Metadata-Version: 2.4
Name: flashinfer-python
Version: 0.2.6.post1
Summary: FlashInfer: Kernel Library for LLM Serving
Author: FlashInfer team
License-Expression: Apache-2.0
Project-URL: Homepage, https://github.com/flashinfer-ai/flashinfer
Requires-Python: <4.0,>=3.9
Description-Content-Type: text/markdown
License-File: LICENSE
Requires-Dist: numpy
Requires-Dist: torch
Requires-Dist: ninja
Requires-Dist: requests
Dynamic: license-file
Dynamic: requires-dist

<p align="center">
  <picture>
    <source media="(prefers-color-scheme: dark)" srcset="https://github.com/flashinfer-ai/web-data/blob/main/logo/FlashInfer-black-background.png?raw=true">
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</p>
<h1 align="center">
Kernel Library for LLM Serving
</h1>

<p align="center">
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FlashInfer is a library and kernel generator for Large Language Models that provides high-performance implementation of LLM GPU kernels such as FlashAttention, SparseAttention, PageAttention, Sampling, and more. FlashInfer focuses on LLM serving and inference, and delivers state-of-the-art performance across diverse scenarios.

Check our [v0.2 release blog](https://flashinfer.ai/2024/12/16/flashinfer-v02-release.html) for new features!

The core features of FlashInfer include:
1. **Efficient Sparse/Dense Attention Kernels**: Efficient single/batch attention for sparse(paged)/dense KV-storage on CUDA Cores and Tensor Cores (both FA2 & FA3) templates. The vector-sparse attention can achieve 90% of the bandwidth of dense kernels with same problem size.
2. **Load-Balanced Scheduling**: FlashInfer decouples `plan`/`run` stage of attention computation where we schedule the computation of variable-length inputs in `plan` stage to alleviate load-imbalance issue.
3. **Memory Efficiency**: FlashInfer offers [Cascade Attention](https://docs.flashinfer.ai/api/cascade.html#flashinfer.cascade.MultiLevelCascadeAttentionWrapper) for hierarchical KV-Cache, and implements Head-Query fusion for accelerating Grouped-Query Attention, and efficient kernels for low-precision attention and fused-RoPE attention for compressed KV-Cache.
4. **Customizable Attention**: Bring your own attention variants through JIT-compilation.
5. **CUDAGraph and torch.compile Compatibility**: FlashInfer kernels can be captured by CUDAGraphs and torch.compile for low-latency inference.
6. **Efficient LLM-specific Operators**: High-Performance [fused kernel for Top-P, Top-K/Min-P sampling](https://docs.flashinfer.ai/api/sampling.html) without the need to sorting.

FlashInfer supports PyTorch, TVM and C++ (header-only) APIs, and can be easily integrated into existing projects.

## News
- [Mar 10, 2025] [Blog Post](https://flashinfer.ai/2025/03/10/sampling.html) Sorting-Free GPU Kernels for LLM Sampling, which explains the design of sampling kernels in FlashInfer.
- [Mar 1, 2025] Checkout flashinfer's [intra-kernel profiler](https://github.com/flashinfer-ai/flashinfer/tree/main/profiler) for visualizing the timeline of each threadblock in GPU kernels.
- [Dec 16, 2024] [Blog Post](https://flashinfer.ai/2024/12/16/flashinfer-v02-release.html) FlashInfer 0.2 - Efficient and Customizable Kernels for LLM Inference Serving
- [Sept 2024] We've launched a [Slack](https://join.slack.com/t/flashinfer/shared_invite/zt-2r93kj2aq-wZnC2n_Z2~mf73N5qnVGGA) workspace for Flashinfer users and developers. Join us for timely support, discussions, updates and knowledge sharing!
- [Jan 31, 2024] [Blog Post](https://flashinfer.ai/2024/01/08/cascade-inference.html) Cascade Inference: Memory-Efficient Shared Prefix Batch Decoding
- [Jan 31, 2024] [Blog Post](https://flashinfer.ai/2024/01/03/introduce-flashinfer.html) Accelerating Self-Attentions for LLM Serving with FlashInfer

## Getting Started

Using our PyTorch API is the easiest way to get started:

### Install from PIP

We provide prebuilt python wheels for Linux. Install FlashInfer with the following command:

```bash
# For CUDA 12.6 & torch 2.6
pip install flashinfer-python -i https://flashinfer.ai/whl/cu126/torch2.6
# For other CUDA & torch versions, check https://docs.flashinfer.ai/installation.html
```

To try the latest features from the main branch, use our nightly-built wheels:

```bash
pip install flashinfer-python -i https://flashinfer.ai/whl/nightly/cu126/torch2.6
```

For a JIT version (compiling every kernel from scratch, [NVCC](https://developer.nvidia.com/cuda-downloads) is required), install from [PyPI](https://pypi.org/project/flashinfer-python/):

```bash
pip install flashinfer-python
```

### Install from Source

Alternatively, build FlashInfer from source:

```bash
git clone https://github.com/flashinfer-ai/flashinfer.git --recursive
cd flashinfer
python -m pip install -v .
```

To pre-compile essential kernels ahead-of-time (AOT), run the following command:

```bash
# Set target CUDA architectures
export TORCH_CUDA_ARCH_LIST="7.5 8.0 8.9 9.0a 10.0a"
# Build AOT kernels. Will produce AOT kernels in aot-ops/
python -m flashinfer.aot
# Build AOT wheel
python -m build --no-isolation --wheel
# Install AOT wheel
python -m pip install dist/flashinfer-*.whl
```

For more details, refer to the [Install from Source documentation](https://docs.flashinfer.ai/installation.html#install-from-source).

