vLLM with Intel® Gaudi® AI Accelerators - Gaudi Software Suite 1.18.0
Requirements and Installation
Please follow the instructions provided in the Gaudi Installation Guide to set up the environment. To achieve the best performance, please follow the methods outlined in the Optimizing Training Platform Guide.
Requirements
- OS: Ubuntu 22.04 LTS
- Python: 3.10
- Intel Gaudi accelerator
- Intel Gaudi software version 1.18.0
To verify that the Intel Gaudi software was correctly installed, run:
$ hl-smi # verify that hl-smi is in your PATH and each Gaudi accelerator is visible
$ apt list --installed | grep habana # verify that habanalabs-firmware-tools, habanalabs-graph, habanalabs-rdma-core and habanalabs-thunk are installed
$ pip list | grep habana # verify that habana-torch-plugin, habana-torch-dataloader, habana-pyhlml and habana-media-loader are installed
$ pip list | grep neural # verify that neural-compressor is installed
Refer to Intel Gaudi Software Stack Verification for more details.
Run Docker Image
It is highly recommended to use the latest Docker image from Intel Gaudi vault. Refer to the Intel Gaudi documentation for more details.
Use the following commands to run a Docker image:
$ docker pull vault.habana.ai/gaudi-docker/1.18.0/ubuntu22.04/habanalabs/pytorch-installer-2.4.0:latest
$ docker run -it --runtime=habana -e HABANA_VISIBLE_DEVICES=all -e OMPI_MCA_btl_vader_single_copy_mechanism=none --cap-add=sys_nice --net=host --ipc=host vault.habana.ai/gaudi-docker/1.18.0/ubuntu22.04/habanalabs/pytorch-installer-2.4.0:latest
Build and Install vLLM
Currently, the latest features and performance optimizations are developed in Gaudi's vLLM-fork and we periodically upstream them to vLLM main repo. To install latest HabanaAI/vLLM-fork, run the following:
$ git clone https://github.com/HabanaAI/vllm-fork.git
$ cd vllm-fork
$ git checkout v0.5.3.post1+Gaudi-1.18.0
$ pip install -e .
Supported Features
- Offline batched inference
- Online inference via OpenAI-Compatible Server
- HPU autodetection - no need to manually select device within vLLM
- Paged KV cache with algorithms enabled for Intel Gaudi accelerators
- Custom Intel Gaudi implementations of Paged Attention, KV cache ops, prefill attention, Root Mean Square Layer Normalization, Rotary Positional Encoding
- Tensor parallelism support for multi-card inference
- Inference with HPU Graphs for accelerating low-batch latency and throughput
- Attention with Linear Biases (ALiBi)
- LoRA adapters
- Quantization with INC
Unsupported Features
- Beam search
- Prefill chunking (mixed-batch inferencing)
Supported Configurations
The following configurations have been validated to be function with Gaudi2 devices. Configurations that are not listed may or may not work.
- meta-llama/Llama-2-7b on single HPU, or with tensor parallelism on 2x and 8x HPU, BF16 datatype with random or greedy sampling
- meta-llama/Llama-2-7b-chat-hf on single HPU, or with tensor parallelism on 2x and 8x HPU, BF16 datatype with random or greedy sampling
- meta-llama/Meta-Llama-3-8B on single HPU, or with tensor parallelism on 2x and 8x HPU, BF16 datatype with random or greedy sampling
- meta-llama/Meta-Llama-3-8B-Instruct on single HPU, or with tensor parallelism on 2x and 8x HPU, BF16 datatype with random or greedy sampling
- meta-llama/Meta-Llama-3.1-8B on single HPU, or with tensor parallelism on 2x and 8x HPU, BF16 datatype with random or greedy sampling
- meta-llama/Meta-Llama-3.1-8B-Instruct on single HPU, or with tensor parallelism on 2x and 8x HPU, BF16 datatype with random or greedy sampling
- meta-llama/Llama-2-70b with tensor parallelism on 8x HPU, BF16 datatype with random or greedy sampling
- meta-llama/Llama-2-70b-chat-hf with tensor parallelism on 8x HPU, BF16 datatype with random or greedy sampling
- meta-llama/Meta-Llama-3-70B with tensor parallelism on 8x HPU, BF16 datatype with random or greedy sampling
- meta-llama/Meta-Llama-3-70B-Instruct with tensor parallelism on 8x HPU, BF16 datatype with random or greedy sampling
- meta-llama/Meta-Llama-3.1-70B with tensor parallelism on 8x HPU, BF16 datatype with random or greedy sampling
- meta-llama/Meta-Llama-3.1-70B-Instruct with tensor parallelism on 8x HPU, BF16 datatype with random or greedy sampling
- mistralai/Mistral-7B-Instruct-v0.3 on single HPU or with tensor parallelism on 2x HPU, BF16 datatype with random or greedy sampling
- mistralai/Mixtral-8x7B-Instruct-v0.1 with tensor parallelism on 2x HPU, BF16 datatype with random or greedy sampling
Performance Tuning
Execution modes
Currently in vLLM for HPU we support four execution modes, depending on selected HPU PyTorch Bridge backend (via PT_HPU_LAZY_MODE
environment variable), and --enforce-eager
flag.
