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android / platform / cts / 96f4d40076c3165e8ea2e123759340be2e7aad32 / . / tests / camera / src / android / hardware / camera2 / cts / CameraTestUtils.java
blob: d78b3b549e3a983cd71aba5447e374b1b0ad9c0f [file] [log] [blame]
/*
* Copyright 2013 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.
*/
package android.hardware.camera2.cts;
import android.graphics.Bitmap;
import android.graphics.BitmapFactory;
import android.graphics.ImageFormat;
import android.graphics.PointF;
import android.graphics.Rect;
import android.hardware.camera2.CameraAccessException;
import android.hardware.camera2.CameraCaptureSession;
import android.hardware.camera2.CameraConstrainedHighSpeedCaptureSession;
import android.hardware.camera2.CameraDevice;
import android.hardware.camera2.CameraManager;
import android.hardware.camera2.CameraCharacteristics;
import android.hardware.camera2.CaptureFailure;
import android.hardware.camera2.CaptureRequest;
import android.hardware.camera2.CaptureResult;
import android.hardware.camera2.cts.helpers.CameraErrorCollector;
import android.hardware.camera2.cts.helpers.StaticMetadata;
import android.hardware.camera2.params.InputConfiguration;
import android.hardware.camera2.TotalCaptureResult;
import android.hardware.cts.helpers.CameraUtils;
import android.hardware.camera2.params.MeteringRectangle;
import android.hardware.camera2.params.StreamConfigurationMap;
import android.location.Location;
import android.location.LocationManager;
import android.media.ExifInterface;
import android.media.Image;
import android.media.ImageReader;
import android.media.ImageWriter;
import android.media.Image.Plane;
import android.os.Build;
import android.os.Environment;
import android.os.Handler;
import android.util.Log;
import android.util.Pair;
import android.util.Size;
import android.view.Display;
import android.view.Surface;
import android.view.WindowManager;
import com.android.ex.camera2.blocking.BlockingCameraManager;
import com.android.ex.camera2.blocking.BlockingCameraManager.BlockingOpenException;
import com.android.ex.camera2.blocking.BlockingSessionCallback;
import com.android.ex.camera2.blocking.BlockingStateCallback;
import com.android.ex.camera2.exceptions.TimeoutRuntimeException;
import junit.framework.Assert;
import org.mockito.Mockito;
import java.io.FileOutputStream;
import java.io.IOException;
import java.lang.reflect.Array;
import java.nio.ByteBuffer;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collections;
import java.util.Comparator;
import java.util.Date;
import java.util.HashMap;
import java.util.List;
import java.util.concurrent.atomic.AtomicLong;
import java.util.concurrent.LinkedBlockingQueue;
import java.util.concurrent.Semaphore;
import java.util.concurrent.TimeUnit;
import java.text.ParseException;
import java.text.SimpleDateFormat;
/**
* A package private utility class for wrapping up the camera2 cts test common utility functions
*/
public class CameraTestUtils extends Assert {
private static final String TAG = "CameraTestUtils";
private static final boolean VERBOSE = Log.isLoggable(TAG, Log.VERBOSE);
private static final boolean DEBUG = Log.isLoggable(TAG, Log.DEBUG);
public static final Size SIZE_BOUND_1080P = new Size(1920, 1088);
public static final Size SIZE_BOUND_2160P = new Size(3840, 2160);
// Only test the preview size that is no larger than 1080p.
public static final Size PREVIEW_SIZE_BOUND = SIZE_BOUND_1080P;
// Default timeouts for reaching various states
public static final int CAMERA_OPEN_TIMEOUT_MS = 3000;
public static final int CAMERA_CLOSE_TIMEOUT_MS = 3000;
public static final int CAMERA_IDLE_TIMEOUT_MS = 3000;
public static final int CAMERA_ACTIVE_TIMEOUT_MS = 1000;
public static final int CAMERA_BUSY_TIMEOUT_MS = 1000;
public static final int CAMERA_UNCONFIGURED_TIMEOUT_MS = 1000;
public static final int CAMERA_CONFIGURE_TIMEOUT_MS = 3000;
public static final int CAPTURE_RESULT_TIMEOUT_MS = 3000;
public static final int CAPTURE_IMAGE_TIMEOUT_MS = 3000;
public static final int SESSION_CONFIGURE_TIMEOUT_MS = 3000;
public static final int SESSION_CLOSE_TIMEOUT_MS = 3000;
public static final int SESSION_READY_TIMEOUT_MS = 3000;
public static final int SESSION_ACTIVE_TIMEOUT_MS = 1000;
public static final int MAX_READER_IMAGES = 5;
private static final int EXIF_DATETIME_LENGTH = 19;
private static final int EXIF_DATETIME_ERROR_MARGIN_SEC = 60;
private static final float EXIF_FOCAL_LENGTH_ERROR_MARGIN = 0.001f;
private static final float EXIF_EXPOSURE_TIME_ERROR_MARGIN_RATIO = 0.05f;
private static final float EXIF_EXPOSURE_TIME_MIN_ERROR_MARGIN_SEC = 0.002f;
private static final float EXIF_APERTURE_ERROR_MARGIN = 0.001f;
private static final Location sTestLocation0 = new Location(LocationManager.GPS_PROVIDER);
private static final Location sTestLocation1 = new Location(LocationManager.GPS_PROVIDER);
private static final Location sTestLocation2 = new Location(LocationManager.NETWORK_PROVIDER);
protected static final String DEBUG_FILE_NAME_BASE =
Environment.getExternalStorageDirectory().getPath();
static {
sTestLocation0.setTime(1199145600L);
sTestLocation0.setLatitude(37.736071);
sTestLocation0.setLongitude(-122.441983);
sTestLocation0.setAltitude(21.0);
sTestLocation1.setTime(1199145601L);
sTestLocation1.setLatitude(0.736071);
sTestLocation1.setLongitude(0.441983);
sTestLocation1.setAltitude(1.0);
sTestLocation2.setTime(1199145602L);
sTestLocation2.setLatitude(-89.736071);
sTestLocation2.setLongitude(-179.441983);
sTestLocation2.setAltitude(100000.0);
}
// Exif test data vectors.
public static final ExifTestData[] EXIF_TEST_DATA = {
new ExifTestData(
/*gpsLocation*/ sTestLocation0,
/* orientation */90,
/* jpgQuality */(byte) 80,
/* thumbQuality */(byte) 75),
new ExifTestData(
/*gpsLocation*/ sTestLocation1,
/* orientation */180,
/* jpgQuality */(byte) 90,
/* thumbQuality */(byte) 85),
new ExifTestData(
/*gpsLocation*/ sTestLocation2,
/* orientation */270,
/* jpgQuality */(byte) 100,
/* thumbQuality */(byte) 100)
};
/**
* Create an {@link android.media.ImageReader} object and get the surface.
*
* @param size The size of this ImageReader to be created.
* @param format The format of this ImageReader to be created
* @param maxNumImages The max number of images that can be acquired simultaneously.
* @param listener The listener used by this ImageReader to notify callbacks.
* @param handler The handler to use for any listener callbacks.
*/
public static ImageReader makeImageReader(Size size, int format, int maxNumImages,
ImageReader.OnImageAvailableListener listener, Handler handler) {
ImageReader reader;
reader = ImageReader.newInstance(size.getWidth(), size.getHeight(), format,
maxNumImages);
reader.setOnImageAvailableListener(listener, handler);
if (VERBOSE) Log.v(TAG, "Created ImageReader size " + size);
return reader;
}
/**
* Create an ImageWriter and hook up the ImageListener.
*
* @param inputSurface The input surface of the ImageWriter.
* @param maxImages The max number of Images that can be dequeued simultaneously.
* @param listener The listener used by this ImageWriter to notify callbacks
* @param handler The handler to post listener callbacks.
* @return ImageWriter object created.
*/
public static ImageWriter makeImageWriter(
Surface inputSurface, int maxImages,
ImageWriter.OnImageReleasedListener listener, Handler handler) {
ImageWriter writer = ImageWriter.newInstance(inputSurface, maxImages);
writer.setOnImageReleasedListener(listener, handler);
return writer;
}
/**
* Close pending images and clean up an {@link android.media.ImageReader} object.
* @param reader an {@link android.media.ImageReader} to close.
*/
public static void closeImageReader(ImageReader reader) {
if (reader != null) {
reader.close();
}
}
/**
* Close pending images and clean up an {@link android.media.ImageWriter} object.
* @param writer an {@link android.media.ImageWriter} to close.
*/
public static void closeImageWriter(ImageWriter writer) {
if (writer != null) {
writer.close();
}
}
/**
* Dummy listener that release the image immediately once it is available.
*
* <p>
* It can be used for the case where we don't care the image data at all.
* </p>
*/
public static class ImageDropperListener implements ImageReader.OnImageAvailableListener {
@Override
public void onImageAvailable(ImageReader reader) {
Image image = null;
try {
image = reader.acquireNextImage();
} finally {
if (image != null) {
image.close();
}
}
}
}
/**
* Image listener that release the image immediately after validating the image
*/
public static class ImageVerifierListener implements ImageReader.OnImageAvailableListener {
private Size mSize;
private int mFormat;
public ImageVerifierListener(Size sz, int format) {
mSize = sz;
mFormat = format;
}
@Override
public void onImageAvailable(ImageReader reader) {
Image image = null;
try {
image = reader.acquireNextImage();
} finally {
if (image != null) {
validateImage(image, mSize.getWidth(), mSize.getHeight(), mFormat, null);
image.close();
}
}
}
}
public static class SimpleImageReaderListener
implements ImageReader.OnImageAvailableListener {
private final LinkedBlockingQueue<Image> mQueue =
new LinkedBlockingQueue<Image>();
// Indicate whether this listener will drop images or not,
// when the queued images reaches the reader maxImages
private final boolean mAsyncMode;
// maxImages held by the queue in async mode.
private final int mMaxImages;
/**
* Create a synchronous SimpleImageReaderListener that queues the images
* automatically when they are available, no image will be dropped. If
* the caller doesn't call getImage(), the producer will eventually run
* into buffer starvation.
