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| Getting Started | Request Customizations | Changing Pipeline Model | Further Reading | Known Issues |
Intel® Deep Learning Streamer (Intel® DL Streamer) Pipeline Server is a python package and microservice for deploying optimized media analytics pipelines. It supports pipelines defined in GStreamer* or FFmpeg* and provides APIs to discover, start, stop, customize and monitor pipeline execution. Intel® DL Streamer Pipeline Server is based on Intel® Deep Learning Streamer Pipeline Framework and FFmpeg Video Analytics.
Customizable Media Analytics Containers | Scripts and dockerfiles to build and run container images with the required dependencies for hardware optimized media analytics pipelines. |
No-Code Pipeline Definitions and Templates | JSON based definition files, a flexible way for developers to define and parameterize pipelines while abstracting the low level details from their users. |
Deep Learning Model Integration | A simple way to package and reference OpenVINO™ based models in pipeline definitions. The precision of a model can be auto-selected at runtime based on the chosen inference device. |
Intel® DL Streamer Pipeline Server Python API | A python module to discover, start, stop, customize and monitor pipelines based on their no-code definitions. |
Intel® DL Streamer Pipeline Server Microservice | A RESTful microservice providing endpoints and APIs matching the functionality of the python module. |
IMPORTANT: Intel® DL Streamer Pipeline Server is provided as a sample. It is not intended to be deployed into production environments without modification. Developers deploying Intel® DL Streamer Pipeline Server should review it against their production requirements.
The sample microservice includes five categories of media analytics pipelines. Click on the links below to find out more about each of them.
object_detection | Detect and label objects |
object_classification | As object_detection adding meta-data such as object subtype and color |
object_tracking | As object_classification adding tracking identifier to meta-data |
audio_detection | Analyze audio streams for events such as breaking glass or barking dogs. |
Docker | Intel® DL Streamer Pipeline Server requires Docker for its build, development, and runtime environments. Please install the latest for your platform. Docker. |
bash | Intel® DL Streamer Pipeline Server's build and run scripts require bash and have been tested on systems using versions greater than or equal to: GNU bash, version 4.3.48(1)-release (x86_64-pc-linux-gnu) . Most users shouldn't need to update their version but if you run into issues please install the latest for your platform. Instructions for macOS®* users here. |
Refer to Intel® DL Streamer Hardware Requirements for supported development and target runtime platforms and the Intel® DL Streamer Install Guide for details on providing access to accelerator devices.
Build the sample microservice with the following command:
./docker/build.sh
The script will automatically include the sample models, pipelines and required dependencies.
To verify the build succeeded execute the following command:
docker images dlstreamer-pipeline-server-gstreamer:latest
Expected output:
REPOSITORY TAG IMAGE ID CREATED SIZE
dlstreamer-pipeline-server-gstreamer latest f51f2695639f 2 minutes ago 2.81GB
Start the sample microservice with the following command:
./docker/run.sh -v /tmp:/tmp
This script issues a standard docker run command to launch the
container, run a Tornado based web service on port 8080, and mount the
/tmp
folder. The /tmp
folder is mounted to share sample
results with the host and is optional in actual deployments.
