TensorRT-LLMs/examples/auto_deploy/README.md

🔥🚀⚡ AutoDeploy

Seamless Model Deployment from PyTorch to TRT-LLM

AutoDeploy is designed to simplify and accelerate the deployment of PyTorch models, including off-the-shelf models like those from Hugging Face, to TensorRT-LLM. It automates graph transformations to integrate inference optimizations such as tensor parallelism, KV-caching and quantization. AutoDeploy supports optimized in-framework deployment, minimizing the amount of manual modification needed.

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Latest News 🔥

• 2025/02/14

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Motivation & Approach

Deploying large language models (LLMs) can be challenging, especially when balancing ease of use with high performance. Teams need simple, intuitive deployment solutions that reduce engineering effort, speed up the integration of new models, and support rapid experimentation without compromising performance.

AutoDeploy addresses these challenges with a streamlined, (semi-)automated pipeline that transforms in-framework PyTorch models, including Hugging Face models, into optimized inference-ready models for TRT-LLM. It simplifies deployment, optimizes models for efficient inference, and bridges the gap between simplicity and performance.

Key Features:

• Seamless Model Transition: Automatically converts PyTorch/Hugging Face models to TRT-LLM without manual rewrites.
• Unified Model Definition: Maintain a single source of truth with your original PyTorch/Hugging Face model.
• Optimized Inference: Built-in transformations for sharding, quantization, KV-cache integration, MHA fusion, and CudaGraph optimization.
• Immediate Deployment: Day-0 support for models with continuous performance enhancements.
• Quick Setup & Prototyping: Lightweight pip package for easy installation with a demo environment for fast testing.

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Get Started

1. Install AutoDeploy:

AutoDeploy is accessible through TRT-LLM installation.

sudo apt-get -y install libopenmpi-dev && pip3 install --upgrade pip setuptools && pip3 install tensorrt_llm

You can refer to TRT-LLM installation guide for more information.

2. Run Llama Example:

You are ready to run an in-framework LLama Demo now.

The general entrypoint to run the auto-deploy demo is the build_and_run_ad.py script, Checkpoints are loaded directly from Huggingface (HF) or a local HF-like directory:

cd examples/auto_deploy
python build_and_run_ad.py --config '{"model": "TinyLlama/TinyLlama-1.1B-Chat-v1.0"}'

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Support Matrix

AutoDeploy streamlines the model deployment process through an automated workflow designed for efficiency and performance. The workflow begins with a PyTorch model, which is exported using torch.export to generate a standard Torch graph. This graph contains core PyTorch ATen operations alongside custom attention operations, determined by the attention backend specified in the configuration.

The exported graph then undergoes a series of automated transformations, including graph sharding, KV-cache insertion, and GEMM fusion, to optimize model performance. After these transformations, the graph is compiled using one of the supported compile backends (like torch-opt), followed by deploying it via the TRT-LLM runtime.

Supported Models

Bring Your Own Model: AutoDeploy leverages torch.export and dynamic graph pattern matching, enabling seamless integration for a wide variety of models without relying on hard-coded architectures.

Additionally, we have officially verified support for the following models:

Click to expand supported models list

Model Series	HF Model Card	Model Factory	Precision	World Size	Runtime	Compile Backend			Attention Backend
						torch-simple	torch-compile	torch-opt	TritonWithFlattenedInputs	FlashInfer	MultiHeadLatentAttention
LLaMA	meta-llama/Llama-2-7b-chat-hf meta-llama/Meta-Llama-3.1-8B-Instruct meta-llama/Llama-3.1-70B-Instruct codellama/CodeLlama-13b-Instruct-hf	AutoModelForCausalLM	BF16	1,2,4	demollm, trtllm	✅	✅	✅	✅	✅	n/a
Nvidia Minitron	nvidia/Llama-3_1-Nemotron-51B-Instruct nvidia/Llama-3.1-Minitron-4B-Width-Base nvidia/Llama-3.1-Minitron-4B-Depth-Base	AutoModelForCausalLM	BF16	1,2,4	demollm, trtllm	✅	✅	✅	✅	✅	n/a
Nvidia Model Optimizer	nvidia/Llama-3.1-8B-Instruct-FP8 nvidia/Llama-3.1-405B-Instruct-FP8	AutoModelForCausalLM	FP8	1,2,4	demollm, trtllm	✅	✅	✅	✅	✅	n/a
DeepSeek	deepseek-ai/DeepSeek-R1-Distill-Llama-70B	AutoModelForCausalLM	BF16	1,2,4	demollm, trtllm	✅	✅	✅	✅	✅	n/a
Mistral	mistralai/Mixtral-8x7B-Instruct-v0.1 mistralai/Mistral-7B-Instruct-v0.3	AutoModelForCausalLM	BF16	1,2,4	demollm, trtllm	✅	✅	✅	✅	✅	n/a
BigCode	bigcode/starcoder2-15b	AutoModelForCausalLM	FP32	1,2,4	demollm, trtllm	✅	✅	✅	✅	✅	n/a
Deepseek-V3	deepseek-ai/DeepSeek-V3	AutoModelForCausalLM	BF16	1,2,4	demollm	✅	❌	❌	n/a	n/a	✅

