You can use ML Kit to recognize text in images. ML Kit has both a general-purpose API suitable for recognizing text in images, such as the text of a street sign, and an API optimized for recognizing the text of documents. The general-purpose API has both on-device and cloud-based models. Document text recognition is available only as a cloud-based model. See the overview for a comparison of the cloud and on-device models.
Before you begin
- If you haven't already, add Firebase to your Android project.
- Add the dependencies for the ML Kit Android libraries to your module
(app-level) Gradle file (usually
app/build.gradle
):apply plugin: 'com.android.application' apply plugin: 'com.google.gms.google-services' dependencies { // ... implementation 'com.google.firebase:firebase-ml-vision:24.0.3' }
-
Optional but recommended: If you use the on-device API, configure your
app to automatically download the ML model to the device after your app is
installed from the Play Store.
To do so, add the following declaration to your app's
AndroidManifest.xml
file: If you do not enable install-time model downloads, the model will be downloaded the first time you run the on-device detector. Requests you make before the download has completed will produce no results.<application ...> ... <meta-data android:name="com.google.firebase.ml.vision.DEPENDENCIES" android:value="ocr" /> <!-- To use multiple models: android:value="ocr,model2,model3" --> </application>
-
If you want to use the Cloud-based model, and you have not already enabled the Cloud-based APIs for your project, do so now:
- Open the ML Kit APIs page of the Firebase console.
-
If you have not already upgraded your project to a 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.
If you want to use only the on-device model, you can skip this step.
Now you are ready to start recognizing text in images.
Input image guidelines
-
For ML Kit to accurately recognize text, input images must contain text that is represented by sufficient pixel data. Ideally, for Latin text, each character should be at least 16x16 pixels. For Chinese, Japanese, and Korean text (only supported by the cloud-based APIs), each character should be 24x24 pixels. For all languages, there is generally no accuracy benefit for characters to be larger than 24x24 pixels.
So, for example, a 640x480 image might work well to scan a business card that occupies the full width of the image. To scan a document printed on letter-sized paper, a 720x1280 pixel image might be required.
-
Poor image focus can hurt text recognition accuracy. If you aren't getting acceptable results, try asking the user to recapture the image.
-
If you are recognizing text in a real-time application, you might also want to consider the overall dimensions of the input images. Smaller images can be processed faster, so to reduce latency, capture images at lower resolutions (keeping in mind the above accuracy requirements) and ensure that the text occupies as much of the image as possible. Also see Tips to improve real-time performance.
Recognize text in images
To recognize text in an image using either an on-device or cloud-based model, run the text recognizer as described below.
1. Run the text recognizer
To recognize text 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
FirebaseVisionTextRecognizer
's processImage
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 ML Kit'sROTATION_
constants before callingFirebaseVisionImage.fromMediaImage()
: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 Kit Vision API // ... } }
Kotlin
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 Kit 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:
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; }
Kotlin
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 }
Then, pass the
media.Image
object and the rotation value toFirebaseVisionImage.fromMediaImage()
:Java
FirebaseVisionImage image = FirebaseVisionImage.fromMediaImage(mediaImage, rotation);
Kotlin
val 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.Java
FirebaseVisionImage image; try { image = FirebaseVisionImage.fromFilePath(context, uri); } catch (IOException e) { e.printStackTrace(); }
Kotlin
val image: FirebaseVisionImage try { image = FirebaseVisionImage.fromFilePath(context, uri) } catch (e: IOException) { 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: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();
Kotlin
val metadata = 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:Java
FirebaseVisionImage image = FirebaseVisionImage.fromByteBuffer(buffer, metadata); // Or: FirebaseVisionImage image = FirebaseVisionImage.fromByteArray(byteArray, metadata);
Kotlin
val image = FirebaseVisionImage.fromByteBuffer(buffer, metadata) // Or: val image = FirebaseVisionImage.fromByteArray(byteArray, metadata)
- To create a
FirebaseVisionImage
object from aBitmap
object:Java
FirebaseVisionImage image = FirebaseVisionImage.fromBitmap(bitmap);
Kotlin
val image = FirebaseVisionImage.fromBitmap(bitmap)
Bitmap
object must be upright, with no additional rotation required.
