Wallaroo Frequently Asked Questions
Table of Contents
How Do I Install Wallaroo?
The Wallaroo Install Guides contain all steps on how to register with Wallaroo and receive a license, install Wallaroo into a Kubernetes cluster, and get Wallaroo running.
What Are The Prerequisites For Installing Wallaroo In A Cloud Service?
Wallaroo Community and Wallaroo Enterprise can be installed into a Kubernetes environment with the following requirements:
- Minimum number of nodes: 4
- Minimum Number of CPU Cores: 8
- Minimum RAM: 16 GB
- Kubernetes requirements:
- Kubernetes Version
1.20
is the minimum requirement1.22
is preferred version for Wallaroo versions before 2022.4.1.23
:- Is the preferred version for Wallaroo version 2022.4.
1.23 and above
:- Are the preferred versions for Wallaroo versions 2023.1 and later.
- Are not supported for versions of Wallaroo released before Wallaroo version 2022.4.
1.25
:- The preferred version for Wallaroo 2023.2.1.
- Runtime: containerd is required.
- Kubernetes Version
The following guide demonstrate how to set up a minimum Kubernetes environment in their cloud services and install Wallaroo:
Who Do I Contact For More Help With Wallaroo Community?
Wallaroo Community users can message community@wallaroo.ai for more assistance. Feel free to ask any questions about:
- Installing Wallaroo
- Uploading models and deploying pipelines
- How to use the SDK
How Do I Set Up My Wallaroo Community User Account?
Setting up a Wallaroo Community account is fast and easy at https://portal.wallaroo.community. See the Wallaroo Install Guides for full details on registering an account and downloading your Wallaroo Community License.
How Do I Invite Collaborators And Peers To Work With After Installing Wallaroo?
Yes you can! Wallaroo Community supports up to 2 team members, while Wallaroo Enterprise has no such limitations.
See the Wallaroo User Management Guide for how to add users to your Wallaroo instance. For details on how to add users to a Wallaroo Workspace, see the Wallaroo Workspace Management Guide.
What Are The Resources I Need To Be Able To Learn About The Wallaroo Platform?
Wallaroo has provided the following resources to help you:
- The Wallaroo 101 Guide teaches the basic concepts of how Wallaroo works, then provides a full tutorial for uploading a model and running an inference.
- Wallaroo Tutorials are paired with the Wallaroo Tutorials Repository to provide Jupyter Notebooks that you can upload to Wallaroo along with sample models and data to see how to deploy your own ML Models.
- The Wallaroo Essential SDK walks you the process of user, model, workspace, and pipeline management using the Wallaroo SDK.
How Fast is Wallaroo?
Not only is Wallaroo fast - its more cost efficient. Using the Aloha Tutorial as a benchmark, Wallaroo provides the following:
# inferences per second | inferences/dollar | |
---|---|---|
Vertex | 1.824 | 6,493,506 |
Databricks | 1.856 | 16,000,000 |
SageMaker | 5.008 | 28,169,014 |
Wallaroo | 21.584 | 127,659,574 |
IMPORTANT NOTE
Based on results from ALOHA (ALOHA: Auxiliary Loss Optimization for Hypothesis Augmentation) model, a complex, open-source model used for benchmark and performance testing. Test involved scoring 2 Billion events a day (23k events every second), analyzed in batches running on 16-CPU server on GCP (Vertex), AWS (sageMaker) and Azure (Databricks).How Can I Bring My Models Into Wallaroo?
Absolutely! Wallaroo supports the ONNX ML Standard and can convert other models through our auto-conversion feature.
Supported Models
The following frameworks are supported. Frameworks fall under either Native or Containerized runtimes in the Wallaroo engine. For more details, see the specific framework what runtime a specific model framework runs in.
Runtime Display | Model Runtime Space | Pipeline Configuration |
---|---|---|
tensorflow | Native | Native Runtime Configuration Methods |
onnx | Native | Native Runtime Configuration Methods |
python | Native | Native Runtime Configuration Methods |
mlflow | Containerized | Containerized Runtime Deployment |
Please note the following.
IMPORTANT NOTICE: FRAMEWORK VERSIONS
The supported frameworks include the specific version of the model framework supported by Wallaroo. It is highly recommended to verify that models uploaded to Wallaroo meet the library and version requirements to ensure proper functioning.Wallaroo natively supports Open Neural Network Exchange (ONNX) models into the Wallaroo engine.
Parameter | Description |
---|---|
Web Site | https://onnx.ai/ |
Supported Libraries | See table below. |
Framework | Framework.ONNX aka onnx |
Runtime | Native aka onnx |
The following ONNX versions models are supported:
Wallaroo Version | ONNX Version | ONNX IR Version | ONNX OPset Version | ONNX ML Opset Version |
---|---|---|---|---|
2023.2.1 (July 2023) | 1.12.1 | 8 | 17 | 3 |
2023.2 (May 2023) | 1.12.1 | 8 | 17 | 3 |
2023.1 (March 2023) | 1.12.1 | 8 | 17 | 3 |
2022.4 (December 2022) | 1.12.1 | 8 | 17 | 3 |
After April 2022 until release 2022.4 (December 2022) | 1.10.* | 7 | 15 | 2 |
Before April 2022 | 1.6.* | 7 | 13 | 2 |
For the most recent release of Wallaroo 2023.2.1, the following native runtimes are supported:
- If converting another ML Model to ONNX (PyTorch, XGBoost, etc) using the onnxconverter-common library, the supported
DEFAULT_OPSET_NUMBER
is 17.
Using different versions or settings outside of these specifications may result in inference issues and other unexpected behavior.
ONNX models always run in the native runtime space.
Data Schemas
ONNX models deployed to Wallaroo have the following data requirements.
- Equal rows constraint: The number of input rows and output rows must match.
- All inputs are tensors: The inputs are tensor arrays with the same shape.
- Data Type Consistency: Data types within each tensor are of the same type.
Equal Rows Constraint
Inference performed through ONNX models are assumed to be in batch format, where each input row corresponds to an output row. This is reflected in the in
fields returned for an inference. In the following example, each input row for an inference is related directly to the inference output.