*/
public SimpleImageReaderListener() {
mAsyncMode = false;
mMaxImages = 0;
}
/**
* Create a synchronous/asynchronous SimpleImageReaderListener that
* queues the images automatically when they are available. For
* asynchronous listener, image will be dropped if the queued images
* reach to maxImages queued. If the caller doesn't call getImage(), the
* producer will not be blocked. For synchronous listener, no image will
* be dropped. If the caller doesn't call getImage(), the producer will
* eventually run into buffer starvation.
*
* @param asyncMode If the listener is operating at asynchronous mode.
* @param maxImages The max number of images held by this listener.
*/
/**
*
* @param asyncMode
*/
public SimpleImageReaderListener(boolean asyncMode, int maxImages) {
mAsyncMode = asyncMode;
mMaxImages = maxImages;
}
@Override
public void onImageAvailable(ImageReader reader) {
try {
mQueue.put(reader.acquireNextImage());
if (mAsyncMode && mQueue.size() >= mMaxImages) {
Image img = mQueue.poll();
img.close();
}
} catch (InterruptedException e) {
throw new UnsupportedOperationException(
"Can't handle InterruptedException in onImageAvailable");
}
}
/**
* Get an image from the image reader.
*
* @param timeout Timeout value for the wait.
* @return The image from the image reader.
*/
public Image getImage(long timeout) throws InterruptedException {
Image image = mQueue.poll(timeout, TimeUnit.MILLISECONDS);
assertNotNull("Wait for an image timed out in " + timeout + "ms", image);
return image;
}
/**
* Drain the pending images held by this listener currently.
*
*/
public void drain() {
while (!mQueue.isEmpty()) {
Image image = mQueue.poll();
assertNotNull("Unable to get an image", image);
image.close();
}
}
}
public static class SimpleImageWriterListener implements ImageWriter.OnImageReleasedListener {
private final Semaphore mImageReleasedSema = new Semaphore(0);
private final ImageWriter mWriter;
@Override
public void onImageReleased(ImageWriter writer) {
if (writer != mWriter) {
return;
}
if (VERBOSE) {
Log.v(TAG, "Input image is released");
}
mImageReleasedSema.release();
}
public SimpleImageWriterListener(ImageWriter writer) {
if (writer == null) {
throw new IllegalArgumentException("writer cannot be null");
}
mWriter = writer;
}
public void waitForImageReleased(long timeoutMs) throws InterruptedException {
if (!mImageReleasedSema.tryAcquire(timeoutMs, TimeUnit.MILLISECONDS)) {
fail("wait for image available timed out after " + timeoutMs + "ms");
}
}
}
public static class SimpleCaptureCallback extends CameraCaptureSession.CaptureCallback {
private final LinkedBlockingQueue<TotalCaptureResult> mQueue =
new LinkedBlockingQueue<TotalCaptureResult>();
private final LinkedBlockingQueue<CaptureFailure> mFailureQueue =
new LinkedBlockingQueue<>();
// Pair<CaptureRequest, Long> is a pair of capture request and timestamp.
private final LinkedBlockingQueue<Pair<CaptureRequest, Long>> mCaptureStartQueue =
new LinkedBlockingQueue<>();
private AtomicLong mNumFramesArrived = new AtomicLong(0);
@Override
public void onCaptureStarted(CameraCaptureSession session, CaptureRequest request,
long timestamp, long frameNumber) {
try {
mCaptureStartQueue.put(new Pair(request, timestamp));
} catch (InterruptedException e) {
throw new UnsupportedOperationException(
"Can't handle InterruptedException in onCaptureStarted");
}
}
@Override
public void onCaptureCompleted(CameraCaptureSession session, CaptureRequest request,
TotalCaptureResult result) {
try {
mNumFramesArrived.incrementAndGet();
mQueue.put(result);
} catch (InterruptedException e) {
throw new UnsupportedOperationException(
"Can't handle InterruptedException in onCaptureCompleted");
}
}
@Override
public void onCaptureFailed(CameraCaptureSession session, CaptureRequest request,
CaptureFailure failure) {
try {
mFailureQueue.put(failure);
} catch (InterruptedException e) {
throw new UnsupportedOperationException(
"Can't handle InterruptedException in onCaptureFailed");
}
}
@Override
public void onCaptureSequenceCompleted(CameraCaptureSession session, int sequenceId,
long frameNumber) {
}
public long getTotalNumFrames() {
return mNumFramesArrived.get();
}
public CaptureResult getCaptureResult(long timeout) {
return getTotalCaptureResult(timeout);
}
public TotalCaptureResult getCaptureResult(long timeout, long timestamp) {
try {
long currentTs = -1L;
TotalCaptureResult result;
while (true) {
result = mQueue.poll(timeout, TimeUnit.MILLISECONDS);
if (result == null) {
throw new RuntimeException(
"Wait for a capture result timed out in " + timeout + "ms");
}
currentTs = result.get(CaptureResult.SENSOR_TIMESTAMP);
if (currentTs == timestamp) {
return result;
}
}
} catch (InterruptedException e) {
throw new UnsupportedOperationException("Unhandled interrupted exception", e);
}
}
public TotalCaptureResult getTotalCaptureResult(long timeout) {
try {
TotalCaptureResult result = mQueue.poll(timeout, TimeUnit.MILLISECONDS);
assertNotNull("Wait for a capture result timed out in " + timeout + "ms", result);
return result;
} catch (InterruptedException e) {
throw new UnsupportedOperationException("Unhandled interrupted exception", e);
}
}
/**
* Get the {@link #CaptureResult capture result} for a given
* {@link #CaptureRequest capture request}.
*
* @param myRequest The {@link #CaptureRequest capture request} whose
* corresponding {@link #CaptureResult capture result} was
* being waited for
* @param numResultsWait Number of frames to wait for the capture result
* before timeout.
* @throws TimeoutRuntimeException If more than numResultsWait results are
* seen before the result matching myRequest arrives, or each
* individual wait for result times out after
* {@value #CAPTURE_RESULT_TIMEOUT_MS}ms.
*/
public CaptureResult getCaptureResultForRequest(CaptureRequest myRequest,
int numResultsWait) {
return getTotalCaptureResultForRequest(myRequest, numResultsWait);
}
/**
* Get the {@link #TotalCaptureResult total capture result} for a given
* {@link #CaptureRequest capture request}.
*
* @param myRequest The {@link #CaptureRequest capture request} whose
* corresponding {@link #TotalCaptureResult capture result} was
* being waited for
* @param numResultsWait Number of frames to wait for the capture result
* before timeout.
* @throws TimeoutRuntimeException If more than numResultsWait results are
* seen before the result matching myRequest arrives, or each
* individual wait for result times out after
* {@value #CAPTURE_RESULT_TIMEOUT_MS}ms.
*/
public TotalCaptureResult getTotalCaptureResultForRequest(CaptureRequest myRequest,
int numResultsWait) {
ArrayList<CaptureRequest> captureRequests = new ArrayList<>(1);
captureRequests.add(myRequest);
return getTotalCaptureResultsForRequests(captureRequests, numResultsWait)[0];
}
/**
* Get an array of {@link #TotalCaptureResult total capture results} for a given list of
* {@link #CaptureRequest capture requests}. This can be used when the order of results
* may not the same as the order of requests.
*
* @param captureRequests The list of {@link #CaptureRequest capture requests} whose
* corresponding {@link #TotalCaptureResult capture results} are
* being waited for.
* @param numResultsWait Number of frames to wait for the capture results
* before timeout.
* @throws TimeoutRuntimeException If more than numResultsWait results are
* seen before all the results matching captureRequests arrives.
*/
public TotalCaptureResult[] getTotalCaptureResultsForRequests(
List<CaptureRequest> captureRequests, int numResultsWait) {
if (numResultsWait < 0) {
throw new IllegalArgumentException("numResultsWait must be no less than 0");
}
if (captureRequests == null || captureRequests.size() == 0) {
throw new IllegalArgumentException("captureRequests must have at least 1 request.");
}
// Create a request -> a list of result indices map that it will wait for.
HashMap<CaptureRequest, ArrayList<Integer>> remainingResultIndicesMap = new HashMap<>();
for (int i = 0; i < captureRequests.size(); i++) {
CaptureRequest request = captureRequests.get(i);
ArrayList<Integer> indices = remainingResultIndicesMap.get(request);
if (indices == null) {
indices = new ArrayList<>();
remainingResultIndicesMap.put(request, indices);
}
indices.add(i);
}
TotalCaptureResult[] results = new TotalCaptureResult[captureRequests.size()];
int i = 0;
do {
TotalCaptureResult result = getTotalCaptureResult(CAPTURE_RESULT_TIMEOUT_MS);
CaptureRequest request = result.getRequest();
ArrayList<Integer> indices = remainingResultIndicesMap.get(request);
if (indices != null) {
results[indices.get(0)] = result;
indices.remove(0);
// Remove the entry if all results for this request has been fulfilled.
if (indices.isEmpty()) {
remainingResultIndicesMap.remove(request);
}
}
if (remainingResultIndicesMap.isEmpty()) {
return results;
}
} while (i++ < numResultsWait);
throw new TimeoutRuntimeException("Unable to get the expected capture result after "
+ "waiting for " + numResultsWait + " results");
}
/**
* Get an array list of {@link #CaptureFailure capture failure} with maxNumFailures entries
* at most. If it times out before maxNumFailures failures are received, return the failures
* received so far.
