Fine-Tuning Language Models with Azure AI Foundry: A Detailed Guide
What is Azure AI Foundry? Azure AI Foundry is a comprehensive platform designed to simplify the development, deployment, and management of AI models. It provides a user-friendly interface and powerful tools that enable developers to create custom AI solutions without needing extensive machine learning expertise. Key Features of Azure AI Foundry One-Button Fine-Tuning: A streamlined process that allows users to fine-tune models with minimal configuration. Integration with Development Tools: Seamless integration with popular development environments, particularly Visual Studio Code. Support for Multiple Models: Access to a variety of pre-trained models, including the Phi family of models. Understanding Fine-Tuning Fine-tuning is the process of taking a pre-trained model and adapting it to a specific dataset or task. This is particularly useful when the base model has been trained on a large corpus of general data but needs to perform well on a narrower domain. Why Fine-Tune? Improved Performance: Fine-tuning can significantly enhance the model's accuracy and relevance for specific tasks. Reduced Training Time: Starting with a pre-trained model reduces the amount of data and time required for training. Customization: Tailor the model to meet the unique needs of your application or business. One-Button Fine-Tuning in Azure AI Foundry Step-by-Step Process Select the Model: Log in to Azure AI Foundry and navigate to the model selection interface. Choose Phi-3 or another small language model from the available options. Prepare Your Data: Ensure your dataset is formatted correctly. Typically, this involves having a set of input-output pairs that the model can learn from. Upload your dataset to Azure AI Foundry. The platform supports various data formats, making it easy to integrate your existing data. Initiate Fine-Tuning: Locate the one-button fine-tuning feature within the Azure AI Foundry interface. Click the button to start the fine-tuning process. The platform will handle the configuration and setup automatically. Monitor Progress: After initiating fine-tuning, you can monitor the process through the Azure portal. The portal provides real-time updates on training metrics, allowing you to track the model's performance as it learns. Evaluate the Model: Once fine-tuning is complete, evaluate the model's performance using a validation dataset. Azure AI Foundry provides tools for assessing accuracy, precision, recall, and other relevant metrics. Deploy the Model: After successful evaluation, you can deploy the fine-tuned model directly from Azure AI Foundry. The platform supports various deployment options, including REST APIs and integration with other Azure services. Using the AI Toolkit in Visual Studio Code Overview of the AI Toolkit The AI Toolkit for Visual Studio Code enhances the development experience by providing tools specifically designed for AI model management and fine-tuning. This integration allows developers to work within a familiar environment while leveraging powerful AI capabilities. Key Features of the AI Toolkit 1) Model Management: Easily manage and switch between different models, including Phi-3 and Ollama models. 2) Data Handling: Simplified data upload and preprocessing tools to prepare datasets for training. 3) Real-Time Collaboration: Collaborate with team members in real-time, sharing insights and progress on AI projects. How to Use the AI Toolkit 1) Install the AI Toolkit: Open Visual Studio Code and navigate to the Extensions Marketplace. Search for "AI Toolkit" and install the extension. 2) Connect to Azure AI Foundry: Once installed, configure the toolkit to connect to your Azure AI Foundry account. This will allow you to access your models and datasets directly from Visual Studio Code. 3) Fine-Tune Models: Use the toolkit to initiate fine-tuning processes directly from your development environment. Monitor training progress and view logs without leaving Visual Studio Code. 4) Consume Ollama Models: The AI Toolkit supports the consumption of Ollama models, providing additional flexibility in your AI projects. This feature allows you to integrate various models seamlessly, enhancing your application's capabilities. Microsoft ONNX Live for Fine-Tuning What is Microsoft ONNX Live? Microsoft ONNX Live is a platform that allows developers to deploy and optimize AI models using the Open Neural Network Exchange (ONNX) format. ONNX is an open-source format that enables interoperability between different AI frameworks, making it easier to deploy models across various environments. Key Features of Microsoft ONNX Live Model Optimization: ONNX Live provides tools to optimize models for performance, ensuring they run efficiently in production environments. Cross-Framework Compatibility: Models trained in different frameworks (like PyTorch or TensorFlow) can be converted to ONNX format, allowing for greater flexibility in deployment. Real-Time Inference: ONNX Live supports real-time inference, enabling applications to utilize AI models for immediate predictions. Fine-Tuning with ONNX Live Model Conversion: If you have a model trained in a different framework, you can convert it to ONNX format using tools provided by Microsoft. This conversion allows you to leverage the benefits of ONNX Live for deployment and optimization. Integration with Azure AI Foundry: Once your model is in ONNX format, you can integrate it with Azure AI Foundry for fine-tuning. The one-button fine-tuning feature can be used to adapt the ONNX model to your specific dataset. Optimization Techniques: After fine-tuning, you can apply various optimization techniques available in ONNX Live to enhance the model's performance. Techniques such as quantization and pruning can significantly reduce the model size and improve inference speed. Deployment: Once optimized, the model can be deployed directly from Azure AI Foundry or ONNX Live. This deployment can be done as a REST API, allowing easy integration with web applications and services. Additional Resources To further enhance your understanding and capabilities in fine-tuning language models, consider exploring the following resources: Phi-3 Cookbook: This comprehensive guide provides insights into getting started with Phi models, including best practices for fine-tuning and deployment. Explore the Phi-3 Cookbook. Ignite Fine-Tuning Workshop: This workshop offers a hands-on approach to learning about fine-tuning techniques and tools. It includes real-world scenarios to help you understand the practical applications of fine-tuning. Visit the GitHub Repository. Conclusion Fine-tuning language models like Phi-3 using Azure AI Foundry, combined with the AI Toolkit in Visual Studio Code and Microsoft ONNX Live, provides a powerful and efficient workflow for developers. The one-button fine-tuning feature simplifies the process, while the integration with ONNX Live allows for optimization and deployment flexibility. By leveraging these tools, you can enhance your AI applications, ensuring they are tailored to meet specific needs and perform optimally in production environments. Whether you are a seasoned AI developer or just starting, Azure AI Foundry and its associated tools offer a robust ecosystem for building and deploying advanced AI solutions. References Microsoft Docs Links Fine-Tuning Models in Azure OpenAI Azure AI Services Documentation Azure Machine Learning Documentation Microsoft Learn Links Develop Generative AI Apps in Azure Fine-Tune a Language Model Azure AI Foundry Overview Get started with AI Toolkit for Visual Studio CodeRecipe Generator Application with Phi-3 Vision on AI Toolkit Locally