df = pd.read_json('./data/cc_data_1k.df.json')
display(df.head())
result = ccfraud_pipeline.infer(df.head())
display(result)
INPUT
tensor | |
---|---|
0 | [-1.0603297501, 2.3544967095000002, -3.5638788326, 5.1387348926, -1.2308457019, -0.7687824608, -3.5881228109, 1.8880837663, -3.2789674274, -3.9563254554, 4.0993439118, -5.6539176395, -0.8775733373, -9.131571192000001, -0.6093537873, -3.7480276773, -5.0309125017, -0.8748149526000001, 1.9870535692, 0.7005485718000001, 0.9204422758, -0.1041491809, 0.3229564351, -0.7418141657, 0.0384120159, 1.0993439146, 1.2603409756, -0.1466244739, -1.4463212439] |
1 | [-1.0603297501, 2.3544967095000002, -3.5638788326, 5.1387348926, -1.2308457019, -0.7687824608, -3.5881228109, 1.8880837663, -3.2789674274, -3.9563254554, 4.0993439118, -5.6539176395, -0.8775733373, -9.131571192000001, -0.6093537873, -3.7480276773, -5.0309125017, -0.8748149526000001, 1.9870535692, 0.7005485718000001, 0.9204422758, -0.1041491809, 0.3229564351, -0.7418141657, 0.0384120159, 1.0993439146, 1.2603409756, -0.1466244739, -1.4463212439] |
2 | [-1.0603297501, 2.3544967095000002, -3.5638788326, 5.1387348926, -1.2308457019, -0.7687824608, -3.5881228109, 1.8880837663, -3.2789674274, -3.9563254554, 4.0993439118, -5.6539176395, -0.8775733373, -9.131571192000001, -0.6093537873, -3.7480276773, -5.0309125017, -0.8748149526000001, 1.9870535692, 0.7005485718000001, 0.9204422758, -0.1041491809, 0.3229564351, -0.7418141657, 0.0384120159, 1.0993439146, 1.2603409756, -0.1466244739, -1.4463212439] |
3 | [-1.0603297501, 2.3544967095000002, -3.5638788326, 5.1387348926, -1.2308457019, -0.7687824608, -3.5881228109, 1.8880837663, -3.2789674274, -3.9563254554, 4.0993439118, -5.6539176395, -0.8775733373, -9.131571192000001, -0.6093537873, -3.7480276773, -5.0309125017, -0.8748149526000001, 1.9870535692, 0.7005485718000001, 0.9204422758, -0.1041491809, 0.3229564351, -0.7418141657, 0.0384120159, 1.0993439146, 1.2603409756, -0.1466244739, -1.4463212439] |
4 | [0.5817662108, 0.09788155100000001, 0.1546819424, 0.4754101949, -0.19788623060000002, -0.45043448540000003, 0.016654044700000002, -0.0256070551, 0.0920561602, -0.2783917153, 0.059329944100000004, -0.0196585416, -0.4225083157, -0.12175388770000001, 1.5473094894000001, 0.2391622864, 0.3553974881, -0.7685165301, -0.7000849355000001, -0.1190043285, -0.3450517133, -1.1065114108, 0.2523411195, 0.0209441826, 0.2199267436, 0.2540689265, -0.0450225094, 0.10867738980000001, 0.2547179311] |
OUTPUT
time | in.tensor | out.dense_1 | check_failures | |
---|---|---|---|---|
0 | 2023-11-17 20:34:17.005 | [-1.0603297501, 2.3544967095, -3.5638788326, 5.1387348926, -1.2308457019, -0.7687824608, -3.5881228109, 1.8880837663, -3.2789674274, -3.9563254554, 4.0993439118, -5.6539176395, -0.8775733373, -9.131571192, -0.6093537873, -3.7480276773, -5.0309125017, -0.8748149526, 1.9870535692, 0.7005485718, 0.9204422758, -0.1041491809, 0.3229564351, -0.7418141657, 0.0384120159, 1.0993439146, 1.2603409756, -0.1466244739, -1.4463212439] | [0.99300325] | 0 |
1 | 2023-11-17 20:34:17.005 | [-1.0603297501, 2.3544967095, -3.5638788326, 5.1387348926, -1.2308457019, -0.7687824608, -3.5881228109, 1.8880837663, -3.2789674274, -3.9563254554, 4.0993439118, -5.6539176395, -0.8775733373, -9.131571192, -0.6093537873, -3.7480276773, -5.0309125017, -0.8748149526, 1.9870535692, 0.7005485718, 0.9204422758, -0.1041491809, 0.3229564351, -0.7418141657, 0.0384120159, 1.0993439146, 1.2603409756, -0.1466244739, -1.4463212439] | [0.99300325] | 0 |
2 | 2023-11-17 20:34:17.005 | [-1.0603297501, 2.3544967095, -3.5638788326, 5.1387348926, -1.2308457019, -0.7687824608, -3.5881228109, 1.8880837663, -3.2789674274, -3.9563254554, 4.0993439118, -5.6539176395, -0.8775733373, -9.131571192, -0.6093537873, -3.7480276773, -5.0309125017, -0.8748149526, 1.9870535692, 0.7005485718, 0.9204422758, -0.1041491809, 0.3229564351, -0.7418141657, 0.0384120159, 1.0993439146, 1.2603409756, -0.1466244739, -1.4463212439] | [0.99300325] | 0 |
3 | 2023-11-17 20:34:17.005 | [-1.0603297501, 2.3544967095, -3.5638788326, 5.1387348926, -1.2308457019, -0.7687824608, -3.5881228109, 1.8880837663, -3.2789674274, -3.9563254554, 4.0993439118, -5.6539176395, -0.8775733373, -9.131571192, -0.6093537873, -3.7480276773, -5.0309125017, -0.8748149526, 1.9870535692, 0.7005485718, 0.9204422758, -0.1041491809, 0.3229564351, -0.7418141657, 0.0384120159, 1.0993439146, 1.2603409756, -0.1466244739, -1.4463212439] | [0.99300325] | 0 |
4 | 2023-11-17 20:34:17.005 | [0.5817662108, 0.097881551, 0.1546819424, 0.4754101949, -0.1978862306, -0.4504344854, 0.0166540447, -0.0256070551, 0.0920561602, -0.2783917153, 0.0593299441, -0.0196585416, -0.4225083157, -0.1217538877, 1.5473094894, 0.2391622864, 0.3553974881, -0.7685165301, -0.7000849355, -0.1190043285, -0.3450517133, -1.1065114108, 0.2523411195, 0.0209441826, 0.2199267436, 0.2540689265, -0.0450225094, 0.1086773898, 0.2547179311] | [0.0010916889] | 0 |
All Inputs Are Tensors
All inputs into an ONNX model must be tensors. This requires that the shape of each element is the same. For example, the following is a proper input:
t [
[2.35, 5.75],
[3.72, 8.55],
[5.55, 97.2]
]
Another example is a 2,2,3 tensor, where the shape of each element is (3,), and each element has 2 rows.
t = [
[2.35, 5.75, 19.2],
[3.72, 8.55, 10.5]
],
[
[5.55, 7.2, 15.7],
[9.6, 8.2, 2.3]
]
In this example each element has a shape of (2,)
. Tensors with elements of different shapes, known as ragged tensors, are not supported. For example:
t = [
[2.35, 5.75],
[3.72, 8.55, 10.5],
[5.55, 97.2]
])
**INVALID SHAPE**
For models that require ragged tensor or other shapes, see other data formatting options such as Bring Your Own Predict models.
Data Type Consistency
All inputs into an ONNX model must have the same internal data type. For example, the following is valid because all of the data types within each element are float32
.
t = [
[2.35, 5.75],
[3.72, 8.55],
[5.55, 97.2]
]
The following is invalid, as it mixes floats and strings in each element:
t = [
[2.35, "Bob"],
[3.72, "Nancy"],
[5.55, "Wani"]
]
The following inputs are valid, as each data type is consistent within the elements.
df = pd.DataFrame({
"t": [
[2.35, 5.75, 19.2],
[5.55, 7.2, 15.7],
],
"s": [
["Bob", "Nancy", "Wani"],
["Jason", "Rita", "Phoebe"]
]
})
df
t | s | |
---|---|---|
0 | [2.35, 5.75, 19.2] | [Bob, Nancy, Wani] |
1 | [5.55, 7.2, 15.7] | [Jason, Rita, Phoebe] |
Parameter | Description |
---|---|
Web Site | https://www.tensorflow.org/ |
Supported Libraries | tensorflow==2.9.1 |
Framework | Framework.TENSORFLOW aka tensorflow |
Runtime | Native aka tensorflow |
Supported File Types | SavedModel format as .zip file |
IMPORTANT NOTE
These requirements are <strong>not</strong> for Tensorflow Keras models, only for non-Keras Tensorflow models in the SavedModel format. For Tensorflow Keras deployment in Wallaroo, see the Tensorflow Keras requirements.
