Home

Awesome

fastLLaMa

License: MIT

fastLLaMa is an experimental high-performance framework designed to tackle the challenges associated with deploying large language models (LLMs) in production environments.

It offers a user-friendly Python interface to a C++ library, llama.cpp, enabling developers to create custom workflows, implement adaptable logging, and seamlessly switch contexts between sessions. This framework is geared towards enhancing the efficiency of operating LLMs at scale, with ongoing development focused on introducing features such as optimized cold boot times, Int4 support for NVIDIA GPUs, model artifact management, and multiple programming language support.

                ___            __    _    _         __ __      
                | | '___  ___ _| |_ | |  | |   ___ |  \  \ ___ 
                | |-<_> |<_-<  | |  | |_ | |_ <_> ||     |<_> |
                |_| <___|/__/  |_|  |___||___|<___||_|_|_|<___|
                                                            
                                                                                        
                                                                           
                                                       .+*+-.                
                                                      -%#--                  
                                                    :=***%*++=.              
                                                   :+=+**####%+              
                                                   ++=+*%#                   
                                                  .*+++==-                   
                  ::--:.                           .**++=::                   
                 #%##*++=......                    =*+==-::                   
                .@@@*@%*==-==-==---:::::------::==*+==--::                   
                 %@@@@+--====+===---=---==+=======+++----:                   
                 .%@@*++*##***+===-=====++++++*++*+====++.                   
                 :@@%*##%@@%#*%#+==++++++=++***==-=+==+=-                    
                  %@%%%%%@%#+=*%*##%%%@###**++++==--==++                     
                  #@%%@%@@##**%@@@%#%%%%**++*++=====-=*-                     
                  -@@@@@@@%*#%@@@@@@@%%%%#+*%#++++++=*+.                     
                   +@@@@@%%*-#@@@@@@@@@@@%%@%**#*#+=-.                       
                    #%%###%:  ..+#%@@@@%%@@@@%#+-                            
                    :***#*-         ...  *@@@%*+:                            
                     =***=               -@%##**.                            
                    :#*++                -@#-:*=.                            
                     =##-                .%*..##                             
                      +*-                 *:  +-                             
                      :+-                :+   =.                             
                       =-.               *+   =-                             
                        :-:-              =--  :::                           
                                                                           


Features

Supported Models


Requirements

  1. CMake

    • For Linux:
      sudo apt-get -y install cmake

    • For OS X:
      brew install cmake

    • For Windows
      Download cmake-*.exe installer from Download page and run it.

  2. GCC 11 or greater

  3. Minimum C++ 17

  4. Python 3.x

Installation

To install fastLLaMa through pip use

pip install git+https://github.com/PotatoSpudowski/fastLLaMa.git@main

Usage

Importing the package

To import fastLLaMa just run

from fastllama import Model 

Initializing the Model

MODEL_PATH = "./models/7B/ggml-model-q4_0.bin"

model = Model(
        path=MODEL_PATH, #path to model
        num_threads=8, #number of threads to use
        n_ctx=512, #context size of model
        last_n_size=64, #size of last n tokens (used for repetition penalty) (Optional)
        seed=0, #seed for random number generator (Optional)
        n_batch=128, #batch size (Optional)
        use_mmap=False, #use mmap to load model (Optional)
    )

Ingesting Prompts

prompt = """Transcript of a dialog, where the User interacts with an Assistant named Bob. Bob is helpful, kind, honest, good at writing, and never fails to answer the User's requests immediately and with precision.

User: Hello, Bob.
Bob: Hello. How may I help you today?
User: Please tell me the largest city in Europe.
Bob: Sure. The largest city in Europe is Moscow, the capital of Russia.
User: """

res = model.ingest(prompt, is_system_prompt=True) #ingest model with prompt

Generating Output

def stream_token(x: str) -> None:
    """
    This function is called by the library to stream tokens
    """
    print(x, end='', flush=True)

res = model.generate(
    num_tokens=100, 
    top_p=0.95, #top p sampling (Optional)
    temp=0.8, #temperature (Optional)
    repeat_penalty=1.0, #repetition penalty (Optional)
    streaming_fn=stream_token, #streaming function
    stop_words=["User:", "\n"] #stop generation when this word is encountered (Optional)
    )

Loading model using Multithreads

model = Model(
        path=MODEL_PATH, #path to model
        num_threads=8, #number of threads to use
        n_ctx=512, #context size of model
        last_n_size=64, #size of last n tokens (used for repetition penalty) (Optional)
        seed=0, #seed for random number generator (Optional)
        n_batch=128, #batch size (Optional)
        load_parallel=True
    )

Saving Model State

To cache the session, you can use the save_state method.

res = model.save_state("./models/fast_llama.bin")

Loading Model State

To load the session, use the load_state method.

res = model.load_state("./models/fast_llama.bin")

Resetting the Model State

To reset the session use the reset method.

model.reset()

Attaching LoRA Adapters to Base model during runtime

To attach LoRA Adapter during runtime use the attach_lora method.