In today's data-driven world, images have become a ubiquitous source of information. From social media feeds to medical imaging, we encounter and generate images constantly. Extracting meaningful insights from these visual data requires sophisticated analysis techniques. In this blog post let’s build an Image Analysis Application using the cutting-edge Phi-3 Vision model completely free of cost and on-premise environment using the VS Code AI Toolkit. We'll explore the exciting possibilities that this powerful combination offers. The AI Toolkit for Visual Studio Code (VS Code) is a VS Code extension that simplifies generative AI app development by bringing together cutting-edge AI development tools and models. I would recommend going through the following blogs for getting started with VS Code AI Toolkit. 1. Visual Studio Code AI Toolkit: How to Run LLMs locally 2. Visual Studio AI Toolkit : Building Phi-3 GenAI Applications 3. Building Retrieval Augmented Generation on VSCode & AI Toolkit 4. Bring your own models on AI Toolkit - using Ollama and API keys Setup VS Code AI Toolkit: Launch the VS Code application and Click on the VS Code AI Toolkit extension. Login to the GitHub account if not already done. Once ready, click on model catalog. In the model catalog there are a lot of models, broadly classified into two categories, Local Run (with CPU and with GPU) Remote Access (Hosted by GitHub and other providers) For this blog, we will be using a Local Run model. This will utilize the local machine’s hardware to run the Language model. Since it involves analyzing images, we will be using the language model which supports vision operations and hence Phi-3-Vision will be a good fit as its light and supports local run. Download the model and then further it will be loaded it in the playground to test. Once downloaded, Launch the “Playground” tab and load the Phi-3 Vision model from the dropdown. The Playground also shows that Phi-3 vision allows image attachments. We can try it out before we start developing the application. Let’s upload the image using the “Paperclip icon” on the UI. I have uploaded image of Microsoft logo and prompted the language model to Analyze and explain the image. Phi-3 vision running on local premise boasts an uncanny ability to not just detect but unerringly pinpoint the exact Company logo and decipher the name with astonishing precision. This is a simple use case, but it can be built upon with various applications to unlock a world of new possibilities. Port Forwarding: Port Forwarding, a valuable feature within the AI Toolkit, serves as a crucial gateway for seamless communication with the GenAI model. To do this, launch the terminal and navigate to the “Ports” section. There will be button “Forward a Port”, click on that and select any desired port, in this blog we will use 5272 as the port. The Model-as-a-server is now ready, where the model will be available on the port 5272 to respond to the API calls. It can be tested with any API testing application. To know more click here. Creating Application with Python using OpenAI SDK: To follow this section, Python must be installed on the local machine. Launch the new VS Code window and set the working directory. Create a new Python Virtual environment. Once the setup is ready, open the terminal on VS Code, and install the libraries using “pip”. pip install openai pip install streamlit Before we build the streamlit application, lets develop the basic program and check the responses in the VSCode terminal and then further develop a basic webapp using the streamlit framework. Basic Program Import libraries: import base64 from openai import OpenAI base64: The base64 module provides functions for encoding binary data to base64-encoded strings and decoding base64-encoded strings back to binary data. Base64 encoding is commonly used for encoding binary data in text-based formats such as JSON or XML. OpenAI: The OpenAI package is a Python client library for interacting with OpenAI's API. The OpenAI class provides methods for accessing various OpenAI services, such as generating text, performing natural language processing tasks, and more. Initialize Client: Initialize an instance of the OpenAI class from the openai package, client = OpenAI( base_url="http://127.0.0.1:5272/v1/", api_key="xyz" # required by API but not used ) OpenAI (): Initializes a OpenAI model with specific parameters, including a base URL for the API, an API key, a custom model name, and a temperature setting. This model is used to generate responses based on user queries. This instance will be used to interact with the OpenAI API. base_url = "http://127.0.0.1:5272/v1/": Specifies the base URL for the OpenAI API. In this case, it points to a local server running on 127.0.0.1 (localhost) at port 5272. api_key = "ai-toolkit": The API key used to authenticate requests to the OpenAI API. In case of AI Toolkit usage, we don’t have to specify any API key. The image analysis application will frequently deal with images uploaded by users. But to send these images to GenAI model, we need them in a format it understands. This is where the encode_image function comes in. # Function to encode the image def encode_image(image_path): with open(image_path, "rb") as image_file: return base64.b64encode(image_file.read()).decode("utf-8") Function Definition: def encode_image(image_path): defines a function named encode_image that takes a single argument, image_path. This argument represents the file path of the image we want to encode. Opening the Image: with open(image_path, "rb") as image_file: opens the image file specified by image_path in binary reading mode ("rb"). This is crucial because we're dealing with raw image data, not text. Reading Image Content: image_file.read() reads the entire content of the image file into a byte stream. Remember, images are stored as collections of bytes representing color values for each pixel. Base64 Encoding: base64.b64encode(image_file.read()) encodes the byte stream containing the image data into base64 format. Base64 encoding is a way to represent binary data using a combination of printable characters, which makes it easier to transmit or store the data. Decoding to UTF-8: .decode("utf-8") decodes the base64-encoded data into a UTF-8 string. This step is necessary because the OpenAI API typically expects text input, and the base64-encoded string can be treated as text containing special characters. Returning the Encoded Image: return returns the base64-encoded string representation of the image. This encoded string is what we'll send to the AI model for analysis. In essence, the encode_image function acts as a bridge, transforming an image file on your computer into a format that the AI model can understand and process. Path for the Image: We will use an image stored on our local machine for this section, while we develop the webapp, we will change this to accept it to what the user uploads. image_path = "C:/img.jpg" #path of the image here This line of code is crucial for any program that needs to interact with an image file. It provides the necessary information for the program to locate and access the image data. Base64 String: # Getting the base64 string base64_image = encode_image(image_path) This