TensorFlow File Format
TensorFlow models are .zip file of the SavedModel format. For example, the Aloha sample TensorFlow model is stored in the directory alohacnnlstm
:
├── saved_model.pb
└── variables
├── variables.data-00000-of-00002
├── variables.data-00001-of-00002
└── variables.index
This is compressed into the .zip file alohacnnlstm.zip
with the following command:
zip -r alohacnnlstm.zip alohacnnlstm/
ML models that meet the Tensorflow and SavedModel format will run as Wallaroo Native runtimes by default.
See the SavedModel guide for full details.
Parameter | Description |
---|---|
Web Site | https://www.python.org/ |
Supported Libraries | python==3.8 |
Framework | Framework.PYTHON aka python |
Runtime | Native aka python |
Python models uploaded to Wallaroo are executed as a native runtime.
Note that Python models - aka “Python steps” - are standalone python scripts that use the python libraries natively supported by the Wallaroo platform. These are used for either simple model deployment (such as ARIMA Statsmodels), or data formatting such as the postprocessing steps. A Wallaroo Python model will be composed of one Python script that matches the Wallaroo requirements.
This is contrasted with Arbitrary Python models, also known as Bring Your Own Predict (BYOP) allow for custom model deployments with supporting scripts and artifacts. These are used with pre-trained models (PyTorch, Tensorflow, etc) along with whatever supporting artifacts they require. Supporting artifacts can include other Python modules, model files, etc. These are zipped with all scripts, artifacts, and a requirements.txt
file that indicates what other Python models need to be imported that are outside of the typical Wallaroo platform.
Python Models Requirements
Python models uploaded to Wallaroo are Python scripts that must include the wallaroo_json
method as the entry point for the Wallaroo engine to use it as a Pipeline step.
This method receives the results of the previous Pipeline step, and its return value will be used in the next Pipeline step.
If the Python model is the first step in the pipeline, then it will be receiving the inference request data (for example: a preprocessing step). If it is the last step in the pipeline, then it will be the data returned from the inference request.
In the example below, the Python model is used as a post processing step for another ML model. The Python model expects to receive data from a ML Model who’s output is a DataFrame with the column dense_2
. It then extracts the values of that column as a list, selects the first element, and returns a DataFrame with that element as the value of the column output
.
def wallaroo_json(data: pd.DataFrame):
print(data)
return [{"output": [data["dense_2"].to_list()[0][0]]}]
In line with other Wallaroo inference results, the outputs of a Python step that returns a pandas DataFrame or Arrow Table will be listed in the out.
metadata, with all inference outputs listed as out.{variable 1}
, out.{variable 2}
, etc. In the example above, this results the output
field as the out.output
field in the Wallaroo inference result.
time | in.tensor | out.output | check_failures | |
---|---|---|---|---|
0 | 2023-06-20 20:23:28.395 | [0.6878518042, 0.1760734021, -0.869514083, 0.3.. | [12.886651039123535] | 0 |
Parameter | Description |
---|---|
Web Site | https://huggingface.co/models |
Supported Libraries |
|
Frameworks | The following Hugging Face pipelines are supported by Wallaroo.
|
Runtime | Containerized aka tensorflow / mlflow |
Hugging Face Schemas
Input and output schemas for each Hugging Face pipeline are defined below. Note that adding additional inputs not specified below will raise errors, except for the following:
Framework.HUGGING-FACE-IMAGE-TO-TEXT
Framework.HUGGING-FACE-TEXT-CLASSIFICATION
Framework.HUGGING-FACE-SUMMARIZATION
Framework.HUGGING-FACE-TRANSLATION
Additional inputs added to these Hugging Face pipelines will be added as key/pair value arguments to the model’s generate method. If the argument is not required, then the model will default to the values coded in the original Hugging Face model’s source code.
See the Hugging Face Pipeline documentation for more details on each pipeline and framework.
Wallaroo Framework | Reference |
---|---|
Framework.HUGGING-FACE-FEATURE-EXTRACTION |
Schemas:
input_schema = pa.schema([
pa.field('inputs', pa.string())
])
output_schema = pa.schema([
pa.field('output', pa.list_(
pa.list_(
pa.float64(),
list_size=128
),
))
])
Wallaroo Framework | Reference |
---|---|
Framework.HUGGING-FACE-IMAGE-CLASSIFICATION |
Schemas:
input_schema = pa.schema([
pa.field('inputs', pa.list_(
pa.list_(
pa.list_(
pa.int64(),
list_size=3
),
list_size=100
),
list_size=100
)),
pa.field('top_k', pa.int64()),
])
output_schema = pa.schema([
pa.field('score', pa.list_(pa.float64(), list_size=2)),
pa.field('label', pa.list_(pa.string(), list_size=2)),
])
Wallaroo Framework | Reference |
---|---|
Framework.HUGGING-FACE-IMAGE-SEGMENTATION |
Schemas:
input_schema = pa.schema([
pa.field('inputs',
pa.list_(
pa.list_(
pa.list_(
pa.int64(),
list_size=3
),
list_size=100
),
list_size=100
)),
pa.field('threshold', pa.float64()),
pa.field('mask_threshold', pa.float64()),
pa.field('overlap_mask_area_threshold', pa.float64()),
])
output_schema = pa.schema([
pa.field('score', pa.list_(pa.float64())),
pa.field('label', pa.list_(pa.string())),
pa.field('mask',
pa.list_(
pa.list_(
pa.list_(
pa.int64(),
list_size=100
),
list_size=100
),
)),
])
Wallaroo Framework | Reference |
---|---|
Framework.HUGGING-FACE-IMAGE-TO-TEXT |
Any parameter that is not part of the required inputs
list will be forwarded to the model as a key/pair value to the underlying models generate
method. If the additional input is not supported by the model, an error will be returned.