PT_HPU_LAZY_MODE |
enforce_eager |
execution mode |
---|---|---|
0 | 0 | torch.compile |
0 | 1 | PyTorch eager mode |
1 | 0 | HPU Graphs |
1 | 1 | PyTorch lazy mode |
Warning
In 1.18.0, all modes utilizing PT_HPU_LAZY_MODE=0
are highly experimental and should be only used for validating functional correctness. Their performance will be improved in the next releases. For obtaining the best performance in 1.18.0, please use HPU Graphs, or PyTorch lazy mode.
Bucketing mechanism
Intel Gaudi accelerators work best when operating on models with fixed tensor shapes. Intel Gaudi Graph Compiler is responsible for generating optimized binary code that implements the given model topology on Gaudi. In its default configuration, the produced binary code may be heavily dependent on input and output tensor shapes, and can require graph recompilation when encountering differently shaped tensors within the same topology. While the resulting binaries utilize Gaudi efficiently, the compilation itself may introduce a noticeable overhead in end-to-end execution. In a dynamic inference serving scenario, there is a need to minimize the number of graph compilations and reduce the risk of graph compilation occurring during server runtime. Currently it is achieved by "bucketing" model's forward pass across two dimensions - batch_size
and sequence_length
.
Note
Bucketing allows us to reduce the number of required graphs significantly, but it does not handle any graph compilation and device code generation - this is done in warmup and HPUGraph capture phase.
Bucketing ranges are determined with 3 parameters - min
, step
and max
. They can be set separately for prompt and decode phase, and for batch size and sequence length dimension. These parameters can be observed in logs during vLLM startup:
INFO 08-01 21:37:59 habana_model_runner.py:493] Prompt bucket config (min, step, max_warmup) bs:[1, 32, 4], seq:[128, 128, 1024]
INFO 08-01 21:37:59 habana_model_runner.py:499] Generated 24 prompt buckets: [(1, 128), (1, 256), (1, 384), (1, 512), (1, 640), (1, 768), (1, 896), (1, 1024), (2, 128), (2, 256), (2, 384), (2, 512), (2, 640), (2, 768), (2, 896), (2, 1024), (4, 128), (4, 256), (4, 384), (4, 512), (4, 640), (4, 768), (4, 896), (4, 1024)]
INFO 08-01 21:37:59 habana_model_runner.py:504] Decode bucket config (min, step, max_warmup) bs:[1, 128, 4], seq:[128, 128, 2048]
INFO 08-01 21:37:59 habana_model_runner.py:509] Generated 48 decode buckets: [(1, 128), (1, 256), (1, 384), (1, 512), (1, 640), (1, 768), (1, 896), (1, 1024), (1, 1152), (1, 1280), (1, 1408), (1, 1536), (1, 1664), (1, 1792), (1, 1920), (1, 2048), (2, 128), (2, 256), (2, 384), (2, 512), (2, 640), (2, 768), (2, 896), (2, 1024), (2, 1152), (2, 1280), (2, 1408), (2, 1536), (2, 1664), (2, 1792), (2, 1920), (2, 2048), (4, 128), (4, 256), (4, 384), (4, 512), (4, 640), (4, 768), (4, 896), (4, 1024), (4, 1152), (4, 1280), (4, 1408), (4, 1536), (4, 1664), (4, 1792), (4, 1920), (4, 2048)]
min
determines the lowest value of the bucket. step
determines the interval between buckets, and max
determines the upper bound of the bucket. Furthermore, interval between min
and step
has special handling - min
gets multiplied by consecutive powers of two, until step
gets reached. We call this the ramp-up phase and it is used for handling lower batch sizes with minimum wastage, while allowing larger padding on larger batch sizes.
