// Copyright 2018 Google LLC. // // 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. // syntax = "proto3"; package google.cloud.videointelligence.v1; import "google/api/annotations.proto"; import "google/longrunning/operations.proto"; import "google/protobuf/duration.proto"; import "google/protobuf/timestamp.proto"; import "google/rpc/status.proto"; option csharp_namespace = "Google.Cloud.VideoIntelligence.V1"; option go_package = "google.golang.org/genproto/googleapis/cloud/videointelligence/v1;videointelligence"; option java_multiple_files = true; option java_outer_classname = "VideoIntelligenceServiceProto"; option java_package = "com.google.cloud.videointelligence.v1"; option php_namespace = "Google\\Cloud\\VideoIntelligence\\V1"; // Service that implements Google Cloud Video Intelligence API. service VideoIntelligenceService { // Performs asynchronous video annotation. Progress and results can be // retrieved through the `google.longrunning.Operations` interface. // `Operation.metadata` contains `AnnotateVideoProgress` (progress). // `Operation.response` contains `AnnotateVideoResponse` (results). rpc AnnotateVideo(AnnotateVideoRequest) returns (google.longrunning.Operation) { option (google.api.http) = { post: "/v1/videos:annotate" body: "*" }; } } // Video annotation request. message AnnotateVideoRequest { // Input video location. Currently, only // [Google Cloud Storage](https://cloud.google.com/storage/) URIs are // supported, which must be specified in the following format: // `gs://bucket-id/object-id` (other URI formats return // [google.rpc.Code.INVALID_ARGUMENT][google.rpc.Code.INVALID_ARGUMENT]). For // more information, see [Request URIs](/storage/docs/reference-uris). A video // URI may include wildcards in `object-id`, and thus identify multiple // videos. Supported wildcards: '*' to match 0 or more characters; // '?' to match 1 character. If unset, the input video should be embedded // in the request as `input_content`. If set, `input_content` should be unset. string input_uri = 1; // The video data bytes. // If unset, the input video(s) should be specified via `input_uri`. // If set, `input_uri` should be unset. bytes input_content = 6; // Requested video annotation features. repeated Feature features = 2; // Additional video context and/or feature-specific parameters. VideoContext video_context = 3; // Optional location where the output (in JSON format) should be stored. // Currently, only [Google Cloud Storage](https://cloud.google.com/storage/) // URIs are supported, which must be specified in the following format: // `gs://bucket-id/object-id` (other URI formats return // [google.rpc.Code.INVALID_ARGUMENT][google.rpc.Code.INVALID_ARGUMENT]). For // more information, see [Request URIs](/storage/docs/reference-uris). string output_uri = 4; // Optional cloud region where annotation should take place. Supported cloud // regions: `us-east1`, `us-west1`, `europe-west1`, `asia-east1`. If no region // is specified, a region will be determined based on video file location. string location_id = 5; } // Video context and/or feature-specific parameters. message VideoContext { // Video segments to annotate. The segments may overlap and are not required // to be contiguous or span the whole video. If unspecified, each video is // treated as a single segment. repeated VideoSegment segments = 1; // Config for LABEL_DETECTION. LabelDetectionConfig label_detection_config = 2; // Config for SHOT_CHANGE_DETECTION. ShotChangeDetectionConfig shot_change_detection_config = 3; // Config for EXPLICIT_CONTENT_DETECTION. ExplicitContentDetectionConfig explicit_content_detection_config = 4; // Config for FACE_DETECTION. FaceDetectionConfig face_detection_config = 5; // Config for SPEECH_TRANSCRIPTION. SpeechTranscriptionConfig speech_transcription_config = 6; // Config for TEXT_DETECTION. TextDetectionConfig text_detection_config = 8; } // Config for LABEL_DETECTION. message LabelDetectionConfig { // What labels should be detected with LABEL_DETECTION, in addition to // video-level labels or segment-level labels. // If unspecified, defaults to `SHOT_MODE`. LabelDetectionMode label_detection_mode = 1; // Whether the video has been shot from a stationary (i.e. non-moving) camera. // When set to true, might improve detection accuracy for moving objects. // Should be used with `SHOT_AND_FRAME_MODE` enabled. bool stationary_camera = 2; // Model to use for label detection. // Supported values: "builtin/stable" (the default if unset) and // "builtin/latest". string model = 3; } // Config for SHOT_CHANGE_DETECTION. message