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GPTFast

Accelerate your Hugging Face Transformers 7.6-9x with GPTFast!

Background

GPTFast was originally a set of techniques developed by the PyTorch Team to accelerate the inference speed of Llama-2-7b. This pip package generalizes those techniques to all Hugging Face models.

Demo

GPTFast Inference Time Eager Inference Time

Roadmap

  • ⟳ 0.7.x (xx/xx/xx): Medusa, Speculative Sampling, Eagle
  • ⟳ 0.6.x (xx/xx/xx): BitNet and 1-bit quantization, AWQ, QoQ, GGUF, HQQ
  • ⟳ 0.5.x (xx/xx/xx): PagedAttention (vLLM) + FlashAttention integration
  • ⟳ 0.4.x (xx/xx/xx): Tensor parallelism + GPU distributed inference
  • ✅ 0.3.x (06/20/24): GPTQ int4 quantization and optimized int4 matmul kernels enabled for all HF models (9x inference acceleration)
  • ✅ 0.2.x (04/02/24): static key-value cache enabled for all HF models (8.5x inference acceleration)
  • ✅ 0.1.x (02/22/24): torch.compile, int8 quantization, speculative decoding (7x inference acceleration)

Getting Started

WARNING: The below documentation is now deprecated with version 0.3.0. New docs will be up soon!

  • Make sure that your python version >= 3.10, and you are on a cuda enabled device.
  • Make a virtual environment on your machine and activate it.
    $python3 -m venv VENV_NAME
    source VENV_NAME/bin/activate #./VENV_NAME/scripts/activate if you are on Windows
  • Call the following: pip install gptfast
  • Copy the following code into a python file:
      import os
      import torch
      from transformers import AutoTokenizer
      from GPTFast.Core import gpt_fast
      from GPTFast.Helpers import timed
      
      torch._dynamo.reset()
      os.environ["TOKENIZERS_PARALLELISM"] = "false"
      
      device = "cuda" if torch.cuda.is_available() else "cpu"
      
      def argmax_variation(self, probabilities:torch.Tensor, temperature:float = 1, k:int = 5):
          # Apply temperature scaling
          device = probabilities.device
          scaled_probabilities = probabilities / temperature
      
          # Ensure k is within a valid range
          k = min(k, probabilities.size(-1))
      
          # Get the indices of the top-k scaled probabilities along the specified dimension
          top_k_indices = torch.topk(scaled_probabilities, k, dim=-1).indices
      
          # Generate random indices for sampling
          random_indices = torch.randint(0, k, (1,) * probabilities.dim()).to(device)
      
          # Use gathered indices to get the final sampled token
          sampled_token = top_k_indices.gather(-1, random_indices).to(device)
      
          return sampled_token.unsqueeze(0)
      
      def argmax(self, probabilities):
          # Use argmax to get the token with the maximum probability
          max_prob_index = torch.argmax(probabilities, dim=-1)
          return max_prob_index.view(1, 1)
      
      model_name = "gpt2-xl"
      draft_model_name = "gpt2"
      
      tokenizer = AutoTokenizer.from_pretrained(model_name)
      initial_string = "Write me a short story."
      input_tokens = tokenizer.encode(initial_string, return_tensors="pt").to(device)
      
      N_ITERS=10
      MAX_TOKENS=50
      
      cache_config = {
          "model_config": {
              "path_to_blocks": ["transformer", "h"],
              "child_ref_in_parent_forward": ["transformer", "block"],
          },
          "block_config": {
              "path_to_attn": ["attn"],
              "child_ref_in_parent_forward": ["attn"], 
          },
          "attn_config": {
              "cache_update_config":{
                  "kv_cache_condition":"if layer_past is not None",
                  "key_name": "key",
                  "value_name": "value",
              },
              "causal_mask_config": {
                  "causal_mask_application": "conditional",
                  "causal_mask_method": "_attn",
                  "causal_mask_condition": "not self.is_cross_attention"
              }
          },
          "imports": ["import torch", 
                      "import transformers", 
                      "from transformers import *", 
                      "from torch import *", 
                      "from typing import *", 
                      "import types", 
                      "from transformers.modeling_outputs import *", 
                      "from torch import nn"]
      }
      
      gpt_fast_model = gpt_fast(model_name, sample_function=argmax, max_length=60, cache_config=cache_config, draft_model_name=draft_model_name)
      gpt_fast_model.to(device)
      
      fast_compile_times = []
      for i in range(N_ITERS):
          with torch.no_grad():
              res, compile_time = timed(lambda: gpt_fast_model.generate(cur_tokens=input_tokens, max_tokens=MAX_TOKENS, speculate_k=6))
          fast_compile_times.append(compile_time)
          print(f"gpt fast eval time {i}: {compile_time}")
      print("~" * 10)
      
      print(tokenizer.decode(res[0]))
  • Run it and watch the magic 🪄!