line of code is responsible for obtaining the base64-encoded representation of the image specified by the image_path. Let's break it down: encode_image(image_path): This part calls the encode_image function, which we've discussed earlier. This function takes the image_path as input and performs the following: Reads the image file from the specified path. Converts the image data into a base64-encoded string. Returns the resulting base64-encoded string. base64_image = ...: This part assigns the return value of the encode_image function to the variable base64_image. This section effectively fetches the image from the given location and transforms it into a special format (base64) that can be easily handled and transmitted by the computer system. This base64-encoded string will be used subsequently to send the image data to the AI model for analysis. Invoking the Language Model: This code tells the AI model what to do with the image. response = client.chat.completions.create( model="Phi-3-vision-128k-cpu-int4-rtn-block-32-acc-level-4-onnx", messages=[ { "role": "user", "content": [ { "type": "text", "text": "What's in the Image?", }, { "type": "image_url", "image_url": {"url": f"data:image/jpeg;base64,{base64_image}"}, }, ], } ], ) response = client.chat.completions.create(...): This line sends instructions to the AI model we're using (represented by client). Here's a breakdown of what it's telling the model: chat.completions.create: We're using a specific part of the OpenAI API designed for having a conversation-like interaction with the model. The ... part: This represents additional details that define what we want the model to do, which we'll explore next. Let's break down the details (...) sent to the model: 1) model="Phi-3-vision-128k-cpu-int4-rtn-block-32-acc-level-4-onnx": This tells the model exactly which AI model to use for analysis. In our case, it's the "Phi-3-vision" model. 2) messages: This defines what information we're providing to the model. Here, we're sending two pieces of information: role": "user": This specifies that the first message comes from a user (us). The content: This includes two parts: "What's in the Image?": This is the prompt we're sending to the model about the image. "image_url": {"url": f"data:image/jpeg;base64,{base64_image}"}: This sends the actual image data encoded in base64 format (stored in base64_image). In a nutshell, this code snippet acts like giving instructions to the AI model. We specify the model to use, tell it we have a question about an image, and then provide the image data itself. Printing the response on the console: print(response.choices[0].message.content) We asked the AI model "What's in this image?" This line of code would then display the AI's answer. Console response: Finally, we can see the response on the terminal. Now to make things more interesting, let’s convert this into a webapp using the streamlit framework. Recipe Generator Application with Streamlit: Now we know how to interact with the Vision model offline using a basic console. Let’s make things even more exciting by applying all this to a use-case which probably will be most loved by all those who are cooking enthusiasts!! Yes, let’s create an application which will assist in cooking by looking what’s in the image of ingredients! Create a new file and name is as “app.py” select the same. venv that was used earlier. Make sure the Visual studio toolkit is running and serving the Phi-3 Vision model through the port 5272. First step is importing the libraries, import streamlit as st import base64 from openai import OpenAI base64 and OpenAI is the same as we had used in the earlier section. Streamlit: This part imports the entire Streamlit library, which provides a powerful set of tools for creating user interfaces (UIs) with Python. Streamlit simplifies the process of building web apps by allowing you to write Python scripts that directly translate into interactive web pages. client = OpenAI( base_url="http://127.0.0.1:5272/v1/", api_key="xyz" # required by API but not used ) As discussed in the earlier section, initializing the client and configuring the base_url and api_key. st.title('Recipe Generator 🍔') st.write('This is a simple recipe generator application.Upload images of the Ingridients and get the recipe by Chef GenAI! 🧑🍳') uploaded_file = st.file_uploader("Choose a file") if uploaded_file is not None: st.image(uploaded_file, width=300) st.title('Recipe Generator 🍔'): This line sets the title of the Streamlit application as "Recipe Generator" with a visually appealing burger emoji. st.write(...): This line displays a brief description of the application's functionality to the user. uploaded_file = st.file_uploader("Choose a file"): This creates a file uploader component within the Streamlit app. Users can select and upload an image file (likely an image of ingredients). if uploaded_file is not None: : This conditional block executes only when the user has actually selected and uploaded a file. st.image(uploaded_file, width=300): If an image is uploaded, this line displays the uploaded image within the Streamlit app with a width of 300 pixels. In essence, this code establishes the basic user interface for the Recipe Generator app. It allows users to upload an image, and if an image is uploaded, it displays the image within the app. preference = st.sidebar.selectbox( "Choose your preference", ("Vegetarian", "Non-Vegetarian") ) cuisine = st.sidebar.selectbox( "Select for Cuisine", ("Indian","Chinese","French","Thai","Italian","Mexican","Japanese","American","Greek","Spanish") ) We use Streamlit's sidebar and selectbox features to create interactive user input options within a web application: st.sidebar.selectbox(...): This line creates a dropdown menu (selectbox) within the sidebar of the Streamlit application.The first argument, "Choose your preference", sets the label or title for the dropdown.The second argument, ("Vegetarian", "Non-Vegetarian"), defines the list of options available for the user to select (in this case, dietary preferences). cuisine = st.sidebar.selectbox(...): This line creates another dropdown menu in the sidebar, this time for selecting the desired cuisine.The label is "Select for Cuisine".The options provided include "Indian", "Chinese", "French", and several other popular cuisines. In essence, this code allows users to interact with the application by selecting their preferred dietary restrictions (Vegetarian or Non-Vegetarian) and desired cuisine from the dropdown menus in the sidebar. def encode_image(uploaded_file): """Encodes a Streamlit uploaded file into base64 format""" if uploaded_file is not None: content = uploaded_file.read() return base64.b64encode(content).decode("utf-8") else: return None base64_image = encode_image(uploaded_file) The same function of encode_image as discussed in the earlier section is being used here. if st.button("Ask Chef GenAI!"): if base64_image: response = client.chat.completions.create( model="Phi-3-vision-128k-cpu-int4-rtn-block-32-acc-level-4-onnx", messages=[ { "role": "user", "content": [ { "type": "text", "text": f"STRICTLY use the ingredients in the image to generate a {preference} recipe and {cuisine} cuisine.", }, { "type": "image_url", "image_url": {"url": f"data:image/jpeg;base64,{base64_image}"}, }, ], } ], ) print(response.choices[0].message.content) st.write(response.choices[0].message.content) else: st.write("Please upload an image with any number of ingridients and instantly