Latency and Memory Analysis of Transformer Models for Training and Inference
Many formulas or equations are floating around in papers, blogs, etc., about how to calculate training or inference latency and memory for Large Language Models (LLMs) or Transformers. Rather than doing math on papers or typing in Excel sheets, let's automate the boring stuff with llm-analysis :gear:!
Given the specified model, GPU, data type, and parallelism configurations, llm-analysis estimates the latency and memory usage of LLMs for training or inference. With llm-analysis, one can easily try out different training/inference setups theoretically, and better understand the system performance for different scenarios.
llm-analysis helps answer questions such as:
- what batch size, data type, parallelism scheme to use to get a feasible (not getting OOM) and optimal (maximizing throughput with a latency constraint) setup for training or inference
- time it takes with the given setup to do training or inference and the cost (GPU-hours)
- how the latency/memory changes if using a different model, GPU type, number of GPU, data type for weights and activations, parallelism configuration (suggesting the performance benefit of modeling change, hardware improvement, quantization, parallelism, etc.)
Check the example use cases. With llm-analysis, you can do such analysis in minutes :rocket:! - Llama 2 Models - LLaMA Models - Megatron-LM Models - Megatron Turing NLG 530B - FasterTransformer
To install llm-analysis from pypi:
sh
pip install llm-analysis
To install the latest development build:
sh
pip install --upgrade git+https://github.com/cli99/llm-analysis.git@main
pip install . or poetry install (install poetry by pip install poetry).LLMAnalysis classTo integrate llm-analysis in your code, use the LLMAnalysis class. Refer to doc LLMAnalysis for details.
LLMAnalysis is constructed with flops and memory efficiency numbers and the following configuration classes:
ModelConfig covers model information, i.e. max sequence length, number of transformer layers, number of attention heads, hidden dimension, vocabulary sizeGPUConfig covers GPU compute and memory specificationsDtypeConfig covers the number of bits used for the model weight, activation, and embeddingParallelismConfig covers Tensor Parallelism (tp), Pipeline Parallelism (pp), Sequence Parallelism (sp), Expert Parallelism (ep),and Data Parallelism (dp).Then LLMAnalysis can be queried with different arguments through the training and inference methods.
llm-analysis provides two entry functions, train and infer, for ease of use through the command line interface. Run
python -m llm_analysis.analysis train --help
or
python -m llm_analysis.analysis infer --help
to check the options or read the linked doc. Refer to the examples to see how they are used.
train and infer use the pre-defined name-to-configuration mappings (model_configs, gpu_configs, dtype_configs) and other user-input arguments to construct the LLMAnalysis and do the query.
The pre-defined mappings are populated at the runtime from the model, GPU, and data type configuration json files under model_configs, gpu_configs, and dtype_configs. To add a new model, GPU or data type to the mapping for query, just add a json description file to the corresponding folder.
llm-analysis also supports retrieving ModelConfig from a model config json file path or Hugging Face with the model name .
- From a local model config json file, e.g., python -m llm_analysis.analysis train --model_name=local_example_model.json. Check the model configurations under the model_configs folder.
- From Hugging Face, e.g., use EleutherAI/gpt-neox-20b as model_name when calling the train or infer entry functions. python -m llm_analysis.analysis train --model_name=EleutherAI/gpt-neox-20b --total_num_gpus 32 --ds_zero 3
A list of handy commands is provided to query against the pre-defined mappings as well as Hugging Face, or to dump configurations. Run python -m llm_analysis.config --help for details.
Some examples:
python -m llm_analysis.config get_model_config_by_name EleutherAI/gpt-neox-20b
gets the ModelConfig from the populated mapping by name, if not found, llm-analysis tries to get it from HuggingFace.
Note that LLaMA models need at least transformers-4.28.1 to retrieve, either update to a later transformers library, or use the predefined ModelConfig for LLaMA models (/ in model names are replaced with _).
python -m llm_analysis.config list_gpu_configs
lists the names of all predefined GPU configurations, then you can query with
python -m llm_analysis.config get_gpu_config_by_name a100-sxm-80gb
to show the corresponding GPUConfig.
Setting flops and memory efficiency to 1 (default) gives the lower bound of training or inference latency, as it assumes the peak hardware performance (which is never the case).
A close-to-reality flops or memory efficiency can be found by benchmarking and profiling using the input dimensions in the model.
If one has to make assumptions, for flops efficiency, literature reports up to 0.5 for large scale model training, and up to 0.7 for inference; 0.9 can be an aggressive target for memory efficiency.
llm-analysis aims to provide a lower-bound estimation of memory usage and latency.
llm-analysis currently covers Tensor Parallelism (tp), Pipeline Parallelism (pp), Sequence Parallelism (sp), Expert Parallelism (ep), and Data Parallelism (dp).
Megatron-LM for training and FasterTransformer for inferenceDeepSpeed ZeRO or FSDP. ds_zero is used to specify the dp sharding strategy| ds_zero | DeepSpeed ZeRO | FSDP | Sharding |
|---|---|---|---|
| 0 | disabled | NO_SHARD | No sharding |
| 1 | Stage 1 | N/A | Shard optimizer states |
| 2 | Stage 2 | SHARD_GRAD_OP | Shard gradients and optimizer states |
| 3 | Stage 3 | FULL_SHARD | Shard gradients, optimizer states, model parameters |
ep_size devices, i.e. the number of experts per GPU is total number of experts / ep_size. Thus for the MLP module, the number of devices for other parallelization dimensions is divided by ep_size compared to other parts of the model.tp communication is calculated as using ring allreduce. pp, dp, ep communications are ignored for now, i.e. assuming perfect computation and communication overlapping, which is not true when communication cannot overlap with compute due to dependency, or when communication is too long to hide due to slow interconnect or large data volume.
llm-analysis supports both full and selective activation recomputation, as described in Reducing Activation Recomputation in Large Transformer Models
Data types are expressed with the number of bits, only 32 (FP32, TF32), 16 (FP16, BF16), 8 (INT8), and 4 (INT4) bits data types are modeled for now.
Fine-tuning is modeled the same (controlled by total_num_tokens passed to the train entry function) as pre-training, thus assuming full (all model parameters) fine-tuning. Parameter-efficient fine-tuning (PEFT) is
in future support.
Inference assumes perfect overlapping of compute and memory operations when calculating latency, and maximum memory reuse when calculating memory usage.
Check the TODOs below for what's next and stay tuned :radio:! Any contributions or feedback are highly welcome!
If you use llm-analysis in your work, please cite:
Cheng Li. (2023). LLM-Analysis: Latency and Memory Analysis of Transformer Models for Training and Inference. GitHub repository, https://github.com/cli99/llm-analysis.
or
@misc{llm-analysis-chengli,
author = {Cheng Li},
title = {LLM-Analysis: Latency and Memory Analysis of Transformer Models for Training and Inference},
year = {2023},
publisher = {GitHub},
journal = {GitHub repository},
howpublished = {\url{https://github.com/cli99/llm-analysis}},
}
Contributions and suggestions are welcome.
llm-analysis uses pre-commit to ensure code formatting is consistent. For pull requests with code contribution, please install the pre-commit (pip install pre-commit) as well as the used hooks (pip install in the repo), and format the code (runs automatically before each git commit) before submitting the PR.
$ claude mcp add llm-analysis \
-- python -m otcore.mcp_server <graph>