You can use Firebase ML to recognize well-known landmarks in an image.
Before you begin
- If you haven't already, add Firebase to your Android project.
-
In your module (app-level) Gradle file
(usually
<project>/<app-module>/build.gradle.kts
or<project>/<app-module>/build.gradle
), add the dependency for the Firebase ML Vision library for Android. We recommend using the Firebase Android BoM to control library versioning.dependencies { // Import the BoM for the Firebase platform implementation(platform("com.google.firebase:firebase-bom:33.6.0")) // Add the dependency for the Firebase ML Vision library // When using the BoM, you don't specify versions in Firebase library dependencies implementation 'com.google.firebase:firebase-ml-vision' }
By using the Firebase Android BoM, your app will always use compatible versions of Firebase Android libraries.
(Alternative) Add Firebase library dependencies without using the BoM
If you choose not to use the Firebase BoM, you must specify each Firebase library version in its dependency line.
Note that if you use multiple Firebase libraries in your app, we strongly recommend using the BoM to manage library versions, which ensures that all versions are compatible.
dependencies { // Add the dependency for the Firebase ML Vision library // When NOT using the BoM, you must specify versions in Firebase library dependencies implementation 'com.google.firebase:firebase-ml-vision:24.1.0' }
-
If you have not already enabled Cloud-based APIs for your project, do so now:
- Open the Firebase ML APIs page of the Firebase console.
-
If you have not already upgraded your project to the Blaze pricing plan, click Upgrade to do so. (You will be prompted to upgrade only if your project isn't on the Blaze plan.)
Only Blaze-level projects can use Cloud-based APIs.
- If Cloud-based APIs aren't already enabled, click Enable Cloud-based APIs.
Configure the landmark detector
By default, the Cloud detector uses the STABLE
version of the
model and returns up to 10 results. If you want to change either of these
settings, specify them with a FirebaseVisionCloudDetectorOptions
object.
For example, to change both of the default settings, build a
FirebaseVisionCloudDetectorOptions
object as in the following
example:
Kotlin+KTX
val options = FirebaseVisionCloudDetectorOptions.Builder() .setModelType(FirebaseVisionCloudDetectorOptions.LATEST_MODEL) .setMaxResults(15) .build()
Java
FirebaseVisionCloudDetectorOptions options = new FirebaseVisionCloudDetectorOptions.Builder() .setModelType(FirebaseVisionCloudDetectorOptions.LATEST_MODEL) .setMaxResults(15) .build();
To use the default settings, you can use
FirebaseVisionCloudDetectorOptions.DEFAULT
in the next step.
Run the landmark detector
To recognize landmarks in an image, create aFirebaseVisionImage
object
from either a Bitmap
, media.Image
, ByteBuffer
, byte array, or a file on
the device. Then, pass the FirebaseVisionImage
object to the
FirebaseVisionCloudLandmarkDetector
's detectInImage
method.
Create a
FirebaseVisionImage
object from your image.-
To create a
FirebaseVisionImage
object from amedia.Image
object, such as when capturing an image from a device's camera, pass themedia.Image
object and the image's rotation toFirebaseVisionImage.fromMediaImage()
.If you use the CameraX library, the
OnImageCapturedListener
andImageAnalysis.Analyzer
classes calculate the rotation value for you, so you just need to convert the rotation to one of Firebase ML'sROTATION_
constants before callingFirebaseVisionImage.fromMediaImage()
:Kotlin+KTX
private class YourImageAnalyzer : ImageAnalysis.Analyzer { private fun degreesToFirebaseRotation(degrees: Int): Int = when(degrees) { 0 -> FirebaseVisionImageMetadata.ROTATION_0 90 -> FirebaseVisionImageMetadata.ROTATION_90 180 -> FirebaseVisionImageMetadata.ROTATION_180 270 -> FirebaseVisionImageMetadata.ROTATION_270 else -> throw Exception("Rotation must be 0, 90, 180, or 270.") } override fun analyze(imageProxy: ImageProxy?, degrees: Int) { val mediaImage = imageProxy?.image val imageRotation = degreesToFirebaseRotation(degrees) if (mediaImage != null) { val image = FirebaseVisionImage.fromMediaImage(mediaImage, imageRotation) // Pass image to an ML Vision API // ... } } }
Java
private class YourAnalyzer implements ImageAnalysis.Analyzer { private int degreesToFirebaseRotation(int degrees) { switch (degrees) { case 0: return FirebaseVisionImageMetadata.ROTATION_0; case 90: return FirebaseVisionImageMetadata.ROTATION_90; case 180: return FirebaseVisionImageMetadata.ROTATION_180; case 270: return FirebaseVisionImageMetadata.ROTATION_270; default: throw new IllegalArgumentException( "Rotation must be 0, 90, 180, or 270."); } } @Override public void analyze(ImageProxy imageProxy, int degrees) { if (imageProxy == null || imageProxy.getImage() == null) { return; } Image mediaImage = imageProxy.getImage(); int rotation = degreesToFirebaseRotation(degrees); FirebaseVisionImage image = FirebaseVisionImage.fromMediaImage(mediaImage, rotation); // Pass image to an ML Vision API // ... } }