*
* @param maxNumFailures The maximal number of failures to return. If it times out before
* the maximal number of failures are received, return the received
* failures so far.
* @throws UnsupportedOperationException If an error happens while waiting on the failure.
*/
public ArrayList<CaptureFailure> getCaptureFailures(long maxNumFailures) {
ArrayList<CaptureFailure> failures = new ArrayList<>();
try {
for (int i = 0; i < maxNumFailures; i++) {
CaptureFailure failure = mFailureQueue.poll(CAPTURE_RESULT_TIMEOUT_MS,
TimeUnit.MILLISECONDS);
if (failure == null) {
// If waiting on a failure times out, return the failures so far.
break;
}
failures.add(failure);
}
} catch (InterruptedException e) {
throw new UnsupportedOperationException("Unhandled interrupted exception", e);
}
return failures;
}
/**
* Wait until the capture start of a request and expected timestamp arrives or it times
* out after a number of capture starts.
*
* @param request The request for the capture start to wait for.
* @param timestamp The timestamp for the capture start to wait for.
* @param numCaptureStartsWait The number of capture start events to wait for before timing
* out.
*/
public void waitForCaptureStart(CaptureRequest request, Long timestamp,
int numCaptureStartsWait) throws Exception {
Pair<CaptureRequest, Long> expectedShutter = new Pair<>(request, timestamp);
int i = 0;
do {
Pair<CaptureRequest, Long> shutter = mCaptureStartQueue.poll(
CAPTURE_RESULT_TIMEOUT_MS, TimeUnit.MILLISECONDS);
if (shutter == null) {
throw new TimeoutRuntimeException("Unable to get any more capture start " +
"event after waiting for " + CAPTURE_RESULT_TIMEOUT_MS + " ms.");
} else if (expectedShutter.equals(shutter)) {
return;
}
} while (i++ < numCaptureStartsWait);
throw new TimeoutRuntimeException("Unable to get the expected capture start " +
"event after waiting for " + numCaptureStartsWait + " capture starts");
}
public boolean hasMoreResults()
{
return mQueue.isEmpty();
}
public void drain() {
mQueue.clear();
mNumFramesArrived.getAndSet(0);
mFailureQueue.clear();
mCaptureStartQueue.clear();
}
}
/**
* Block until the camera is opened.
*
* <p>Don't use this to test #onDisconnected/#onError since this will throw
* an AssertionError if it fails to open the camera device.</p>
*
* @return CameraDevice opened camera device
*
* @throws IllegalArgumentException
* If the handler is null, or if the handler's looper is current.
* @throws CameraAccessException
* If open fails immediately.
* @throws BlockingOpenException
* If open fails after blocking for some amount of time.
* @throws TimeoutRuntimeException
* If opening times out. Typically unrecoverable.
*/
public static CameraDevice openCamera(CameraManager manager, String cameraId,
CameraDevice.StateCallback listener, Handler handler) throws CameraAccessException,
BlockingOpenException {
/**
* Although camera2 API allows 'null' Handler (it will just use the current
* thread's Looper), this is not what we want for CTS.
*
* In CTS the default looper is used only to process events in between test runs,
* so anything sent there would not be executed inside a test and the test would fail.
*
* In this case, BlockingCameraManager#openCamera performs the check for us.
*/
return (new BlockingCameraManager(manager)).openCamera(cameraId, listener, handler);
}
/**
* Block until the camera is opened.
*
* <p>Don't use this to test #onDisconnected/#onError since this will throw
* an AssertionError if it fails to open the camera device.</p>
*
* @throws IllegalArgumentException
* If the handler is null, or if the handler's looper is current.
* @throws CameraAccessException
* If open fails immediately.
* @throws BlockingOpenException
* If open fails after blocking for some amount of time.
* @throws TimeoutRuntimeException
* If opening times out. Typically unrecoverable.
*/
public static CameraDevice openCamera(CameraManager manager, String cameraId, Handler handler)
throws CameraAccessException,
BlockingOpenException {
return openCamera(manager, cameraId, /*listener*/null, handler);
}
/**
* Configure a new camera session with output surfaces and type.
*
* @param camera The CameraDevice to be configured.
* @param outputSurfaces The surface list that used for camera output.
* @param listener The callback CameraDevice will notify when capture results are available.
*/
public static CameraCaptureSession configureCameraSession(CameraDevice camera,
List<Surface> outputSurfaces, boolean isHighSpeed,
CameraCaptureSession.StateCallback listener, Handler handler)
throws CameraAccessException {
BlockingSessionCallback sessionListener = new BlockingSessionCallback(listener);
if (isHighSpeed) {
camera.createConstrainedHighSpeedCaptureSession(outputSurfaces,
sessionListener, handler);
} else {
camera.createCaptureSession(outputSurfaces, sessionListener, handler);
}
CameraCaptureSession session =
sessionListener.waitAndGetSession(SESSION_CONFIGURE_TIMEOUT_MS);
assertFalse("Camera session should not be a reprocessable session",
session.isReprocessable());
String sessionType = isHighSpeed ? "High Speed" : "Normal";
assertTrue("Capture session type must be " + sessionType,
isHighSpeed ==
CameraConstrainedHighSpeedCaptureSession.class.isAssignableFrom(session.getClass()));
return session;
}
/**
* Configure a new camera session with output surfaces.
*
* @param camera The CameraDevice to be configured.
* @param outputSurfaces The surface list that used for camera output.
* @param listener The callback CameraDevice will notify when capture results are available.
*/
public static CameraCaptureSession configureCameraSession(CameraDevice camera,
List<Surface> outputSurfaces,
CameraCaptureSession.StateCallback listener, Handler handler)
throws CameraAccessException {
return configureCameraSession(camera, outputSurfaces, /*isHighSpeed*/false,
listener, handler);
}
public static CameraCaptureSession configureReprocessableCameraSession(CameraDevice camera,
InputConfiguration inputConfiguration, List<Surface> outputSurfaces,
CameraCaptureSession.StateCallback listener, Handler handler)
throws CameraAccessException {
BlockingSessionCallback sessionListener = new BlockingSessionCallback(listener);
camera.createReprocessableCaptureSession(inputConfiguration, outputSurfaces,
sessionListener, handler);
Integer[] sessionStates = {BlockingSessionCallback.SESSION_READY,
BlockingSessionCallback.SESSION_CONFIGURE_FAILED};
int state = sessionListener.getStateWaiter().waitForAnyOfStates(
Arrays.asList(sessionStates), SESSION_CONFIGURE_TIMEOUT_MS);
assertTrue("Creating a reprocessable session failed.",
state == BlockingSessionCallback.SESSION_READY);
CameraCaptureSession session =
sessionListener.waitAndGetSession(SESSION_CONFIGURE_TIMEOUT_MS);
assertTrue("Camera session should be a reprocessable session", session.isReprocessable());
return session;
}
public static <T> void assertArrayNotEmpty(T arr, String message) {
assertTrue(message, arr != null && Array.getLength(arr) > 0);
}
/**
* Check if the format is a legal YUV format camera supported.
*/
public static void checkYuvFormat(int format) {
if ((format != ImageFormat.YUV_420_888) &&
(format != ImageFormat.NV21) &&
(format != ImageFormat.YV12)) {
fail("Wrong formats: " + format);
}
}
/**
* Check if image size and format match given size and format.
*/
public static void checkImage(Image image, int width, int height, int format) {
// Image reader will wrap YV12/NV21 image by YUV_420_888
if (format == ImageFormat.NV21 || format == ImageFormat.YV12) {
format = ImageFormat.YUV_420_888;
}
assertNotNull("Input image is invalid", image);
assertEquals("Format doesn't match", format, image.getFormat());
assertEquals("Width doesn't match", width, image.getWidth());
assertEquals("Height doesn't match", height, image.getHeight());
}
/**
* <p>Read data from all planes of an Image into a contiguous unpadded, unpacked
* 1-D linear byte array, such that it can be write into disk, or accessed by
* software conveniently. It supports YUV_420_888/NV21/YV12 and JPEG input
* Image format.</p>
*
* <p>For YUV_420_888/NV21/YV12/Y8/Y16, it returns a byte array that contains
* the Y plane data first, followed by U(Cb), V(Cr) planes if there is any
* (xstride = width, ystride = height for chroma and luma components).</p>
*
* <p>For JPEG, it returns a 1-D byte array contains a complete JPEG image.</p>
*/
public static byte[] getDataFromImage(Image image) {
assertNotNull("Invalid image:", image);
int format = image.getFormat();
int width = image.getWidth();
int height = image.getHeight();
int rowStride, pixelStride;
byte[] data = null;
// Read image data
Plane[] planes = image.getPlanes();
assertTrue("Fail to get image planes", planes != null && planes.length > 0);
// Check image validity
checkAndroidImageFormat(image);
ByteBuffer buffer = null;
// JPEG doesn't have pixelstride and rowstride, treat it as 1D buffer.