Runtime Integrations

AutoDeploy runs natively with the entire TRT-LLM stack via the LLM API. In addition, we provide a light-weight wrapper of the LLM API for onboarding and debugging new models:

"runtime"	Description
trtllm	A robust, production-grade runtime optimized for high-performance inference.
demollm	A lightweight runtime wrapper designed for development and testing, featuring a naive scheduler and KV-cache manager for simplified debugging and testing.

Compile Backends

AutoDeploy supports multiple backends for compiling the exported Torch graph:

"compile_backend"	Description
torch-simple	Exports the graph without additional optimizations.
torch-compile	Applies torch.compile to the graph after all AutoDeploy transformations have been completed.
torch-cudagraph	Performs CUDA graph capture (without torch.compile).
torch-opt	Uses torch.compile along with CUDA Graph capture to enhance inference performance.

Attention backends

Optimize attention operations using different attention kernel implementations:

"attn_backend"	Description
TritonWithFlattenedInputs	Custom fused multi-head attention (MHA) with KV Cache kernels for efficient attention processing.
FlashInfer	Uses off-the-shelf optimized attention kernels with KV Cache from the flashinfer library.

Precision Support

AutoDeploy supports a range of precision formats to enhance model performance, including:

• BF16, FP32
• Quantization formats like FP8.

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Advanced Usage

Example Build Script (build_and_run_ad.py)

Base Command

To build and run AutoDeploy example, use the following command with the build_and_run_ad.py script:

In the below example:

Configuration Key	Description
"model"	The HF model card or path to a HF checkpoint folder
"model_factory"	Choose model factory implementation ("hf" or "llama4")
"skip_loading_weights"	Only load the architecture, not the weights
"customize_tokenizer"	Use tokenizer from model factory (true) or from LLM API (false)
"model_kwargs"	Extra kwargs for the model config class to customize the model config
"tokenizer_kwargs"	Extra kwargs for the tokenizer class to customize the tokenizer
"world_size"	The number of GPUs for Tensor Parallel
"runtime"	Specifies which type of Engine to use during runtime
"compile_backend"	Specifies how to compile the graph at the end
"attn_backend"	Specifies kernel implementation for attention
"mla_backend"	Specifies implementation for multi-head latent attention
"max_seq_len"	Maximum sequence length for inference/cache
"max_batch_size"	Maximum dimension for statically allocated KV cache
"page_size"	Page size for attention
"benchmark"	Indicates whether to run the built-in benchmark for token generation

For default values and additional configuration options, refer to the simple_config.py file.

cd examples/auto_deploy
python build_and_run_ad.py \
--config '{"model": {HF_modelcard_or_path_to_local_folder}, "world_size": {num_GPUs}, "runtime": {"demollm"|"trtllm"}, "compile_backend": {"torch-simple"|"torch-opt"}, "attn_backend": {"TritonWithFlattenedInputs"|"FlashInfer"}, "benchmark": {true|false} }'

Experiment Configuration

The experiment configuration dataclass is defined in simple_config.py. Check it out for detailed documentation on each available configuration.

Arguments can be overwritten during runtime by specifying the --config argument on the command line and providing a valid config dictionary in json format. For example, to run any experiment with benchmarking enabled, use:

cd examples/auto_deploy
python build_and_run_ad.py --config '{"benchmark": true}'

The model_kwargs and tokenizer_kwargs dictionaries can be supplied on the command line via --model-kwargs '{}' and --tokenizer-kwargs '{}'.