If you don't use a camera library that gives you the image's rotation, you can calculate it from the device's rotation and the orientation of camera sensor in the device:
Kotlin+KTX
private val ORIENTATIONS = SparseIntArray() init { ORIENTATIONS.append(Surface.ROTATION_0, 90) ORIENTATIONS.append(Surface.ROTATION_90, 0) ORIENTATIONS.append(Surface.ROTATION_180, 270) ORIENTATIONS.append(Surface.ROTATION_270, 180) } /** * Get the angle by which an image must be rotated given the device's current * orientation. */ @RequiresApi(api = Build.VERSION_CODES.LOLLIPOP) @Throws(CameraAccessException::class) private fun getRotationCompensation(cameraId: String, activity: Activity, context: Context): Int { // Get the device's current rotation relative to its "native" orientation. // Then, from the ORIENTATIONS table, look up the angle the image must be // rotated to compensate for the device's rotation. val deviceRotation = activity.windowManager.defaultDisplay.rotation var rotationCompensation = ORIENTATIONS.get(deviceRotation) // On most devices, the sensor orientation is 90 degrees, but for some // devices it is 270 degrees. For devices with a sensor orientation of // 270, rotate the image an additional 180 ((270 + 270) % 360) degrees. val cameraManager = context.getSystemService(CAMERA_SERVICE) as CameraManager val sensorOrientation = cameraManager .getCameraCharacteristics(cameraId) .get(CameraCharacteristics.SENSOR_ORIENTATION)!! rotationCompensation = (rotationCompensation + sensorOrientation + 270) % 360 // Return the corresponding FirebaseVisionImageMetadata rotation value. val result: Int when (rotationCompensation) { 0 -> result = FirebaseVisionImageMetadata.ROTATION_0 90 -> result = FirebaseVisionImageMetadata.ROTATION_90 180 -> result = FirebaseVisionImageMetadata.ROTATION_180 270 -> result = FirebaseVisionImageMetadata.ROTATION_270 else -> { result = FirebaseVisionImageMetadata.ROTATION_0 Log.e(TAG, "Bad rotation value: $rotationCompensation") } } return result }
Java
private static final SparseIntArray ORIENTATIONS = new SparseIntArray(); static { ORIENTATIONS.append(Surface.ROTATION_0, 90); ORIENTATIONS.append(Surface.ROTATION_90, 0); ORIENTATIONS.append(Surface.ROTATION_180, 270); ORIENTATIONS.append(Surface.ROTATION_270, 180); } /** * Get the angle by which an image must be rotated given the device's current * orientation. */ @RequiresApi(api = Build.VERSION_CODES.LOLLIPOP) private int getRotationCompensation(String cameraId, Activity activity, Context context) throws CameraAccessException { // Get the device's current rotation relative to its "native" orientation. // Then, from the ORIENTATIONS table, look up the angle the image must be // rotated to compensate for the device's rotation. int deviceRotation = activity.getWindowManager().getDefaultDisplay().getRotation(); int rotationCompensation = ORIENTATIONS.get(deviceRotation); // On most devices, the sensor orientation is 90 degrees, but for some // devices it is 270 degrees. For devices with a sensor orientation of // 270, rotate the image an additional 180 ((270 + 270) % 360) degrees. CameraManager cameraManager = (CameraManager) context.getSystemService(CAMERA_SERVICE); int sensorOrientation = cameraManager .getCameraCharacteristics(cameraId) .get(CameraCharacteristics.SENSOR_ORIENTATION); rotationCompensation = (rotationCompensation + sensorOrientation + 270) % 360; // Return the corresponding FirebaseVisionImageMetadata rotation value. int result; switch (rotationCompensation) { case 0: result = FirebaseVisionImageMetadata.ROTATION_0; break; case 90: result = FirebaseVisionImageMetadata.ROTATION_90; break; case 180: result = FirebaseVisionImageMetadata.ROTATION_180; break; case 270: result = FirebaseVisionImageMetadata.ROTATION_270; break; default: result = FirebaseVisionImageMetadata.ROTATION_0; Log.e(TAG, "Bad rotation value: " + rotationCompensation); } return result; }
Then, pass the
media.Image
object and the rotation value toFirebaseVisionImage.fromMediaImage()
:Kotlin+KTX
val image = FirebaseVisionImage.fromMediaImage(mediaImage, rotation)
Java
FirebaseVisionImage image = FirebaseVisionImage.fromMediaImage(mediaImage, rotation);
- To create a
FirebaseVisionImage
object from a file URI, pass the app context and file URI toFirebaseVisionImage.fromFilePath()
. This is useful when you use anACTION_GET_CONTENT