// Same goes for DEPTH_POINT_CLOUD
if (format == ImageFormat.JPEG || format == ImageFormat.DEPTH_POINT_CLOUD) {
buffer = planes[0].getBuffer();
assertNotNull("Fail to get jpeg or depth ByteBuffer", buffer);
data = new byte[buffer.remaining()];
buffer.get(data);
buffer.rewind();
return data;
}
int offset = 0;
data = new byte[width * height * ImageFormat.getBitsPerPixel(format) / 8];
int maxRowSize = planes[0].getRowStride();
for (int i = 0; i < planes.length; i++) {
if (maxRowSize < planes[i].getRowStride()) {
maxRowSize = planes[i].getRowStride();
}
}
byte[] rowData = new byte[maxRowSize];
if(VERBOSE) Log.v(TAG, "get data from " + planes.length + " planes");
for (int i = 0; i < planes.length; i++) {
buffer = planes[i].getBuffer();
assertNotNull("Fail to get bytebuffer from plane", buffer);
rowStride = planes[i].getRowStride();
pixelStride = planes[i].getPixelStride();
assertTrue("pixel stride " + pixelStride + " is invalid", pixelStride > 0);
if (VERBOSE) {
Log.v(TAG, "pixelStride " + pixelStride);
Log.v(TAG, "rowStride " + rowStride);
Log.v(TAG, "width " + width);
Log.v(TAG, "height " + height);
}
// For multi-planar yuv images, assuming yuv420 with 2x2 chroma subsampling.
int w = (i == 0) ? width : width / 2;
int h = (i == 0) ? height : height / 2;
assertTrue("rowStride " + rowStride + " should be >= width " + w , rowStride >= w);
for (int row = 0; row < h; row++) {
int bytesPerPixel = ImageFormat.getBitsPerPixel(format) / 8;
int length;
if (pixelStride == bytesPerPixel) {
// Special case: optimized read of the entire row
length = w * bytesPerPixel;
buffer.get(data, offset, length);
offset += length;
} else {
// Generic case: should work for any pixelStride but slower.
// Use intermediate buffer to avoid read byte-by-byte from
// DirectByteBuffer, which is very bad for performance
length = (w - 1) * pixelStride + bytesPerPixel;
buffer.get(rowData, 0, length);
for (int col = 0; col < w; col++) {
data[offset++] = rowData[col * pixelStride];
}
}
// Advance buffer the remainder of the row stride
if (row < h - 1) {
buffer.position(buffer.position() + rowStride - length);
}
}
if (VERBOSE) Log.v(TAG, "Finished reading data from plane " + i);
buffer.rewind();
}
return data;
}
/**
* <p>Check android image format validity for an image, only support below formats:</p>
*
* <p>YUV_420_888/NV21/YV12, can add more for future</p>
*/
public static void checkAndroidImageFormat(Image image) {
int format = image.getFormat();
Plane[] planes = image.getPlanes();
switch (format) {
case ImageFormat.YUV_420_888:
case ImageFormat.NV21:
case ImageFormat.YV12:
assertEquals("YUV420 format Images should have 3 planes", 3, planes.length);
break;
case ImageFormat.JPEG:
case ImageFormat.RAW_SENSOR:
case ImageFormat.DEPTH16:
case ImageFormat.DEPTH_POINT_CLOUD:
assertEquals("JPEG/RAW/depth Images should have one plane", 1, planes.length);
break;
default:
fail("Unsupported Image Format: " + format);
}
}
public static void dumpFile(String fileName, Bitmap data) {
FileOutputStream outStream;
try {
Log.v(TAG, "output will be saved as " + fileName);
outStream = new FileOutputStream(fileName);
} catch (IOException ioe) {
throw new RuntimeException("Unable to create debug output file " + fileName, ioe);
}
try {
data.compress(Bitmap.CompressFormat.JPEG, /*quality*/90, outStream);
outStream.close();
} catch (IOException ioe) {
throw new RuntimeException("failed writing data to file " + fileName, ioe);
}
}
public static void dumpFile(String fileName, byte[] data) {
FileOutputStream outStream;
try {
Log.v(TAG, "output will be saved as " + fileName);
outStream = new FileOutputStream(fileName);
} catch (IOException ioe) {
throw new RuntimeException("Unable to create debug output file " + fileName, ioe);
}
try {
outStream.write(data);
outStream.close();
} catch (IOException ioe) {
throw new RuntimeException("failed writing data to file " + fileName, ioe);
}
}
/**
* Get the available output sizes for the user-defined {@code format}.
*
* <p>Note that implementation-defined/hidden formats are not supported.</p>
*/
public static Size[] getSupportedSizeForFormat(int format, String cameraId,
CameraManager cameraManager) throws CameraAccessException {
CameraCharacteristics properties = cameraManager.getCameraCharacteristics(cameraId);
assertNotNull("Can't get camera characteristics!", properties);
if (VERBOSE) {
Log.v(TAG, "get camera characteristics for camera: " + cameraId);
}
StreamConfigurationMap configMap =
properties.get(CameraCharacteristics.SCALER_STREAM_CONFIGURATION_MAP);
Size[] availableSizes = configMap.getOutputSizes(format);
assertArrayNotEmpty(availableSizes, "availableSizes should not be empty for format: "
+ format);
Size[] highResAvailableSizes = configMap.getHighResolutionOutputSizes(format);
if (highResAvailableSizes != null && highResAvailableSizes.length > 0) {
Size[] allSizes = new Size[availableSizes.length + highResAvailableSizes.length];
System.arraycopy(availableSizes, 0, allSizes, 0,
availableSizes.length);
System.arraycopy(highResAvailableSizes, 0, allSizes, availableSizes.length,
highResAvailableSizes.length);
availableSizes = allSizes;
}
if (VERBOSE) Log.v(TAG, "Supported sizes are: " + Arrays.deepToString(availableSizes));
return availableSizes;
}
/**
* Get the available output sizes for the given class.
*
*/
public static Size[] getSupportedSizeForClass(Class klass, String cameraId,
CameraManager cameraManager) throws CameraAccessException {
CameraCharacteristics properties = cameraManager.getCameraCharacteristics(cameraId);
assertNotNull("Can't get camera characteristics!", properties);
if (VERBOSE) {
Log.v(TAG, "get camera characteristics for camera: " + cameraId);
}
StreamConfigurationMap configMap =
properties.get(CameraCharacteristics.SCALER_STREAM_CONFIGURATION_MAP);
Size[] availableSizes = configMap.getOutputSizes(klass);
assertArrayNotEmpty(availableSizes, "availableSizes should not be empty for class: "
+ klass);
Size[] highResAvailableSizes = configMap.getHighResolutionOutputSizes(ImageFormat.PRIVATE);
if (highResAvailableSizes != null && highResAvailableSizes.length > 0) {
Size[] allSizes = new Size[availableSizes.length + highResAvailableSizes.length];
System.arraycopy(availableSizes, 0, allSizes, 0,
availableSizes.length);
System.arraycopy(highResAvailableSizes, 0, allSizes, availableSizes.length,
highResAvailableSizes.length);
availableSizes = allSizes;
}
if (VERBOSE) Log.v(TAG, "Supported sizes are: " + Arrays.deepToString(availableSizes));
return availableSizes;
}
/**
* Size comparator that compares the number of pixels it covers.
*
* <p>If two the areas of two sizes are same, compare the widths.</p>
*/
public static class SizeComparator implements Comparator<Size> {
@Override
public int compare(Size lhs, Size rhs) {
return CameraUtils
.compareSizes(lhs.getWidth(), lhs.getHeight(), rhs.getWidth(), rhs.getHeight());
}
}
/**
* Get sorted size list in descending order. Remove the sizes larger than
* the bound. If the bound is null, don't do the size bound filtering.
*/
static public List<Size> getSupportedPreviewSizes(String cameraId,
CameraManager cameraManager, Size bound) throws CameraAccessException {
Size[] rawSizes = getSupportedSizeForClass(android.view.SurfaceHolder.class, cameraId,
cameraManager);
assertArrayNotEmpty(rawSizes,
"Available sizes for SurfaceHolder class should not be empty");
if (VERBOSE) {
Log.v(TAG, "Supported sizes are: " + Arrays.deepToString(rawSizes));
}
if (bound == null) {
return getAscendingOrderSizes(Arrays.asList(rawSizes), /*ascending*/false);
}
List<Size> sizes = new ArrayList<Size>();
for (Size sz: rawSizes) {
if (sz.getWidth() <= bound.getWidth() && sz.getHeight() <= bound.getHeight()) {
sizes.add(sz);
}
}
return getAscendingOrderSizes(sizes, /*ascending*/false);
}
/**
* Get a sorted list of sizes from a given size list.
*
* <p>
* The size is compare by area it covers, if the areas are same, then
* compare the widths.
* </p>
*
* @param sizeList The input size list to be sorted
* @param ascending True if the order is ascending, otherwise descending order
* @return The ordered list of sizes
*/
static public List<Size> getAscendingOrderSizes(final List<Size> sizeList, boolean ascending) {
if (sizeList == null) {
throw new IllegalArgumentException("sizeList shouldn't be null");
}
Comparator<Size> comparator = new SizeComparator();
List<Size> sortedSizes = new ArrayList<Size>();
sortedSizes.addAll(sizeList);
Collections.sort(sortedSizes, comparator);
if (!ascending) {
Collections.reverse(sortedSizes);
}
return sortedSizes;
}
/**
* Get sorted (descending order) size list for given format. Remove the sizes larger than
* the bound. If the bound is null, don't do the size bound filtering.
*/
static public List<Size> getSortedSizesForFormat(String cameraId,
CameraManager cameraManager, int format, Size bound) throws CameraAccessException {
Comparator<Size> comparator = new SizeComparator();
Size[] sizes = getSupportedSizeForFormat(format, cameraId, cameraManager);
List<Size> sortedSizes = null;
if (bound != null) {
sortedSizes = new ArrayList<Size>(/*capacity*/1);
for (Size sz : sizes) {
if (comparator.compare(sz, bound) <= 0) {
sortedSizes.add(sz);
}
}
} else {
sortedSizes = Arrays.asList(sizes);
}
assertTrue("Supported size list should have at least one element",
sortedSizes.size() > 0);
Collections.sort(sortedSizes, comparator);
// Make it in descending order.
Collections.reverse(sortedSizes);
return sortedSizes;
}
/**
* Get supported video size list for a given camera device.