Schemas:
input_schema = pa.schema([
pa.field('inputs', pa.list_( #required
pa.list_(
pa.list_(
pa.int64(),
list_size=3
),
list_size=100
),
list_size=100
)),
# pa.field('max_new_tokens', pa.int64()), # optional
])
output_schema = pa.schema([
pa.field('generated_text', pa.list_(pa.string())),
])
Wallaroo Framework | Reference |
---|---|
Framework.HUGGING-FACE-OBJECT-DETECTION |
Schemas:
input_schema = pa.schema([
pa.field('inputs',
pa.list_(
pa.list_(
pa.list_(
pa.int64(),
list_size=3
),
list_size=100
),
list_size=100
)),
pa.field('threshold', pa.float64()),
])
output_schema = pa.schema([
pa.field('score', pa.list_(pa.float64())),
pa.field('label', pa.list_(pa.string())),
pa.field('box',
pa.list_( # dynamic output, i.e. dynamic number of boxes per input image, each sublist contains the 4 box coordinates
pa.list_(
pa.int64(),
list_size=4
),
),
),
])
Wallaroo Framework | Reference |
---|---|
Framework.HUGGING-FACE-QUESTION-ANSWERING |
Schemas:
input_schema = pa.schema([
pa.field('question', pa.string()),
pa.field('context', pa.string()),
pa.field('top_k', pa.int64()),
pa.field('doc_stride', pa.int64()),
pa.field('max_answer_len', pa.int64()),
pa.field('max_seq_len', pa.int64()),
pa.field('max_question_len', pa.int64()),
pa.field('handle_impossible_answer', pa.bool_()),
pa.field('align_to_words', pa.bool_()),
])
output_schema = pa.schema([
pa.field('score', pa.float64()),
pa.field('start', pa.int64()),
pa.field('end', pa.int64()),
pa.field('answer', pa.string()),
])
Wallaroo Framework | Reference |
---|---|
Framework.HUGGING-FACE-STABLE-DIFFUSION-TEXT-2-IMG |
Schemas:
input_schema = pa.schema([
pa.field('prompt', pa.string()),
pa.field('height', pa.int64()),
pa.field('width', pa.int64()),
pa.field('num_inference_steps', pa.int64()), # optional
pa.field('guidance_scale', pa.float64()), # optional
pa.field('negative_prompt', pa.string()), # optional
pa.field('num_images_per_prompt', pa.string()), # optional
pa.field('eta', pa.float64()) # optional
])
output_schema = pa.schema([
pa.field('images', pa.list_(
pa.list_(
pa.list_(
pa.int64(),
list_size=3
),
list_size=128
),
list_size=128
)),
])
Wallaroo Framework | Reference |
---|---|
Framework.HUGGING-FACE-SUMMARIZATION |
Any parameter that is not part of the required inputs
list will be forwarded to the model as a key/pair value to the underlying models generate
method. If the additional input is not supported by the model, an error will be returned.
Schemas:
input_schema = pa.schema([
pa.field('inputs', pa.string()),
pa.field('return_text', pa.bool_()),
pa.field('return_tensors', pa.bool_()),
pa.field('clean_up_tokenization_spaces', pa.bool_()),
# pa.field('extra_field', pa.int64()), # every extra field you specify will be forwarded as a key/value pair
])
output_schema = pa.schema([
pa.field('summary_text', pa.string()),
])
Wallaroo Framework | Reference |
---|---|
Framework.HUGGING-FACE-TEXT-CLASSIFICATION |
Schemas
input_schema = pa.schema([
pa.field('inputs', pa.string()), # required
pa.field('top_k', pa.int64()), # optional
pa.field('function_to_apply', pa.string()), # optional
])
output_schema = pa.schema([
pa.field('label', pa.list_(pa.string(), list_size=2)), # list with a number of items same as top_k, list_size can be skipped but may lead in worse performance
pa.field('score', pa.list_(pa.float64(), list_size=2)), # list with a number of items same as top_k, list_size can be skipped but may lead in worse performance
])
Wallaroo Framework | Reference |
---|---|
Framework.HUGGING-FACE-TRANSLATION |
Any parameter that is not part of the required inputs
list will be forwarded to the model as a key/pair value to the underlying models generate
method. If the additional input is not supported by the model, an error will be returned.
Schemas:
input_schema = pa.schema([
pa.field('inputs', pa.string()), # required
pa.field('return_tensors', pa.bool_()), # optional
pa.field('return_text', pa.bool_()), # optional
pa.field('clean_up_tokenization_spaces', pa.bool_()), # optional
pa.field('src_lang', pa.string()), # optional
pa.field('tgt_lang', pa.string()), # optional
# pa.field('extra_field', pa.int64()), # every extra field you specify will be forwarded as a key/value pair
])
output_schema = pa.schema([
pa.field('translation_text', pa.string()),
])
Wallaroo Framework | Reference |
---|---|
Framework.HUGGING-FACE-ZERO-SHOT-CLASSIFICATION |
Schemas:
input_schema = pa.schema([
pa.field('inputs', pa.string()), # required
pa.field('candidate_labels', pa.list_(pa.string(), list_size=2)), # required
pa.field('hypothesis_template', pa.string()), # optional
pa.field('multi_label', pa.bool_()), # optional
])
output_schema = pa.schema([
pa.field('sequence', pa.string()),
pa.field('scores', pa.list_(pa.float64(), list_size=2)), # same as number of candidate labels, list_size can be skipped by may result in slightly worse performance
pa.field('labels', pa.list_(pa.string(), list_size=2)), # same as number of candidate labels, list_size can be skipped by may result in slightly worse performance
])
Wallaroo Framework | Reference |
---|---|
Framework.HUGGING-FACE-ZERO-SHOT-IMAGE-CLASSIFICATION |
Schemas:
input_schema = pa.schema([
pa.field('inputs', # required
pa.list_(
pa.list_(
pa.list_(
pa.int64(),
list_size=3
),
list_size=100
),
list_size=100
)),
pa.field('candidate_labels', pa.list_(pa.string(), list_size=2)), # required
pa.field('hypothesis_template', pa.string()), # optional
])
output_schema = pa.schema([
pa.field('score', pa.list_(pa.float64(), list_size=2)), # same as number of candidate labels
pa.field('label', pa.list_(pa.string(), list_size=2)), # same as number of candidate labels
])
Wallaroo Framework | Reference |
---|---|
Framework.HUGGING-FACE-ZERO-SHOT-OBJECT-DETECTION |
Schemas:
input_schema = pa.schema([
pa.field('images',
pa.list_(
pa.list_(
pa.list_(
pa.int64(),
list_size=3
),
list_size=640
),
list_size=480
)),
pa.field('candidate_labels', pa.list_(pa.string(), list_size=3)),
pa.field('threshold', pa.float64()),
# pa.field('top_k', pa.int64()), # we want the model to return exactly the number of predictions, we shouldn't specify this
])
output_schema = pa.schema([
pa.field('score', pa.list_(pa.float64())), # variable output, depending on detected objects
pa.field('label', pa.list_(pa.string())), # variable output, depending on detected objects
pa.field('box',
pa.list_( # dynamic output, i.e. dynamic number of boxes per input image, each sublist contains the 4 box coordinates
pa.list_(
pa.int64(),
list_size=4
),
),
),
])
Wallaroo Framework | Reference |
---|---|
Framework.HUGGING-FACE-SENTIMENT-ANALYSIS | Hugging Face Sentiment Analysis |
Wallaroo Framework | Reference |
---|---|
Framework.HUGGING-FACE-TEXT-GENERATION |
Any parameter that is not part of the required inputs
list will be forwarded to the model as a key/pair value to the underlying models generate
method. If the additional input is not supported by the model, an error will be returned.
input_schema = pa.schema([
pa.field('inputs', pa.string()),
pa.field('return_tensors', pa.bool_()), # optional
pa.field('return_text', pa.bool_()), # optional
pa.field('return_full_text', pa.bool_()), # optional
pa.field('clean_up_tokenization_spaces', pa.bool_()), # optional
pa.field('prefix', pa.string()), # optional
pa.field('handle_long_generation', pa.string()), # optional
# pa.field('extra_field', pa.int64()), # every extra field you specify will be forwarded as a key/value pair
])
output_schema = pa.schema([
pa.field('generated_text', pa.list_(pa.string(), list_size=1))
])
Parameter | Description |
---|---|
Web Site | https://pytorch.org/ |
Supported Libraries |
|
Framework | Framework.PYTORCH aka pytorch |
Supported File Types | pt ot pth in TorchScript format |
Runtime | Containerized aka mlflow |
Sci-kit Learn aka SKLearn.