get a recipe.") Above code block implements the core functionality of the Recipe Generator app, triggered when the user clicks a button labeled "Ask Chef GenAI!": if st.button("Ask Chef GenAI!"): This line checks if the user has clicked the button. If they have, the code within the if block executes. if base64_image: This inner if condition checks if a variable named base64_image has a value. This variable likely stores the base64 encoded representation of the uploaded image (containing ingredients). If base64_image has a value (meaning an image is uploaded), the code proceeds. client.chat.completions.create(...): Client that had been defined earlier interacts with the API . Here, it calls a to generate text completions, thereby invoking a small language model. The arguments provided specify the model to be used ("Phi-3-vision-128k-cpu-int4-rtn-block-32-acc-level-4-onnx") and the message to be completed. The message consists of two parts within a list: User Input: The first part defines the user's role ("user") and the content they provide. This content is an instruction with two key points: Dietary Preference: It specifies to "STRICTLY use the ingredients in the image" to generate a recipe that adheres to the user's preference (vegetarian or non-vegetarian, set using the preference dropdown). Cuisine Preference: It mentions the desired cuisine type (Indian, Chinese, etc., selected using the cuisine dropdown). Image Data: The second part provides the image data itself. It includes the type ("image_url") and the URL, which is constructed using the base64_image variable containing the base64 encoded image data. print(response.choices[0].message.content) & st.write(...): The response will contain a list of possible completions. Here, the code retrieves the first completion (response.choices[0]) and extracts its message content. This content is then printed to the console like before and displayed on the Streamlit app using st.write. else block: If no image is uploaded (i.e., base64_image is empty), the else block executes. It displays a message reminding the user to upload an image to get recipe recommendations. The above code block is the same as before except the we have now modified it to accept few inputs and also have made it compatible with streamlit. The coding is now completed for our streamlit application! It's time to test the application. Navigate to the terminal on Visual Studio Code and enter the following command, (if the file is named as app.py) streamlit run app.py Upon successful run, it will redirect to default browser and a screen with the Recipe generator will be launched, Upload an image with ingredients, select the recipe, cuisine and click on “Ask Chef GenAI”. It will take a few moments for delightful recipe generation. While generating we can see the logs on the terminal and finally the recipe will be shown on the screen! Enjoy your first recipe curated by Chef GenAI powered by Phi-3 vision model on local prem using Visual Studio AI Toolkit! The code is available on the following GitHub Repository. In the upcoming series we will explore more types of Gen AI implementations with AI toolkit. Resources: 1. Visual Studio Code AI Toolkit: Run LLMs locally 2. Visual Studio AI Toolkit : Building Phi-3 GenAI Applications 3. Building Retrieval Augmented Generation on VSCode & AI Toolkit 4. Bring your own models on AI Toolkit - using Ollama and API keys 5. Expanded model catalog for AI Toolkit 6. Azure Toolkit Samples GitHub RepositoryFine-Tuning and Deploying Phi-3.5 Model with Azure and AI Toolkit
What is Phi-3.5? Phi-3.5 as a state-of-the-art language model with strong multilingual capabilities. Emphasize that it is designed to handle multiple languages with high proficiency, making it a versatile tool for Natural Language Processing (NLP) tasks across different linguistic backgrounds. Key Features of Phi-3.5 Highlight the core features of the Phi-3.5 model: Multilingual Capabilities: Explain that the model supports a wide variety of languages, including major world languages such as English, Spanish, Chinese, French, and others. You can provide an example of its ability to handle a sentence or document translation from one language to another without losing context or meaning. Fine-Tuning Ability: Discuss how the model can be fine-tuned for specific use cases. For instance, in a customer support setting, the Phi-3.5 model can be fine-tuned to understand the nuances of different languages used by customers across the globe, improving response accuracy. High Performance in NLP Tasks: Phi-3.5 is optimized for tasks like text classification, machine translation, summarization, and more. It has superior performance in handling large-scale datasets and producing coherent, contextually correct language outputs. Applications in Real-World Scenarios To make this section more engaging, provide a few real-world applications where the Phi-3.5 model can be utilized: Customer Support Chatbots: For companies with global customer bases, the model’s multilingual support can enhance chatbot capabilities, allowing for real-time responses in a customer’s native language, no matter where they are located. Content Creation for Global Markets: Discuss how businesses can use Phi-3.5 to automatically generate or translate content for different regions. For example, marketing copy can be adapted to fit cultural and linguistic nuances in multiple languages. Document Summarization Across Languages: Highlight how the model can be used to summarize long documents or articles written in one language and then translate the summary into another language, improving access to information for non-native speakers. Why Choose Phi-3.5 for Your Project? End this section by emphasizing why someone should use Phi-3.5: Versatility: It’s not limited to just one or two languages but performs well across many. Customization: The ability to fine-tune it for particular use cases or industries makes it highly adaptable. Ease of Deployment: With tools like Azure ML and Ollama, deploying Phi-3.5 in the cloud or locally is accessible even for smaller teams. Objective Of Blog Specialized Language Models (SLMs) are at the forefront of advancements in Natural Language Processing, offering fine-tuned, high-performance solutions for specific tasks and languages. Among these, the Phi-3.5 model has emerged as a powerful tool, excelling in its multilingual capabilities. Whether you're working with English, Spanish, Mandarin, or any other major world language, Phi-3.5 offers robust, reliable language processing that adapts to various real-world applications. This makes it an ideal choice for businesses looking to deploy multilingual chatbots, automate content generation, or translate customer interactions in real time. Moreover, its fine-tuning ability allows for customization, making Phi-3.5 versatile across industries and tasks. Customization and Fine-Tuning for Different Applications The Phi-3.5 model is not just limited to general language understanding tasks. It can be fine-tuned for specific applications, industries, and language models, allowing users to tailor its performance to meet their needs. Customizable for Industry-Specific Use Cases: With fine-tuning, the model can be trained further on domain-specific data to handle particular use cases like legal document translation, medical records analysis, or technical support. Example: A healthcare company can fine-tune Phi-3.5 to understand medical terminology in