ShotChangeDetectionConfig { // Model to use for shot change detection. // Supported values: "builtin/stable" (the default if unset) and // "builtin/latest". string model = 1; } // Config for EXPLICIT_CONTENT_DETECTION. message ExplicitContentDetectionConfig { // Model to use for explicit content detection. // Supported values: "builtin/stable" (the default if unset) and // "builtin/latest". string model = 1; } // Config for FACE_DETECTION. message FaceDetectionConfig { // Model to use for face detection. // Supported values: "builtin/stable" (the default if unset) and // "builtin/latest". string model = 1; // Whether bounding boxes be included in the face annotation output. bool include_bounding_boxes = 2; } // Config for TEXT_DETECTION. message TextDetectionConfig { // Language hint can be specified if the language to be detected is known a // priori. It can increase the accuracy of the detection. Language hint must // be language code in BCP-47 format. // // Automatic language detection is performed if no hint is provided. repeated string language_hints = 1; } // Video segment. message VideoSegment { // Time-offset, relative to the beginning of the video, // corresponding to the start of the segment (inclusive). google.protobuf.Duration start_time_offset = 1; // Time-offset, relative to the beginning of the video, // corresponding to the end of the segment (inclusive). google.protobuf.Duration end_time_offset = 2; } // Video segment level annotation results for label detection. message LabelSegment { // Video segment where a label was detected. VideoSegment segment = 1; // Confidence that the label is accurate. Range: [0, 1]. float confidence = 2; } // Video frame level annotation results for label detection. message LabelFrame { // Time-offset, relative to the beginning of the video, corresponding to the // video frame for this location. google.protobuf.Duration time_offset = 1; // Confidence that the label is accurate. Range: [0, 1]. float confidence = 2; } // Detected entity from video analysis. message Entity { // Opaque entity ID. Some IDs may be available in // [Google Knowledge Graph Search // API](https://developers.google.com/knowledge-graph/). string entity_id = 1; // Textual description, e.g. `Fixed-gear bicycle`. string description = 2; // Language code for `description` in BCP-47 format. string language_code = 3; } // Label annotation. message LabelAnnotation { // Detected entity. Entity entity = 1; // Common categories for the detected entity. // E.g. when the label is `Terrier` the category is likely `dog`. And in some // cases there might be more than one categories e.g. `Terrier` could also be // a `pet`. repeated Entity category_entities = 2; // All video segments where a label was detected. repeated LabelSegment segments = 3; // All video frames where a label was detected. repeated LabelFrame frames = 4; } // Video frame level annotation results for explicit content. message ExplicitContentFrame { // Time-offset, relative to the beginning of the video, corresponding to the // video frame for this location. google.protobuf.Duration time_offset = 1; // Likelihood of the pornography content.. Likelihood pornography_likelihood = 2; } // Explicit content annotation (based on per-frame visual signals only). // If no explicit content has been detected in a frame, no annotations are // present for that frame. message ExplicitContentAnnotation { // All video frames where explicit content was detected. repeated ExplicitContentFrame frames = 1; } // Normalized bounding box. // The normalized vertex coordinates are relative to the original image. // Range: [0, 1]. message NormalizedBoundingBox { // Left X coordinate. float left = 1; // Top Y coordinate. float top = 2; // Right X coordinate. float right = 3; // Bottom Y coordinate. float bottom = 4; } // Video segment level annotation results for face detection. message FaceSegment { // Video segment where a face was detected. VideoSegment segment = 1; } // Video frame level annotation results for face detection. message FaceFrame { // Normalized Bounding boxes in a frame. // There can be more than one boxes if the same face is detected in multiple // locations within the current frame. repeated NormalizedBoundingBox normalized_bounding_boxes = 1; // Time-offset, relative to the beginning of the video, // corresponding to the video frame for this location. google.protobuf.Duration time_offset = 2; } // Face annotation. message FaceAnnotation { // Thumbnail of a representative face view (in JPEG format). bytes thumbnail = 1; // All video segments where a face was detected. repeated