# mlx-embeddings **Repository Path**: dotacn/mlx-embeddings ## Basic Information - **Project Name**: mlx-embeddings - **Description**: No description available - **Primary Language**: Unknown - **License**: Not specified - **Default Branch**: main - **Homepage**: None - **GVP Project**: No ## Statistics - **Stars**: 0 - **Forks**: 0 - **Created**: 2026-05-01 - **Last Updated**: 2026-05-01 ## Categories & Tags **Categories**: Uncategorized **Tags**: None ## README # MLX-Embeddings [![image](https://img.shields.io/pypi/v/mlx-embeddings.svg)](https://pypi.python.org/pypi/mlx-embeddings) [![Upload Python Package](https://github.com/Blaizzy/mlx-embeddings/actions/workflows/python-publish.yaml/badge.svg)](https://github.com/Blaizzy/mlx-embeddings/actions/workflows/python-publish.yaml) **MLX-Embeddings is a package for running Vision and Language Embedding models locally on your Mac using MLX.** - Free software: GNU General Public License v3 ## Features - Generate embeddings for text and images using MLX models - Support for single-item and batch processing - Utilities for comparing text similarities ## Supported Models Archictectures MLX-Embeddings supports a variety of model architectures for text embedding tasks. Here's a breakdown of the currently supported architectures: - XLM-RoBERTa (Cross-lingual Language Model - Robustly Optimized BERT Approach) - BERT (Bidirectional Encoder Representations from Transformers) - ModernBERT (modernized bidirectional encoder-only Transformer model) - Qwen3 (Qwen3's embedding model) - Qwen3-VL (multimodal Qwen3-VL embedding and reranking model) - Llama Bidirectional (Llama-based bidirectional embedding models, e.g. NVIDIA NV-Embed) - Llama Nemotron VL (multimodal vision-language embedding model with SigLIP vision + bidirectional Llama) - OpenAI Privacy Filter (bidirectional GPT-OSS variant for PII token classification with sparse MoE, GQA + attention sinks, and YARN RoPE) We're continuously working to expand our support for additional model architectures. Check our GitHub repository or documentation for the most up-to-date list of supported models and their specific versions. ## Installation You can install mlx-embeddings using pip: ```bash pip install mlx-embeddings ``` ## Usage ### Qwen3-VL Qwen3-VL uses a model-specific processor and a high-level `model.process(...)` API for multimodal embedding and reranking. #### Multimodal Embedding ```python import mlx.core as mx from mlx_embeddings import load model, processor = load("Qwen/Qwen3-VL-Embedding-2B") inputs = [ { "text": "A woman playing with her dog on a beach at sunset.", "instruction": "Retrieve images or text relevant to the user's query.", }, { "text": "A woman shares a joyful moment with her golden retriever on a sun-drenched beach at sunset." }, { "image": "https://qianwen-res.oss-cn-beijing.aliyuncs.com/Qwen-VL/assets/demo.jpeg" }, { "text": "A woman shares a joyful moment with her golden retriever on a sun-drenched beach at sunset.", "image": "https://qianwen-res.oss-cn-beijing.aliyuncs.com/Qwen-VL/assets/demo.jpeg", }, ] embeddings = model.process(inputs, processor=processor) similarity = embeddings @ embeddings.T mx.eval(embeddings, similarity) print(embeddings.shape) # (4, 2048) print(similarity) ``` #### Multimodal Reranking ```python import mlx.core as mx from mlx_embeddings import load model, processor = load("Qwen/Qwen3-VL-Reranker-2B") inputs = { "instruction": "Retrieve images or text relevant to the user's query.", "query": {"text": "A woman playing with her dog on a beach at sunset."}, "documents": [ { "text": "A woman shares a joyful moment with her golden retriever on a sun-drenched beach at sunset." }, { "image": "https://qianwen-res.oss-cn-beijing.aliyuncs.com/Qwen-VL/assets/demo.jpeg" }, { "text": "A woman shares a joyful moment with her golden retriever on a sun-drenched beach at sunset.", "image": "https://qianwen-res.oss-cn-beijing.aliyuncs.com/Qwen-VL/assets/demo.jpeg", }, ], } scores = model.process(inputs, processor=processor) mx.eval(scores) print(scores.shape) # (3,) print(scores) ``` ### Single Item Embedding #### Text Embedding To generate an embedding for a single piece of text: ```python from mlx_embeddings.utils import load # Load the model and tokenizer