Expected output:
{"levelname": "INFO", "asctime": "2021-04-05 23:43:42,406", "message": "=================", "module": "pipeline_manager"}
{"levelname": "INFO", "asctime": "2021-04-05 23:43:42,406", "message": "Loading Pipelines", "module": "pipeline_manager"}
{"levelname": "INFO", "asctime": "2021-04-05 23:43:42,406", "message": "=================", "module": "pipeline_manager"}
{"levelname": "INFO", "asctime": "2021-04-05 23:43:43,073", "message": "Loading Pipelines from Config Path /home/pipeline-server/pipelines", "module": "pipeline_manager"}
{"levelname": "INFO", "asctime": "2021-04-05 23:43:43,088", "message": "Loading Pipeline: audio_detection version: environment type: GStreamer from /home/pipeline-server/pipelines/audio_detection/environment/pipeline.json", "module": "pipeline_manager"}
{"levelname": "INFO", "asctime": "2021-04-05 23:43:43,090", "message": "Loading Pipeline: object_classification version: vehicle_attributes type: GStreamer from /home/pipeline-server/pipelines/object_classification/vehicle_attributes/pipeline.json", "module": "pipeline_manager"}
{"levelname": "INFO", "asctime": "2021-04-05 23:43:43,102", "message": "Loading Pipeline: object_detection version: edgex type: GStreamer from /home/pipeline-server/pipelines/object_detection/edgex/pipeline.json", "module": "pipeline_manager"}
{"levelname": "INFO", "asctime": "2021-04-05 23:43:43,104", "message": "Loading Pipeline: object_detection version: person_vehicle_bike type: GStreamer from /home/pipeline-server/pipelines/object_detection/person_vehicle_bike/pipeline.json", "module": "pipeline_manager"}
{"levelname": "INFO", "asctime": "2021-04-05 23:43:43,109", "message": "Loading Pipeline: object_tracking version: person_vehicle_bike type: GStreamer from /home/pipeline-server/pipelines/object_tracking/person_vehicle_bike/pipeline.json", "module": "pipeline_manager"}
{"levelname": "INFO", "asctime": "2021-04-05 23:43:43,109", "message": "===========================", "module": "pipeline_manager"}
{"levelname": "INFO", "asctime": "2021-04-05 23:43:43,109", "message": "Completed Loading Pipelines", "module": "pipeline_manager"}
{"levelname": "INFO", "asctime": "2021-04-05 23:43:43,109", "message": "===========================", "module": "pipeline_manager"}
{"levelname": "INFO", "asctime": "2021-04-05 23:43:43,217", "message": "Starting Tornado Server on port: 8080", "module": "__main__"}
The Pipeline Server includes a sample client pipeline_client that can connect to the service and make requests. We will use pipeline_client to explain how to use the key microservice features.
Note: Any RESTful tool or library can be used to send requests to the Pipeline Server service. We are using pipeline_client as it simplifies interaction with the service.
Note: The microservice has to be up and running before the sample client is invoked.
Before running a pipeline, we need to know what pipelines are available. We do this using pipeline_client's list-pipeline
command.
In new shell run the following command:
./client/pipeline_client.sh list-pipelines
- object_classification/vehicle_attributes
- audio_detection/environment
- object_tracking/object_line_crossing
- object_tracking/person_vehicle_bike
- object_detection/object_zone_count
- object_detection/app_src_dst
- object_detection/person_vehicle_bike
Note: The pipelines you will see may differ slightly
Pipelines are displayed as a name/version tuple. The name reflects the action and version supplies more details of that action. Let's go with object_detection/person_vehicle_bike
. Now we need to choose a media source. We recommend the IoT Devkit sample videos to get started. As the pipeline version indicates support for detecting people, person-bicycle-car-detection.mp4 would be a good choice.
Note: Make sure to include
raw=true
parameter in the Github URL as shown in our examples. Failure to do so will result in a pipeline execution error.
pipeline_client offers a run
command that takes two additional arguments the pipeline
and the uri
for the media source. The run
command displays inference results until either the media is exhausted or CTRL+C
is pressed.
Inference result bounding boxes are displayed in the format label (confidence) [top left width height] {meta-data}
provided applicable data is present. At the end of the pipeline run, the average fps is shown.