Parameter | Description |
---|---|
Web Site | https://scikit-learn.org/stable/index.html |
Supported Libraries |
|
Framework | Framework.SKLEARN aka sklearn |
Runtime | Containerized aka tensorflow / mlflow |
SKLearn Schema Inputs
SKLearn schema follows a different format than other models. To prevent inputs from being out of order, the inputs should be submitted in a single row in the order the model is trained to accept, with all of the data types being the same. For example, the following DataFrame has 4 columns, each column a float
.
sepal length (cm) | sepal width (cm) | petal length (cm) | petal width (cm) | |
---|---|---|---|---|
0 | 5.1 | 3.5 | 1.4 | 0.2 |
1 | 4.9 | 3.0 | 1.4 | 0.2 |
For submission to an SKLearn model, the data input schema will be a single array with 4 float values.
input_schema = pa.schema([
pa.field('inputs', pa.list_(pa.float64(), list_size=4))
])
When submitting as an inference, the DataFrame is converted to rows with the column data expressed as a single array. The data must be in the same order as the model expects, which is why the data is submitted as a single array rather than JSON labeled columns: this insures that the data is submitted in the exact order as the model is trained to accept.
Original DataFrame:
sepal length (cm) | sepal width (cm) | petal length (cm) | petal width (cm) | |
---|---|---|---|---|
0 | 5.1 | 3.5 | 1.4 | 0.2 |
1 | 4.9 | 3.0 | 1.4 | 0.2 |
Converted DataFrame:
inputs | |
---|---|
0 | [5.1, 3.5, 1.4, 0.2] |
1 | [4.9, 3.0, 1.4, 0.2] |
SKLearn Schema Outputs
Outputs for SKLearn that are meant to be predictions
or probabilities
when output by the model are labeled in the output schema for the model when uploaded to Wallaroo. For example, a model that outputs either 1 or 0 as its output would have the output schema as follows:
output_schema = pa.schema([
pa.field('predictions', pa.int32())
])
When used in Wallaroo, the inference result is contained in the out
metadata as out.predictions
.
pipeline.infer(dataframe)
time | in.inputs | out.predictions | check_failures | |
---|---|---|---|---|
0 | 2023-07-05 15:11:29.776 | [5.1, 3.5, 1.4, 0.2] | 0 | 0 |
1 | 2023-07-05 15:11:29.776 | [4.9, 3.0, 1.4, 0.2] | 0 | 0 |
Parameter | Description |
---|---|
Web Site | https://www.tensorflow.org/api_docs/python/tf/keras/Model |
Supported Libraries |
|
Framework | Framework.KERAS aka keras |
Supported File Types | SavedModel format as .zip file and HDF5 format |
Runtime | Containerized aka mlflow |
TensorFlow Keras SavedModel Format
TensorFlow Keras SavedModel models are .zip file of the SavedModel format. For example, the Aloha sample TensorFlow model is stored in the directory alohacnnlstm
:
├── saved_model.pb
└── variables
├── variables.data-00000-of-00002
├── variables.data-00001-of-00002
└── variables.index
This is compressed into the .zip file alohacnnlstm.zip
with the following command:
zip -r alohacnnlstm.zip alohacnnlstm/
See the SavedModel guide for full details.
TensorFlow Keras H5 Format
Wallaroo supports the H5 for Tensorflow Keras models.
Parameter | Description |
---|---|
Web Site | https://xgboost.ai/ |
Supported Libraries | xgboost==1.7.4 |
Framework | Framework.XGBOOST aka xgboost |
Supported File Types | pickle (XGB files are not supported.) |
Runtime | Containerized aka tensorflow / mlflow |
XGBoost Schema Inputs
XGBoost schema follows a different format than other models. To prevent inputs from being out of order, the inputs should be submitted in a single row in the order the model is trained to accept, with all of the data types being the same. If a model is originally trained to accept inputs of different data types, it will need to be retrained to only accept one data type for each column - typically pa.float64()
is a good choice.
For example, the following DataFrame has 4 columns, each column a float
.
sepal length (cm) | sepal width (cm) | petal length (cm) | petal width (cm) | |
---|---|---|---|---|
0 | 5.1 | 3.5 | 1.4 | 0.2 |
1 | 4.9 | 3.0 | 1.4 | 0.2 |
For submission to an XGBoost model, the data input schema will be a single array with 4 float values.
input_schema = pa.schema([
pa.field('inputs', pa.list_(pa.float64(), list_size=4))
])
When submitting as an inference, the DataFrame is converted to rows with the column data expressed as a single array. The data must be in the same order as the model expects, which is why the data is submitted as a single array rather than JSON labeled columns: this insures that the data is submitted in the exact order as the model is trained to accept.
Original DataFrame:
sepal length (cm) | sepal width (cm) | petal length (cm) | petal width (cm) | |
---|---|---|---|---|
0 | 5.1 | 3.5 | 1.4 | 0.2 |
1 | 4.9 | 3.0 | 1.4 | 0.2 |
Converted DataFrame:
inputs | |
---|---|
0 | [5.1, 3.5, 1.4, 0.2] |
1 | [4.9, 3.0, 1.4, 0.2] |
XGBoost Schema Outputs
Outputs for XGBoost are labeled based on the trained model outputs. For this example, the output is simply a single output listed as output
. In the Wallaroo inference result, it is grouped with the metadata out
as out.output
.
output_schema = pa.schema([
pa.field('output', pa.int32())
])
pipeline.infer(dataframe)
time | in.inputs | out.output | check_failures | |
---|---|---|---|---|
0 | 2023-07-05 15:11:29.776 | [5.1, 3.5, 1.4, 0.2] | 0 | 0 |
1 | 2023-07-05 15:11:29.776 | [4.9, 3.0, 1.4, 0.2] | 0 | 0 |
Parameter | Description |
---|---|
Web Site | https://www.python.org/ |
Supported Libraries | python==3.8 |
Framework | Framework.CUSTOM aka custom |
Runtime | Containerized aka mlflow |
Arbitrary Python models, also known as Bring Your Own Predict (BYOP) allow for custom model deployments with supporting scripts and artifacts. These are used with pre-trained models (PyTorch, Tensorflow, etc) along with whatever supporting artifacts they require. Supporting artifacts can include other Python modules, model files, etc. These are zipped with all scripts, artifacts, and a requirements.txt
file that indicates what other Python models need to be imported that are outside of the typical Wallaroo platform.
Contrast this with Wallaroo Python models - aka “Python steps”. These are standalone python scripts that use the python libraries natively supported by the Wallaroo platform. These are used for either simple model deployment (such as ARIMA Statsmodels), or data formatting such as the postprocessing steps. A Wallaroo Python model will be composed of one Python script that matches the Wallaroo requirements.