Example (with ramp-up)
min = 2, step = 32, max = 64
=> ramp_up = (2, 4, 8, 16)
=> stable = (32, 64)
=> buckets = ramp_up + stable => (2, 4, 8, 16, 32, 64)
Example (without ramp-up)
min = 128, step = 128, max = 512
=> ramp_up = ()
=> stable = (128, 256, 384, 512)
=> buckets = ramp_up + stable => (128, 256, 384, 512)
In the logged scenario, 24 buckets were generated for prompt (prefill) runs, and 48 buckets for decode runs. Each bucket corresponds to a separate optimized device binary for a given model with specified tensor shapes. Whenever a batch of requests is processed, it is padded across batch and sequence length dimension to the smallest possible bucket.
Warning
If a request exceeds maximum bucket size in any dimension, it will be processed without padding, and its processing may require a graph compilation, potentially significantly increasing end-to-end latency. The boundaries of the buckets are user-configurable via environment variables, and upper bucket boundaries can be increased to avoid such scenario.
As an example, if a request of 3 sequences, with max sequence length of 412 comes in to an idle vLLM server, it will be padded executed as (4, 512)
prefill bucket, as batch_size
(number of sequences) will be padded to 4 (closest batch_size dimension higher than 3), and max sequence length will be padded to 512 (closest sequence length dimension higher than 412). After prefill stage, it will be executed as (4, 512)
decode bucket and will continue as that bucket until either batch dimension changes (due to request being finished) - in which case it will become a (2, 512)
bucket, or context length increases above 512 tokens, in which case it will become (4, 640)
bucket.
Note
Bucketing is transparent to a client - padding in sequence length dimension is never returned to the client, and padding in batch dimension does not create new requests.
Warmup
Warmup is an optional, but highly recommended step occurring before vLLM server starts listening. It executes a forward pass for each bucket with dummy data. The goal is to pre-compile all graphs and not incur any graph compilation overheads within bucket boundaries during server runtime. Each warmup step is logged during vLLM startup:
INFO 08-01 22:26:47 habana_model_runner.py:1066] [Warmup][Prompt][1/24] batch_size:4 seq_len:1024 free_mem:79.16 GiB
INFO 08-01 22:26:47 habana_model_runner.py:1066] [Warmup][Prompt][2/24] batch_size:4 seq_len:896 free_mem:55.43 GiB
INFO 08-01 22:26:48 habana_model_runner.py:1066] [Warmup][Prompt][3/24] batch_size:4 seq_len:768 free_mem:55.43 GiB
...
INFO 08-01 22:26:59 habana_model_runner.py:1066] [Warmup][Prompt][24/24] batch_size:1 seq_len:128 free_mem:55.43 GiB
INFO 08-01 22:27:00 habana_model_runner.py:1066] [Warmup][Decode][1/48] batch_size:4 seq_len:2048 free_mem:55.43 GiB
INFO 08-01 22:27:00 habana_model_runner.py:1066] [Warmup][Decode][2/48] batch_size:4 seq_len:1920 free_mem:55.43 GiB
INFO 08-01 22:27:01 habana_model_runner.py:1066] [Warmup][Decode][3/48] batch_size:4 seq_len:1792 free_mem:55.43 GiB
...
INFO 08-01 22:27:16 habana_model_runner.py:1066] [Warmup][Decode][47/48] batch_size:2 seq_len:128 free_mem:55.43 GiB
INFO 08-01 22:27:16 habana_model_runner.py:1066] [Warmup][Decode][48/48] batch_size:1 seq_len:128 free_mem:55.43 GiB
This example uses the same buckets as in Bucketing mechanism section. Each output line corresponds to execution of a single bucket. When bucket is executed for the first time, its graph is compiled and can be reused later on, skipping further graph compilations.