./client/pipeline_client.sh run object_detection/person_vehicle_bike https://github.com/intel-iot-devkit/sample-videos/blob/master/person-bicycle-car-detection.mp4?raw=true
Timestamp 48583333333
- vehicle (0.95) [0.00, 0.12, 0.15, 0.36]
Timestamp 48666666666
- vehicle (0.79) [0.00, 0.12, 0.14, 0.36]
Timestamp 48833333333
- vehicle (0.68) [0.00, 0.13, 0.11, 0.36]
Timestamp 48916666666
- vehicle (0.78) [0.00, 0.13, 0.10, 0.36]
Timestamp 49000000000
- vehicle (0.63) [0.00, 0.13, 0.09, 0.36]
Timestamp 49083333333
- vehicle (0.63) [0.00, 0.14, 0.07, 0.35]
Timestamp 49166666666
- vehicle (0.69) [0.00, 0.14, 0.07, 0.35]
Timestamp 49250000000
- vehicle (0.64) [0.00, 0.14, 0.05, 0.34]
avg_fps: 39.66
NOTE: Inference results are not obtained via a REST API but read from an output file. The file path is specified in the
destination
section of the REST request and will be discussed in a later section.
The pipeline_client run
command starts the pipeline. The underlying REST request returns a pipeline instance
which is used to query the state of the pipeline.
All being well it will go into QUEUED
then RUNNING
state. We can interrogate the pipeline status by using the pipeline_client start
command that kicks off the pipeline like run
and then exits displaying the pipeline instance
(a UUID) which is used by the status
command to view pipeline state.
NOTE: The pipeline instance value depends on the number of pipelines started while the server is running so may differ from the value shown in the following examples.
./client/pipeline_client.sh start object_detection/person_vehicle_bike https://github.com/intel-iot-devkit/sample-videos/blob/master/person-bicycle-car-detection.mp4?raw=true
<snip>
Starting pipeline object_detection/person_vehicle_bike, instance = d83502e3ef314e8fbec8dc926eadd0c2
You will need both the pipeline tuple and instance
id for the status command. This command will display pipeline state:
./client/pipeline_client.sh status object_detection/person_vehicle_bike d83502e3ef314e8fbec8dc926eadd0c2
<snip>
RUNNING (49fps)
Then wait for a minute or so and try again. Pipeline will be completed.
./client/pipeline_client.sh status object_detection/person_vehicle_bike d83502e3ef314e8fbec8dc926eadd0c2
<snip>
COMPLETED (50fps)
If a pipeline is stopped, rather than allowed to complete, it goes into the ABORTED state. Start the pipeline again, this time we'll stop it.
./client/pipeline_client.sh start object_detection/person_vehicle_bike https://github.com/intel-iot-devkit/sample-videos/blob/master/person-bicycle-car-detection.mp4?raw=true
<snip>
Starting pipeline object_detection/person_vehicle_bike, instance = 8ad2c85af4bd473e8a693aff562be316
./client/pipeline_client.sh status object_detection/person_vehicle_bike 8ad2c85af4bd473e8a693aff562be316
<snip>
RUNNING (50fps)
./client/pipeline_client.sh stop object_detection/person_vehicle_bike 8ad2c85af4bd473e8a693aff562be316
<snip>
Stopping Pipeline...
Pipeline stopped
avg_fps: 24.33
./client/pipeline_client.sh status object_detection/person_vehicle_bike 8ad2c85af4bd473e8a693aff562be316
<snip>
ABORTED (47fps)
The error state covers a number of outcomes such as the request could not be satisfied, a pipeline dependency was missing or an initialization problem. We can create an error condition by supplying a valid but unreachable uri.
./client/pipeline_client.sh start object_detection/person_vehicle_bike http://bad-uri
<snip>
Starting pipeline object_detection/person_vehicle_bike, instance = 2bb2d219310a4ee881faf258fbcc4355
Note that the Pipeline Server does not report an error at this stage as it goes into QUEUED
state before it realizes that the source is not providing media.
Checking on state a few seconds later will show the error.
./client/pipeline_client.sh status object_detection/person_vehicle_bike 2bb2d219310a4ee881faf258fbcc4355
<snip>
ERROR (0fps)
With pipeline_client it is easy to customize service requests. Here will use a vehicle classification pipeline object_classification/vehicle_attributes
with the IoT Devkit video car-detection.mp4
. Note how pipeline_client now displays classification metadata including type and color of vehicle.