LORA_ADAPTER_PATH = "./models/ALPACA-7B-ADAPTER/ggml-adapter-model.bin"

model.attach_lora(LORA_ADAPTER_PATH)

Note: It is a good idea to reset the state of the model after attaching a LoRA Adapter.

Detaching LoRA Adapters to Base model during runtime

To detach LoRA Adapter during runtime use the detach_lora method.

model.detach_lora()

Calculating perplexity

To caculate the perplexity, use the perplexity method.


with open("test.txt", "r") as f:
    data = f.read(8000)
       
total_perplexity = model.perplexity(data)
print(f"Total Perplexity: {total_perplexity:.4f}")

Getting the embeddings of the model

To get the embeddings of the model, use the get_embeddings method.

embeddings = model.get_embeddings()

Getting the logits of the model

To get the logits of the model, use the get_logits method.

logits = model.get_logits()

Using the logger

from fastLLaMa import Logger

class MyLogger(Logger):
    def __init__(self):
        super().__init__()
        self.file = open("logs.log", "w")

    def log_info(self, func_name: str, message: str) -> None:
        #Modify this to do whatever you want when you see info logs
        print(f"[Info]: Func('{func_name}') {message}", flush=True, end='', file=self.file)
        pass
    
    def log_err(self, func_name: str, message: str) -> None:
        #Modify this to do whatever you want when you see error logs
        print(f"[Error]: Func('{func_name}') {message}", flush=True, end='', file=self.file)
    
    def log_warn(self, func_name: str, message: str) -> None:
        #Modify this to do whatever you want when you see warning logs
        print(f"[Warn]: Func('{func_name}') {message}", flush=True, end='', file=self.file)

For more clarity, check the examples/python/ folder.

Running LLaMA

# obtain the original LLaMA model weights and place them in ./models
ls ./models
65B 30B 13B 7B tokenizer_checklist.chk tokenizer.model

# convert the 7B model to ggml FP16 format
# python [PythonFile] [ModelPath] [Floattype] [Vocab Only] [SplitType]
python3 scripts/convert-pth-to-ggml.py models/7B/ 1 0

# quantize the model to 4-bits
./build/src/quantize models/7B/ggml-model-f16.bin models/7B/ggml-model-q4_0.bin 2

# run the inference
#Run the scripts from the root dir of the project for now!
python ./examples/python/example.py

Running Alpaca-LoRA

# Before running this command
# You need to provide the HF model paths here
python ./scripts/export-from-huggingface.py
# Alternatively you can just download the ggml models from huggingface directly and run them! 

python3 ./scripts/convert-pth-to-ggml.py models/ALPACA-LORA-7B 1 0

./build/src/quantize models/ALPACA-LORA-7B/ggml-model-f16.bin models/ALPACA-LORA-7B/alpaca-lora-q4_0.bin 2

python ./examples/python/example-alpaca.py

Using LoRA adapters during runtime

# Download lora adapters and paste them inside models folder
# https://huggingface.co/tloen/alpaca-lora-7b


python scripts/convert-lora-to-ggml.py models/ALPACA-7B-ADAPTER/ -t fp32 
# Change -t to fp16 to use fp16 weights
# Inorder to use LoRA adapters without caching, pass the --no-cache flag
#   - Only supported for fp32 adapter weights

python examples/python/example-lora-adapter.py

# Make sure to set paths correctly for the base model and adapter inside the example
# Commands: 
# load_lora: Attaches the adapter to the base model 
# unload_lora: Deattaches the adapter (Deattach for fp16 is yet to be added!)
# reset: Resets the model state

Running the webUI

To run the WebSocket Server and the WebUI, Follow the instructions on the respective branches.

Memory/Disk Requirements

As the models are currently fully loaded into memory, you will need adequate disk space to save them and sufficient RAM to load them. At the moment, memory and disk requirements are the same.

model sizeoriginal sizequantized size (4-bit)
7B13 GB3.9 GB
13B24 GB7.8 GB
30B60 GB19.5 GB
65B120 GB38.5 GB

Info: Run time may require extra memory during inference!
(Depends on hyperparmeters used during model initialization)

Contributing

Notes