Tip
Compiling all the buckets might take some time and can be turned off with VLLM_SKIP_WARMUP=true
environment variable. Keep in mind that if you do that, you may face graph compilations once executing a given bucket for the first time. It is fine to disable warmup for development, but it's highly recommended to enable it in deployment.
HPU Graph capture
HPU Graphs are currently the most performant execution method of vLLM on Intel Gaudi. When HPU Graphs are enabled, execution graphs will be traced (recorded) ahead of time (after performing warmup), to be later replayed during inference, significantly reducing host overheads. Recording can take large amounts of memory, which needs to be taken into account when allocating KV cache. Enabling HPU Graphs will impact the number of available KV cache blocks, but vLLM provides user-configurable variables to control memory management.
When HPU Graphs are being used, they share the common memory pool ("usable memory") as KV cache, determined by gpu_memory_utilization
flag (0.9
by default). Before KV cache gets allocated, model weights are loaded onto the device, and a forward pass of the model is executed on dummy data, to estimate memory usage. Only after that, gpu_memory_utilization
flag is utilized - at its default value, will mark 90% of free device memory at that point as usable. Next, KV cache gets allocated, model is warmed up, and HPU Graphs are captured. Environment variable VLLM_GRAPH_RESERVED_MEM
defines the ratio of memory reserved for HPU Graphs capture. With its default value (VLLM_GRAPH_RESERVED_MEM=0.4
), 40% of usable memory will be reserved for graph capture (later referred to as "usable graph memory"), and the remaining 60% will be utilized for KV cache. Environment variable VLLM_GRAPH_PROMPT_RATIO
determines the ratio of usable graph memory reserved for prefill and decode graphs. By default (VLLM_GRAPH_PROMPT_RATIO=0.5
), both stages have equal memory constraints. Lower value corresponds to less usable graph memory reserved for prefill stage, e.g. VLLM_GRAPH_PROMPT_RATIO=0.2
will reserve 20% of usable graph memory for prefill graphs, and 80% of usable graph memory for decode graphs.
Note
gpu_memory_utilization
does not correspond to the absolute memory usage across HPU. It specifies the memory margin after loading the model and performing a profile run. If device has 100 GiB of total memory, and 50 GiB of free memory after loading model weights and executing profiling run, gpu_memory_utilization
at its default value will mark 90% of 50 GiB as usable, leaving 5 GiB of margin, regardless of total device memory.
User can also configure the strategy for capturing HPU Graphs for prompt and decode stages separately. Strategy affects the order of capturing graphs. There are two strategies implemented: - max_bs
- graph capture queue will sorted in descending order by their batch sizes. Buckets with equal batch sizes are sorted by sequence length in ascending order (e.g. (64, 128)
, (64, 256)
, (32, 128)
, (32, 256)
, (1, 128)
, (1,256)
), default strategy for decode - min_tokens
- graph capture queue will be sorted in ascending order by the number of tokens each graph processes (batch_size*sequence_length
), default strategy for prompt
When there's large amount of requests pending, vLLM scheduler will attempt to fill the maximum batch size for decode as soon as possible. When a request is finished, decode batch size decreases. When that happens, vLLM will attempt to schedule a prefill iteration for requests in the waiting queue, to fill the decode batch size to its previous state. This means that in a full load scenario, decode batch size is often at its maximum, which makes large batch size HPU Graphs crucial to capture, as reflected by max_bs
strategy. On the other hand, prefills will be executed most frequently with very low batch sizes (1-4), which is reflected in min_tokens
strategy.
Note
VLLM_GRAPH_PROMPT_RATIO
does not set a hard limit on memory taken by graphs for each stage (prefill and decode). vLLM will first attempt to use up entirety of usable prefill graph memory (usable graph memory * VLLM_GRAPH_PROMPT_RATIO
) for capturing prefill HPU Graphs, next it will attempt do the same for decode graphs and usable decode graph memory pool. If one stage is fully captured, and there is unused memory left within usable graph memory pool, vLLM will attempt further graph capture for the other stage, until no more HPU Graphs can be captured without exceeding reserved memory pool. The behavior on that mechanism can be observed in the example below.