*
* <p>
* Filter out the sizes that are larger than the bound. If the bound is
* null, don't do the size bound filtering.
* </p>
*/
static public List<Size> getSupportedVideoSizes(String cameraId,
CameraManager cameraManager, Size bound) throws CameraAccessException {
Size[] rawSizes = getSupportedSizeForClass(android.media.MediaRecorder.class,
cameraId, cameraManager);
assertArrayNotEmpty(rawSizes,
"Available sizes for MediaRecorder class should not be empty");
if (VERBOSE) {
Log.v(TAG, "Supported sizes are: " + Arrays.deepToString(rawSizes));
}
if (bound == null) {
return getAscendingOrderSizes(Arrays.asList(rawSizes), /*ascending*/false);
}
List<Size> sizes = new ArrayList<Size>();
for (Size sz: rawSizes) {
if (sz.getWidth() <= bound.getWidth() && sz.getHeight() <= bound.getHeight()) {
sizes.add(sz);
}
}
return getAscendingOrderSizes(sizes, /*ascending*/false);
}
/**
* Get supported video size list (descending order) for a given camera device.
*
* <p>
* Filter out the sizes that are larger than the bound. If the bound is
* null, don't do the size bound filtering.
* </p>
*/
static public List<Size> getSupportedStillSizes(String cameraId,
CameraManager cameraManager, Size bound) throws CameraAccessException {
return getSortedSizesForFormat(cameraId, cameraManager, ImageFormat.JPEG, bound);
}
static public Size getMinPreviewSize(String cameraId, CameraManager cameraManager)
throws CameraAccessException {
List<Size> sizes = getSupportedPreviewSizes(cameraId, cameraManager, null);
return sizes.get(sizes.size() - 1);
}
/**
* Get max supported preview size for a camera device.
*/
static public Size getMaxPreviewSize(String cameraId, CameraManager cameraManager)
throws CameraAccessException {
return getMaxPreviewSize(cameraId, cameraManager, /*bound*/null);
}
/**
* Get max preview size for a camera device in the supported sizes that are no larger
* than the bound.
*/
static public Size getMaxPreviewSize(String cameraId, CameraManager cameraManager, Size bound)
throws CameraAccessException {
List<Size> sizes = getSupportedPreviewSizes(cameraId, cameraManager, bound);
return sizes.get(0);
}
/**
* Get max depth size for a camera device.
*/
static public Size getMaxDepthSize(String cameraId, CameraManager cameraManager)
throws CameraAccessException {
List<Size> sizes = getSortedSizesForFormat(cameraId, cameraManager, ImageFormat.DEPTH16,
/*bound*/ null);
return sizes.get(0);
}
/**
* Get the largest size by area.
*
* @param sizes an array of sizes, must have at least 1 element
*
* @return Largest Size
*
* @throws IllegalArgumentException if sizes was null or had 0 elements
*/
public static Size getMaxSize(Size... sizes) {
if (sizes == null || sizes.length == 0) {
throw new IllegalArgumentException("sizes was empty");
}
Size sz = sizes[0];
for (Size size : sizes) {
if (size.getWidth() * size.getHeight() > sz.getWidth() * sz.getHeight()) {
sz = size;
}
}
return sz;
}
/**
* Returns true if the given {@code array} contains the given element.
*
* @param array {@code array} to check for {@code elem}
* @param elem {@code elem} to test for
* @return {@code true} if the given element is contained
*/
public static boolean contains(int[] array, int elem) {
if (array == null) return false;
for (int i = 0; i < array.length; i++) {
if (elem == array[i]) return true;
}
return false;
}
/**
* Get object array from byte array.
*
* @param array Input byte array to be converted
* @return Byte object array converted from input byte array
*/
public static Byte[] toObject(byte[] array) {
return convertPrimitiveArrayToObjectArray(array, Byte.class);
}
/**
* Get object array from int array.
*
* @param array Input int array to be converted
* @return Integer object array converted from input int array
*/
public static Integer[] toObject(int[] array) {
return convertPrimitiveArrayToObjectArray(array, Integer.class);
}
/**
* Get object array from float array.
*
* @param array Input float array to be converted
* @return Float object array converted from input float array
*/
public static Float[] toObject(float[] array) {
return convertPrimitiveArrayToObjectArray(array, Float.class);
}
/**
* Get object array from double array.
*
* @param array Input double array to be converted
* @return Double object array converted from input double array
*/
public static Double[] toObject(double[] array) {
return convertPrimitiveArrayToObjectArray(array, Double.class);
}
/**
* Convert a primitive input array into its object array version (e.g. from int[] to Integer[]).
*
* @param array Input array object
* @param wrapperClass The boxed class it converts to
* @return Boxed version of primitive array
*/
private static <T> T[] convertPrimitiveArrayToObjectArray(final Object array,
final Class<T> wrapperClass) {
// getLength does the null check and isArray check already.
int arrayLength = Array.getLength(array);
if (arrayLength == 0) {
throw new IllegalArgumentException("Input array shouldn't be empty");
}
@SuppressWarnings("unchecked")
final T[] result = (T[]) Array.newInstance(wrapperClass, arrayLength);
for (int i = 0; i < arrayLength; i++) {
Array.set(result, i, Array.get(array, i));
}
return result;
}
/**
* Validate image based on format and size.
*
* @param image The image to be validated.
* @param width The image width.
* @param height The image height.
* @param format The image format.
* @param filePath The debug dump file path, null if don't want to dump to
* file.
* @throws UnsupportedOperationException if calling with an unknown format
*/
public static void validateImage(Image image, int width, int height, int format,
String filePath) {
checkImage(image, width, height, format);
/**
* TODO: validate timestamp:
* 1. capture result timestamp against the image timestamp (need
* consider frame drops)
* 2. timestamps should be monotonically increasing for different requests
*/
if(VERBOSE) Log.v(TAG, "validating Image");
byte[] data = getDataFromImage(image);
assertTrue("Invalid image data", data != null && data.length > 0);
switch (format) {
case ImageFormat.JPEG:
validateJpegData(data, width, height, filePath);
break;
case ImageFormat.YUV_420_888:
case ImageFormat.YV12:
validateYuvData(data, width, height, format, image.getTimestamp(), filePath);
break;
case ImageFormat.RAW_SENSOR:
validateRaw16Data(data, width, height, format, image.getTimestamp(), filePath);
break;
case ImageFormat.DEPTH16:
validateDepth16Data(data, width, height, format, image.getTimestamp(), filePath);
break;
case ImageFormat.DEPTH_POINT_CLOUD:
validateDepthPointCloudData(data, width, height, format, image.getTimestamp(), filePath);
break;
default:
throw new UnsupportedOperationException("Unsupported format for validation: "
+ format);
}
}
/**
* Provide a mock for {@link CameraDevice.StateCallback}.
*
* <p>Only useful because mockito can't mock {@link CameraDevice.StateCallback} which is an
* abstract class.</p>
*
* <p>
* Use this instead of other classes when needing to verify interactions, since
* trying to spy on {@link BlockingStateCallback} (or others) will cause unnecessary extra
* interactions which will cause false test failures.
* </p>
*
*/
public static class MockStateCallback extends CameraDevice.StateCallback {
@Override
public void onOpened(CameraDevice camera) {
}
@Override
public void onDisconnected(CameraDevice camera) {
}
@Override
public void onError(CameraDevice camera, int error) {
}
private MockStateCallback() {}
/**
* Create a Mockito-ready mocked StateCallback.
*/
public static MockStateCallback mock() {
return Mockito.spy(new MockStateCallback());
}
}
private static void validateJpegData(byte[] jpegData, int width, int height, String filePath) {
BitmapFactory.Options bmpOptions = new BitmapFactory.Options();
// DecodeBound mode: only parse the frame header to get width/height.
// it doesn't decode the pixel.
bmpOptions.inJustDecodeBounds = true;
BitmapFactory.decodeByteArray(jpegData, 0, jpegData.length, bmpOptions);
assertEquals(width, bmpOptions.outWidth);
assertEquals(height, bmpOptions.outHeight);
// Pixel decoding mode: decode whole image. check if the image data
// is decodable here.
assertNotNull("Decoding jpeg failed",
BitmapFactory.decodeByteArray(jpegData, 0, jpegData.length));
if (DEBUG && filePath != null) {
String fileName =
filePath + "/" + width + "x" + height + ".jpeg";
dumpFile(fileName, jpegData);
}
}
private static void validateYuvData(byte[] yuvData, int width, int height, int format,
long ts, String filePath) {
checkYuvFormat(format);
if (VERBOSE) Log.v(TAG, "Validating YUV data");
int expectedSize = width * height * ImageFormat.getBitsPerPixel(format) / 8;
assertEquals("Yuv data doesn't match", expectedSize, yuvData.length);
// TODO: Can add data validation for test pattern.
if (DEBUG && filePath != null) {
String fileName =
filePath + "/" + width + "x" + height + "_" + ts / 1e6 + ".yuv";
dumpFile(fileName, yuvData);
}
}
private static void validateRaw16Data(byte[] rawData, int width, int height, int format,
long ts, String filePath) {
if (VERBOSE) Log.v(TAG, "Validating raw data");
int expectedSize = width * height * ImageFormat.getBitsPerPixel(format) / 8;
assertEquals("Raw data doesn't match", expectedSize, rawData.length);
// TODO: Can add data validation for test pattern.
if (DEBUG && filePath != null) {
String fileName =
filePath + "/" + width + "x" + height + "_" + ts / 1e6 + ".raw16";
dumpFile(fileName, rawData);
}
return;
}
private static void validateDepth16Data(byte[] depthData, int width, int height, int format,
long ts, String filePath) {
if (VERBOSE) Log.v(TAG, "Validating depth16 data");
int expectedSize = width * height * ImageFormat.getBitsPerPixel(format) / 8;
assertEquals("Depth data doesn't match", expectedSize, depthData.length);
if (DEBUG && filePath != null) {
String fileName =
filePath + "/" + width + "x" + height + "_" + ts / 1e6 + ".depth16";
dumpFile(fileName, depthData);
}
return;
}
private static void validateDepthPointCloudData(byte[] depthData, int width, int height, int format,
long ts, String filePath) {
if (VERBOSE) Log.v(TAG, "Validating depth point cloud data");
// Can't validate size since it is variable
if (DEBUG && filePath != null) {
String fileName =
filePath + "/" + width + "x" + height + "_" + ts / 1e6 + ".depth_point_cloud";
dumpFile(fileName, depthData);
}
return;
}
public static <T> T getValueNotNull(CaptureResult result, CaptureResult.Key<T> key) {
if (result == null) {
throw new IllegalArgumentException("Result must not be null");
}
T value = result.get(key);
assertNotNull("Value of Key " + key.getName() + "shouldn't be null", value);
return value;
}
public static <T> T getValueNotNull(CameraCharacteristics characteristics,
CameraCharacteristics.Key<T> key) {
if (characteristics == null) {
throw new IllegalArgumentException("Camera characteristics must not be null");
}
T value = characteristics.get(key);
assertNotNull("Value of Key " + key.getName() + "shouldn't be null", value);
return value;
}
/**
* Get a crop region for a given zoom factor and center position.