model_name = "mlx-community/all-MiniLM-L6-v2-4bit" model, tokenizer = load(model_name) # Prepare the text text = "I like reading" # Tokenize and generate embedding input_ids = tokenizer.encode(text, return_tensors="mlx") outputs = model(input_ids) raw_embeds = outputs.last_hidden_state[:, 0, :] # CLS token text_embeds = outputs.text_embeds # mean pooled and normalized embeddings ``` Note : text-embeds use mean pooling for bert and xlm-robert. For modernbert, pooling strategy is set through the config file, defaulting to mean #### Masked Language Modeling To generate embeddings for masked language modeling tasks: ```python from mlx_embeddings.utils import load # Load ModernBERT model and tokenizer model, tokenizer = load("mlx-community/answerdotai-ModernBERT-base-4bit") # Masked Language Modeling example text = "The capital of France is [MASK]." inputs = tokenizer.encode(text, return_tensors="mlx") outputs = model(inputs) # Get predictions for the masked token masked_index = inputs.tolist()[0].index(tokenizer.mask_token_id) predicted_token_id = mx.argmax(outputs.pooler_output[0, masked_index]).tolist() predicted_token = tokenizer.decode(predicted_token_id) print("Predicted token:", predicted_token) # Should output: Paris ``` #### Sequence classification ```python from mlx_embeddings.utils import load # Load ModernBERT model and tokenizer model, tokenizer = load( "NousResearch/Minos-v1", ) id2label=model.config.id2label # Masked Language Modeling example text = "<|user|> Explain the theory of relativity in simple terms. <|assistant|> Imagine space and time are like a stretchy fabric. Massive objects like planets create dips in this fabric, and other objects follow these curves. That's gravity! Also, the faster you move, the slower time passes for you compared to someone standing still" inputs = tokenizer.encode(text, return_tensors="mlx") outputs = model(inputs) # Get predictions for the masked token predictions = outputs.pooler_output[0] # Shape: (num_label,) print(text) # Print results print("\nTop predictions for classification:") for idx, logit in enumerate(predictions.tolist()): label = id2label[str(idx)] print(f"{label}: {logit:.3f}") ``` #### Token Classification (PII detection) `openai/privacy-filter` is a bidirectional 1.5B-parameter / 50M-active sparse-MoE token classifier that tags personally identifiable information (PII) with BIOES spans over 8 categories (person, email, phone, URL, address, date, account number, secret). ```python from itertools import groupby import mlx.core as mx from mlx_embeddings.utils import load model, tokenizer = load("openai/privacy-filter") id2label = model.config.id2label text = "My name is Alice Smith and my email is alice@example.com. Phone: 555-1234." inputs = tokenizer(text, return_tensors="mlx") outputs = model(inputs["input_ids"], attention_mask=inputs["attention_mask"]) preds = mx.argmax(outputs.logits, axis=-1)[0].tolist() entity = lambda p: id2label[str(p)].split("-", 1)[-1] if id2label[str(p)] != "O" else None for ent, group in groupby(zip(inputs["input_ids"][0].tolist(), preds), key=lambda x: entity(x[1])): if ent: span = tokenizer.decode([tid for tid, _ in group]).strip() print(f"{ent:18s} -> {span!r}") ``` ### Batch Processing #### Multiple Texts Comparison To embed multiple texts and compare them using their embeddings: ```python from sklearn.metrics.pairwise import cosine_similarity import matplotlib.pyplot as plt import seaborn as sns import mlx.core as mx from mlx_embeddings.utils import load # Load the model and tokenizer model, tokenizer = load("mlx-community/all-MiniLM-L6-v2-4bit") def get_embedding(texts, model, tokenizer): inputs = tokenizer.batch_encode_plus(texts, return_tensors="mlx", padding=True, truncation=True, max_length=512) outputs = model( inputs["input_ids"], attention_mask=inputs["attention_mask"] ) return outputs.text_embeds # mean pooled and normalized embeddings def compute_and_print_similarity(embeddings): B, _ = embeddings.shape similarity_matrix = cosine_similarity(embeddings) print("Similarity matrix between sequences:") print(similarity_matrix) print("\n") for i in range(B): for j in range(i+1, B): print(f"Similarity between sequence {i+1} and sequence {j+1}: {similarity_matrix[i][j]:.4f}") return