multiple languages, enabling it to assist in processing patient records or generating multilingual health reports. Adapting for Specialized Tasks: You can train Phi-3.5 to perform specialized tasks like sentiment analysis, text summarization, or named entity recognition in specific languages. Fine-tuning helps enhance the model's ability to handle unique text formats or requirements. Example: A marketing team can fine-tune the model to analyse customer feedback in different languages to identify trends or sentiment across various regions. The model can quickly classify feedback as positive, negative, or neutral, even in less widely spoken languages like Arabic or Korean. Applications in Real-World Scenarios To illustrate the versatility of Phi-3.5, here are some real-world applications where this model excels, demonstrating its multilingual capabilities and customization potential: Case Study 1: Multilingual Customer Support Chatbots Many global companies rely on chatbots to handle customer queries in real-time. With Phi-3.5’s multilingual abilities, businesses can deploy a single model that understands and responds in multiple languages, cutting down on the need to create language-specific chatbots. Example: A global airline can use Phi-3.5 to power its customer service bot. Passengers from different countries can inquire about their flight status or baggage policies in their native languages—whether it's Japanese, Hindi, or Portuguese—and the model responds accurately in the appropriate language. Case Study 2: Multilingual Content Generation Phi-3.5 is also useful for businesses that need to generate content in different languages. For example, marketing campaigns often require creating region-specific ads or blog posts in multiple languages. Phi-3.5 can help automate this process by generating localized content that is not just translated but adapted to fit the cultural context of the target audience. Example: An international cosmetics brand can use Phi-3.5 to automatically generate product descriptions for different regions. Instead of merely translating a product description from English to Spanish, the model can tailor the description to fit cultural expectations, using language that resonates with Spanish-speaking audiences. Case Study 3: Document Translation and Summarization Phi-3.5 can be used to translate or summarize complex documents across languages. Its ability to preserve meaning and context across languages makes it ideal for industries where accuracy is crucial, such as legal or academic fields. Example: A legal firm working on cross-border cases can use Phi-3.5 to translate contracts or legal briefs from German to English, ensuring the context and legal terminology are accurately preserved. It can also summarize lengthy documents in multiple languages, saving time for legal teams. Fine-Tuning Phi-3.5 Model Fine-tuning a language model like Phi-3.5 is a crucial step in adapting it to perform specific tasks or cater to specific domains. This section will walk through what fine-tuning is, its importance in NLP, and how to fine-tune the Phi-3.5 model using Azure Model Catalog for different languages and tasks. We'll also explore a code example and best practices for evaluating and validating the fine-tuned model. What is Fine-Tuning? Fine-tuning refers to the process of taking a pre-trained model and adapting it to a specific task or dataset by training it further on domain-specific data. In the context of NLP, fine-tuning is often required to ensure that the language model understands the nuances of a particular language, industry-specific terminology, or a specific use case. Why Fine-Tuning is Necessary Pre-trained Large Language Models (LLMs) are trained on diverse datasets and can handle various tasks like text summarization, generation, and question answering. However, they may not perform optimally in specialized domains without fine-tuning. The goal of fine-tuning is to enhance the model's performance on specific tasks by leveraging its prior knowledge while adapting it to new contexts. Challenges of Fine-Tuning Resource Intensiveness: Fine-tuning large models can be computationally expensive, requiring significant hardware resources. Storage Costs: Each fine-tuned model can be large, leading to increased storage needs when deploying multiple models for different tasks. LoRA and QLoRA To address these challenges, techniques like LoRA (Low-rank Adaptation) and QLoRA (Quantized Low-rank Adaptation) have emerged. Both methods aim to make the fine-tuning process more efficient: LoRA: This technique reduces the number of trainable parameters by introducing low-rank matrices into the model while keeping the original model weights frozen. This approach minimizes memory usage and speeds up the fine-tuning process. QLoRA: An enhancement of LoRA, QLoRA incorporates quantization techniques to further reduce memory requirements and increase the efficiency of the fine-tuning process. It allows for the deployment of large models on consumer hardware without the extensive resource demands typically associated with full fine-tuning. from transformers import AutoModelForSequenceClassification, Trainer, TrainingArguments from peft import get_peft_model, LoraConfig # Load a pre-trained model model = AutoModelForSequenceClassification.from_pretrained("bert-base-uncased") # Configure LoRA lora_config = LoraConfig( r=16, # Rank lora_alpha=32, lora_dropout=0.1, ) # Wrap the model with LoRA model = get_peft_model(model, lora_config) # Define training arguments training_args = TrainingArguments( output_dir="./results", evaluation_strategy="epoch", learning_rate=2e-5, per_device_train_batch_size=16, per_device_eval_batch_size=16, num_train_epochs=3, ) # Create a Trainer trainer = Trainer( model=model, args=training_args, train_dataset=train_dataset, eval_dataset=eval_dataset, ) # Start fine-tuning trainer.train() This code outlines how to set up a model for fine-tuning using LoRA, which can significantly reduce the resource requirements while still adapting the model effectively to specific tasks. In summary, fine-tuning with methods like LoRA and QLoRA is essential for optimizing pre-trained models for specific applications in NLP, making it feasible to deploy these powerful models in various domains efficiently. Why is Fine-Tuning Important in NLP? Task-Specific Performance: Fine-tuning helps improve performance for tasks like text classification, machine translation, or sentiment analysis in specific domains (e.g., legal, healthcare). Language-Specific Adaptation: Since models like Phi-3.5 are trained on general datasets, fine-tuning helps them handle industry-specific jargon or linguistic quirks. Efficient Resource Utilization: Instead of training a model from scratch, fine-tuning leverages pre-trained knowledge, saving computational resources and time. Steps to Fine-Tune Phi-3.5 in Azure AI Foundry Fine-tuning the Phi-3.5 model in Azure AI Foundry involves several key steps. Azure provides a user-friendly interface to streamline model customization, allowing you to quickly configure, train, and deploy models. Step 1: Setting Up the Environment in Azure AI Foundry Access Azure AI Foundry: Log in to Azure AI Foundry. If you don’t have an account, you can create one and set up a workspace. Create a New Experiment: Once in the Azure AI Foundry, create a new training experiment. Choose the Phi-3.5 model from the pre-trained models provided in the Azure Model Zoo. Set Up the Data for Fine-Tuning: Upload your custom dataset for fine-tuning. Ensure the dataset is in a compatible format (e.g., CSV, JSON). For instance, if you are fine-tuning the model for a customer service chatbot, you could upload customer queries in different languages. Step 2: Configure Fine-Tuning Settings Select the Training Dataset: Select the dataset you uploaded and link it to the Phi-3.5 model. 