mDegree(degree) {
782 }
783 
~IntegratingVelocityTrackerStrategy()784 IntegratingVelocityTrackerStrategy::~IntegratingVelocityTrackerStrategy() {
785 }
786 
clear()787 void IntegratingVelocityTrackerStrategy::clear() {
788     mPointerIdBits.clear();
789 }
790 
clearPointers(BitSet32 idBits)791 void IntegratingVelocityTrackerStrategy::clearPointers(BitSet32 idBits) {
792     mPointerIdBits.value &= ~idBits.value;
793 }
794 
addMovement(nsecs_t eventTime,BitSet32 idBits,const VelocityTracker::Position * positions)795 void IntegratingVelocityTrackerStrategy::addMovement(nsecs_t eventTime, BitSet32 idBits,
796         const VelocityTracker::Position* positions) {
797     uint32_t index = 0;
798     for (BitSet32 iterIdBits(idBits); !iterIdBits.isEmpty();) {
799         uint32_t id = iterIdBits.clearFirstMarkedBit();
800         State& state = mPointerState[id];
801         const VelocityTracker::Position& position = positions[index++];
802         if (mPointerIdBits.hasBit(id)) {
803             updateState(state, eventTime, position.x, position.y);
804         } else {
805             initState(state, eventTime, position.x, position.y);
806         }
807     }
808 
809     mPointerIdBits = idBits;
810 }
811 
getEstimator(uint32_t id,VelocityTracker::Estimator * outEstimator) const812 bool IntegratingVelocityTrackerStrategy::getEstimator(uint32_t id,
813         VelocityTracker::Estimator* outEstimator) const {
814     outEstimator->clear();
815 
816     if (mPointerIdBits.hasBit(id)) {
817         const State& state = mPointerState[id];
818         populateEstimator(state, outEstimator);
819         return true;
820     }
821 
822     return false;
823 }
824 
initState(State & state,nsecs_t eventTime,float xpos,float ypos) const825 void IntegratingVelocityTrackerStrategy::initState(State& state,
826         nsecs_t eventTime, float xpos, float ypos) const {
827     state.updateTime = eventTime;
828     state.degree = 0;
829 
830     state.xpos = xpos;
831     state.xvel = 0;
832     state.xaccel = 0;
833     state.ypos = ypos;
834     state.yvel = 0;
835     state.yaccel = 0;
836 }
837 
updateState(State & state,nsecs_t eventTime,float xpos,float ypos) const838 void IntegratingVelocityTrackerStrategy::updateState(State& state,
839         nsecs_t eventTime, float xpos, float ypos) const {
840     const nsecs_t MIN_TIME_DELTA = 2 * NANOS_PER_MS;
841     const float FILTER_TIME_CONSTANT = 0.010f; // 10 milliseconds
842 
843     if (eventTime <= state.updateTime + MIN_TIME_DELTA) {
844         return;
845     }
846 
847     float dt = (eventTime - state.updateTime) * 0.000000001f;
848     state.updateTime = eventTime;
849 
850     float xvel = (xpos - state.xpos) / dt;
851     float yvel = (ypos - state.ypos) / dt;
852     if (state.degree == 0) {
853         state.xvel = xvel;
854         state.yvel = yvel;
855         state.degree = 1;
856     } else {
857         float alpha = dt / (FILTER_TIME_CONSTANT + dt);
858         if (mDegree == 1) {
859             state.xvel += (xvel - state.xvel) * alpha;
860             state.yvel += (yvel - state.yvel) * alpha;
861         } else {
862             float xaccel = (xvel - state.xvel) / dt;
863             float yaccel = (yvel - state.yvel) / dt;
864             if (state.degree == 1) {
865                 state.xaccel = xaccel;
866                 state.yaccel = yaccel;
867                 state.degree = 2;
868             } else {
869                 state.xaccel += (xaccel - state.xaccel) * alpha;
870                 state.yaccel += (yaccel - state.yaccel) * alpha;
871             }
872             state.xvel += (state.xaccel * dt) * alpha;
873             state.yvel += (state.yaccel * dt) * alpha;
874         }
875     }
876     state.xpos = xpos;
877     state.ypos = ypos;