* <p>
* The center position is normalized position in range of [0, 1.0], where
* (0, 0) represents top left corner, (1.0. 1.0) represents bottom right
* corner. The center position could limit the effective minimal zoom
* factor, for example, if the center position is (0.75, 0.75), the
* effective minimal zoom position becomes 2.0. If the requested zoom factor
* is smaller than 2.0, a crop region with 2.0 zoom factor will be returned.
* </p>
* <p>
* The aspect ratio of the crop region is maintained the same as the aspect
* ratio of active array.
* </p>
*
* @param zoomFactor The zoom factor to generate the crop region, it must be
* >= 1.0
* @param center The normalized zoom center point that is in the range of [0, 1].
* @param maxZoom The max zoom factor supported by this device.
* @param activeArray The active array size of this device.
* @return crop region for the given normalized center and zoom factor.
*/
public static Rect getCropRegionForZoom(float zoomFactor, final PointF center,
final float maxZoom, final Rect activeArray) {
if (zoomFactor < 1.0) {
throw new IllegalArgumentException("zoom factor " + zoomFactor + " should be >= 1.0");
}
if (center.x > 1.0 || center.x < 0) {
throw new IllegalArgumentException("center.x " + center.x
+ " should be in range of [0, 1.0]");
}
if (center.y > 1.0 || center.y < 0) {
throw new IllegalArgumentException("center.y " + center.y
+ " should be in range of [0, 1.0]");
}
if (maxZoom < 1.0) {
throw new IllegalArgumentException("max zoom factor " + maxZoom + " should be >= 1.0");
}
if (activeArray == null) {
throw new IllegalArgumentException("activeArray must not be null");
}
float minCenterLength = Math.min(Math.min(center.x, 1.0f - center.x),
Math.min(center.y, 1.0f - center.y));
float minEffectiveZoom = 0.5f / minCenterLength;
if (minEffectiveZoom > maxZoom) {
throw new IllegalArgumentException("Requested center " + center.toString() +
" has minimal zoomable factor " + minEffectiveZoom + ", which exceeds max"
+ " zoom factor " + maxZoom);
}
if (zoomFactor < minEffectiveZoom) {
Log.w(TAG, "Requested zoomFactor " + zoomFactor + " > minimal zoomable factor "
+ minEffectiveZoom + ". It will be overwritten by " + minEffectiveZoom);
zoomFactor = minEffectiveZoom;
}
int cropCenterX = (int)(activeArray.width() * center.x);
int cropCenterY = (int)(activeArray.height() * center.y);
int cropWidth = (int) (activeArray.width() / zoomFactor);
int cropHeight = (int) (activeArray.height() / zoomFactor);
return new Rect(
/*left*/cropCenterX - cropWidth / 2,
/*top*/cropCenterY - cropHeight / 2,
/*right*/ cropCenterX + cropWidth / 2 - 1,
/*bottom*/cropCenterY + cropHeight / 2 - 1);
}
/**
* Calculate output 3A region from the intersection of input 3A region and cropped region.
*
* @param requestRegions The input 3A regions
* @param cropRect The cropped region
* @return expected 3A regions output in capture result
*/
public static MeteringRectangle[] getExpectedOutputRegion(
MeteringRectangle[] requestRegions, Rect cropRect){
MeteringRectangle[] resultRegions = new MeteringRectangle[requestRegions.length];
for (int i = 0; i < requestRegions.length; i++) {
Rect requestRect = requestRegions[i].getRect();
Rect resultRect = new Rect();
assertTrue("Input 3A region must intersect cropped region",
resultRect.setIntersect(requestRect, cropRect));
resultRegions[i] = new MeteringRectangle(
resultRect,
requestRegions[i].getMeteringWeight());
}
return resultRegions;
}
/**
* Copy source image data to destination image.
*
* @param src The source image to be copied from.
* @param dst The destination image to be copied to.
* @throws IllegalArgumentException If the source and destination images have
* different format, or one of the images is not copyable.
*/
public static void imageCopy(Image src, Image dst) {
if (src == null || dst == null) {
throw new IllegalArgumentException("Images should be non-null");
}
if (src.getFormat() != dst.getFormat()) {
throw new IllegalArgumentException("Src and dst images should have the same format");
}
if (src.getFormat() == ImageFormat.PRIVATE ||
dst.getFormat() == ImageFormat.PRIVATE) {
throw new IllegalArgumentException("PRIVATE format images are not copyable");
}
// TODO: check the owner of the dst image, it must be from ImageWriter, other source may
// not be writable. Maybe we should add an isWritable() method in image class.
Plane[] srcPlanes = src.getPlanes();
Plane[] dstPlanes = dst.getPlanes();
ByteBuffer srcBuffer = null;
ByteBuffer dstBuffer = null;
for (int i = 0; i < srcPlanes.length; i++) {
srcBuffer = srcPlanes[i].getBuffer();
int srcPos = srcBuffer.position();
srcBuffer.rewind();
dstBuffer = dstPlanes[i].getBuffer();
dstBuffer.rewind();
dstBuffer.put(srcBuffer);
srcBuffer.position(srcPos);
dstBuffer.rewind();
}
}
/**
* <p>
* Checks whether the two images are strongly equal.
* </p>
* <p>
* Two images are strongly equal if and only if the data, formats, sizes,
* and timestamps are same. For {@link ImageFormat#PRIVATE PRIVATE} format
* images, the image data is not not accessible thus the data comparison is
* effectively skipped as the number of planes is zero.
* </p>
* <p>
* Note that this method compares the pixel data even outside of the crop
* region, which may not be necessary for general use case.
* </p>
*
* @param lhsImg First image to be compared with.
* @param rhsImg Second image to be compared with.
* @return true if the two images are equal, false otherwise.
* @throws IllegalArgumentException If either of image is null.
*/
public static boolean isImageStronglyEqual(Image lhsImg, Image rhsImg) {
if (lhsImg == null || rhsImg == null) {
throw new IllegalArgumentException("Images should be non-null");
}
if (lhsImg.getFormat() != rhsImg.getFormat()) {
Log.i(TAG, "lhsImg format " + lhsImg.getFormat() + " is different with rhsImg format "
+ rhsImg.getFormat());
return false;
}
if (lhsImg.getWidth() != rhsImg.getWidth()) {
Log.i(TAG, "lhsImg width " + lhsImg.getWidth() + " is different with rhsImg width "
+ rhsImg.getWidth());
return false;
}
if (lhsImg.getHeight() != rhsImg.getHeight()) {
Log.i(TAG, "lhsImg height " + lhsImg.getHeight() + " is different with rhsImg height "
+ rhsImg.getHeight());
return false;
}
if (lhsImg.getTimestamp() != rhsImg.getTimestamp()) {
Log.i(TAG, "lhsImg timestamp " + lhsImg.getTimestamp()
+ " is different with rhsImg timestamp " + rhsImg.getTimestamp());
return false;
}
if (!lhsImg.getCropRect().equals(rhsImg.getCropRect())) {
Log.i(TAG, "lhsImg crop rect " + lhsImg.getCropRect()
+ " is different with rhsImg crop rect " + rhsImg.getCropRect());
return false;
}
// Compare data inside of the image.
Plane[] lhsPlanes = lhsImg.getPlanes();
Plane[] rhsPlanes = rhsImg.getPlanes();
ByteBuffer lhsBuffer = null;
ByteBuffer rhsBuffer = null;
for (int i = 0; i < lhsPlanes.length; i++) {
lhsBuffer = lhsPlanes[i].getBuffer();
rhsBuffer = rhsPlanes[i].getBuffer();
if (!lhsBuffer.equals(rhsBuffer)) {
Log.i(TAG, "byte buffers for plane " + i + " don't matach.");
return false;
}
}
return true;
}
/**
* Set jpeg related keys in a capture request builder.
*
* @param builder The capture request builder to set the keys inl
* @param exifData The exif data to set.
* @param thumbnailSize The thumbnail size to set.
* @param collector The camera error collector to collect errors.