2) Configure the Hyperparameters: Set up training hyperparameters like the number of epochs, learning rate, and batch size. You may need to experiment with these settings to achieve optimal performance. 3) Choose the Task Type: Specify the task you are fine-tuning for, such as text classification, translation, or summarization. This helps Azure AI Foundry understand how to optimize the model during fine-tuning. 4) Fine-Tuning for Specific Languages: If you are fine-tuning for a specific language or multilingual tasks, ensure that the dataset is labeled appropriately and contains enough examples in the target language(s). This will allow Phi-3.5 to learn language-specific features effectively. Step 3: Train the Model Launch the Training Process: Once the configuration is complete, launch the training process in Azure AI Foundry. Depending on the size of your dataset and the complexity of the model, this could take some time. Monitor Training Progress: Use Azure AI Foundry’s built-in monitoring tools to track performance metrics such as loss, accuracy, and F1 score. You can view the model’s progress during training to ensure that it is learning effectively. Code Example: Fine-Tuning Phi-3.5 for a Specific Use Case Here's a code snippet for fine-tuning the Phi-3.5 model using Python and Azure AI Foundry SDK. In this example, we are fine-tuning the model for a customer support chatbot in multiple languages. from azure.ai import Foundry from azure.ai.model import Model # Initialize Azure AI Foundry foundry = Foundry() # Load the Phi-3.5 model model = Model.load("phi-3.5") # Set up the training dataset training_data = foundry.load_dataset("customer_queries_dataset") # Fine-tune the model model.fine_tune(training_data, epochs=5, learning_rate=0.001) # Save the fine-tuned model model.save("fine_tuned_phi_3.5") Best Practices for Evaluating and Validating Fine-Tuned Models Once the model is fine-tuned, it's essential to evaluate and validate its performance before deploying it in production. Split Data for Validation: Always split your dataset into training and validation sets. This ensures that the model is evaluated on unseen data to prevent overfitting. Evaluate Key Metrics: Measure performance using key metrics such as: Accuracy: The proportion of correct predictions. F1 Score: A measure of precision and recall. Confusion Matrix: Helps visualize true vs. false predictions for classification tasks. Cross-Language Validation: If the model is fine-tuned for multiple languages, test its performance across all supported languages to ensure consistency and accuracy. Test in Production-Like Environments: Before full deployment, test the fine-tuned model in a production-like environment to catch any potential issues. Continuous Monitoring and Re-Fine-Tuning: Once deployed, continuously monitor the model’s performance and re-fine-tune it periodically as new data becomes available. Deploying Phi-3.5 Model After fine-tuning the Phi-3.5 model, the next crucial step is deploying it to make it accessible for real-world applications. This section will cover two key deployment strategies: deploying in Azure for cloud-based scaling and reliability, and deploying locally with AI Toolkit for simpler offline usage. Each deployment strategy offers its own advantages depending on the use case. Deploying in Azure Azure provides a powerful environment for deploying machine learning models at scale, enabling organizations to deploy models like Phi-3.5 with high availability, scalability, and robust security features. Azure AI Foundry simplifies the entire deployment pipeline. Set Up Azure AI Foundry Workspace: Log in to Azure AI Foundry and navigate to the workspace where the Phi-3.5 model was fine-tuned. Go to the Deployments section and create a new deployment environment for the model. Choose Compute Resources: Compute Target: Select a compute target suitable for your deployment. For large-scale usage, it’s advisable to choose a GPU-based compute instance. Example: Choose an Azure Kubernetes Service (AKS) cluster for handling large-scale requests efficiently. Configure Scaling Options: Azure allows you to set up auto-scaling based on traffic. This ensures that the model can handle surges in demand without affecting performance. Model Deployment Configuration: Create an Inference Pipeline: In Azure AI Foundry, set up an inference pipeline for your model. Specify the Model: Link the fine-tuned Phi-3.5 model to the deployment pipeline. Deploy the Model: Select the option to deploy the model to the chosen compute resource. Test the Deployment: Once the model is deployed, test the endpoint by sending sample requests to verify the predictions. Configuration Steps (Compute, Resources, Scaling) During deployment, Azure AI Foundry allows you to configure essential aspects like compute type, resource allocation, and scaling options. Compute Type: Choose between CPU or GPU clusters depending on the computational intensity of the model. Resource Allocation: Define the minimum and maximum resources to be allocated for the deployment. For real-time applications, use Azure Kubernetes Service (AKS) for high availability. For batch inference, Azure Container Instances (ACI) is suitable. Auto-Scaling: Set up automatic scaling of the compute instances based on the number of requests. For example, configure the deployment to start with 1 node and scale to 10 nodes during peak usage. Cost Comparison: Phi-3.5 vs. Larger Language Models When comparing the costs of using Phi-3.5 with larger language models (LLMs), several factors come into play, including computational resources, pricing structures, and performance efficiency. Here’s a breakdown: Cost Efficiency Phi-3.5: Designed as a Small Language Model (SLM), Phi-3.5 is optimized for lower computational costs. It offers competitive performance at a fraction of the cost of larger models, making it suitable for budget-conscious projects. The smaller size (3.8 billion parameters) allows for reduced resource consumption during both training and inference. Larger Language Models (e.g., GPT-3.5): Typically require more computational resources, leading to higher operational costs. Larger models may incur additional costs for storage and processing power, especially in cloud environments. Performance vs. Cost Performance Parity: Phi-3.5 has been shown to achieve performance parity with larger models on various benchmarks, including language comprehension and reasoning tasks. This means that for many applications, Phi-3.5 can deliver similar results to larger models without the associated costs. Use Case Suitability: For simpler tasks or applications that do not require extensive factual knowledge, Phi-3.5 is often the more cost-effective choice. Larger models may still be preferred for complex tasks requiring deep contextual understanding or extensive factual recall. Pricing Structure Azure Pricing: Phi-3.5 is available through Azure with a pay-as-you-go billing model, allowing users to scale costs based on usage. Pricing details for Phi-3.5 can be found on the Azure pricing page, where users can