Each described step is logged by vLLM server, as follows (negative values correspond to memory being released):
INFO 08-02 17:37:44 habana_model_runner.py:493] Prompt bucket config (min, step, max_warmup) bs:[1, 32, 4], seq:[128, 128, 1024]
INFO 08-02 17:37:44 habana_model_runner.py:499] Generated 24 prompt buckets: [(1, 128), (1, 256), (1, 384), (1, 512), (1, 640), (1, 768), (1, 896), (1, 1024), (2, 128), (2, 256), (2, 384), (2, 512), (2, 640), (2, 768), (2, 896), (2, 1024), (4, 128), (4, 256), (4, 384), (4, 512), (4, 640), (4, 768), (4, 896), (4, 1024)]
INFO 08-02 17:37:44 habana_model_runner.py:504] Decode bucket config (min, step, max_warmup) bs:[1, 128, 4], seq:[128, 128, 2048]
INFO 08-02 17:37:44 habana_model_runner.py:509] Generated 48 decode buckets: [(1, 128), (1, 256), (1, 384), (1, 512), (1, 640), (1, 768), (1, 896), (1, 1024), (1, 1152), (1, 1280), (1, 1408), (1, 1536), (1, 1664), (1, 1792), (1, 1920), (1, 2048), (2, 128), (2, 256), (2, 384), (2, 512), (2, 640), (2, 768), (2, 896), (2, 1024), (2, 1152), (2, 1280), (2, 1408), (2, 1536), (2, 1664), (2, 1792), (2, 1920), (2, 2048), (4, 128), (4, 256), (4, 384), (4, 512), (4, 640), (4, 768), (4, 896), (4, 1024), (4, 1152), (4, 1280), (4, 1408), (4, 1536), (4, 1664), (4, 1792), (4, 1920), (4, 2048)]
INFO 08-02 17:37:52 habana_model_runner.py:430] Pre-loading model weights on hpu:0 took 14.97 GiB of device memory (14.97 GiB/94.62 GiB used) and 2.95 GiB of host memory (475.2 GiB/1007 GiB used)
INFO 08-02 17:37:52 habana_model_runner.py:438] Wrapping in HPU Graph took 0 B of device memory (14.97 GiB/94.62 GiB used) and -252 KiB of host memory (475.2 GiB/1007 GiB used)
INFO 08-02 17:37:52 habana_model_runner.py:442] Loading model weights took in total 14.97 GiB of device memory (14.97 GiB/94.62 GiB used) and 2.95 GiB of host memory (475.2 GiB/1007 GiB used)
INFO 08-02 17:37:54 habana_worker.py:134] Model profiling run took 504 MiB of device memory (15.46 GiB/94.62 GiB used) and 180.9 MiB of host memory (475.4 GiB/1007 GiB used)
INFO 08-02 17:37:54 habana_worker.py:158] Free device memory: 79.16 GiB, 39.58 GiB usable (gpu_memory_utilization=0.5), 15.83 GiB reserved for HPUGraphs (VLLM_GRAPH_RESERVED_MEM=0.4), 23.75 GiB reserved for KV cache
INFO 08-02 17:37:54 habana_executor.py:85] # HPU blocks: 1519, # CPU blocks: 0
INFO 08-02 17:37:54 habana_worker.py:190] Initializing cache engine took 23.73 GiB of device memory (39.2 GiB/94.62 GiB used) and -1.238 MiB of host memory (475.4 GiB/1007 GiB used)
INFO 08-02 17:37:54 habana_model_runner.py:1066] [Warmup][Prompt][1/24] batch_size:4 seq_len:1024 free_mem:55.43 GiB
...
INFO 08-02 17:38:22 habana_model_runner.py:1066] [Warmup][Decode][48/48] batch_size:1 seq_len:128 free_mem:55.43 GiB
INFO 08-02 17:38:22 habana_model_runner.py:1159] Using 15.85 GiB/55.43 GiB of free device memory for HPUGraphs, 7.923 GiB for prompt and 7.923 GiB for decode (VLLM_GRAPH_PROMPT_RATIO=0.5)
INFO 08-02 17:38:22 habana_model_runner.py:1066] [Warmup][Graph/Prompt][1/24] batch_size:1 seq_len:128 free_mem:55.43 GiB
...