878 }
879 
populateEstimator(const State & state,VelocityTracker::Estimator * outEstimator) const880 void IntegratingVelocityTrackerStrategy::populateEstimator(const State& state,
881         VelocityTracker::Estimator* outEstimator) const {
882     outEstimator->time = state.updateTime;
883     outEstimator->confidence = 1.0f;
884     outEstimator->degree = state.degree;
885     outEstimator->xCoeff[0] = state.xpos;
886     outEstimator->xCoeff[1] = state.xvel;
887     outEstimator->xCoeff[2] = state.xaccel / 2;
888     outEstimator->yCoeff[0] = state.ypos;
889     outEstimator->yCoeff[1] = state.yvel;
890     outEstimator->yCoeff[2] = state.yaccel / 2;
891 }
892 
893 
894 // --- LegacyVelocityTrackerStrategy ---
895 
LegacyVelocityTrackerStrategy()896 LegacyVelocityTrackerStrategy::LegacyVelocityTrackerStrategy() {
897     clear();
898 }
899 
~LegacyVelocityTrackerStrategy()900 LegacyVelocityTrackerStrategy::~LegacyVelocityTrackerStrategy() {
901 }
902 
clear()903 void LegacyVelocityTrackerStrategy::clear() {
904     mIndex = 0;
905     mMovements[0].idBits.clear();
906 }
907 
clearPointers(BitSet32 idBits)908 void LegacyVelocityTrackerStrategy::clearPointers(BitSet32 idBits) {
909     BitSet32 remainingIdBits(mMovements[mIndex].idBits.value & ~idBits.value);
910     mMovements[mIndex].idBits = remainingIdBits;
911 }
912 
addMovement(nsecs_t eventTime,BitSet32 idBits,const VelocityTracker::Position * positions)913 void LegacyVelocityTrackerStrategy::addMovement(nsecs_t eventTime, BitSet32 idBits,
914         const VelocityTracker::Position* positions) {
915     if (++mIndex == HISTORY_SIZE) {
916         mIndex = 0;
917     }
918 
919     Movement& movement = mMovements[mIndex];
920     movement.eventTime = eventTime;
921     movement.idBits = idBits;
922     uint32_t count = idBits.count();
923     for (uint32_t i = 0; i < count; i++) {
924         movement.positions[i] = positions[i];
925     }
926 }
927 
getEstimator(uint32_t id,VelocityTracker::Estimator * outEstimator) const928 bool LegacyVelocityTrackerStrategy::getEstimator(uint32_t id,
929         VelocityTracker::Estimator* outEstimator) const {
930     outEstimator->clear();
931 
932     const Movement& newestMovement = mMovements[mIndex];
933     if (!newestMovement.idBits.hasBit(id)) {
934         return false; // no data
935     }
936 
937     // Find the oldest sample that contains the pointer and that is not older than HORIZON.
938     nsecs_t minTime = newestMovement.eventTime - HORIZON;
939     uint32_t oldestIndex = mIndex;
940     uint32_t numTouches = 1;
941     do {
942         uint32_t nextOldestIndex = (oldestIndex == 0 ? HISTORY_SIZE : oldestIndex) - 1;
943         const Movement& nextOldestMovement = mMovements[nextOldestIndex];
944         if (!nextOldestMovement.idBits.hasBit(id)
945                 || nextOldestMovement.eventTime < minTime) {
946             break;
947         }
948         oldestIndex = nextOldestIndex;
949     } while (++numTouches < HISTORY_SIZE);
950 
951     // Calculate an exponentially weighted moving average of the velocity estimate
952     // at different points in time measured relative to the oldest sample.
953     // This is essentially an IIR filter.  Newer samples are weighted more heavily
954     // than older samples.  Samples at equal time points are weighted more or less
955     // equally.
956     //
957     // One tricky problem is that the sample data may be poorly conditioned.
958     // Sometimes samples arrive very close together in time which can cause us to
959     // overestimate the velocity at that time point.  Most samples might be measured
960     // 16ms apart but some consecutive samples could be only 0.5sm apart because
961     // the hardware or driver reports them irregularly or in bursts.