similarity_matrix # Visualize results def plot_similarity_matrix(similarity_matrix, labels): plt.figure(figsize=(5, 4)) sns.heatmap(similarity_matrix, annot=True, cmap='coolwarm', xticklabels=labels, yticklabels=labels) plt.title('Similarity Matrix Heatmap') plt.tight_layout() plt.show() # Sample texts texts = [ "I like grapes", "I like fruits", "The slow green turtle crawls under the busy ant." ] embeddings = get_embedding(texts, model, tokenizer) similarity_matrix = compute_and_print_similarity(embeddings) # Visualize results labels = [f"Text {i+1}" for i in range(len(texts))] plot_similarity_matrix(similarity_matrix, labels) ``` #### Masked Language Modeling To get predictions for the masked token in multiple texts: ```python import mlx.core as mx from mlx_embeddings.utils import load # Load the model and tokenizer model, tokenizer = load("mlx-community/answerdotai-ModernBERT-base-4bit") text = ["The capital of France is [MASK].", "The capital of Poland is [MASK]."] inputs = tokenizer.batch_encode_plus(text, return_tensors="mlx", padding=True, truncation=True, max_length=512) outputs = model(**inputs) # To get predictions for the mask: # Find mask token indices for each sequence in the batch # Find mask indices for all sequences in batch mask_indices = mx.array([ids.tolist().index(tokenizer.mask_token_id) for ids in inputs["input_ids"]]) # Get predictions for all masked tokens at once batch_indices = mx.arange(len(mask_indices)) predicted_token_ids = mx.argmax(outputs.pooler_output[batch_indices, mask_indices], axis=-1).tolist() # Decode the predicted tokens predicted_token = tokenizer.batch_decode(predicted_token_ids) print("Predicted token:", predicted_token) # Predicted token: Paris, Warsaw ``` ## Vision Transformer Models MLX-Embeddings also supports vision models that can generate embeddings for images or image-text pairs. ### Single Image Processing To evaluate how well an image matches different text descriptions: ```python import mlx.core as mx from mlx_embeddings.utils import load import requests from PIL import Image # Load vision model and processor model, processor = load("mlx-community/siglip-so400m-patch14-384") # Load an image url = "http://images.cocodataset.org/val2017/000000039769.jpg" image = Image.open(requests.get(url, stream=True).raw) # Create text descriptions to compare with the image texts = ["a photo of 2 dogs", "a photo of 2 cats"] # Process inputs inputs = processor(text=texts, images=image, padding="max_length", return_tensors="np") pixel_values = mx.array(inputs.pixel_values).transpose(0, 2, 3, 1).astype(mx.float32) input_ids = mx.array(inputs.input_ids) # Generate embeddings and calculate similarity outputs = model(pixel_values=pixel_values, input_ids=input_ids) logits_per_image = outputs.logits_per_image probs = mx.sigmoid(logits_per_image) # probabilities of image matching each text # Print results print(f"{probs[0][0]:.1%} that image matches '{texts[0]}'") print(f"{probs[0][1]:.1%} that image matches '{texts[1]}'") ``` ### Batch Processing for Multiple Images comparison Process multiple images and compare them with text descriptions: ```python import mlx.core as mx from mlx_embeddings.utils import load import requests from PIL import Image import matplotlib.pyplot as plt import seaborn as sns # Load vision model and processor model, processor = load("mlx-community/siglip-so400m-patch14-384") # Load multiple images image_urls = [ "./images/cats.jpg", # cats "./images/desktop_setup.png" # desktop setup ] images = [Image.open(requests.get(url, stream=True).raw) if url.startswith("http") else Image.open(url) for url in image_urls] # Text descriptions texts = ["a photo of cats", "a photo of a desktop setup", "a photo of a person"] # Process all image-text pairs all_probs = [] # Process all image-text pairs in batch inputs = processor(text=texts, images=images, padding="max_length", return_tensors="np") pixel_values = mx.array(inputs.pixel_values).transpose(0, 2, 3, 1).astype(mx.float32) input_ids = mx.array(inputs.input_ids) # Generate embeddings and calculate similarity outputs = model(pixel_values=pixel_values, input_ids=input_ids) logits_per_image = outputs.logits_per_image probs = mx.sigmoid(logits_per_image) # probabilities for this image