*/
public static void setJpegKeys(CaptureRequest.Builder builder, ExifTestData exifData,
Size thumbnailSize, CameraErrorCollector collector) {
builder.set(CaptureRequest.JPEG_THUMBNAIL_SIZE, thumbnailSize);
builder.set(CaptureRequest.JPEG_GPS_LOCATION, exifData.gpsLocation);
builder.set(CaptureRequest.JPEG_ORIENTATION, exifData.jpegOrientation);
builder.set(CaptureRequest.JPEG_QUALITY, exifData.jpegQuality);
builder.set(CaptureRequest.JPEG_THUMBNAIL_QUALITY,
exifData.thumbnailQuality);
// Validate request set and get.
collector.expectEquals("JPEG thumbnail size request set and get should match",
thumbnailSize, builder.get(CaptureRequest.JPEG_THUMBNAIL_SIZE));
collector.expectTrue("GPS locations request set and get should match.",
areGpsFieldsEqual(exifData.gpsLocation,
builder.get(CaptureRequest.JPEG_GPS_LOCATION)));
collector.expectEquals("JPEG orientation request set and get should match",
exifData.jpegOrientation,
builder.get(CaptureRequest.JPEG_ORIENTATION));
collector.expectEquals("JPEG quality request set and get should match",
exifData.jpegQuality, builder.get(CaptureRequest.JPEG_QUALITY));
collector.expectEquals("JPEG thumbnail quality request set and get should match",
exifData.thumbnailQuality,
builder.get(CaptureRequest.JPEG_THUMBNAIL_QUALITY));
}
/**
* Simple validation of JPEG image size and format.
* <p>
* Only validate the image object sanity. It is fast, but doesn't actually
* check the buffer data. Assert is used here as it make no sense to
* continue the test if the jpeg image captured has some serious failures.
* </p>
*
* @param image The captured jpeg image
* @param expectedSize Expected capture jpeg size
*/
public static void basicValidateJpegImage(Image image, Size expectedSize) {
Size imageSz = new Size(image.getWidth(), image.getHeight());
assertTrue(
String.format("Image size doesn't match (expected %s, actual %s) ",
expectedSize.toString(), imageSz.toString()), expectedSize.equals(imageSz));
assertEquals("Image format should be JPEG", ImageFormat.JPEG, image.getFormat());
assertNotNull("Image plane shouldn't be null", image.getPlanes());
assertEquals("Image plane number should be 1", 1, image.getPlanes().length);
// Jpeg decoding validate was done in ImageReaderTest, no need to duplicate the test here.
}
/**
* Verify the JPEG EXIF and JPEG related keys in a capture result are expected.
* - Capture request get values are same as were set.
* - capture result's exif data is the same as was set by
* the capture request.
* - new tags in the result set by the camera service are
* present and semantically correct.
*
* @param image The output JPEG image to verify.
* @param captureResult The capture result to verify.
* @param expectedSize The expected JPEG size.
* @param expectedThumbnailSize The expected thumbnail size.
* @param expectedExifData The expected EXIF data
* @param staticInfo The static metadata for the camera device.
* @param jpegFilename The filename to dump the jpeg to.
* @param collector The camera error collector to collect errors.
*/
public static void verifyJpegKeys(Image image, CaptureResult captureResult, Size expectedSize,
Size expectedThumbnailSize, ExifTestData expectedExifData, StaticMetadata staticInfo,
CameraErrorCollector collector) throws Exception {
basicValidateJpegImage(image, expectedSize);
byte[] jpegBuffer = getDataFromImage(image);
// Have to dump into a file to be able to use ExifInterface
String jpegFilename = DEBUG_FILE_NAME_BASE + "/verifyJpegKeys.jpeg";
dumpFile(jpegFilename, jpegBuffer);
ExifInterface exif = new ExifInterface(jpegFilename);
if (expectedThumbnailSize.equals(new Size(0,0))) {
collector.expectTrue("Jpeg shouldn't have thumbnail when thumbnail size is (0, 0)",
!exif.hasThumbnail());
} else {
collector.expectTrue("Jpeg must have thumbnail for thumbnail size " +
expectedThumbnailSize, exif.hasThumbnail());
}
// Validate capture result vs. request
Size resultThumbnailSize = captureResult.get(CaptureResult.JPEG_THUMBNAIL_SIZE);
int orientationTested = expectedExifData.jpegOrientation;
// Legacy shim always doesn't rotate thumbnail size
if ((orientationTested == 90 || orientationTested == 270) &&
staticInfo.isHardwareLevelLimitedOrBetter()) {
int exifOrientation = exif.getAttributeInt(ExifInterface.TAG_ORIENTATION,
/*defaultValue*/-1);
if (exifOrientation == ExifInterface.ORIENTATION_UNDEFINED) {
// Device physically rotated image+thumbnail data
// Expect thumbnail size to be also rotated
resultThumbnailSize = new Size(resultThumbnailSize.getHeight(),
resultThumbnailSize.getWidth());
}
}
collector.expectEquals("JPEG thumbnail size result and request should match",
expectedThumbnailSize, resultThumbnailSize);
if (collector.expectKeyValueNotNull(captureResult, CaptureResult.JPEG_GPS_LOCATION) !=
null) {
collector.expectTrue("GPS location result and request should match.",
areGpsFieldsEqual(expectedExifData.gpsLocation,
captureResult.get(CaptureResult.JPEG_GPS_LOCATION)));
}
collector.expectEquals("JPEG orientation result and request should match",
expectedExifData.jpegOrientation,
captureResult.get(CaptureResult.JPEG_ORIENTATION));
collector.expectEquals("JPEG quality result and request should match",
expectedExifData.jpegQuality, captureResult.get(CaptureResult.JPEG_QUALITY));
collector.expectEquals("JPEG thumbnail quality result and request should match",
expectedExifData.thumbnailQuality,
captureResult.get(CaptureResult.JPEG_THUMBNAIL_QUALITY));
// Validate other exif tags for all non-legacy devices
if (!staticInfo.isHardwareLevelLegacy()) {
verifyJpegExifExtraTags(exif, expectedSize, captureResult, staticInfo, collector);
}
}
/**
* Get the degree of an EXIF orientation.
*/
private static int getExifOrientationInDegree(int exifOrientation,
CameraErrorCollector collector) {
switch (exifOrientation) {
case ExifInterface.ORIENTATION_NORMAL:
return 0;
case ExifInterface.ORIENTATION_ROTATE_90:
return 90;
case ExifInterface.ORIENTATION_ROTATE_180:
return 180;
case ExifInterface.ORIENTATION_ROTATE_270:
return 270;
default:
collector.addMessage("It is impossible to get non 0, 90, 180, 270 degress exif" +
"info based on the request orientation range");
return 0;
}
}
/**
* Validate and return the focal length.
*
* @param result Capture result to get the focal length
* @return Focal length from capture result or -1 if focal length is not available.
*/
private static float validateFocalLength(CaptureResult result, StaticMetadata staticInfo,
CameraErrorCollector collector) {
float[] focalLengths = staticInfo.getAvailableFocalLengthsChecked();
Float resultFocalLength = result.get(CaptureResult.LENS_FOCAL_LENGTH);
if (collector.expectTrue("Focal length is invalid",
resultFocalLength != null && resultFocalLength > 0)) {
List<Float> focalLengthList =
Arrays.asList(CameraTestUtils.toObject(focalLengths));
collector.expectTrue("Focal length should be one of the available focal length",
focalLengthList.contains(resultFocalLength));
return resultFocalLength;
}
return -1;
}
/**
* Validate and return the aperture.
*
* @param result Capture result to get the aperture
* @return Aperture from capture result or -1 if aperture is not available.
*/
private static float validateAperture(CaptureResult result, StaticMetadata staticInfo,
CameraErrorCollector collector) {
float[] apertures = staticInfo.getAvailableAperturesChecked();
Float resultAperture = result.get(CaptureResult.LENS_APERTURE);
if (collector.expectTrue("Capture result aperture is invalid",
resultAperture != null && resultAperture > 0)) {
List<Float> apertureList =
Arrays.asList(CameraTestUtils.toObject(apertures));
collector.expectTrue("Aperture should be one of the available apertures",
apertureList.contains(resultAperture));
return resultAperture;
}
return -1;
}
/**
* Return the closest value in an array of floats.
*/
private static float getClosestValueInArray(float[] values, float target) {
int minIdx = 0;
float minDistance = Math.abs(values[0] - target);
for(int i = 0; i < values.length; i++) {
float distance = Math.abs(values[i] - target);
if (minDistance > distance) {
minDistance = distance;
minIdx = i;
}
}
return values[minIdx];
}
/**
* Return if two Location's GPS field are the same.
*/
private static boolean areGpsFieldsEqual(Location a, Location b) {
if (a == null || b == null) {
return false;
}
return a.getTime() == b.getTime() && a.getLatitude() == b.getLatitude() &&
a.getLongitude() == b.getLongitude() && a.getAltitude() == b.getAltitude() &&
a.getProvider() == b.getProvider();
}
/**
* Verify extra tags in JPEG EXIF
*/
private static void verifyJpegExifExtraTags(ExifInterface exif, Size jpegSize,
CaptureResult result, StaticMetadata staticInfo, CameraErrorCollector collector)
throws ParseException {
/**
* TAG_IMAGE_WIDTH and TAG_IMAGE_LENGTH and TAG_ORIENTATION.
* Orientation and exif width/height need to be tested carefully, two cases:
*
* 1. Device rotate the image buffer physically, then exif width/height may not match
* the requested still capture size, we need swap them to check.
*
* 2. Device use the exif tag to record the image orientation, it doesn't rotate
* the jpeg image buffer itself. In this case, the exif width/height should always match
* the requested still capture size, and the exif orientation should always match the
* requested orientation.