./client/pipeline_client.sh run object_classification/vehicle_attributes https://github.com/intel-iot-devkit/sample-videos/blob/master/car-detection.mp4?raw=true
Starting pipeline object_classification/vehicle_attributes, instance = <uuid>
Pipeline running
<snip>
Timestamp 18080000000
- vehicle (1.00) [0.41, 0.00, 0.57, 0.33] {'color': 'red', 'type': 'car'}
Timestamp 18160000000
- vehicle (1.00) [0.41, 0.00, 0.57, 0.31] {'color': 'red', 'type': 'car'}
- vehicle (0.50) [0.09, 0.92, 0.27, 1.00] {'color': 'white', 'type': 'van'}
Timestamp 18240000000
- vehicle (1.00) [0.40, 0.00, 0.57, 0.27] {'color': 'red', 'type': 'car'}
Timestamp 18320000000
- vehicle (1.00) [0.40, 0.00, 0.56, 0.24] {'color': 'red', 'type': 'car'}
Timestamp 18400000000
- vehicle (1.00) [0.40, 0.00, 0.56, 0.22] {'color': 'red', 'type': 'car'}
- vehicle (0.53) [0.52, 0.19, 0.98, 0.99] {'color': 'black', 'type': 'truck'}
Timestamp 18480000000
- vehicle (0.99) [0.40, 0.00, 0.56, 0.20] {'color': 'red', 'type': 'car'}
- vehicle (0.81) [0.69, 0.00, 1.00, 0.36] {'color': 'black', 'type': 'bus'}
Timestamp 18560000000
- vehicle (1.00) [0.40, 0.00, 0.55, 0.18] {'color': 'red', 'type': 'car'}
- vehicle (0.71) [0.70, 0.00, 1.00, 0.36] {'color': 'black', 'type': 'bus'}
Timestamp 18640000000
- vehicle (0.98) [0.40, 0.00, 0.55, 0.15] {'color': 'red', 'type': 'car'}
If you look at the video, you can see that there are some errors in classification - there are no trucks or buses in the video. However you can see that associated confidence is much lower than the correct classification of the white and red cars.
Inference accelerator devices can be easily selected using the device parameter. Here we run the car classification pipeline again,
but this time use the integrated GPU for detection inference by setting the detection-device
parameter.
./client/pipeline_client.sh run object_classification/vehicle_attributes https://github.com/intel-iot-devkit/sample-videos/blob/master/car-detection.mp4?raw=true --parameter detection-device GPU --parameter detection-model-instance-id person_vehicle_bike_detection_gpu
Starting pipeline object_classification/vehicle_attributes, instance = <uuid>
Note: The GPU inference plug-in dynamically builds OpenCL kernels when it is first loaded resulting in a ~30s delay before inference results are produced.
Note: The
detection-model-instance-id
parameter caches the GPU model with a unique id. For more information read about model instance ids.
pipeline_client's fps measurement is useful when assessing pipeline performance with different accelerators.
Pipeline server allows you to optionally visualize inference results using either Real Time Streaming Protocol (RTSP) or Web Real Time Communication (WebRTC) by configuring the frame destination section of the request.
RTSP is simpler to set up but you must have an RTSP player (e.g. VLC) to render output. WebRTC setup is more complex (e.g., requires additional server-side microservices) but has the upside of using a web browser for client visualization.
Before requesting visualization, the corresponding feature must be enabled in the server, see Visualizing Inference Output.
RTSP allows you to connect to a server and display a video stream. The Pipeline Server includes an RTSP server that creates a stream that shows the incoming video with superimposed bounding boxes and meta-data. You will need a client that connects to the server and displays the video. We recommend vlc.
First start the Pipeline Server with RTSP enabled. By default, the RTSP stream will use port 8554.
docker/run.sh --enable-rtsp -v /tmp:/tmp
Then start pipeline and visualize as per RTSP section in Customizing Pipeline Requests.
Note: The pipeline must be running before you hit play otherwise VLC will not be able to connect to the RTSP server. For shorter video files you should have VLC ready to go before starting pipeline otherwise by the time you hit play the pipeline will have completed and the RTSP server will have shut down.