Arbitrary Python File Requirements
Arbitrary Python (BYOP) models are uploaded to Wallaroo via a ZIP file with the following components:
Artifact | Type | Description |
---|---|---|
Python scripts aka .py files with classes that extend mac.inference.Inference and mac.inference.creation.InferenceBuilder | Python Script | Extend the classes mac.inference.Inference and mac.inference.creation.InferenceBuilder . These are included with the Wallaroo SDK. Further details are in Arbitrary Python Script Requirements. Note that there is no specified naming requirements for the classes that extend mac.inference.Inference and mac.inference.creation.InferenceBuilder - any qualified class name is sufficient as long as these two classes are extended as defined below. |
requirements.txt | Python requirements file | This sets the Python libraries used for the arbitrary python model. These libraries should be targeted for Python 3.8 compliance. These requirements and the versions of libraries should be exactly the same between creating the model and deploying it in Wallaroo. This insures that the script and methods will function exactly the same as during the model creation process. |
Other artifacts | Files | Other models, files, and other artifacts used in support of this model. |
For example, the if the arbitrary python model will be known as vgg_clustering
, the contents may be in the following structure, with vgg_clustering
as the storage directory:
vgg_clustering\
feature_extractor.h5
kmeans.pkl
custom_inference.py
requirements.txt
Note the inclusion of the custom_inference.py
file. This file name is not required - any Python script or scripts that extend the classes listed above are sufficient. This Python script could have been named vgg_custom_model.py
or any other name as long as it includes the extension of the classes listed above.
The sample arbitrary python model file is created with the command zip -r vgg_clustering.zip vgg_clustering/
.
Wallaroo Arbitrary Python uses the Wallaroo SDK mac
module, included in the Wallaroo SDK 2023.2.1 and above. See the Wallaroo SDK Install Guides for instructions on installing the Wallaroo SDK.
Arbitrary Python Script Requirements
The entry point of the arbitrary python model is any python script that extends the following classes. These are included with the Wallaroo SDK. The required methods that must be overridden are specified in each section below.
mac.inference.Inference
interface serves model inferences based on submitted input some input. Its purpose is to serve inferences for any supported arbitrary model framework (e.g.scikit
,keras
etc.).classDiagram class Inference { <<Abstract>> +model Optional[Any] +expected_model_types()* Set +predict(input_data: InferenceData)* InferenceData -raise_error_if_model_is_not_assigned() None -raise_error_if_model_is_wrong_type() None }
mac.inference.creation.InferenceBuilder
builds a concreteInference
, i.e. instantiates anInference
object, loads the appropriate model and assigns the model to to the Inference object.classDiagram class InferenceBuilder { +create(config InferenceConfig) * Inference -inference()* Any }
mac.inference.Inference
mac.inference.Inference Objects
Object | Type | Description |
---|---|---|
model Optional[Any] | An optional list of models that match the supported frameworks from wallaroo.framework.Framework included in the arbitrary python script. Note that this is optional - no models are actually required. A BYOP can refer to a specific model(s) used, be used for data processing and reshaping for later pipeline steps, or other needs. |
mac.inference.Inference Methods
Method | Returns | Description |
---|---|---|
expected_model_types (Required) | Set | Returns a Set of models expected for the inference as defined by the developer. Typically this is a set of one. Wallaroo checks the expected model types to verify that the model submitted through the InferenceBuilder method matches what this Inference class expects. |
_predict (input_data: mac.types.InferenceData) (Required) | mac.types.InferenceData | The entry point for the Wallaroo inference with the following input and output parameters that are defined when the model is updated.
InferenceDataValidationError exception is raised when the input data does not match mac.types.InferenceData . |
raise_error_if_model_is_not_assigned | N/A | Error when expected_model_types is not set. |
raise_error_if_model_is_wrong_type | N/A | Error when the model does not match the expected_model_types . |
mac.inference.creation.InferenceBuilder
InferenceBuilder
builds a concrete Inference
, i.e. instantiates an Inference
object, loads the appropriate model and assigns the model to the Inference.
classDiagram class InferenceBuilder { +create(config InferenceConfig) * Inference -inference()* Any }
Each model that is included requires its own InferenceBuilder
. InferenceBuilder
loads one model, then submits it to the Inference
class when created. The Inference
class checks this class against its expected_model_types()
Set.
mac.inference.creation.InferenceBuilder Methods
Method | Returns | Description |
---|---|---|
create(config mac.config.inference.CustomInferenceConfig) (Required) | The custom Inference instance. | Creates an Inference subclass, then assigns a model and attributes. The CustomInferenceConfig is used to retrieve the config.model_path , which is a pathlib.Path object pointing to the folder where the model artifacts are saved. Every artifact loaded must be relative to config.model_path . This is set when the arbitrary python .zip file is uploaded and the environment for running it in Wallaroo is set. For example: loading the artifact vgg_clustering\feature_extractor.h5 would be set with config.model_path \ feature_extractor.h5 . The model loaded must match an existing module. For our example, this is from sklearn.cluster import KMeans , and this must match the Inference expected_model_types . |
inference | custom Inference instance. | Returns the instantiated custom Inference object created from the create method. |
Arbitrary Python Runtime
Arbitrary Python always run in the containerized model runtime.
Parameter | Description |
---|---|
Web Site | https://mlflow.org |
Supported Libraries | mlflow==1.30.0 |
Runtime | Containerized aka mlflow |
For models that do not fall under the supported model frameworks, organizations can use containerized MLFlow ML Models.
This guide details how to add ML Models from a model registry service into Wallaroo.
Wallaroo supports both public and private containerized model registries. See the Wallaroo Private Containerized Model Container Registry Guide for details on how to configure a Wallaroo instance with a private model registry.
Wallaroo users can register their trained MLFlow ML Models from a containerized model container registry into their Wallaroo instance and perform inferences with it through a Wallaroo pipeline.
As of this time, Wallaroo only supports MLFlow 1.30.0 containerized models. For information on how to containerize an MLFlow model, see the MLFlow Documentation.
Wallaroo supports both public and private containerized model registries. See the Wallaroo Private Containerized Model Container Registry Guide for details on how to configure a Wallaroo instance with a private model registry.
List Wallaroo Frameworks
Wallaroo frameworks are listed from the Wallaroo.Framework class. The following demonstrates listing all available supported frameworks.
from wallaroo.framework import Framework
[e.value for e in Framework]
['onnx',
'tensorflow',
'python',
'keras',
'sklearn',
'pytorch',
'xgboost',
'hugging-face-feature-extraction',
'hugging-face-image-classification',
'hugging-face-image-segmentation',
'hugging-face-image-to-text',
'hugging-face-object-detection',
'hugging-face-question-answering',
'hugging-face-stable-diffusion-text-2-img',
'hugging-face-summarization',
'hugging-face-text-classification',
'hugging-face-translation',
'hugging-face-zero-shot-classification',
'hugging-face-zero-shot-image-classification',
'hugging-face-zero-shot-object-detection',
'hugging-face-sentiment-analysis',
'hugging-face-text-generation']
Models can be converted to native runtime models by meeting the following requirements.
Wallaroo natively supports Open Neural Network Exchange (ONNX) models into the Wallaroo engine.