962     float accumVx = 0;
963     float accumVy = 0;
964     uint32_t index = oldestIndex;
965     uint32_t samplesUsed = 0;
966     const Movement& oldestMovement = mMovements[oldestIndex];
967     const VelocityTracker::Position& oldestPosition = oldestMovement.getPosition(id);
968     nsecs_t lastDuration = 0;
969 
970     while (numTouches-- > 1) {
971         if (++index == HISTORY_SIZE) {
972             index = 0;
973         }
974         const Movement& movement = mMovements[index];
975         nsecs_t duration = movement.eventTime - oldestMovement.eventTime;
976 
977         // If the duration between samples is small, we may significantly overestimate
978         // the velocity.  Consequently, we impose a minimum duration constraint on the
979         // samples that we include in the calculation.
980         if (duration >= MIN_DURATION) {
981             const VelocityTracker::Position& position = movement.getPosition(id);
982             float scale = 1000000000.0f / duration; // one over time delta in seconds
983             float vx = (position.x - oldestPosition.x) * scale;
984             float vy = (position.y - oldestPosition.y) * scale;
985             accumVx = (accumVx * lastDuration + vx * duration) / (duration + lastDuration);
986             accumVy = (accumVy * lastDuration + vy * duration) / (duration + lastDuration);
987             lastDuration = duration;
988             samplesUsed += 1;
989         }
990     }
991 
992     // Report velocity.
993     const VelocityTracker::Position& newestPosition = newestMovement.getPosition(id);
994     outEstimator->time = newestMovement.eventTime;
995     outEstimator->confidence = 1;
996     outEstimator->xCoeff[0] = newestPosition.x;
997     outEstimator->yCoeff[0] = newestPosition.y;
998     if (samplesUsed) {
999         outEstimator->xCoeff[1] = accumVx;
1000         outEstimator->yCoeff[1] = accumVy;
1001         outEstimator->degree = 1;
1002     } else {
1003         outEstimator->degree = 0;
1004     }
1005     return true;
1006 }
1007 
1008 // --- ImpulseVelocityTrackerStrategy ---
1009 
ImpulseVelocityTrackerStrategy()1010 ImpulseVelocityTrackerStrategy::ImpulseVelocityTrackerStrategy() {
1011     clear();
1012 }
1013 
~ImpulseVelocityTrackerStrategy()1014 ImpulseVelocityTrackerStrategy::~ImpulseVelocityTrackerStrategy() {
1015 }
1016 
clear()1017 void ImpulseVelocityTrackerStrategy::clear() {
1018     mIndex = 0;
1019     mMovements[0].idBits.clear();
1020 }
1021 
clearPointers(BitSet32 idBits)1022 void ImpulseVelocityTrackerStrategy::clearPointers(BitSet32 idBits) {
1023     BitSet32 remainingIdBits(mMovements[mIndex].idBits.value & ~idBits.value);
1024     mMovements[mIndex].idBits = remainingIdBits;
1025 }
1026 
addMovement(nsecs_t eventTime,BitSet32 idBits,const VelocityTracker::Position * positions)1027 void ImpulseVelocityTrackerStrategy::addMovement(nsecs_t eventTime, BitSet32 idBits,
1028         const VelocityTracker::Position* positions) {
1029     if (mMovements[mIndex].eventTime != eventTime) {
1030         // When ACTION_POINTER_DOWN happens, we will first receive ACTION_MOVE with the coordinates
1031         // of the existing pointers, and then ACTION_POINTER_DOWN with the coordinates that include
1032         // the new pointer. If the eventtimes for both events are identical, just update the data
1033         // for this time.
1034         // We only compare against the last value, as it is likely that addMovement is called
1035         // in chronological order as events occur.
1036         mIndex++;
1037     }
1038     if (mIndex == HISTORY_SIZE) {
1039         mIndex = 0;
1040     }
1041 
1042     Movement& movement = mMovements[mIndex];
1043     movement.eventTime = eventTime;
1044     movement.idBits = idBits;
1045     uint32_t count = idBits.count();
1046     for (uint32_t i = 0; i < count; i++) {
1047         movement.positions[i] = positions[i];
1048     }
1049 }
1050 
1051 /**
1052  * Calculate the total impulse provided to the screen and the resulting velocity.