WebRTC is more complex. Follow setup instructions in the sample. More details on fine tuning request can be found in the WebRTC section in Customizing Pipeline Requests.
As the previous example has shown, the pipeline_client application works by converting command line arguments into Pipeline Server REST requests.
The --show-request
option displays the REST verb, uri and body in the request.
Let's repeat the previous GPU inference example, adding RTSP output and show the underlying request.
./client/pipeline_client.sh run object_classification/vehicle_attributes https://github.com/intel-iot-devkit/sample-videos/blob/master/car-detection.mp4?raw=true --parameter detection-device GPU --rtsp-path pipeline-server --show-request
<snip>
POST http://localhost:8080/pipelines/object_classification/vehicle_attributes
Body:{'source': {'uri': 'https://github.com/intel-iot-devkit/sample-videos/blob/master/car-detection.mp4?raw=true', 'type': 'uri'}, 'destination': {'metadata': {'type': 'file', 'path': '/tmp/results.jsonl', 'format': 'json-lines'}, 'frame': {'type': 'rtsp', 'path': 'pipeline-server'}}, 'parameters': {'detection-device': 'GPU'}}
The REST request is broken into three parts
- VERB:
POST
- URI:
http://localhost:8080/pipelines/object_classification/vehicle_attributes
- BODY:
{"source": {"uri": ...
The uri is easy to decode. It's the service address, pipelines
command and the pipeline tuplet. The body contains three components:
- The media source
- The frame and metadata destinations
- Pipeline parameters.
They are easier to understand when the json is pretty-printed
{
"source": {
"uri": "https://github.com/intel-iot-devkit/sample-videos/blob/master/car-detection.mp4?raw=true",
"type": "uri"
},
"destination": {
"metadata": {
"type": "file",
"path": "/tmp/results.jsonl",
"format": "json-lines"
},
"frame": {
"type": "rtsp",
"path": "pipeline-server"
}
},
"parameters": {
"detection-device": "GPU"
}
}
- Media source: type is
uri
and the uri is the car-detection.mp4 video - Destinations:
- metadata: this is the inference results, they are sent to file
/tmp/results.jsonl
injson-lines
format. pipeline_client parses this file to display the inference results and metadata. - frames: this the watermarked frames. Here they are sent to the RTSP server and available over given endpoint
pipeline-server
.
- metadata: this is the inference results, they are sent to file
- Parameters set pipeline properties. See the Defining Pipelines document for more details on parameters.
The --show-request
output can be easily converted int a curl command.
curl <URI> -X <VERB> -H "Content-Type: application/json' -d <BODY>
So the above request would be as below. Note the pipeline instance 1
returned by the request.
curl localhost:8080/pipelines/object_classification/vehicle_attributes -X POST -H \
'Content-Type: application/json' -d \
'{
"source": {
"uri": "https://github.com/intel-iot-devkit/sample-videos/blob/master/car-detection.mp4?raw=true",
"type": "uri"
},
"destination": {
"metadata": {
"type": "file",
"path": "/tmp/results.jsonl",
"format": "json-lines"
},
"frame": {
"type": "rtsp",
"path": "pipeline-server"
}
},
"parameters": {
"detection-device": "GPU"
}
}'
59896b90853511ec838b0242ac110002
The Pipeline Server makes pipeline customization and model selection a simple task. The Changing Object Detection Models Tutorial provides step by step instructions for changing the object detection reference pipeline to use a model better suited to a different video source.
Media Frameworks | Media Analytics | Samples and Reference Designs |
---|---|---|
- GStreamer* - GStreamer* Overview - FFmpeg* |
- Intel® Deep Learning Streamer Pipeline Framework - OpenVINO™ Toolkit - FFmpeg* Video Analytics |
- Open Visual Cloud Smart City Sample - Open Visual Cloud Ad Insertion Sample - Edge Insights for Retail |
Known issues are tracked on GitHub*
* Other names and brands may be claimed as the property of others.