-
Get an instance of
FirebaseVisionTextRecognizer
.To use the on-device model:
Java
FirebaseVisionTextRecognizer detector = FirebaseVision.getInstance() .getOnDeviceTextRecognizer();
Kotlin
val detector = FirebaseVision.getInstance() .onDeviceTextRecognizer
To use the cloud-based model:
Java
FirebaseVisionTextRecognizer detector = FirebaseVision.getInstance() .getCloudTextRecognizer(); // Or, to change the default settings: // FirebaseVisionTextRecognizer detector = FirebaseVision.getInstance() // .getCloudTextRecognizer(options);
// Or, to provide language hints to assist with language detection: // See https://cloud.google.com/vision/docs/languages for supported languages FirebaseVisionCloudTextRecognizerOptions options = new FirebaseVisionCloudTextRecognizerOptions.Builder() .setLanguageHints(Arrays.asList("en", "hi")) .build();
Kotlin
val detector = FirebaseVision.getInstance().cloudTextRecognizer // Or, to change the default settings: // val detector = FirebaseVision.getInstance().getCloudTextRecognizer(options)
// Or, to provide language hints to assist with language detection: // See https://cloud.google.com/vision/docs/languages for supported languages val options = FirebaseVisionCloudTextRecognizerOptions.Builder() .setLanguageHints(listOf("en", "hi")) .build()
Finally, pass the image to the
processImage
method:Java
Task<FirebaseVisionText> result = detector.processImage(image) .addOnSuccessListener(new OnSuccessListener<FirebaseVisionText>() { @Override public void onSuccess(FirebaseVisionText firebaseVisionText) { // Task completed successfully // ... } }) .addOnFailureListener( new OnFailureListener() { @Override public void onFailure(@NonNull Exception e) { // Task failed with an exception // ... } });
Kotlin
val result = detector.processImage(image) .addOnSuccessListener { firebaseVisionText -> // Task completed successfully // ... } .addOnFailureListener { e -> // Task failed with an exception // ... }
2. Extract text from blocks of recognized text
If the text recognition operation succeeds, aFirebaseVisionText
object will be passed to the success
listener. A FirebaseVisionText
object contains the full text recognized in
the image and zero or more TextBlock
objects.
Each TextBlock
represents a rectangular block of text, which contains zero or
more Line
objects. Each Line
object contains zero or more
Element
objects, which represent words and word-like
entities (dates, numbers, and so on).
For each TextBlock
, Line
, and Element
object, you can get the text
recognized in the region and the bounding coordinates of the region.
For example:
Java
String resultText = result.getText(); for (FirebaseVisionText.TextBlock block: result.getTextBlocks()) { String blockText = block.getText(); Float blockConfidence = block.getConfidence(); List<RecognizedLanguage> blockLanguages = block.getRecognizedLanguages(); Point[] blockCornerPoints = block.getCornerPoints(); Rect blockFrame = block.getBoundingBox(); for (FirebaseVisionText.Line line: block.getLines()) { String lineText = line.getText(); Float lineConfidence = line.getConfidence(); List<RecognizedLanguage> lineLanguages = line.getRecognizedLanguages(); Point[] lineCornerPoints = line.getCornerPoints(); Rect lineFrame = line.getBoundingBox(); for (FirebaseVisionText.Element element: line.getElements()) { String elementText = element.getText(); Float elementConfidence = element.getConfidence(); List<RecognizedLanguage> elementLanguages = element.getRecognizedLanguages(); Point[] elementCornerPoints = element.getCornerPoints(); Rect elementFrame = element.getBoundingBox(); } } }
Kotlin
val resultText = result.text for (block in result.textBlocks) { val blockText = block.text val blockConfidence = block.confidence val blockLanguages = block.recognizedLanguages val blockCornerPoints = block.cornerPoints val blockFrame = block.boundingBox for (line in block.lines) { val lineText = line.text val lineConfidence = line.confidence val lineLanguages = line.recognizedLanguages val lineCornerPoints = line.cornerPoints val lineFrame = line.boundingBox for (element in line.elements) { val elementText = element.text val elementConfidence = element.confidence val elementLanguages = element.recognizedLanguages val elementCornerPoints = element.cornerPoints val elementFrame = element.boundingBox } } }
Tips to improve real-time performance
If you want use the on-device model to recognize text in a real-time application, follow these guidelines to achieve the best framerates:
- Throttle calls to the text recognizer. If a new video frame becomes available while the text recognizer is running, drop the frame.