1053  *
1054  * The touchscreen is modeled as a physical object.
1055  * Initial condition is discussed below, but for now suppose that v(t=0) = 0
1056  *
1057  * The kinetic energy of the object at the release is E=0.5*m*v^2
1058  * Then vfinal = sqrt(2E/m). The goal is to calculate E.
1059  *
1060  * The kinetic energy at the release is equal to the total work done on the object by the finger.
1061  * The total work W is the sum of all dW along the path.
1062  *
1063  * dW = F*dx, where dx is the piece of path traveled.
1064  * Force is change of momentum over time, F = dp/dt = m dv/dt.
1065  * Then substituting:
1066  * dW = m (dv/dt) * dx = m * v * dv
1067  *
1068  * Summing along the path, we get:
1069  * W = sum(dW) = sum(m * v * dv) = m * sum(v * dv)
1070  * Since the mass stays constant, the equation for final velocity is:
1071  * vfinal = sqrt(2*sum(v * dv))
1072  *
1073  * Here,
1074  * dv : change of velocity = (v[i+1]-v[i])
1075  * dx : change of distance = (x[i+1]-x[i])
1076  * dt : change of time = (t[i+1]-t[i])
1077  * v : instantaneous velocity = dx/dt
1078  *
1079  * The final formula is:
1080  * vfinal = sqrt(2) * sqrt(sum((v[i]-v[i-1])*|v[i]|)) for all i
1081  * The absolute value is needed to properly account for the sign. If the velocity over a
1082  * particular segment descreases, then this indicates braking, which means that negative
1083  * work was done. So for two positive, but decreasing, velocities, this contribution would be
1084  * negative and will cause a smaller final velocity.
1085  *
1086  * Initial condition
1087  * There are two ways to deal with initial condition:
1088  * 1) Assume that v(0) = 0, which would mean that the screen is initially at rest.
1089  * This is not entirely accurate. We are only taking the past X ms of touch data, where X is
1090  * currently equal to 100. However, a touch event that created a fling probably lasted for longer
1091  * than that, which would mean that the user has already been interacting with the touchscreen
1092  * and it has probably already been moving.
1093  * 2) Assume that the touchscreen has already been moving at a certain velocity, calculate this
1094  * initial velocity and the equivalent energy, and start with this initial energy.
1095  * Consider an example where we have the following data, consisting of 3 points:
1096  *                 time: t0, t1, t2
1097  *                 x   : x0, x1, x2
1098  *                 v   : 0 , v1, v2
1099  * Here is what will happen in each of these scenarios:
1100  * 1) By directly applying the formula above with the v(0) = 0 boundary condition, we will get
1101  * vfinal = sqrt(2*(|v1|*(v1-v0) + |v2|*(v2-v1))). This can be simplified since v0=0
1102  * vfinal = sqrt(2*(|v1|*v1 + |v2|*(v2-v1))) = sqrt(2*(v1^2 + |v2|*(v2 - v1)))
1103  * since velocity is a real number
1104  * 2) If we treat the screen as already moving, then it must already have an energy (per mass)
1105  * equal to 1/2*v1^2. Then the initial energy should be 1/2*v1*2, and only the second segment
1106  * will contribute to the total kinetic energy (since we can effectively consider that v0=v1).
1107  * This will give the following expression for the final velocity:
1108  * vfinal = sqrt(2*(1/2*v1^2 + |v2|*(v2-v1)))
1109  * This analysis can be generalized to an arbitrary number of samples.
1110  *
1111  *
1112  * Comparing the two equations above, we see that the only mathematical difference
1113  * is the factor of 1/2 in front of the first velocity term.
1114  * This boundary condition would allow for the "proper" calculation of the case when all of the
1115  * samples are equally spaced in time and distance, which should suggest a constant velocity.
1116  *
1117  * Note that approach 2) is sensitive to the proper ordering of the data in time, since
1118  * the boundary condition must be applied to the oldest sample to be accurate.
