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Triton clients

PyTriton client is a user-friendly tool designed to communicate with the Triton Inference Server effortlessly. It manages the technical details for you, allowing you to concentrate on your data and the outcomes you aim to achieve. Here's how it assists:

  1. Fetching Model Configuration: The client retrieves details about the model from the server, such as the shape and names of the input and output data tensors. This step is crucial for preparing your data correctly and for interpreting the response. This functionality is encapsulated in the ModelClient class.

  2. Sending Requests: Utilizing the model information, the client generates an inference request by mapping arguments you pass to the infer_sample or infer_batch methods to model inputs. It sends your data to the Triton server, requesting the model to perform inference. Arguments can be passed as positional or keyword arguments (mixing them is not allowed), and the client handles the rest.

  3. Returning Responses: It then delivers the model's response back to you. It decodes inputs as numpy arrays and maps model outputs to dictionary elements returned to you from the infer_sample or infer_batch methods. It also removes the batch dimension if it was added by the client.

This process might introduce a bit of delay due to the extra step of fetching model configuration. However, you can minimize this by reusing the PyTriton client for multiple requests or by setting it up with pre-loaded model configuration if you have it.

PyTriton includes five specialized high-level clients to cater to different needs:

  • ModelClient: A straightforward, synchronous client for simple request-response operations.
  • FuturesModelClient: A multithreaded client that handles multiple requests in parallel, speeding up operations.
  • DecoupledModelClient: A synchronous client designed for decoupled models, which allow for flexible interaction patterns with the Triton server.
  • AsyncioModelClient: An asynchronous client that works well with Python's asyncio for efficient concurrent operations.
  • AsyncioDecoupledModelClient: An asyncio-compatible client specifically for working with decoupled models asynchronously.

PyTriton clients used tritonclient package from Triton. It is a Python client library for Triton Inference Server. It provides low level API for communicating with the server using HTTP or gRPC protocol. PyTriton clients are built on top of tritonclient and provide high level API for communicating with the server. Not all features of tritonclient are available in PyTriton clients. If you need more control over the communication with the server, you can use tritonclient directly.

ModelClient

ModelClient is a simple client that can perform inference requests synchronously. You can use ModelClient to communicate with the deployed model using HTTP or gRPC protocol. You can specify the protocol when creating the ModelClient object.

You need Linear model described in quick_start. You should run it so client can connect to it.

For example, you can use ModelClient to send requests to a PyTorch model that performs linear regression:

import torch
from pytriton.client import ModelClient

# Create some input data as a numpy array
input1_data = torch.randn(128, 2).cpu().detach().numpy()

# Create a ModelClient object with the server address and model name
client = ModelClient("localhost:8000", "Linear")
# Call the infer_batch method with the input data
result_dict = client.infer_batch(input1_data)
# Close the client to release the resources
client.close()

# Print the result dictionary
print(result_dict)

URL localhost:8000 is the default address for Triton server HTTP protocol. If you have a different address, you should replace it with the correct one. You can also use the gRPC protocol by putting grpc in address string:

client = ModelClient("grpc://localhost", "Linear")

You can omit port number if it is default for HTTP or gRPC protocol. Default port for HTTP is 8000 and for gRPC is 8001.

You can also use ModelClient to send requests to a model that performs image classification. The example assumes that a model takes in an image and returns the top 5 predicted classes. This model is not included in the PyTriton library.

You need to convert the image to a numpy array and resize it to the expected input shape. You can use Pillow package to do this.

You need to install Pillow package to run the example:

pip install Pillow

import numpy as np
from PIL import Image
from pytriton.client import ModelClient

# Create some input data as a numpy array of an image
img = Image.open("cat.jpg")
img = img.resize((224, 224))
input_data = np.array(img)

# Create a ModelClient object with the server address and model name
client = ModelClient("localhost:8000", "ImageNet")
# Call the infer_sample method with the input data
result_dict = client.infer_sample(input_data)
# Close the client to release the resources
client.close()

# Print the result dictionary
print(result_dict)

FuturesModelClient

FuturesModelClient is a concurrent.futures based client that can perform inference requests in a parallel way. You can use FuturesModelClient to communicate with the deployed model using HTTP or gRPC protocol. You can specify the protocol when creating the FuturesModelClient object.