Documentation

At its core, this library provides a simple interface to LLM Inference acceleration techniques. All of the following functions can be imported from GPTFast.Core:

  • gpt_fast(model_name:str, sample_function:Callable[torch.Tensor, Dict[str, Any], torch.Tensor], max_length:int, cache_config:dict, draft_model_name:str) -> torch.nn.Module
    • Parameters:

      • model_name: This is the name of the Hugging Face model that you want to optimize.
      • sample_function: This is a function which will take in a PyTorch Tensor which takes in a pytorch tensor as a first argument among other **sampling_kwargs and returns a Tensor of shape (1, 1).
      • max_length: This is an int specifying up to how many tokens you will generating. It is recommended that you set this value higher than how many tokens you will actually generated.
      • cache_config: This is a dictionary which will specify how the static key-value cache will be integrated into the model. More details for this dictionary follow below.
      • draft_model_name: This is an optional argument which is the name of the Hugging Face draft model which is needed for speculative decoding. Note that the model and the draft model must both use the same tokenizer, and the draft model must be significantly smaller to achieve inference acceleration. If draft_model_name is not specified, speculative decoding will not be applied to your model.
    • Returns:

      • An accelerated model with one method:
        • generate(self, cur_tokens:torch.Tensor, max_tokens:int, speculate_k:int, **sampling_kwargs) -> torch.Tensor
          • Parameters:
            • cur_tokens: A PyTorch Tensor of size (1, seq_len).
            • max_tokens: An int representing how many tokens you want to generate.
            • speculate_k: An int specifying how far you want the draft model to speculate in speculative decoding.
            • **sampling_kwargs: Additional parameters that are necessary for sampling from the distribution. Should match the **sampling_kwargs of sample_function above.
          • Returns:
            • The generated tokens to your prompt, a tensor with dimensions (1, max_tokens).

  • load_int8(model_name:str) -> torch.nn.Module
    • Parameters:
      • model_name: This is a string specifying the model that you are using.
    • Returns:
      • An int8 quantized version of your model.

  • add_kv_cache(transformer:nn.Module, sampling_fn:Callable[torch.Tensor, Dict[str, Any], torch.Tensor], max_length:int, cache_config:dict) -> KVCacheModel
    • Parameters:

      • transformer: This is the Hugging Face model that you are adding a static key-value cache to.
      • sampling_fn: This is the same as the sampling_function paramter for the gpt_fast function.
      • max_length: This is the same as the max_length paramter for the gpt_fast function.
      • cache_config: This is a dictionary which will specify how you directly modify the source code of the forward pass of the model so that a static cache can be accomadated. The full specifications for this dictionary are below:
         -model_config: this defines how your model should be modified to accomodate a static kv cache.
            -path_to_blocks (list[str]): Starting from the model itself, this defines the child attributes on a parent ```nn.Module``` attribute/object that we access
             to reach the blocks of a transformer.
            -child_ref_in_parent_forward (list[str]): starting from the original model, this is how each child module/attribute in ```path_to_blocks``` is referenced in
             the forward pass of the parent module/attribute. 
        
        -block_config: this defines how your block needs to be modified to accomodate a static kv cache.
            -path_to_attn (list[str]): Starting from the block itself, this defines the child attributes on a parent ```nn.Module``` attribute/object that we access to reach
             the attention layer itself.
            -child_ref_in_parent_forward (list[str]): starting from the block, this is how each child module/attribute in path_to_attn is referenced in the forward pass of the
             parent module/attribute.
        
        -attn_config: this defines how the attention layer needs to be modified to accomodate a static kv cache.
            -cache_update_config: this defines how the key-value cache updates will be modified now that it is static.
                - kv_cache_condition (str): the condition under which a kv cache update is triggered in the source
                  code of the original forward pass of the attention layer, typically something like "if layer_past is not None."
                - key_name (str): how the keys are originally referenced pre-update
                - value_name (str): how the values are originally referenced pre-update
                - new_key_name (Optional[str]): how the keys are referenced post_update. If this is not specified, this will simply be key_name. 
                - new_value_name (Optional[str]): how the keys are referenced post_update. If this is not specified, this will simply be value_name. 
        
            -causal_mask_config: this defines how the causal mask is applied - this is necessary because your keys and values now have length ```max_length``` along the
             second-to-last dimension.
                - causal_mask_module (str): the method of the attention layer where the causal mask is applied.
                - causal_mask_application (Union["conditional", Any]): this is either the string "conditional" or some other value.
                - if causal_mask_application is "conditional", you need to add the following additional keys:
                    - causal_mask_condition (str): the condition under which the causal_mask is applied.
                - if it's not conditional, you need to add the following additional keys:
                    - causal_mask_line (str): the starting line we want to replace.
                    - num_lines (int): how many lines we want to replace including causal_mask_line
        
        -imports: these are the imports which are needed to compile your new functions after integrating a static kv cache.
        
    • Returns:

      • An instance of the KVCacheModel class which is essentially just your model but with a key-value cache attached for accelerated inference.

  • add_speculative_decoding(model:nn.Module, draft_model:nn.Module) -> nn.Module
    • Parameters:
      • model: This is the KVCached version of your model.
      • draft_model: This is the KVCached version of your draft model.
    • Returns:
      • An accelerated model with the generate method described above under the gpt_fast section.

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