1119  */
kineticEnergyToVelocity(float work)1120 static float kineticEnergyToVelocity(float work) {
1121     static constexpr float sqrt2 = 1.41421356237;
1122     return (work < 0 ? -1.0 : 1.0) * sqrtf(fabsf(work)) * sqrt2;
1123 }
1124 
calculateImpulseVelocity(const nsecs_t * t,const float * x,size_t count)1125 static float calculateImpulseVelocity(const nsecs_t* t, const float* x, size_t count) {
1126     // The input should be in reversed time order (most recent sample at index i=0)
1127     // t[i] is in nanoseconds, but due to FP arithmetic, convert to seconds inside this function
1128     static constexpr float SECONDS_PER_NANO = 1E-9;
1129 
1130     if (count < 2) {
1131         return 0; // if 0 or 1 points, velocity is zero
1132     }
1133     if (t[1] > t[0]) { // Algorithm will still work, but not perfectly
1134         ALOGE("Samples provided to calculateImpulseVelocity in the wrong order");
1135     }
1136     if (count == 2) { // if 2 points, basic linear calculation
1137         if (t[1] == t[0]) {
1138             ALOGE("Events have identical time stamps t=%" PRId64 ", setting velocity = 0", t[0]);
1139             return 0;
1140         }
1141         return (x[1] - x[0]) / (SECONDS_PER_NANO * (t[1] - t[0]));
1142     }
1143     // Guaranteed to have at least 3 points here
1144     float work = 0;
1145     for (size_t i = count - 1; i > 0 ; i--) { // start with the oldest sample and go forward in time
1146         if (t[i] == t[i-1]) {
1147             ALOGE("Events have identical time stamps t=%" PRId64 ", skipping sample", t[i]);
1148             continue;
1149         }
1150         float vprev = kineticEnergyToVelocity(work); // v[i-1]
1151         float vcurr = (x[i] - x[i-1]) / (SECONDS_PER_NANO * (t[i] - t[i-1])); // v[i]
1152         work += (vcurr - vprev) * fabsf(vcurr);
1153         if (i == count - 1) {
1154             work *= 0.5; // initial condition, case 2) above
1155         }
1156     }
1157     return kineticEnergyToVelocity(work);
1158 }
1159 
getEstimator(uint32_t id,VelocityTracker::Estimator * outEstimator) const1160 bool ImpulseVelocityTrackerStrategy::getEstimator(uint32_t id,
1161         VelocityTracker::Estimator* outEstimator) const {
1162     outEstimator->clear();
1163 
1164     // Iterate over movement samples in reverse time order and collect samples.
1165     float x[HISTORY_SIZE];
1166     float y[HISTORY_SIZE];
1167     nsecs_t time[HISTORY_SIZE];
1168     size_t m = 0; // number of points that will be used for fitting
1169     size_t index = mIndex;
1170     const Movement& newestMovement = mMovements[mIndex];
1171     do {
1172         const Movement& movement = mMovements[index];
1173         if (!movement.idBits.hasBit(id)) {
1174             break;
1175         }
1176 
1177         nsecs_t age = newestMovement.eventTime - movement.eventTime;
1178         if (age > HORIZON) {
1179             break;
1180         }
1181 
1182         const VelocityTracker::Position& position = movement.getPosition(id);
1183         x[m] = position.x;
1184         y[m] = position.y;
1185         time[m] = movement.eventTime;
1186         index = (index == 0 ? HISTORY_SIZE : index) - 1;
1187     } while (++m < HISTORY_SIZE);
1188 
1189     if (m == 0) {
1190         return false; // no data
1191     }
1192     outEstimator->xCoeff[0] = 0;
1193     outEstimator->yCoeff[0] = 0;
1194     outEstimator->xCoeff[1] = calculateImpulseVelocity(time, x, m);
1195     outEstimator->yCoeff[1] = calculateImpulseVelocity(time, y, m);
1196     outEstimator->xCoeff[2] = 0;
1197     outEstimator->yCoeff[2] = 0;
1198     outEstimator->time = newestMovement.eventTime;
1199     outEstimator->degree = 2; // similar results to 2nd degree fit
1200     outEstimator->confidence = 1;
1201 #if DEBUG_STRATEGY
1202     ALOGD("velocity: (%f, %f)", outEstimator->xCoeff[1], outEstimator->yCoeff[1]);
1203 #endif
1204     return true;
1205 }
1206 
1207 } // namespace android
1208