For example, you can use FuturesModelClient to send multiple requests to a text generation model that takes in text prompts and returns generated texts. The TextGen model is not included in the PyTriton library. The example assumes that the model returns a single output tensor with the generated text. The example also assumes that the model takes in a list of text prompts and returns a list of generated texts.

You need to convert the text prompts to numpy arrays of bytes using a tokenizer from transformers. You also need to detokenize the output texts using the same tokenizer:

You need to install torch and transformers package to run the example:

pip install torch transformers

import numpy as np
from pytriton.client import FuturesModelClient
from transformers import AutoTokenizer

# Create some input data as a list of text prompts
input_data_list_text = ["Write a haiku about winter.", "Summarize the article below in one sentence.", "Generate a catchy slogan for PyTriton."]

# Create a tokenizer from transformers
tokenizer = AutoTokenizer.from_pretrained("gpt2")

# Convert the text prompts to numpy arrays of bytes using the tokenizer
input_data_list = [np.array(tokenizer.encode(prompt)) for prompt in input_data_list_text]

# Create a FuturesModelClient object with the server address and model name
with FuturesModelClient("localhost:8000", "TextGen") as client:
    # Call the infer_sample method for each input data in the list and store the returned futures
    output_data_futures = [client.infer_sample(input_data) for input_data in input_data_list]
    # Wait for all the futures to complete and get the results
    output_data_list = [output_data_future.result() for output_data_future in output_data_futures]

# Print tokens
print(output_data_list)

# Detokenize the output texts using the tokenizer and print them
output_texts = [tokenizer.decode(output_data["OUTPUT_1"]) for output_data in output_data_list]
for output_text in output_texts:
    print(output_text)

You can also use FuturesModelClient to send multiple requests to an image classification model that takes in image data and returns class labels or probabilities. The ImageNet model is described above.

In this case, you can use the infer_batch method to send a batch of images as input and get a batch of outputs. You need to stack the images along the first dimension to form a batch. You can also print the class names corresponding to the output labels:

import numpy as np
from PIL import Image
from pytriton.client import FuturesModelClient

# Create some input data as a list of lists of image arrays
input_data_list = []
for batch in [["cat.jpg", "dog.jpg", "bird.jpg"], ["car.jpg", "bike.jpg", "bus.jpg"], ["apple.jpg", "banana.jpg", "orange.jpg"]]:
  batch_data = []
  for filename in batch:
    img = Image.open(filename)
    img = img.resize((224, 224))
    img = np.array(img)
    batch_data.append(img)
  # Stack the images along the first dimension to form a batch
  batch_data = np.stack(batch_data, axis=0)
  input_data_list.append(batch_data)

# Create a list of class names for ImageNet
class_names = ["tench", "goldfish", "great white shark", ...]

# Create a FuturesModelClient object with the server address and model name
with FuturesModelClient("localhost:8000", "ImageNet") as client:
    # Call the infer_batch method for each input data in the list and store the returned futures
    output_data_futures = [client.infer_batch(input_data) for input_data in input_data_list]
    # Wait for all the futures to complete and get the results
    output_data_list = [output_data_future.result() for output_data_future in output_data_futures]

# Print the list of result dictionaries
print(output_data_list)

# Print the class names corresponding to the output labels for each batch
for output_data in output_data_list:
  output_labels = output_data["OUTPUT_1"]
  for output_label in output_labels:
    class_name = class_names[output_label]
    print(f"The image is classified as {class_name}.")

AsyncioModelClient

AsyncioModelClient is an asynchronous client that can perform inference requests using the asyncio library. You can use AsyncioModelClient to communicate with the deployed model using HTTP or gRPC protocol. You can specify the protocol when creating the AsyncioModelClient object.