INFO 08-02 17:38:26 habana_model_runner.py:1066] [Warmup][Graph/Prompt][11/24] batch_size:1 seq_len:896 free_mem:48.77 GiB
INFO 08-02 17:38:27 habana_model_runner.py:1066] [Warmup][Graph/Decode][1/48] batch_size:4 seq_len:128 free_mem:47.51 GiB
...
INFO 08-02 17:38:41 habana_model_runner.py:1066] [Warmup][Graph/Decode][48/48] batch_size:1 seq_len:2048 free_mem:47.35 GiB
INFO 08-02 17:38:41 habana_model_runner.py:1066] [Warmup][Graph/Prompt][12/24] batch_size:4 seq_len:256 free_mem:47.35 GiB
INFO 08-02 17:38:42 habana_model_runner.py:1066] [Warmup][Graph/Prompt][13/24] batch_size:2 seq_len:512 free_mem:45.91 GiB
INFO 08-02 17:38:42 habana_model_runner.py:1066] [Warmup][Graph/Prompt][14/24] batch_size:1 seq_len:1024 free_mem:44.48 GiB
INFO 08-02 17:38:43 habana_model_runner.py:1066] [Warmup][Graph/Prompt][15/24] batch_size:2 seq_len:640 free_mem:43.03 GiB
INFO 08-02 17:38:43 habana_model_runner.py:1128] Graph/Prompt captured:15 (62.5%) used_mem:14.03 GiB buckets:[(1, 128), (1, 256), (1, 384), (1, 512), (1, 640), (1, 768), (1, 896), (1, 1024), (2, 128), (2, 256), (2, 384), (2, 512), (2, 640), (4, 128), (4, 256)]
INFO 08-02 17:38:43 habana_model_runner.py:1128] Graph/Decode captured:48 (100.0%) used_mem:161.9 MiB buckets:[(1, 128), (1, 256), (1, 384), (1, 512), (1, 640), (1, 768), (1, 896), (1, 1024), (1, 1152), (1, 1280), (1, 1408), (1, 1536), (1, 1664), (1, 1792), (1, 1920), (1, 2048), (2, 128), (2, 256), (2, 384), (2, 512), (2, 640), (2, 768), (2, 896), (2, 1024), (2, 1152), (2, 1280), (2, 1408), (2, 1536), (2, 1664), (2, 1792), (2, 1920), (2, 2048), (4, 128), (4, 256), (4, 384), (4, 512), (4, 640), (4, 768), (4, 896), (4, 1024), (4, 1152), (4, 1280), (4, 1408), (4, 1536), (4, 1664), (4, 1792), (4, 1920), (4, 2048)]
INFO 08-02 17:38:43 habana_model_runner.py:1206] Warmup finished in 49 secs, allocated 14.19 GiB of device memory
INFO 08-02 17:38:43 habana_executor.py:91] init_cache_engine took 37.92 GiB of device memory (53.39 GiB/94.62 GiB used) and 57.86 MiB of host memory (475.4 GiB/1007 GiB used)
Recommended vLLM Parameters
- We recommend running inference on Gaudi 2 with
block_size
of 128 for BF16 data type. Using default values (16, 32) might lead to sub-optimal performance due to Matrix Multiplication Engine under-utilization (see Gaudi Architecture). - For max throughput on Llama 7B, we recommend running with batch size of 128 or 256 and max context length of 2048 with HPU Graphs enabled. If you encounter out-of-memory issues, see troubleshooting section.
Environment variables
Diagnostic and profiling knobs:
VLLM_PROFILER_ENABLED
: iftrue
, high level profiler will be enabled. Resulting JSON traces can be viewed in perfetto.habana.ai. Disabled by default.VLLM_HPU_LOG_STEP_GRAPH_COMPILATION
: iftrue
, will log graph compilations per each vLLM engine step, only when there was any - highly recommended to use alongsidePT_HPU_METRICS_GC_DETAILS=1
. Disabled by default.VLLM_HPU_LOG_STEP_GRAPH_COMPILATION_ALL
: iftrue
, will log graph compilations per each vLLM engine step, always, even if there were none. Disabled by default.VLLM_HPU_LOG_STEP_CPU_FALLBACKS
: iftrue
, will log cpu fallbacks per each vLLM engine step, only when there was any. Disabled by default.VLLM_HPU_LOG_STEP_CPU_FALLBACKS_ALL
: iftrue
, will log cpu fallbacks per each vLLM engine step, always, even if there were none. Disabled by default.