FaceSegment segments = 2; // All video frames where a face was detected. repeated FaceFrame frames = 3; } // Annotation results for a single video. message VideoAnnotationResults { // Video file location in // [Google Cloud Storage](https://cloud.google.com/storage/). string input_uri = 1; // Label annotations on video level or user specified segment level. // There is exactly one element for each unique label. repeated LabelAnnotation segment_label_annotations = 2; // Label annotations on shot level. // There is exactly one element for each unique label. repeated LabelAnnotation shot_label_annotations = 3; // Label annotations on frame level. // There is exactly one element for each unique label. repeated LabelAnnotation frame_label_annotations = 4; // Face annotations. There is exactly one element for each unique face. repeated FaceAnnotation face_annotations = 5; // Shot annotations. Each shot is represented as a video segment. repeated VideoSegment shot_annotations = 6; // Explicit content annotation. ExplicitContentAnnotation explicit_annotation = 7; // Speech transcription. repeated SpeechTranscription speech_transcriptions = 11; // OCR text detection and tracking. // Annotations for list of detected text snippets. Each will have list of // frame information associated with it. repeated TextAnnotation text_annotations = 12; // Annotations for list of objects detected and tracked in video. repeated ObjectTrackingAnnotation object_annotations = 14; // If set, indicates an error. Note that for a single `AnnotateVideoRequest` // some videos may succeed and some may fail. google.rpc.Status error = 9; } // Video annotation response. Included in the `response` // field of the `Operation` returned by the `GetOperation` // call of the `google::longrunning::Operations` service. message AnnotateVideoResponse { // Annotation results for all videos specified in `AnnotateVideoRequest`. repeated VideoAnnotationResults annotation_results = 1; } // Annotation progress for a single video. message VideoAnnotationProgress { // Video file location in // [Google Cloud Storage](https://cloud.google.com/storage/). string input_uri = 1; // Approximate percentage processed thus far. Guaranteed to be // 100 when fully processed. int32 progress_percent = 2; // Time when the request was received. google.protobuf.Timestamp start_time = 3; // Time of the most recent update. google.protobuf.Timestamp update_time = 4; } // Video annotation progress. Included in the `metadata` // field of the `Operation` returned by the `GetOperation` // call of the `google::longrunning::Operations` service. message AnnotateVideoProgress { // Progress metadata for all videos specified in `AnnotateVideoRequest`. repeated VideoAnnotationProgress annotation_progress = 1; } // Config for SPEECH_TRANSCRIPTION. message SpeechTranscriptionConfig { // *Required* The language of the supplied audio as a // [BCP-47](https://www.rfc-editor.org/rfc/bcp/bcp47.txt) language tag. // Example: "en-US". // See [Language Support](https://cloud.google.com/speech/docs/languages) // for a list of the currently supported language codes. string language_code = 1; // *Optional* Maximum number of recognition hypotheses to be returned. // Specifically, the maximum number of `SpeechRecognitionAlternative` messages // within each `SpeechTranscription`. The server may return fewer than // `max_alternatives`. Valid values are `0`-`30`. A value of `0` or `1` will // return a maximum of one. If omitted, will return a maximum of one. int32 max_alternatives = 2; // *Optional* If set to `true`, the server will attempt to filter out // profanities, replacing all but the initial character in each filtered word // with asterisks, e.g. "f***". If set to `false` or omitted, profanities // won't be filtered out. bool filter_profanity = 3; // *Optional* A means to provide context to assist the speech recognition. repeated SpeechContext speech_contexts = 4; // *Optional* If 'true', adds punctuation to recognition result hypotheses. // This feature is only available in select languages. Setting this for // requests in other languages has no effect at all. The default 'false' value // does not add punctuation to result hypotheses. NOTE: "This is currently // offered as an experimental service, complimentary to all users. In the // future this may be exclusively available as a premium feature." bool enable_automatic_punctuation = 5; // *Optional* For file formats, such as MXF or MKV, supporting multiple audio // tracks, specify up to two tracks. Default: track 0. repeated int32 audio_tracks = 6; // *Optional* If 