- If you are using the output of the text recognizer to overlay graphics on the input image, first get the result from ML Kit, then render the image and overlay in a single step. By doing so, you render to the display surface only once for each input frame.
-
If you use the Camera2 API, capture images in
ImageFormat.YUV_420_888
format.If you use the older Camera API, capture images in
ImageFormat.NV21
format. - Consider capturing images at a lower resolution. However, also keep in mind this API's image dimension requirements.
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.
Recognize text in images of documents
To recognize the text of a document, configure and run the cloud-based document text recognizer as described below.
The document text recognition API, described below, provides an interface that
is intended to be more convenient for working with images of documents. However,
if you prefer the interface provided by the FirebaseVisionTextRecognizer
API,
you can use it instead to scan documents by configuring the cloud text
recognizer to use the dense text model.
To use the document text recognition API:
1. Run the text recognizer
To recognize text 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
FirebaseVisionDocumentTextRecognizer
's processImage
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 ML Kit'sROTATION_
constants before callingFirebaseVisionImage.fromMediaImage()
: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 Kit Vision API // ... } }
Kotlin
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 Kit 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:
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; }
Kotlin
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 }
Then, pass the
media.Image
object and the rotation value toFirebaseVisionImage.fromMediaImage()
:Java
FirebaseVisionImage image = FirebaseVisionImage.fromMediaImage(mediaImage, rotation);
Kotlin
val 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.Java
FirebaseVisionImage image; try { image = FirebaseVisionImage.fromFilePath(context, uri); } catch (IOException e) { e.printStackTrace(); }
Kotlin
val image: FirebaseVisionImage try { image = FirebaseVisionImage.fromFilePath(context, uri) } catch (e: IOException) { 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: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();
Kotlin
val metadata = 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:Java
FirebaseVisionImage image = FirebaseVisionImage.fromByteBuffer(buffer, metadata); // Or: FirebaseVisionImage image = FirebaseVisionImage.fromByteArray(byteArray, metadata);
Kotlin
val image = FirebaseVisionImage.fromByteBuffer(buffer, metadata) // Or: val image = FirebaseVisionImage.fromByteArray(byteArray, metadata)
- To create a
FirebaseVisionImage
object from aBitmap
object:Java
FirebaseVisionImage image = FirebaseVisionImage.fromBitmap(bitmap);
Kotlin
val image = FirebaseVisionImage.fromBitmap(bitmap)
Bitmap
object must be upright, with no additional rotation required.