Parameter | Description |
---|---|
Web Site | https://onnx.ai/ |
Supported Libraries | See table below. |
Framework | Framework.ONNX aka onnx |
Runtime | Native aka onnx |
The following ONNX versions models are supported:
Wallaroo Version | ONNX Version | ONNX IR Version | ONNX OPset Version | ONNX ML Opset Version |
---|---|---|---|---|
2023.2.1 (July 2023) | 1.12.1 | 8 | 17 | 3 |
2023.2 (May 2023) | 1.12.1 | 8 | 17 | 3 |
2023.1 (March 2023) | 1.12.1 | 8 | 17 | 3 |
2022.4 (December 2022) | 1.12.1 | 8 | 17 | 3 |
After April 2022 until release 2022.4 (December 2022) | 1.10.* | 7 | 15 | 2 |
Before April 2022 | 1.6.* | 7 | 13 | 2 |
For the most recent release of Wallaroo 2023.2.1, the following native runtimes are supported:
- If converting another ML Model to ONNX (PyTorch, XGBoost, etc) using the onnxconverter-common library, the supported
DEFAULT_OPSET_NUMBER
is 17.
Using different versions or settings outside of these specifications may result in inference issues and other unexpected behavior.
ONNX models always run in the native runtime space.
Data Schemas
ONNX models deployed to Wallaroo have the following data requirements.
- Equal rows constraint: The number of input rows and output rows must match.
- All inputs are tensors: The inputs are tensor arrays with the same shape.
- Data Type Consistency: Data types within each tensor are of the same type.
Equal Rows Constraint
Inference performed through ONNX models are assumed to be in batch format, where each input row corresponds to an output row. This is reflected in the in
fields returned for an inference. In the following example, each input row for an inference is related directly to the inference output.
df = pd.read_json('./data/cc_data_1k.df.json')
display(df.head())
result = ccfraud_pipeline.infer(df.head())
display(result)
INPUT
tensor | |
---|---|
0 | [-1.0603297501, 2.3544967095000002, -3.5638788326, 5.1387348926, -1.2308457019, -0.7687824608, -3.5881228109, 1.8880837663, -3.2789674274, -3.9563254554, 4.0993439118, -5.6539176395, -0.8775733373, -9.131571192000001, -0.6093537873, -3.7480276773, -5.0309125017, -0.8748149526000001, 1.9870535692, 0.7005485718000001, 0.9204422758, -0.1041491809, 0.3229564351, -0.7418141657, 0.0384120159, 1.0993439146, 1.2603409756, -0.1466244739, -1.4463212439] |
1 | [-1.0603297501, 2.3544967095000002, -3.5638788326, 5.1387348926, -1.2308457019, -0.7687824608, -3.5881228109, 1.8880837663, -3.2789674274, -3.9563254554, 4.0993439118, -5.6539176395, -0.8775733373, -9.131571192000001, -0.6093537873, -3.7480276773, -5.0309125017, -0.8748149526000001, 1.9870535692, 0.7005485718000001, 0.9204422758, -0.1041491809, 0.3229564351, -0.7418141657, 0.0384120159, 1.0993439146, 1.2603409756, -0.1466244739, -1.4463212439] |
2 | [-1.0603297501, 2.3544967095000002, -3.5638788326, 5.1387348926, -1.2308457019, -0.7687824608, -3.5881228109, 1.8880837663, -3.2789674274, -3.9563254554, 4.0993439118, -5.6539176395, -0.8775733373, -9.131571192000001, -0.6093537873, -3.7480276773, -5.0309125017, -0.8748149526000001, 1.9870535692, 0.7005485718000001, 0.9204422758, -0.1041491809, 0.3229564351, -0.7418141657, 0.0384120159, 1.0993439146, 1.2603409756, -0.1466244739, -1.4463212439] |
3 | [-1.0603297501, 2.3544967095000002, -3.5638788326, 5.1387348926, -1.2308457019, -0.7687824608, -3.5881228109, 1.8880837663, -3.2789674274, -3.9563254554, 4.0993439118, -5.6539176395, -0.8775733373, -9.131571192000001, -0.6093537873, -3.7480276773, -5.0309125017, -0.8748149526000001, 1.9870535692, 0.7005485718000001, 0.9204422758, -0.1041491809, 0.3229564351, -0.7418141657, 0.0384120159, 1.0993439146, 1.2603409756, -0.1466244739, -1.4463212439] |
4 | [0.5817662108, 0.09788155100000001, 0.1546819424, 0.4754101949, -0.19788623060000002, -0.45043448540000003, 0.016654044700000002, -0.0256070551, 0.0920561602, -0.2783917153, 0.059329944100000004, -0.0196585416, -0.4225083157, -0.12175388770000001, 1.5473094894000001, 0.2391622864, 0.3553974881, -0.7685165301, -0.7000849355000001, -0.1190043285, -0.3450517133, -1.1065114108, 0.2523411195, 0.0209441826, 0.2199267436, 0.2540689265, -0.0450225094, 0.10867738980000001, 0.2547179311] |
OUTPUT
time | in.tensor | out.dense_1 | check_failures | |
---|---|---|---|---|
0 | 2023-11-17 20:34:17.005 | [-1.0603297501, 2.3544967095, -3.5638788326, 5.1387348926, -1.2308457019, -0.7687824608, -3.5881228109, 1.8880837663, -3.2789674274, -3.9563254554, 4.0993439118, -5.6539176395, -0.8775733373, -9.131571192, -0.6093537873, -3.7480276773, -5.0309125017, -0.8748149526, 1.9870535692, 0.7005485718, 0.9204422758, -0.1041491809, 0.3229564351, -0.7418141657, 0.0384120159, 1.0993439146, 1.2603409756, -0.1466244739, -1.4463212439] | [0.99300325] | 0 |
1 | 2023-11-17 20:34:17.005 | [-1.0603297501, 2.3544967095, -3.5638788326, 5.1387348926, -1.2308457019, -0.7687824608, -3.5881228109, 1.8880837663, -3.2789674274, -3.9563254554, 4.0993439118, -5.6539176395, -0.8775733373, -9.131571192, -0.6093537873, -3.7480276773, -5.0309125017, -0.8748149526, 1.9870535692, 0.7005485718, 0.9204422758, -0.1041491809, 0.3229564351, -0.7418141657, 0.0384120159, 1.0993439146, 1.2603409756, -0.1466244739, -1.4463212439] | [0.99300325] | 0 |
2 | 2023-11-17 20:34:17.005 | [-1.0603297501, 2.3544967095, -3.5638788326, 5.1387348926, -1.2308457019, -0.7687824608, -3.5881228109, 1.8880837663, -3.2789674274, -3.9563254554, 4.0993439118, -5.6539176395, -0.8775733373, -9.131571192, -0.6093537873, -3.7480276773, -5.0309125017, -0.8748149526, 1.9870535692, 0.7005485718, 0.9204422758, -0.1041491809, 0.3229564351, -0.7418141657, 0.0384120159, 1.0993439146, 1.2603409756, -0.1466244739, -1.4463212439] | [0.99300325] | 0 |
3 | 2023-11-17 20:34:17.005 | [-1.0603297501, 2.3544967095, -3.5638788326, 5.1387348926, -1.2308457019, -0.7687824608, -3.5881228109, 1.8880837663, -3.2789674274, -3.9563254554, 4.0993439118, -5.6539176395, -0.8775733373, -9.131571192, -0.6093537873, -3.7480276773, -5.0309125017, -0.8748149526, 1.9870535692, 0.7005485718, 0.9204422758, -0.1041491809, 0.3229564351, -0.7418141657, 0.0384120159, 1.0993439146, 1.2603409756, -0.1466244739, -1.4463212439] | [0.99300325] | 0 |
4 | 2023-11-17 20:34:17.005 | [0.5817662108, 0.097881551, 0.1546819424, 0.4754101949, -0.1978862306, -0.4504344854, 0.0166540447, -0.0256070551, 0.0920561602, -0.2783917153, 0.0593299441, -0.0196585416, -0.4225083157, -0.1217538877, 1.5473094894, 0.2391622864, 0.3553974881, -0.7685165301, -0.7000849355, -0.1190043285, -0.3450517133, -1.1065114108, 0.2523411195, 0.0209441826, 0.2199267436, 0.2540689265, -0.0450225094, 0.1086773898, 0.2547179311] | [0.0010916889] | 0 |
All Inputs Are Tensors
All inputs into an ONNX model must be tensors. This requires that the shape of each element is the same. For example, the following is a proper input:
t [
[2.35, 5.75],
[3.72, 8.55],
[5.55, 97.2]
]
Another example is a 2,2,3 tensor, where the shape of each element is (3,), and each element has 2 rows.