'true', enables speaker detection for each recognized word in // the top alternative of the recognition result using a speaker_tag provided // in the WordInfo. // Note: When this is true, we send all the words from the beginning of the // audio for the top alternative in every consecutive responses. // This is done in order to improve our speaker tags as our models learn to // identify the speakers in the conversation over time. bool enable_speaker_diarization = 7; // *Optional* // If set, specifies the estimated number of speakers in the conversation. // If not set, defaults to '2'. // Ignored unless enable_speaker_diarization is set to true. int32 diarization_speaker_count = 8; // *Optional* If `true`, the top result includes a list of words and the // confidence for those words. If `false`, no word-level confidence // information is returned. The default is `false`. bool enable_word_confidence = 9; } // Provides "hints" to the speech recognizer to favor specific words and phrases // in the results. message SpeechContext { // *Optional* A list of strings containing words and phrases "hints" so that // the speech recognition is more likely to recognize them. This can be used // to improve the accuracy for specific words and phrases, for example, if // specific commands are typically spoken by the user. This can also be used // to add additional words to the vocabulary of the recognizer. See // [usage limits](https://cloud.google.com/speech/limits#content). repeated string phrases = 1; } // A speech recognition result corresponding to a portion of the audio. message SpeechTranscription { // May contain one or more recognition hypotheses (up to the maximum specified // in `max_alternatives`). These alternatives are ordered in terms of // accuracy, with the top (first) alternative being the most probable, as // ranked by the recognizer. repeated SpeechRecognitionAlternative alternatives = 1; // Output only. The // [BCP-47](https://www.rfc-editor.org/rfc/bcp/bcp47.txt) language tag of the // language in this result. This language code was detected to have the most // likelihood of being spoken in the audio. string language_code = 2; } // Alternative hypotheses (a.k.a. n-best list). message SpeechRecognitionAlternative { // Transcript text representing the words that the user spoke. string transcript = 1; // The confidence estimate between 0.0 and 1.0. A higher number // indicates an estimated greater likelihood that the recognized words are // correct. This field is typically provided only for the top hypothesis, and // only for `is_final=true` results. Clients should not rely on the // `confidence` field as it is not guaranteed to be accurate or consistent. // The default of 0.0 is a sentinel value indicating `confidence` was not set. float confidence = 2; // A list of word-specific information for each recognized word. repeated WordInfo words = 3; } // Word-specific information for recognized words. Word information is only // included in the response when certain request parameters are set, such // as `enable_word_time_offsets`. message WordInfo { // Time offset relative to the beginning of the audio, and // corresponding to the start of the spoken word. This field is only set if // `enable_word_time_offsets=true` and only in the top hypothesis. This is an // experimental feature and the accuracy of the time offset can vary. google.protobuf.Duration start_time = 1; // Time offset relative to the beginning of the audio, and // corresponding to the end of the spoken word. This field is only set if // `enable_word_time_offsets=true` and only in the top hypothesis. This is an // experimental feature and the accuracy of the time offset can vary. google.protobuf.Duration end_time = 2; // The word corresponding to this set of information. string word = 3; // Output only. The confidence estimate between 0.0 and 1.0. A higher number // indicates an estimated greater likelihood that the recognized words are // correct. This field is set only for the top alternative. // This field is not guaranteed to be accurate and users should not rely on it // to be always provided. // The default of 0.0 is a sentinel value indicating `confidence` was not set. float confidence = 4; // Output only. A distinct integer value is assigned for every speaker within // the audio. This field specifies which one of those speakers was detected to // have spoken this word. Value ranges from 1 up to diarization_speaker_count, // and is only set if speaker diarization is enabled. int32 speaker_tag = 5; } // A vertex represents a 2D point in the image. // NOTE: the