Logging Level

Use the following env variable to specify the logging level of our built-in logger ordered by decreasing verbosity;

AUTO_DEPLOY_LOG_LEVEL=DEBUG
AUTO_DEPLOY_LOG_LEVEL=INFO
AUTO_DEPLOY_LOG_LEVEL=WARNING
AUTO_DEPLOY_LOG_LEVEL=ERROR
AUTO_DEPLOY_LOG_LEVEL=INTERNAL_ERROR

The default level is INFO.

Model Evaluation with LM Evaluation Harness

lm-evaluation-harness is supported. To run the evaluation, please use the following command:

# model is defined the same as above. Other config args can also be specified in the model_args (comma separated).
# You can specify any tasks supported with lm-evaluation-harness.
cd examples/auto_deploy
python lm_eval_ad.py \
--model autodeploy --model_args model=meta-llama/Meta-Llama-3.1-8B-Instruct,world_size=2 --tasks mmlu

Mixed-precision Quantization using TensorRT Model Optimizer

TensorRT Model Optimizer AutoQuantize algorithm is a PTQ algorithm from ModelOpt which quantizes a model by searching for the best quantization format per-layer while meeting the performance constraint specified by the user. This way, AutoQuantize enables to trade-off model accuracy for performance.

Currently AutoQuantize supports only effective_bits as the performance constraint (for both weight-only quantization and weight & activation quantization). See AutoQuantize documentation for more details.

1. Quantize a model with ModelOpt

Refer to NVIDIA TensorRT Model Optimizer for generating quantized model checkpoint.

2. Deploy the quantized model with AutoDeploy

cd examples/auto_deploy
python build_and_run_ad.py --config '{"world_size": 1, "model": "{<MODELOPT_CKPT_PATH>}"}'

Incorporating auto_deploy into your own workflow

AutoDeploy can be seamlessly integrated into your existing workflows using TRT-LLM's LLM high-level API. This section provides a blueprint for configuring and invoking AutoDeploy within your custom applications.

Here is an example of how you can build an LLM object with AutoDeploy integration:

Click to expand the example

from tensorrt_llm import LLM
from tensorrt_llm.builder import BuildConfig
from tensorrt_llm._torch.auto_deploy.shim import AutoDeployConfig

# 1. Set up the build configuration
build_config = BuildConfig(
    max_seq_len=<MAX_SEQ_LEN>,
    max_batch_size=<MAX_BS>,
)
build_config.plugin_config.tokens_per_block = <PAGE_SIZE>
# if using "TritonWithFlattenedInputs" as backend, <PAGE_SIZE> should equal to <MAX_SEQ_LEN>
# Refer to examples/auto_deploy/simple_config.py (line 109) for details.

# 2. Set up AutoDeploy configuration
# AutoDeploy will use its own cache implementation
model_kwargs = {"use_cache":False}

ad_config = AutoDeployConfig(
    use_cuda_graph=True, # set True if using "torch-opt" as compile backend
    torch_compile_enabled=True, # set True if using "torch-opt" as compile backend
    model_kwargs=model_kwargs,
    attn_backend="TritonWithFlattenedInputs", # choose between "TritonWithFlattenedInputs" and "FlashInfer"
    skip_loading_weights=False,
)

# 3. Construct the LLM high-level interface object with autodeploy as backend
llm = LLM(
    model=<HF_MODEL_CARD_OR_DIR>,
    backend="autodeploy",
    build_config=build_config,
    pytorch_backend_config=ad_config,
    tensor_parallel_size=<NUM_WORLD_RANK>,
)

For more examples on TRT-LLM LLM API, visit this page.

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Roadmap

1. Model Coverage:

   • Expand support for additional LLM variants and features:
     • LoRA
     • Speculative Decoding
     • Model specialization for disaggregated serving

2. Performance Optimization:

   • Enhance inference speed and efficiency with:
     • MoE fusion and all-reduce fusion techniques
     • Reuse of TRT-LLM PyTorch operators for greater efficiency

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Disclaimer

This project is in active development and is currently in an early (beta) stage. The code is experimental, subject to change, and may include backward-incompatible updates. While we strive for correctness, we provide no guarantees regarding functionality, stability, or reliability. Use at your own risk.