customize options based on their needs. Code Example: API Setup and Endpoints for Live Interaction Below is a Python code snippet demonstrating how to interact with a deployed Phi-3.5 model via an API in Azure: import requests # Define the API endpoint and your API key api_url = "https://<your-azure-endpoint>/predict" api_key = "YOUR_API_KEY" # Prepare the input data input_data = { "text": "What are the benefits of renewable energy?" } # Make the API request response = requests.post(api_url, json=input_data, headers={"Authorization": f"Bearer {api_key}"}) # Print the model's response if response.status_code == 200: print("Model Response:", response.json()) else: print("Error:", response.status_code, response.text) Deploying Locally with AI Toolkit For developers who prefer to run models on their local machines, the AI Toolkit provides a convenient solution. The AI Toolkit is a lightweight platform that simplifies local deployment of AI models, allowing for offline usage, experimentation, and rapid prototyping. Deploying the Phi-3.5 model locally using the AI Toolkit is straightforward and can be used for personal projects, testing, or scenarios where cloud access is limited. Introduction to AI Toolkit The AI Toolkit is an easy-to-use platform for deploying language models locally without relying on cloud infrastructure. It supports a range of AI models and enables developers to work in a low-latency environment. Advantages of deploying locally with AI Toolkit: Offline Capability: No need for continuous internet access. Quick Experimentation: Rapid prototyping and testing without the delays of cloud deployments. Setup Guide: Installing and Running Phi-3.5 Locally Using AI Toolkit Install AI Toolkit: Go to the AI Toolkit website and download the platform for your operating system (Linux, macOS, or Windows). Install AI Toolkit by running the appropriate installation command in your terminal. Download the Phi-3.5 Model: Once AI Toolkit is installed, you can download the Phi-3.5 model locally by running: 3. Run the Model Locally: After downloading the model, start a local session by running: This will launch a local server on your machine where the model will be available for interaction. Code Example: Using Phi-3.5 Locally in a Project Below is a Python code example demonstrating how to send a query to the locally deployed Phi-3.5 model running on the AI Toolkit. import requests # Define the local endpoint local_url = "http://localhost:8000/predict" # Prepare the input data input_data = { "text": "What are the benefits of renewable energy?" } # Make the API request response = requests.post(local_url, json=input_data) # Print the model's response if response.status_code == 200: print("Model Response:", response.json()) else: print("Error:", response.status_code, response.text) Comparing Language Capabilities Test Results: How Phi-3.5 Handles Different Languages The Phi-3.5 model demonstrates robust multilingual capabilities, effectively processing and generating text in various languages. Below are comparative examples showcasing its performance in English, Spanish, and Mandarin: English Example: Input: "What are the benefits of renewable energy?" Output: "Renewable energy sources, such as solar and wind, reduce greenhouse gas emissions and promote sustainability." Spanish Example: Input: "¿Cuáles son los beneficios de la energía renovable?" Output: "Las fuentes de energía renovable, como la solar y la eólica, reducen las emisiones de gases de efecto invernadero y promueven la sostenibilidad." Mandarin Example: Input: "可再生能源的好处是什么?" Output: "可再生能源,如太阳能和风能,减少温室气体排放,促进可持续发展。" Performance Benchmarking and Evaluation Across Different Languages Benchmarking Phi-3.5 across different languages involves evaluating its accuracy, fluency, and contextual understanding. For instance, using BLEU scores and human evaluations, the model can be assessed on its translation quality and coherence in various languages. Real-World Use Case: Multilingual Customer Service Chatbot A practical application of Phi-3.5's multilingual capabilities is in developing a customer service chatbot that can interact with users in their preferred language. For instance, the chatbot could provide support in English, Spanish, and Mandarin, ensuring a wider reach and better user experience. Optimizing and Validating Phi-3.5 Model Model Performance Metrics To validate the model's performance in different scenarios, consider the following metrics: Accuracy: Measure how often the model's outputs are correct or align with expected results. Fluency: Assess the naturalness and readability of the generated text. Contextual Understanding: Evaluate how well the model understands and responds to context-specific queries. Tools to Use in Azure and Ollama for Evaluation Azure Cognitive Services: Utilize tools like Text Analytics and Translator to evaluate performance. Ollama: Use local testing environments to quickly iterate and validate model outputs. Conclusion In summary, Phi-3.5 exhibits impressive multilingual capabilities, effective deployment options, and robust performance metrics. Its ability to handle various languages makes it a versatile tool for natural language processing applications. Phi-3.5 stands out for its adaptability and performance in multilingual contexts, making it an excellent choice for future NLP projects, especially those requiring diverse language support. We encourage readers to experiment with the Phi-3.5 model using Azure AI Foundry or the AI Toolkit, explore fine-tuning techniques for their specific use cases, and share their findings with the community. For more information on optimized fine-tuning techniques, check out the Ignite Fine-Tuning Workshop. References Customize the Phi-3.5 family of models with LoRA fine-tuning in Azure Fine-tune Phi-3.5 models in Azure Fine Tuning with Azure AI Foundry and Microsoft Olive Hands on Labs and Workshop Customize a model with fine-tuning https://learn.microsoft.com/en-us/azure/ai-services/openai/how-to/fine-tuning?tabs=azure-openai%2Cturbo%2Cpython-new&pivots=programming-language-studio Microsoft AI Toolkit - AI Toolkit for VSCodeEvaluate Fine-tuned Phi-3 / 3.5 Models in Azure AI Studio Focusing on Microsoft's Responsible AI
Fine-tuning a model can sometimes lead to unintended or undesired responses. To ensure that the model remains safe and effective, it's important to evaluate the model's potential to generate harmful content and its ability to produce accurate, relevant, and coherent responses. In this tutorial, you will learn how to evaluate the safety and performance of a fine-tuned Phi-3 / Phi-3.5 model integrated with Prompt flow in Azure AI Studio. Before beginning the technical steps, it's essential to understand Microsoft's Responsible AI Principles, an ethical framework designed to guide the responsible development, deployment, and operation of AI systems. These principles guide the responsible design, development, and deployment of AI systems, ensuring that AI technologies are built in a way that is fair, transparent, and inclusive. These principles are the foundation for evaluating the safety of AI models.Create your own Visual Studio Code Chat Participant with Phi-3.5 by GitHub Models
Visual Studio Code provides an API that allows companies and individuals to create different participants based on their business to expand their capabilities in different proprietary fields. In this article, we will focus on Phi-3.5-mini-instruct (128k) and Phi-3.5-vision-instruct (128k) of GitHub Models to create your own Visual Studio Code Chat Participant.A better Phi Family is coming - multi-language support, better vision, intelligence MOEs