normalized vertex coordinates are relative to the original image // and range from 0 to 1. message NormalizedVertex { // X coordinate. float x = 1; // Y coordinate. float y = 2; } // Normalized bounding polygon for text (that might not be aligned with axis). // Contains list of the corner points in clockwise order starting from // top-left corner. For example, for a rectangular bounding box: // When the text is horizontal it might look like: // 0----1 // | | // 3----2 // // When it's clockwise rotated 180 degrees around the top-left corner it // becomes: // 2----3 // | | // 1----0 // // and the vertex order will still be (0, 1, 2, 3). Note that values can be less // than 0, or greater than 1 due to trignometric calculations for location of // the box. message NormalizedBoundingPoly { // Normalized vertices of the bounding polygon. repeated NormalizedVertex vertices = 1; } // Video segment level annotation results for text detection. message TextSegment { // Video segment where a text snippet was detected. VideoSegment segment = 1; // Confidence for the track of detected text. It is calculated as the highest // over all frames where OCR detected text appears. float confidence = 2; // Information related to the frames where OCR detected text appears. repeated TextFrame frames = 3; } // Video frame level annotation results for text annotation (OCR). // Contains information regarding timestamp and bounding box locations for the // frames containing detected OCR text snippets. message TextFrame { // Bounding polygon of the detected text for this frame. NormalizedBoundingPoly rotated_bounding_box = 1; // Timestamp of this frame. google.protobuf.Duration time_offset = 2; } // Annotations related to one detected OCR text snippet. This will contain the // corresponding text, confidence value, and frame level information for each // detection. message TextAnnotation { // The detected text. string text = 1; // All video segments where OCR detected text appears. repeated TextSegment segments = 2; } // Video frame level annotations for object detection and tracking. This field // stores per frame location, time offset, and confidence. message ObjectTrackingFrame { // The normalized bounding box location of this object track for the frame. NormalizedBoundingBox normalized_bounding_box = 1; // The timestamp of the frame in microseconds. google.protobuf.Duration time_offset = 2; } // Annotations corresponding to one tracked object. message ObjectTrackingAnnotation { // Different representation of tracking info in non-streaming batch // and streaming modes. oneof track_info { // Non-streaming batch mode ONLY. // Each object track corresponds to one video segment where it appears. VideoSegment segment = 3; // Streaming mode ONLY. // In streaming mode, we do not know the end time of a tracked object // before it is completed. Hence, there is no VideoSegment info returned. // Instead, we provide a unique identifiable integer track_id so that // the customers can correlate the results of the ongoing // ObjectTrackAnnotation of the same track_id over time. int64 track_id = 5; } // Entity to specify the object category that this track is labeled as. Entity entity = 1; // Object category's labeling confidence of this track. float confidence = 4; // Information corresponding to all frames where this object track appears. // Non-streaming batch mode: it may be one or multiple ObjectTrackingFrame // messages in frames. // Streaming mode: it can only be one ObjectTrackingFrame message in frames. repeated ObjectTrackingFrame frames = 2; } // Video annotation feature. enum Feature { // Unspecified. FEATURE_UNSPECIFIED = 0; // Label detection. Detect objects, such as dog or flower. LABEL_DETECTION = 1; // Shot change detection. SHOT_CHANGE_DETECTION = 2; // Explicit content detection. EXPLICIT_CONTENT_DETECTION = 3; // Human face detection and tracking. FACE_DETECTION = 4; // Speech transcription. SPEECH_TRANSCRIPTION = 6; // OCR text detection and tracking. TEXT_DETECTION = 7; // Object detection and tracking. OBJECT_TRACKING = 9; } // Label detection mode. enum LabelDetectionMode { // Unspecified. LABEL_DETECTION_MODE_UNSPECIFIED = 0; // Detect shot-level labels. SHOT_MODE = 1; // Detect frame-level labels. FRAME_MODE = 2; // Detect both shot-level and frame-level labels. SHOT_AND_FRAME_MODE = 3; } // Bucketized representation of likelihood. enum Likelihood { // Unspecified likelihood. LIKELIHOOD_UNSPECIFIED = 0; // Very unlikely. VERY_UNLIKELY = 1; // Unlikely. UNLIKELY = 2; // Possible. POSSIBLE = 3; // Likely. LIKELY = 4; // Very likely. VERY_LIKELY = 5; }