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A tool for running on-premises large language models on non-public data

Project description

OnPrem.LLM

A tool for running large language models on-premises using non-public data

OnPrem.LLM is a simple Python package that makes it easier to run large language models (LLMs) on non-public or sensitive data and on machines with no internet connectivity (e.g., behind corporate firewalls). Inspired by the privateGPT GitHub repo and Simon Willison’s LLM command-line utility, OnPrem.LLM is designed to help integrate local LLMs into practical applications.

Install

Once installing PyTorch, you can install OnPrem.LLM with:

pip install onprem

For fast GPU-accelerated inference, see additional instructions below.

How to use

Setup

from onprem import LLM

llm = LLM()

By default, a 7B-parameter model is used. If use_larger=True, a 13B-parameter is used. You can also supply the URL to an LLM of your choosing to LLM (see code generation section below for an example). Currently, only models in GGML format are supported. Future versions of OnPrem.LLM will transition to the newer GGUF format.

Send Prompts to the LLM to Solve Problems

This is an example of few-shot prompting, where we provide an example of what we want the LLM to do.

prompt = """Extract the names of people in the supplied sentences. Here is an example:
Sentence: James Gandolfini and Paul Newman were great actors.
People:
James Gandolfini, Paul Newman
Sentence:
I like Cillian Murphy's acting. Florence Pugh is great, too.
People:"""

saved_output = llm.prompt(prompt)
Cillian Murphy, Florence Pugh

Talk to Your Documents

Answers are generated from the content of your documents.

Step 1: Ingest the Documents into a Vector Database

llm.ingest('./sample_data')
2023-09-03 16:30:54.459509: I tensorflow/core/platform/cpu_feature_guard.cc:193] This TensorFlow binary is optimized with oneAPI Deep Neural Network Library (oneDNN) to use the following CPU instructions in performance-critical operations:  SSE4.1 SSE4.2 AVX AVX2 FMA
To enable them in other operations, rebuild TensorFlow with the appropriate compiler flags.
Loading new documents: 100%|██████████████████████| 2/2 [00:00<00:00, 17.16it/s]

Creating new vectorstore
Loading documents from ./sample_data
Loaded 11 new documents from ./sample_data
Split into 62 chunks of text (max. 500 tokens each)
Creating embeddings. May take some minutes...
Ingestion complete! You can now query your documents using the LLM.ask method

Step 2: Answer Questions About the Documents

question = """What is  ktrain?""" 
answer, docs = llm.ask(question)
print('\n\nReferences:\n\n')
for i, document in enumerate(docs):
    print(f"\n{i+1}.> " + document.metadata["source"] + ":")
    print(document.page_content)
 Ktrain is a low-code machine learning library designed to augment human
engineers in the machine learning workow by automating or semi-automating various
aspects of model training, tuning, and application. Through its use, domain experts can
leverage their expertise while still benefiting from the power of machine learning techniques.

References:



1.> ./sample_data/ktrain_paper.pdf:
lection (He et al., 2019). By contrast, ktrain places less emphasis on this aspect of au-
tomation and instead focuses on either partially or fully automating other aspects of the
machine learning (ML) workflow. For these reasons, ktrain is less of a traditional Au-
2

2.> ./sample_data/ktrain_paper.pdf:
possible, ktrain automates (either algorithmically or through setting well-performing de-
faults), but also allows users to make choices that best fit their unique application require-
ments. In this way, ktrain uses automation to augment and complement human engineers
rather than attempting to entirely replace them. In doing so, the strengths of both are
better exploited. Following inspiration from a blog post1 by Rachel Thomas of fast.ai

3.> ./sample_data/ktrain_paper.pdf:
with custom models and data formats, as well.
Inspired by other low-code (and no-
code) open-source ML libraries such as fastai (Howard and Gugger, 2020) and ludwig
(Molino et al., 2019), ktrain is intended to help further democratize machine learning by
enabling beginners and domain experts with minimal programming or data science experi-
4. http://archive.ics.uci.edu/ml/datasets/Twenty+Newsgroups
6

4.> ./sample_data/ktrain_paper.pdf:
ktrain: A Low-Code Library for Augmented Machine Learning
toML platform and more of what might be called a “low-code” ML platform. Through
automation or semi-automation, ktrain facilitates the full machine learning workflow from
curating and preprocessing inputs (i.e., ground-truth-labeled training data) to training,
tuning, troubleshooting, and applying models. In this way, ktrain is well-suited for domain
experts who may have less experience with machine learning and software coding. Where

Text to Code Generation

We’ll use the CodeUp LLM by supplying the URL and employ the particular prompt format this model expects.

from onprem import LLM
url = 'https://huggingface.co/TheBloke/CodeUp-Llama-2-13B-Chat-HF-GGML/resolve/main/codeup-llama-2-13b-chat-hf.ggmlv3.q4_1.bin'
llm = LLM(url, n_gpu_layers=43) # see below for GPU information

Setup the prompt based on what this model expects (this is important):

template = """
Below is an instruction that describes a task. Write a response that appropriately completes the request.

### Instruction:
{prompt}

### Response:"""
answer = llm.prompt('Write Python code to validate an email address.', prompt_template=template)
Here is an example of Python code that can be used to validate an email address:
```
import re

def validate_email(email):
    # Use a regular expression to check if the email address is in the correct format
    pattern = r'^[a-zA-Z0-9._%+-]+@[a-zA-Z0-9.-]+\.[a-zA-Z]{2,}$'
    if re.match(pattern, email):
        return True
    else:
        return False

# Test the validate_email function with different inputs
print("Email address is valid:", validate_email("example@example.com"))  # Should print "True"
print("Email address is invalid:", validate_email("example@"))  # Should print "False"
print("Email address is invalid:", validate_email("example.com"))  # Should print "False"
```
The code defines a function `validate_email` that takes an email address as input and uses a regular expression to check if the email address is in the correct format. The regular expression checks for an email address that consists of one or more letters, numbers, periods, hyphens, or underscores followed by the `@` symbol, followed by one or more letters, periods, hyphens, or underscores followed by a `.` and two to three letters.
The function returns `True` if the email address is valid, and `False` otherwise. The code also includes some test examples to demonstrate how to use the function.

Let’s try out the code generated above.

import re
def validate_email(email):
    # Use a regular expression to check if the email address is in the correct format
    pattern = r'^[a-zA-Z0-9._%+-]+@[a-zA-Z0-9.-]+\.[a-zA-Z]{2,}$'
    if re.match(pattern, email):
        return True
    else:
        return False
print(validate_email('sam@@openai.com')) # bad email address
print(validate_email('sam@openai'))      # bad email address
print(validate_email('sam@openai.com'))  # good email address
False
False
True

The generated code may sometimes need editing, but this one worked out-of-the-box.

Speeding Up Inference Using a GPU

The above example employed the use of a CPU.
If you have a GPU (even an older one with less VRAM), you can speed up responses.

Step 1: Install llama-cpp-python with CUBLAS support

CMAKE_ARGS="-DLLAMA_CUBLAS=on" FORCE_CMAKE=1 pip install --upgrade --force-reinstall llama-cpp-python==0.1.69 --no-cache-dir

It is important to use the specific version shown above due to library incompatibilities.

Step 2: Use the n_gpu_layers argument with LLM

llm = LLM(model_name=os.path.basename(url), n_gpu_layers=128)

With the steps above, calls to methods like llm.prompt will offload computation to your GPU and speed up responses from the LLM.

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