For example, you can use AsyncioModelClient to send requests to a PyTorch model that performs linear regression:

import torch
from pytriton.client import AsyncioModelClient

# Make the code async by adding async before the function definition
async def main():
    # Create some input data as a numpy array
    input1_data = torch.randn(2).cpu().detach().numpy()

    # Create an AsyncioModelClient object with the server address and model name
    client = AsyncioModelClient("localhost:8000", "Linear")
    # Call the infer_sample method with the input data
    result_dict = await client.infer_sample(input1_data)
    # Close the client to release the resources
    await client.close()

    # Print the result dictionary
    print(result_dict)

# Run the code as a coroutine using asyncio.run()
import asyncio
loop = asyncio.get_event_loop()
loop.run_until_complete(main())

You can also use FastAPI to create a web application that exposes the results of inference at an HTTP endpoint. FastAPI is a modern, fast, web framework for building APIs with Python 3.6+ based on standard Python type hints.

To use FastAPI, you need to install it with:

pip install fastapi

You also need an ASGI server, for production such as Uvicorn or Hypercorn.

To install Uvicorn, run:

pip install uvicorn[standard]

The uvicorn uses port 8000 as default for web server. Triton server default port is also 8000 for HTTP protocol. You can change uvicorn port by using --port option. PyTriton also supports custom ports configuration for Triton server. The class TritonConfig contains parameters for ports configuration. You can pass it to Triton during initialization:

config = TritonConfig(http_port=8015)
triton_server = Triton(config=config)

You can use this triton_server object to bind your inference model and run HTTP endpoint from Triton Inference Server at port 8015.

Then you can create a FastAPI app that uses the AsyncioModelClient to perform inference and return the results as JSON:

from fastapi import FastAPI
import torch
from pytriton.client import AsyncioModelClient

# Create an AsyncioModelClient object with the server address and model name
config_client = None

app = FastAPI()

@app.get("/predict")
async def predict():
    # Create some input data as a numpy array
    input1_data = torch.randn(2).cpu().detach().numpy()

    # Create an AsyncioModelClient object with the server address and model name and store it in a global variable
    global config_client
    if not config_client:
        config_client = AsyncioModelClient("localhost:8000", "Linear")
        await config_client.model_config

    # Create an AsyncioModelClient object from existing client to avoid pulling config from server
    async with AsyncioModelClient.from_existing_client(config_client) as request_client:
        # Call the infer_sample method with the input data
        result_dict = await request_client.infer_sample(input1_data)

    output_dict = {key: value.tolist() for key, value in result_dict.items()}

    # Return the result dictionary as JSON
    return output_dict


@app.on_event("shutdown")
async def shutdown():
    # Close the client to release the resources
    await config_client.close()

Save this file as main.py.

To run the app, use the command:

uvicorn main:app --reload --port 8015

You can then access the endpoint at http://127.0.0.1:8015/predict and see the JSON response.

You can also check the interactive API documentation at http://127.0.0.1:8015/docs.

You can test your server using curl:

curl -X 'GET' \
  'http://127.0.0.1:8015/predict' \
  -H 'accept: application/json'

Command will print three random numbers:

[-0.2608422636985779,-0.6435106992721558,-0.3492531180381775]

For more information about FastAPI and Uvicorn, check out these links:

Decoupled models and clients

You can use the PyTriton library to create a decoupled model and client. A decoupled model is a model that is decoupled from batching and other features of the Triton Inference Server. It can receive many requests in parallel and perform inference on each request independently. A decoupled model can send multiple responses to single requests. A decoupled client is a client that can receive multiple responses from a single request. See document about decoupled models for more information.

ModelClient, AsyncioModelClient, and FuturesModelClient refuse to send requests to decoupled models and raise an exception. You can use DecoupledModelClient and AsyncioDecoupledModelClient to send requests to decoupled models. You can only communicate over gRPC protocol with decoupled models.

The Generate Extension is provisional and likely to change in future versions

You can use generate stream endpoint in Triton Inference Server to send requests to decoupled models. See Generate Extension.