Performance tuning knobs:
VLLM_SKIP_WARMUP
: iftrue
, warmup will be skipped,false
by defaultVLLM_GRAPH_RESERVED_MEM
: percentage of memory dedicated for HPUGraph capture,0.4
by defaultVLLM_GRAPH_PROMPT_RATIO
: percentage of reserved graph memory dedicated for prompt graphs,0.5
by defaultVLLM_GRAPH_PROMPT_STRATEGY
: strategy determining order of prompt graph capture,min_tokens
ormax_bs
,min_tokens
by defaultVLLM_GRAPH_DECODE_STRATEGY
: strategy determining order of decode graph capture,min_tokens
ormax_bs
,max_bs
by defaultVLLM_{phase}_{dim}_BUCKET_{param}
- collection of 12 environment variables configuring ranges of bucketing mechanism{phase}
is eitherPROMPT
orDECODE
{dim}
is eitherBS
,SEQ
orBLOCK
{param}
is eitherMIN
,STEP
orMAX
- Default values:
-
Prompt:
- batch size min (
VLLM_PROMPT_BS_BUCKET_MIN
):1
- batch size step (
VLLM_PROMPT_BS_BUCKET_STEP
):min(max_num_seqs, 32)
- batch size max (
VLLM_PROMPT_BS_BUCKET_MAX
):min(max_num_seqs, 64)
- sequence length min (
VLLM_PROMPT_SEQ_BUCKET_MIN
):block_size
- sequence length step (
VLLM_PROMPT_SEQ_BUCKET_STEP
):block_size
- sequence length max (
VLLM_PROMPT_SEQ_BUCKET_MAX
):max_model_len
- batch size min (
-
Decode:
- batch size min (
VLLM_DECODE_BS_BUCKET_MIN
):min(max_num_seqs, 32)
- batch size step (
VLLM_DECODE_BS_BUCKET_STEP
):min(max_num_seqs, 32)
- batch size max (
VLLM_DECODE_BS_BUCKET_MAX
):max_num_seqs
- block size min (
VLLM_DECODE_BLOCK_BUCKET_MIN
):128
- block size step (
VLLM_DECODE_BLOCK_BUCKET_STEP
):128
- block size max (
VLLM_DECODE_BLOCK_BUCKET_MAX
):max(128, (max_num_seqs*max_model_len)/block_size)
- batch size min (
-
Additionally, there are HPU PyTorch Bridge environment variables impacting vLLM execution:
PT_HPU_LAZY_MODE
: if0
, PyTorch Eager backend for Gaudi will be used, if1
PyTorch Lazy backend for Gaudi will be used,1
is defaultPT_HPU_ENABLE_LAZY_COLLECTIVES
: required to betrue
for tensor parallel inference with HPU Graphs
Troubleshooting:
If you experience device out-of-memory issues or want to attempt inference at higher batch sizes, try tweaking HPU Graphs by following the below:
- Tweak
gpu_memory_utilization
knob. It will decrease the allocation of KV cache, leaving some headroom for capturing graphs with larger batch size. By defaultgpu_memory_utilization
is set to 0.9. It attempts to allocate ~90% of HBM left for KV cache after short profiling run. Note that decreasing reduces the number of KV cache blocks you have available, and therefore reduces the effective maximum number of tokens you can handle at a given time. - If this method is not efficient, you can disable
HPUGraph
completely. With HPU Graphs disabled, you are trading latency and throughput at lower batches for potentially higher throughput on higher batches. You can do that by adding--enforce-eager
flag to server (for online inference), or by passingenforce_eager=True
argument to LLM constructor (for offline inference).