After the release of Phi-3 at Microsoft Build 2024, it has received different attention, especially the application of Phi-3-mini and Phi-3-vision on edge devices. In the June update, we improved Benchmark and System role support by adjusting high-quality data training. In the August update, based on community and customer feedback, we brought Phi-3.5-mini-128k-instruct multi-language support, Phi-3.5-vision-128k with multi-frame image input, and provided Phi-3.5 MOE newly added for AI Agent. Next, let's take a look Multi-language support In previous versions, Phi-3-mini had good English corpus support, but weak support for non-English languages. When we tried to ask questions in Chinese, there were often some wrong questions, such as Obviously, this is a wrong answer But in the new version, we can have better understanding and corpus support with the new Chinese prediction support You can also try the enhancements in different languages, or in the scenario without fine-tuning and RAG, it is also a good model. Code Sample: https://github.com/microsoft/Phi-3CookBook/blob/main/code/09.UpdateSamples/Aug/phi3-instruct-demo.ipynb Better vision Phi-3.5-Vision enables Phi-3 to not only understand text and complete dialogues, but also have visual capabilities (OCR, object recognition, and image analysis, etc.). However, in actual application scenarios, we need to analyze multiple images to find associations, such as videos, PPTs, books, etc. In the new Phi-3-Vision, multi-frame or multi-image input is supported, so we can better complete the inductive analysis of videos, PPTs, and books in visual scenes. As shown in this video We can use OpenCV to extract key frames. We can extract 21 key frame images from the video and store them in an array. images = [] placeholder = "" for i in range(1,22): with open("../output/keyframe_"+str(i)+".jpg", "rb") as f: images.append(Image.open("../output/keyframe_"+str(i)+".jpg")) placeholder += f"<|image_{i}|>\n" Combined with Phi-3.5-Vision's chat template, we can perform a comprehensive analysis of multiple frames. This allows us to more efficiently perform dynamic vision-based work, especially in edge scenarios. Code Sample: https://github.com/microsoft/Phi-3CookBook/blob/main/code/09.UpdateSamples/Aug/phi3-vision-demo.ipynb Intelligence MOEs In order to achieve higher performance of the model, in addition to computing power, model size is one of the key factors to improve model performance. Under a limited computing resource budget, training a larger model with fewer training steps is often better than training a smaller model with more steps. Mixture of Experts Models (MoEs) have the following characteristics: Faster pre-training speed than dense models Faster inference speed than models with the same number of parameters Requires a lot of video memory because all expert systems need to be loaded into memory There are many challenges in fine-tuning, but recent research shows that instruction tuning for mixed expert models has great potential. Now there are a lot of AI Agents applications, we can use MOEs to empower AI Agents. In multi-task scenarios, the response is faster. We can explore a simple scenario where we want to use AI to help us write Twitter based on some content and translate it into Chinese and publish it to social networks. We can combine Phi-3.5 MOEs to complete this. We can use Prompt to set and arrange tasks, such as blog content publishing, translated content, and the best answer. """ sys_msg = """You are a helpful AI assistant, you are an agent capable of using a variety of tools to answer a question. Here are a few of the tools available to you: - Blog: This tool helps you describe a certain knowledge point and content, and finally write it into Twitter or Facebook style content - Translate: This is a tool that helps you translate into any language, using plain language as required - Final Answer: the final answer tool must be used to respond to the user. You must use this when you have decided on an answer. To use these tools you must always respond in JSON format containing `"tool_name"` and `"input"` key-value pairs. For example, to answer the question, "Build Muliti Agents with MOE models" you must use the calculator tool like so: { "tool_name": "Blog", "input": "Build Muliti Agents with MOE models" } Or to translate the question "can you introduce yourself in Chinese" you must respond: { "tool_name": "Search", "input": "can you introduce yourself in Chinese" } Remember just output the final result, ouput in JSON format containing `"agentid"`,`"tool_name"` , `"input"` and `"output"` key-value pairs .: [ { "agentid": "step1", "tool_name": "Blog", "input": "Build Muliti Agents with MOE models", "output": "........." }, { "agentid": "step2", "tool_name": "Search", "input": "can you introduce yourself in Chinese", "output": "........." }, { "agentid": "final" "tool_name": "Result", "output": "........." } ] The users answer is as follows. """ We can see that by telling the model what skills it needs to have and the arrangement of tasks, we can assign them to different tasks through Phi-3.5 MOEs to complete related work. Write something about Generative AI with MOEs , translate it to Chinese The result : [ { "agentid": "step1", "tool_name": "Blog", "input": "Generative AI with MOE", "output": "Generative AI with MOE (Mixture of Experts) is a powerful approach that combines the strengths of generative models and the flexibility of MOE architecture. This hybrid model can generate high-quality, diverse, and contextually relevant content, making it suitable for various applications such as content creation, data augmentation, and more." }, { "agentid": "step2", "tool_name": "Translate", "input": "Generative AI with MOE is a powerful approach that combines the strengths of generative models and the flexibility of MOE architecture. This hybrid model can generate high-quality, diverse, and contextually relevant content, making it suitable for various applications such as content creation, data augmentation, and more.", "output": "基于生成AI的MOE(Mixture of Experts)是一种强大的方法,它结合了生成模型的优势和MOE架构的灵活性。这种混合模型可以生成高质量、多样化且上下文相关的内容,使其适用于各种应用,如内容创建、数据增强等。" }, { "agentid": "final", "tool_name": "Result", "output": "基于生成AI的MOE(Mixture of Experts)是一种强大的方法,它结合了生成模型的优势和MOE架构的灵活性。这种混合模型可以生成高质量、多样化且上下文相关的内容,使其适用于各种应用,如内容创建、数据增强等。" } ] If conditions permit, we can more smoothly integrate the Phi-3 MOEs model into frameworks such as AutoGen, Semantic Kernel, and Langchain. Code Sample: https://github.com/microsoft/Phi-3CookBook/blob/main/code/09.UpdateSamples/Aug/phi3_moe_demo.ipynb Thoughts on SLMs SLMs do not replace LLMs but give GenAI a broader scenario. The update of Phi-3 allows more edge devices to have better support, including text, chat, and vision. In modern AI Agents application scenarios, we hope to have more efficient task execution efficiency. In addition to computing power, MoEs are the key to solving problems. Phi-3 is still iterating, and I hope everyone will pay more attention and give us better feedback. Resources 1. Download Microsoft Phi-3 Family https://huggingface.co/collections/microsoft/phi-3-6626e15e9585a200d2d761e3 2. Read the Phi-3 Cookbook https://aka.ms/phi-3cookbook 3. Learn about MOEs https://huggingface.co/blog/moe](https://huggingface.co/blog/moe