-
Get an instance of
FirebaseVisionDocumentTextRecognizer
:Java
FirebaseVisionDocumentTextRecognizer detector = FirebaseVision.getInstance() .getCloudDocumentTextRecognizer();
// Or, to provide language hints to assist with language detection: // See https://cloud.google.com/vision/docs/languages for supported languages FirebaseVisionCloudDocumentRecognizerOptions options = new FirebaseVisionCloudDocumentRecognizerOptions.Builder() .setLanguageHints(Arrays.asList("en", "hi")) .build(); FirebaseVisionDocumentTextRecognizer detector = FirebaseVision.getInstance() .getCloudDocumentTextRecognizer(options);
Kotlin
val detector = FirebaseVision.getInstance() .cloudDocumentTextRecognizer
// Or, to provide language hints to assist with language detection: // See https://cloud.google.com/vision/docs/languages for supported languages val options = FirebaseVisionCloudDocumentRecognizerOptions.Builder() .setLanguageHints(listOf("en", "hi")) .build() val detector = FirebaseVision.getInstance() .getCloudDocumentTextRecognizer(options)
Finally, pass the image to the
processImage
method:Java
detector.processImage(myImage) .addOnSuccessListener(new OnSuccessListener<FirebaseVisionDocumentText>() { @Override public void onSuccess(FirebaseVisionDocumentText result) { // Task completed successfully // ... } }) .addOnFailureListener(new OnFailureListener() { @Override public void onFailure(@NonNull Exception e) { // Task failed with an exception // ... } });
Kotlin
detector.processImage(myImage) .addOnSuccessListener { firebaseVisionDocumentText -> // Task completed successfully // ... } .addOnFailureListener { e -> // Task failed with an exception // ... }
2. Extract text from blocks of recognized text
If the text recognition operation succeeds, it will return a
FirebaseVisionDocumentText
object. A
FirebaseVisionDocumentText
object contains the full text recognized in the
image and a hierarchy of objects that reflect the structure of the recognized
document:
FirebaseVisionDocumentText.Block
FirebaseVisionDocumentText.Paragraph
FirebaseVisionDocumentText.Word
FirebaseVisionDocumentText.Symbol
For each Block
, Paragraph
, Word
, and Symbol
object, you can get the
text recognized in the region and the bounding coordinates of the region.
For example:
Java
String resultText = result.getText(); for (FirebaseVisionDocumentText.Block block: result.getBlocks()) { String blockText = block.getText(); Float blockConfidence = block.getConfidence(); List<RecognizedLanguage> blockRecognizedLanguages = block.getRecognizedLanguages(); Rect blockFrame = block.getBoundingBox(); for (FirebaseVisionDocumentText.Paragraph paragraph: block.getParagraphs()) { String paragraphText = paragraph.getText(); Float paragraphConfidence = paragraph.getConfidence(); List<RecognizedLanguage> paragraphRecognizedLanguages = paragraph.getRecognizedLanguages(); Rect paragraphFrame = paragraph.getBoundingBox(); for (FirebaseVisionDocumentText.Word word: paragraph.getWords()) { String wordText = word.getText(); Float wordConfidence = word.getConfidence(); List<RecognizedLanguage> wordRecognizedLanguages = word.getRecognizedLanguages(); Rect wordFrame = word.getBoundingBox(); for (FirebaseVisionDocumentText.Symbol symbol: word.getSymbols()) { String symbolText = symbol.getText(); Float symbolConfidence = symbol.getConfidence(); List<RecognizedLanguage> symbolRecognizedLanguages = symbol.getRecognizedLanguages(); Rect symbolFrame = symbol.getBoundingBox(); } } } }
Kotlin
val resultText = result.text for (block in result.blocks) { val blockText = block.text val blockConfidence = block.confidence val blockRecognizedLanguages = block.recognizedLanguages val blockFrame = block.boundingBox for (paragraph in block.paragraphs) { val paragraphText = paragraph.text val paragraphConfidence = paragraph.confidence val paragraphRecognizedLanguages = paragraph.recognizedLanguages val paragraphFrame = paragraph.boundingBox for (word in paragraph.words) { val wordText = word.text val wordConfidence = word.confidence val wordRecognizedLanguages = word.recognizedLanguages val wordFrame = word.boundingBox for (symbol in word.symbols) { val symbolText = symbol.text val symbolConfidence = symbol.confidence val symbolRecognizedLanguages = symbol.recognizedLanguages val symbolFrame = symbol.boundingBox } } } }
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.