*
*/
int exifWidth = exif.getAttributeInt(ExifInterface.TAG_IMAGE_WIDTH, /*defaultValue*/0);
int exifHeight = exif.getAttributeInt(ExifInterface.TAG_IMAGE_LENGTH, /*defaultValue*/0);
Size exifSize = new Size(exifWidth, exifHeight);
// Orientation could be missing, which is ok, default to 0.
int exifOrientation = exif.getAttributeInt(ExifInterface.TAG_ORIENTATION,
/*defaultValue*/-1);
// Get requested orientation from result, because they should be same.
if (collector.expectKeyValueNotNull(result, CaptureResult.JPEG_ORIENTATION) != null) {
int requestedOrientation = result.get(CaptureResult.JPEG_ORIENTATION);
final int ORIENTATION_MIN = ExifInterface.ORIENTATION_UNDEFINED;
final int ORIENTATION_MAX = ExifInterface.ORIENTATION_ROTATE_270;
boolean orientationValid = collector.expectTrue(String.format(
"Exif orientation must be in range of [%d, %d]",
ORIENTATION_MIN, ORIENTATION_MAX),
exifOrientation >= ORIENTATION_MIN && exifOrientation <= ORIENTATION_MAX);
if (orientationValid) {
/**
* Device captured image doesn't respect the requested orientation,
* which means it rotates the image buffer physically. Then we
* should swap the exif width/height accordingly to compare.
*/
boolean deviceRotatedImage = exifOrientation == ExifInterface.ORIENTATION_UNDEFINED;
if (deviceRotatedImage) {
// Case 1.
boolean needSwap = (requestedOrientation % 180 == 90);
if (needSwap) {
exifSize = new Size(exifHeight, exifWidth);
}
} else {
// Case 2.
collector.expectEquals("Exif orientaiton should match requested orientation",
requestedOrientation, getExifOrientationInDegree(exifOrientation,
collector));
}
}
}
/**
* Ideally, need check exifSize == jpegSize == actual buffer size. But
* jpegSize == jpeg decode bounds size(from jpeg jpeg frame
* header, not exif) was validated in ImageReaderTest, no need to
* validate again here.
*/
collector.expectEquals("Exif size should match jpeg capture size", jpegSize, exifSize);
// TAG_DATETIME, it should be local time
long currentTimeInMs = System.currentTimeMillis();
long currentTimeInSecond = currentTimeInMs / 1000;
Date date = new Date(currentTimeInMs);
String localDatetime = new SimpleDateFormat("yyyy:MM:dd HH:").format(date);
String dateTime = exif.getAttribute(ExifInterface.TAG_DATETIME);
if (collector.expectTrue("Exif TAG_DATETIME shouldn't be null", dateTime != null)) {
collector.expectTrue("Exif TAG_DATETIME is wrong",
dateTime.length() == EXIF_DATETIME_LENGTH);
long exifTimeInSecond =
new SimpleDateFormat("yyyy:MM:dd HH:mm:ss").parse(dateTime).getTime() / 1000;
long delta = currentTimeInSecond - exifTimeInSecond;
collector.expectTrue("Capture time deviates too much from the current time",
Math.abs(delta) < EXIF_DATETIME_ERROR_MARGIN_SEC);
// It should be local time.
collector.expectTrue("Exif date time should be local time",
dateTime.startsWith(localDatetime));
}
// TAG_FOCAL_LENGTH.
float[] focalLengths = staticInfo.getAvailableFocalLengthsChecked();
float exifFocalLength = (float)exif.getAttributeDouble(ExifInterface.TAG_FOCAL_LENGTH, -1);
collector.expectEquals("Focal length should match",
getClosestValueInArray(focalLengths, exifFocalLength),
exifFocalLength, EXIF_FOCAL_LENGTH_ERROR_MARGIN);
// More checks for focal length.
collector.expectEquals("Exif focal length should match capture result",
validateFocalLength(result, staticInfo, collector), exifFocalLength);
// TAG_EXPOSURE_TIME
// ExifInterface API gives exposure time value in the form of float instead of rational
String exposureTime = exif.getAttribute(ExifInterface.TAG_EXPOSURE_TIME);
collector.expectNotNull("Exif TAG_EXPOSURE_TIME shouldn't be null", exposureTime);
if (staticInfo.areKeysAvailable(CaptureResult.SENSOR_EXPOSURE_TIME)) {
if (exposureTime != null) {
double exposureTimeValue = Double.parseDouble(exposureTime);
long expTimeResult = result.get(CaptureResult.SENSOR_EXPOSURE_TIME);
double expected = expTimeResult / 1e9;
double tolerance = expected * EXIF_EXPOSURE_TIME_ERROR_MARGIN_RATIO;
tolerance = Math.max(tolerance, EXIF_EXPOSURE_TIME_MIN_ERROR_MARGIN_SEC);
collector.expectEquals("Exif exposure time doesn't match", expected,
exposureTimeValue, tolerance);
}
}
// TAG_APERTURE
// ExifInterface API gives aperture value in the form of float instead of rational
String exifAperture = exif.getAttribute(ExifInterface.TAG_APERTURE);
collector.expectNotNull("Exif TAG_APERTURE shouldn't be null", exifAperture);
if (staticInfo.areKeysAvailable(CameraCharacteristics.LENS_INFO_AVAILABLE_APERTURES)) {
float[] apertures = staticInfo.getAvailableAperturesChecked();
if (exifAperture != null) {
float apertureValue = Float.parseFloat(exifAperture);
collector.expectEquals("Aperture value should match",
getClosestValueInArray(apertures, apertureValue),
apertureValue, EXIF_APERTURE_ERROR_MARGIN);
// More checks for aperture.
collector.expectEquals("Exif aperture length should match capture result",
validateAperture(result, staticInfo, collector), apertureValue);
}
}
/**
* TAG_FLASH. TODO: For full devices, can check a lot more info
* (http://www.sno.phy.queensu.ca/~phil/exiftool/TagNames/EXIF.html#Flash)
*/
String flash = exif.getAttribute(ExifInterface.TAG_FLASH);
collector.expectNotNull("Exif TAG_FLASH shouldn't be null", flash);
/**
* TAG_WHITE_BALANCE. TODO: For full devices, with the DNG tags, we
* should be able to cross-check android.sensor.referenceIlluminant.
*/
String whiteBalance = exif.getAttribute(ExifInterface.TAG_WHITE_BALANCE);
collector.expectNotNull("Exif TAG_WHITE_BALANCE shouldn't be null", whiteBalance);
// TAG_MAKE
String make = exif.getAttribute(ExifInterface.TAG_MAKE);
collector.expectEquals("Exif TAG_MAKE is incorrect", Build.MANUFACTURER, make);
// TAG_MODEL
String model = exif.getAttribute(ExifInterface.TAG_MODEL);
collector.expectEquals("Exif TAG_MODEL is incorrect", Build.MODEL, model);
// TAG_ISO
int iso = exif.getAttributeInt(ExifInterface.TAG_ISO, /*defaultValue*/-1);
if (staticInfo.areKeysAvailable(CaptureResult.SENSOR_SENSITIVITY)) {
int expectedIso = result.get(CaptureResult.SENSOR_SENSITIVITY);
collector.expectEquals("Exif TAG_ISO is incorrect", expectedIso, iso);
}
// TAG_DATETIME_DIGITIZED (a.k.a Create time for digital cameras).
String digitizedTime = exif.getAttribute(ExifInterface.TAG_DATETIME_DIGITIZED);
collector.expectNotNull("Exif TAG_DATETIME_DIGITIZED shouldn't be null", digitizedTime);
if (digitizedTime != null) {
String expectedDateTime = exif.getAttribute(ExifInterface.TAG_DATETIME);
collector.expectNotNull("Exif TAG_DATETIME shouldn't be null", expectedDateTime);
if (expectedDateTime != null) {
collector.expectEquals("dataTime should match digitizedTime",
expectedDateTime, digitizedTime);
}
}
/**
* TAG_SUBSEC_TIME. Since the sub second tag strings are truncated to at
* most 9 digits in ExifInterface implementation, use getAttributeInt to
* sanitize it. When the default value -1 is returned, it means that
* this exif tag either doesn't exist or is a non-numerical invalid
* string. Same rule applies to the rest of sub second tags.
*/
int subSecTime = exif.getAttributeInt(ExifInterface.TAG_SUBSEC_TIME, /*defaultValue*/-1);
collector.expectTrue("Exif TAG_SUBSEC_TIME value is null or invalid!", subSecTime > 0);
// TAG_SUBSEC_TIME_ORIG
int subSecTimeOrig = exif.getAttributeInt(ExifInterface.TAG_SUBSEC_TIME_ORIG,
/*defaultValue*/-1);
collector.expectTrue("Exif TAG_SUBSEC_TIME_ORIG value is null or invalid!",
subSecTimeOrig > 0);
// TAG_SUBSEC_TIME_DIG
int subSecTimeDig = exif.getAttributeInt(ExifInterface.TAG_SUBSEC_TIME_DIG,
/*defaultValue*/-1);
collector.expectTrue(
"Exif TAG_SUBSEC_TIME_DIG value is null or invalid!", subSecTimeDig > 0);
}
/**
* Immutable class wrapping the exif test data.
*/
public static class ExifTestData {
public final Location gpsLocation;
public final int jpegOrientation;
public final byte jpegQuality;
public final byte thumbnailQuality;
public ExifTestData(Location location, int orientation,
byte jpgQuality, byte thumbQuality) {
gpsLocation = location;
jpegOrientation = orientation;
jpegQuality = jpgQuality;
thumbnailQuality = thumbQuality;
}
}
public static Size getPreviewSizeBound(WindowManager windowManager, Size bound) {
Display display = windowManager.getDefaultDisplay();
int width = display.getWidth();
int height = display.getHeight();
if (height > width) {
height = width;
width = display.getHeight();
}
if (bound.getWidth() <= width &&
bound.getHeight() <= height)
return bound;
else
return new Size(width, height);
}
}