If you experience error below:
TypeError: PatchedVLLMKVCache.forward() missing 2 required positional arguments: 'block_indices' and 'block_offset'
Try installing:
pip install neural-compressor@git+https://github.com/intel/neural-compressor.git@b196432
What's Changed
- Support FP8 INC in vLLM by @nirda7 in #144
- [Doc][BugFix] Update setup instructions and reference links by @MohitIntel in #191
- split gptbigcode forward by @libinta in #194
- Enable FusedSDPA for prompt attention with VLLM_PROMPT_USE_FUSEDSDPA by @libinta in #168
- Enable LoRA support for HPU by @SanjuCSudhakaran in #170
- Compile mode bug fix for LoRA by @SanjuCSudhakaran in #196
- Ensure buckets do not exceed the batch token limit by @kzawora-intel in #206
- Make max_num_batched_tokens behavior more verbose, add legacy mode by @kzawora-intel in #208
- Update paddings computed to adjust selected_token_indices by @vivekgoe in #210
- Port not warmed-up configurations log warnings by @adobrzyniewicz-habana in #222
- Remove mark step from static MoE loop by @jkaniecki in #231
- Enable llama-405b - w/a for memory allocation error by @afierka-intel in #184
- [bugfix] handle large bucket minimums correctly by @kzawora-intel in #235
- Remove token budget from decode buckets by @kzawora-intel in #241
- [habana_main bugfix] Fix min bucket boundary calculation by @kzawora-intel in #239
- Mask based BGMV implementation by @hlahkar in #223
- Dispersed dummy slots by @madamczykhabana in #243
- Use PT_COMPILE_ONLY_MODE during warmup by @mfylcek in #227
- Do not pass warmup_mode to execute_model_kwargs by @kzawora-intel in #229
- Add error handling for PT_COMPILE_ONLY_MODE by @kzawora-intel in #251
- Hardcode fastapi version due to pydantic error by @hlahkar in #255
- Mask based BGMV implementation for LoRA Embedding by @SanjuCSudhakaran in #247
- Eliminate graph breaks for torch.compile mode by @yuwenzho in #202
- Port flat PA from habana_next to habana_main by @dolszewska in #169
- Add disable_tensor_cache=True to HPUGraph capture by @kzawora-intel in #252
- Fix dispersed slots by @madamczykhabana in #261
- Skip compilation warnings during warmup phase by @jkaniecki in #262
- Port PT Profiler to habana_main by @adobrzyniewicz-habana in #256
- Fix LoRA test by handling mask creation inside the test by @SanjuCSudhakaran in #270
- Attn MetaData dtype should be same as model dtype by @hlahkar in #271
- Support Mixtral quantization using INC by @dudilester in #267
- Fixed ALiBi by @itaraban in #254
- Update gaudi-installation.rst by @dolszewska in #279
- Remove hardcoded value from softmax in flat_pa by @madamczykhabana in #280
- Increase garbage collector's threshold by @kwisniewski98 in #281
- [Bugfix][Habana_main] fix guided_decode HPU failing issue by @xuechendi in #236
- fix rotary embedding
rotary_dim
not equalhead_size
case by @jikunshang in #245 - [Bugfix][Habana_main] - dbrx model and arctic model codes fix to remove CUDA hardcode by @xuechendi in #217
- Add Dockerfile.hpu by @xuechendi in #200
- optimized topp/topk calculation by @ssarkar2 in #195
- Increase garbage collector's threshold 1.18 by @kwisniewski98 in #284
- Cherry pick of delayed sampling by @tzielinski-habana in #263
- Removed padding block from a list of available blocks in allocators by @tzielinski-habana in #312
- Fix lora specific conditions in profile-run by @SanjuCSudhakaran in #319
- Cnange last bucket for decode buckets by @iboiko-habana in #334
- Added missed valid_seq_lengths from FusedSdpa prompt_attention. by @libinta in #314
- Fix runtime errors reported when using long input sequence lengths with LoRA by @vivekgoe in #343
- remove import vllm._C for hpu by @hsubramony in #293
- Add ALiBi to supported features by @kwisniewski98 in #366
- [1.18.0][docs] Move LoRA adapters to "Supported Features" by @kzawora-intel in #371
- Update docs for 1.18.0 by @kzawora-intel in #373
New Contributors
- @nirda7 made their first contribution in #144
- @MohitIntel made their first contribution in #191
- @mfylcek made their first contribution in #227
- @dolszewska made their first contribution in #169
- @dudilester made their first contribution in #267
- @itaraban made their first contribution in #254
- @ssarkar2 made their first contribution in #195
Full Changelog: v0.5.3.post1-Gaudi-1.17.0...v0.5.3.post1+Gaudi-1.18.0