### Trying it out

Below is a minimal example of using FlashInfer's single-request decode/append/prefill attention kernels:

```python
import torch
import flashinfer

kv_len = 2048
num_kv_heads = 32
head_dim = 128

k = torch.randn(kv_len, num_kv_heads, head_dim).half().to(0)
v = torch.randn(kv_len, num_kv_heads, head_dim).half().to(0)

# decode attention

num_qo_heads = 32
q = torch.randn(num_qo_heads, head_dim).half().to(0)

o = flashinfer.single_decode_with_kv_cache(q, k, v) # decode attention without RoPE on-the-fly
o_rope_on_the_fly = flashinfer.single_decode_with_kv_cache(q, k, v, pos_encoding_mode="ROPE_LLAMA") # decode with LLaMA style RoPE on-the-fly

# append attention
append_qo_len = 128
q = torch.randn(append_qo_len, num_qo_heads, head_dim).half().to(0) # append attention, the last 128 tokens in the KV-Cache are the new tokens
o = flashinfer.single_prefill_with_kv_cache(q, k, v, causal=True) # append attention without RoPE on-the-fly, apply causal mask
o_rope_on_the_fly = flashinfer.single_prefill_with_kv_cache(q, k, v, causal=True, pos_encoding_mode="ROPE_LLAMA") # append attention with LLaMA style RoPE on-the-fly, apply causal mask

# prefill attention
qo_len = 2048
q = torch.randn(qo_len, num_qo_heads, head_dim).half().to(0) # prefill attention
o = flashinfer.single_prefill_with_kv_cache(q, k, v, causal=False) # prefill attention without RoPE on-the-fly, do not apply causal mask
```

Check out [documentation](https://docs.flashinfer.ai/) for usage of batch decode/append/prefill kernels and shared-prefix cascading kernels.

## Custom Attention Variants

Starting from FlashInfer v0.2, users can customize their own attention variants with additional parameters. For more details, refer to our [JIT examples](https://github.com/flashinfer-ai/flashinfer/blob/main/tests/test_jit_example.py).

## Run Benchmarks

We profile FlashInfer kernel performance with [nvbench](https://github.com/NVIDIA/nvbench) and you can compile and run the benchmarks with the following commands:

```bash
mkdir build
cp cmake/config.cmake build # you can modify the config.cmake to enable/disable benchmarks and change CUDA architectures
cd build
cmake ..
make -j12
```

You can run `./bench_{single/batch}_{prefill/decode}` to benchmark the performance (e.g. `./bench_single_prefill` for single-request prefill attention). `./bench_{single/batch}_{prefill/decode} --help` will show you the available options.

## C++ API and TVM Bindings

FlashInfer also provides C++ API and TVM bindings, please refer to [documentation](https://docs.flashinfer.ai/) for more details.

## Adoption

We are thrilled to share that FlashInfer is being adopted by many cutting-edge projects, including but not limited to:
- [MLC-LLM](https://github.com/mlc-ai/mlc-llm)
- [Punica](https://github.com/punica-ai/punica)
- [SGLang](https://github.com/sgl-project/sglang)
- [ScaleLLM](https://github.com/vectorch-ai/ScaleLLM)
- [vLLM](https://github.com/vllm-project/vllm)
- [TGI](https://github.com/huggingface/text-generation-inference)
- [lorax](https://github.com/predibase/lorax)
- [TensorRT-LLM](https://github.com/NVIDIA/TensorRT-LLM)
- [LightLLM](https://github.com/ModelTC/lightllm)

## Acknowledgement

FlashInfer is inspired by [FlashAttention 1&2](https://github.com/dao-AILab/flash-attention/), [vLLM](https://github.com/vllm-project/vllm), [stream-K](https://arxiv.org/abs/2301.03598), [cutlass](https://github.com/nvidia/cutlass) and [AITemplate](https://github.com/facebookincubator/AITemplate) projects.

## Citation

If you find FlashInfer helpful in your project or research, please consider citing our [paper](https://arxiv.org/abs/2501.01005):

```bibtex
@article{ye2025flashinfer,
    title = {FlashInfer: Efficient and Customizable Attention Engine for LLM Inference Serving},
    author = {
      Ye, Zihao and
      Chen, Lequn and
      Lai, Ruihang and
      Lin, Wuwei and
      Zhang, Yineng and
      Wang, Stephanie and
      Chen, Tianqi and
      Kasikci, Baris and
      Grover, Vinod and
      Krishnamurthy, Arvind and
      Ceze, Luis
    },
    journal = {arXiv preprint arXiv:2501.01005},
    year = {2025},
    url = {https://arxiv.org/abs/2501.01005}
}
```