For example, you can use DecoupledModelClient to send requests to GPT2 using stream endpoint:

import torch
from pytriton.client import DecoupledModelClient

client = DecoupledModelClient("grpc://localhost", "streaming_bot")
iterator = client.infer_sample(np.array(["AI answers to".encode('utf-8')]))
result = list(iterator)
print(result)
client.close()

Asynchronous version of DecoupledModelClient is AsyncioDecoupledModelClient. You can use it to send requests to decoupled models using asyncio library:

from pytriton.client import AsyncioDecoupledModelClient
# Make the code async by adding async before the function definition
async def main():
    client = AsyncioDecoupledModelClient("grpc://localhost", "streaming_bot")
    async for answer in client.infer_sample(np.array(["AI answers to".encode('utf-8')])):
        print(answer)
    await client.close()

# Run the code as a coroutine using asyncio.run()
import asyncio
loop = asyncio.get_event_loop()
loop.run_until_complete(main())

This will print the following output:

{'response': b'AI answers '},
{'response': b'AI answers to '},
{'response': b'AI answers to the '},
{'response': b'AI answers to the '},
{'response': b'AI answers to the question, '},
{'response': b'AI answers to the question, '},
{'response': b'AI answers to the question, "What '},
{'response': b'AI answers to the question, "What is '},
{'response': b'AI answers to the question, "What is the '},
{'response': b'AI answers to the question, "What is the best '},
{'response': b'AI answers to the question, "What is the best way '},
{'response': b'AI answers to the question, "What is the best way to '},
{'response': b'AI answers to the question, "What is the best way to get '},
{'response': b'AI answers to the question, "What is the best way to get rid '},
{'response': b'AI answers to the question, "What is the best way to get rid of '},
{'response': b'AI answers to the question, "What is the best way to get rid of the '},
{'response': b'AI answers to the question, "What is the best way to get rid of the '},
{'response': b'AI answers to the question, "What is the best way to get rid of the problem?"\n'},
{'response': b'AI answers to the question, "What is the best way to get rid of the problem?"\n'}

Each response contains more tokens than the previous one. The last response contains the full generated text.

Client timeouts

When creating a ModelClient or FuturesModelClient object, you can specify the timeout for waiting until the server and model are ready using the init_timeout_s parameter. By default, the timeout is set to 5 minutes (300 seconds).

Example usage:

import numpy as np
from pytriton.client import ModelClient, FuturesModelClient

input1_data = np.random.randn(128, 2)
client = ModelClient("localhost", "MyModel", init_timeout_s=120)
# Raises PyTritonClientTimeoutError if the server or model is not ready within the specified timeout
result_dict = client.infer_batch(input1_data)
client.close()


with FuturesModelClient("localhost", "MyModel", init_timeout_s=120) as client:
    future = client.infer_batch(input1_data)
    #...
    # It will raise `PyTritonClientTimeoutError` if the server is not ready and the model is not loaded within 120 seconds
    # from the time `infer_batch` was called by a thread from `ThreadPoolExecutor`
    result_dict = future.result()

You can disable the default behavior of waiting for the server and model to be ready during first inference request by setting lazy_init to False:

import numpy as np
from pytriton.client import ModelClient, FuturesModelClient

input1_data = np.random.randn(128, 2)

# will raise PyTritonClientTimeoutError if server is not ready and model loaded
# within 120 seconds during intialization of client
with ModelClient("localhost", "MyModel", init_timeout_s=120, lazy_init=False) as client:
    result_dict = client.infer_batch(input1_data)

You can specify the timeout for the client to wait for the inference response from the server. The default timeout is 60 seconds. You can specify the timeout when creating the ModelClient or FuturesModelClient object:

import numpy as np
from pytriton.client import ModelClient, FuturesModelClient

input1_data = np.random.randn(128, 2)
client = ModelClient("localhost", "MyModel", inference_timeout_s=240)
# Raises `PyTritonClientTimeoutError` if the server does not respond to inference request within 240 seconds
result_dict = client.infer_batch(input1_data)
client.close()


with FuturesModelClient("localhost", "MyModel", inference_timeout_s=240) as client:
    future = client.infer_batch(input1_data)
    ...
    # Raises `PyTritonClientTimeoutError` if the server does not respond within 240 seconds
    # from the time `infer_batch` was called by a thread from `ThreadPoolExecutor`
    result_dict = future.result()

gRPC client timeout not fully supported

There are some missing features in the gRPC client that prevent it from working correctly with timeouts used during the wait for the server and model to be ready. This may cause the client to hang if the server doesn't respond with the current server or model state.

Server side timeout not implemented

Currently, there is no support for server-side timeout. The server will continue to process the request even if the client timeout is reached.