t = [
[2.35, 5.75, 19.2],
[3.72, 8.55, 10.5]
],
[
[5.55, 7.2, 15.7],
[9.6, 8.2, 2.3]
]
In this example each element has a shape of (2,)
. Tensors with elements of different shapes, known as ragged tensors, are not supported. For example:
t = [
[2.35, 5.75],
[3.72, 8.55, 10.5],
[5.55, 97.2]
])
**INVALID SHAPE**
For models that require ragged tensor or other shapes, see other data formatting options such as Bring Your Own Predict models.
Data Type Consistency
All inputs into an ONNX model must have the same internal data type. For example, the following is valid because all of the data types within each element are float32
.
t = [
[2.35, 5.75],
[3.72, 8.55],
[5.55, 97.2]
]
The following is invalid, as it mixes floats and strings in each element:
t = [
[2.35, "Bob"],
[3.72, "Nancy"],
[5.55, "Wani"]
]
The following inputs are valid, as each data type is consistent within the elements.
df = pd.DataFrame({
"t": [
[2.35, 5.75, 19.2],
[5.55, 7.2, 15.7],
],
"s": [
["Bob", "Nancy", "Wani"],
["Jason", "Rita", "Phoebe"]
]
})
df
t | s | |
---|---|---|
0 | [2.35, 5.75, 19.2] | [Bob, Nancy, Wani] |
1 | [5.55, 7.2, 15.7] | [Jason, Rita, Phoebe] |
The following ML Model versions and Python libraries are supported by Wallaroo. When using the Wallaroo autoconversion library or working with a local version of the Wallaroo SDK, use the following versions for maximum compatibility.
Library | Supported Version |
---|---|
Python | 3.8.6 and above |
onnx | 1.12.0 |
tensorflow | 2.9.1 |
keras | 2.9.0 |
pytorch | 1.13.1 |
sk-learn aka scikit-learn | 1.1.2 |
statsmodels | 0.13.2 |
XGBoost | 1.6.2 |
MLFlow | 1.30.0 |
Supported Data Types
The following data types are supported for transporting data to and from Wallaroo in the following run times:
- ONNX
- TensorFlow
- MLFlow
Data Type Conditions
The following conditions apply to data types used in inference requests.
None
orNull
data types are not submitted. All fields must have submitted values that match their data type. For example, if the schema expects afloat
value, then some value of typefloat
must be submitted and can not beNone
orNull
. If a schema expects a string value, then some value of type string must be submitted, etc.datetime
data types must be converted tostring
.- ONNX models support multiple inputs only of the same data type.
Runtime | BFloat16* | Float16 | Float32 | Float64 |
---|---|---|---|---|
ONNX | X | X | ||
TensorFlow | X | X | X | |
MLFlow | X | X | X |
* (Brain Float 16, represented internally as a f32)
Runtime | Int8 | Int16 | Int32 | Int64 |
---|---|---|---|---|
ONNX | X | X | X | X |
TensorFlow | X | X | X | X |
MLFlow | X | X | X | X |
Runtime | Uint8 | Uint16 | Uint32 | Uint64 |
---|---|---|---|---|
ONNX | X | X | X | X |
TensorFlow | X | X | X | X |
MLFlow | X | X | X | X |
Runtime | Boolean | Utf8 (String) | Complex 64 | Complex 128 | FixedSizeList* |
---|---|---|---|---|---|
ONNX | X | ||||
Tensor | X | X | X | ||
MLFlow | X | X | X |
* Fixed sized lists of any of the previously supported data types.
Can I Import My Own Notebooks Into Wallaroo?
Yes! Jupyter Hub is provided as a service in your Wallaroo instance. So feel free to import your notebooks, models, and data to get right to work.
What Is The Difference Between A Model And A Pipeline In Wallaroo?
A Model, or Machine Learning Model (ML), has been trained by data scientists to take in data and return some result. A Wallaroo Pipeline can set one or more models as steps in the pipeline. This lets you submit data to a pipeline, have that data sent to each model, then return a result.
This provides you with the power to set the order for how pipelines provide inferences in different orders, chain different models together to run comparisons, or any other combination of tasks you can come up with.
Can I Train A Model In Wallaroo?
While Wallaroo contains an entire Python library and allows you full access and control within that environment, models should be trained outside of Wallaroo, then imported into Wallaroo to be deployed and run as an object in the Wallaroo engine.
How Can I Serve My Models Up To Return Predictions?
Once you have uploaded your models to Wallaroo and deployed a pipeline that steps through how information is submitted to each model you use for the inference, you can serve your models in the following ways:
- Run an Inference from a File : Submit a file with an array of values, and return the results derived from them.
- Run an Inference through a Pipeline Deployment URL: Submit your inference request through a HTTP Pipeline Deployment URL created when the pipeline is deployed.
Can I A/B Test My Models In Wallaroo?
Yes! Wallaroo supports A/B testing through the following mechanisms:
- Set up Control and Challenger models
- Define a pipeline to split data between the two models
- Test the Challenger model and return the results.
- Perform a Shadow Deploy to send data to both models, but only return to the user the results from the Control model. This allows users to test Challenger models without sacrificing production deployments.
Where Can I See Pipeline Performance Metrics?
Pipeline metrics can be seen through the Wallaroo Dashboard through the following process:
- From the Wallaroo Dashboard, set the current workspace from the top left dropdown list.
- Select View Pipelines from the pipeline’s row.
- To view details on the pipeline, select the name of the pipeline.
- A list of the pipeline’s details will be displayed.
- Select Metrics to view the following information. From here you can select the time period to display metrics from through the drop down to display the following:
- Requests per second
- Cluster inference rate
- Inference latency
- The Audit Log and Anomaly Log are available to view further details of the pipeline’s activities.
How Are Wallaroo Enterprise And Wallaroo Community Edition Different?
Wallaroo Community is different from Wallaroo Enterprise based on the available features and restrictions.
Feature | Wallaroo Community | Wallaroo Enterprise |
---|---|---|
Max Number of Cores | 32 | Unlimited |
Max Number of Users | 2 | Unlimited |
Max Number of Deployed Pipelines | 2 | Unlimited |
Max Steps per Pipeline | 5 | Unlimited |
Single Sign On | ⃠ | √ |
Compute Auto-Scaling | ⃠ | √ |
Wallaroo Support Services | Wallaroo Community Slack | Wallaroo Enterprise Support |