intent to prompt the user to select an image from their gallery app.Kotlin+KTX
val image: FirebaseVisionImage try { image = FirebaseVisionImage.fromFilePath(context, uri) } catch (e: IOException) { e.printStackTrace() }
Java
FirebaseVisionImage image; try { image = FirebaseVisionImage.fromFilePath(context, uri); } catch (IOException e) { e.printStackTrace(); }
- To create a
FirebaseVisionImage
object from aByteBuffer
or a byte array, first calculate the image rotation as described above formedia.Image
input.Then, create a
FirebaseVisionImageMetadata
object that contains the image's height, width, color encoding format, and rotation:Kotlin+KTX
val metadata = FirebaseVisionImageMetadata.Builder() .setWidth(480) // 480x360 is typically sufficient for .setHeight(360) // image recognition .setFormat(FirebaseVisionImageMetadata.IMAGE_FORMAT_NV21) .setRotation(rotation) .build()
Java
FirebaseVisionImageMetadata metadata = new FirebaseVisionImageMetadata.Builder() .setWidth(480) // 480x360 is typically sufficient for .setHeight(360) // image recognition .setFormat(FirebaseVisionImageMetadata.IMAGE_FORMAT_NV21) .setRotation(rotation) .build();
Use the buffer or array, and the metadata object, to create a
FirebaseVisionImage
object:Kotlin+KTX
val image = FirebaseVisionImage.fromByteBuffer(buffer, metadata) // Or: val image = FirebaseVisionImage.fromByteArray(byteArray, metadata)
Java
FirebaseVisionImage image = FirebaseVisionImage.fromByteBuffer(buffer, metadata); // Or: FirebaseVisionImage image = FirebaseVisionImage.fromByteArray(byteArray, metadata);
- To create a
FirebaseVisionImage
object from aBitmap
object:Kotlin+KTX
val image = FirebaseVisionImage.fromBitmap(bitmap)
Java
FirebaseVisionImage image = FirebaseVisionImage.fromBitmap(bitmap);
Bitmap
object must be upright, with no additional rotation required.
-
Get an instance of
FirebaseVisionCloudLandmarkDetector
:Kotlin+KTX
val detector = FirebaseVision.getInstance() .visionCloudLandmarkDetector // Or, to change the default settings: // val detector = FirebaseVision.getInstance() // .getVisionCloudLandmarkDetector(options)
Java
FirebaseVisionCloudLandmarkDetector detector = FirebaseVision.getInstance() .getVisionCloudLandmarkDetector(); // Or, to change the default settings: // FirebaseVisionCloudLandmarkDetector detector = FirebaseVision.getInstance() // .getVisionCloudLandmarkDetector(options);
Finally, pass the image to the
detectInImage
method:Kotlin+KTX
val result = detector.detectInImage(image) .addOnSuccessListener { firebaseVisionCloudLandmarks -> // Task completed successfully // ... } .addOnFailureListener { e -> // Task failed with an exception // ... }
Java
Task<List<FirebaseVisionCloudLandmark>> result = detector.detectInImage(image) .addOnSuccessListener(new OnSuccessListener<List<FirebaseVisionCloudLandmark>>() { @Override public void onSuccess(List<FirebaseVisionCloudLandmark> firebaseVisionCloudLandmarks) { // Task completed successfully // ... } }) .addOnFailureListener(new OnFailureListener() { @Override public void onFailure(@NonNull Exception e) { // Task failed with an exception // ... } });
Get information about the recognized landmarks
If the landmark recognition operation succeeds, a list ofFirebaseVisionCloudLandmark
objects will be passed to the success listener. Each
FirebaseVisionCloudLandmark
object represents a landmark that was recognized in the
image. For each landmark, you can get its bounding coordinates in the input image,
the landmark's name, its latitude and longitude, its Knowledge Graph entity ID
(if available), and the confidence score of the match. For example:
Kotlin+KTX
for (landmark in firebaseVisionCloudLandmarks) { val bounds = landmark.boundingBox val landmarkName = landmark.landmark val entityId = landmark.entityId val confidence = landmark.confidence // Multiple locations are possible, e.g., the location of the depicted // landmark and the location the picture was taken. for (loc in landmark.locations) { val latitude = loc.latitude val longitude = loc.longitude } }
Java
for (FirebaseVisionCloudLandmark landmark: firebaseVisionCloudLandmarks) { Rect bounds = landmark.getBoundingBox(); String landmarkName = landmark.getLandmark(); String entityId = landmark.getEntityId(); float confidence = landmark.getConfidence(); // Multiple locations are possible, e.g., the location of the depicted // landmark and the location the picture was taken. for (FirebaseVisionLatLng loc: landmark.getLocations()) { double latitude = loc.getLatitude(); double longitude = loc.getLongitude(); } }
Next steps
- Before you deploy to production an app that uses a Cloud API, you should take some additional steps to prevent and mitigate the effect of unauthorized API access.