all_probs.append(probs.tolist()) # Print results for this image for i, image in enumerate(images): print(f"Image {i+1}:") for j, text in enumerate(texts): print(f" {probs[i][j]:.1%} match with '{text}'") print() # Visualize results with a heatmap def plot_similarity_matrix(probs_matrix, image_labels, text_labels): # Convert to 2D numpy array if needed import numpy as np probs_matrix = np.array(probs_matrix) # Ensure we have a 2D matrix for the heatmap if probs_matrix.ndim > 2: probs_matrix = probs_matrix.squeeze() plt.figure(figsize=(8, 5)) sns.heatmap(probs_matrix, annot=True, cmap='viridis', xticklabels=text_labels, yticklabels=image_labels, fmt=".1%", vmin=0, vmax=1) plt.title('Image-Text Match Probability') plt.tight_layout() plt.show() # Plot the images for reference plt.figure(figsize=(8, 5)) for i, image in enumerate(images): plt.subplot(1, len(images), i+1) plt.imshow(image) plt.title(f"Image {i+1}") plt.axis('off') plt.tight_layout() plt.show() image_labels = [f"Image {i+1}" for i in range(len(images))] plot_similarity_matrix(all_probs, image_labels, texts) ``` ### Late Interaction Multimodal Retrieval Models (ColPali/ColQwen) ```python import mlx.core as mx import requests from io import BytesIO from PIL import Image from transformers import AutoImageProcessor from mlx_embeddings import load from mlx_embeddings.models.base import normalize_embeddings # Load the model and tokenizer returned by mlx-embeddings model, tokenizer = load("qnguyen3/colqwen2.5-v0.2-mlx") image_processor = AutoImageProcessor.from_pretrained("qnguyen3/colqwen2.5-v0.2-mlx") def fetch_image(url): response = requests.get(url, headers={"User-Agent": "Mozilla/5.0"}, timeout=60) response.raise_for_status() return Image.open(BytesIO(response.content)).convert("RGB") def nonpad_rows(embeds, attention_mask): indices = [i for i, value in enumerate(attention_mask[0].tolist()) if value != 0] return embeds[0, indices, :] def prepare_query(text): suffix = tokenizer.pad_token * 10 query = "Query: " + text + suffix inputs = tokenizer([query], return_tensors="np", padding=True) return { "input_ids": mx.array(inputs["input_ids"]), "attention_mask": mx.array(inputs["attention_mask"]), } def prepare_image(image): image_inputs = image_processor( images=[image], return_tensors="np", data_format="channels_first", do_convert_rgb=True, ) image_grid_thw = mx.array(image_inputs["image_grid_thw"]) num_image_tokens = int( image_inputs["image_grid_thw"][0].prod() // (image_processor.merge_size ** 2) ) prompt = ( "<|im_start|>user\n" "<|vision_start|><|image_pad|><|vision_end|>" "Describe the image.<|im_end|><|endoftext|>" ) prompt = prompt.replace("<|image_pad|>", "<|image_pad|>" * num_image_tokens) text_inputs = tokenizer([prompt], return_tensors="np", padding=True) return { "input_ids": mx.array(text_inputs["input_ids"]), "attention_mask": mx.array(text_inputs["attention_mask"]), "pixel_values": mx.array(image_inputs["pixel_values"]), "image_grid_thw": image_grid_thw, } def embed_query(text): inputs = prepare_query(text) inputs_embeds = model.get_input_embeddings_batch(inputs["input_ids"]) position_ids, _ = model.vlm.language_model.get_rope_index( inputs["input_ids"], attention_mask=inputs["attention_mask"], ) hidden = model.vlm.language_model.model( None, inputs_embeds=inputs_embeds, mask=None, cache=None, position_ids=position_ids, ) embeds = normalize_embeddings(model.embedding_proj_layer(hidden)) embeds = embeds * inputs["attention_mask"][:, :, None] return nonpad_rows(embeds, inputs["attention_mask"]) def embed_image(image): inputs = prepare_image(image) inputs_embeds = model.get_input_embeddings_batch( inputs["input_ids"], inputs["pixel_values"], inputs["image_grid_thw"], ) position_ids, _ = model.vlm.language_model.get_rope_index( inputs["input_ids"], image_grid_thw=inputs["image_grid_thw"], attention_mask=inputs["attention_mask"], ) hidden = model.vlm.language_model.model( None, inputs_embeds=inputs_embeds, mask=None, cache=None, position_ids=position_ids, ) embeds = normalize_embeddings(model.embedding_proj_layer(hidden)) embeds = embeds * inputs["attention_mask"][:, :, None] return nonpad_rows(embeds, inputs["attention_mask"]) def maxsim(query_embeds, image_embeds): sims = query_embeds @ image_embeds.T return mx.sum(mx.max(sims, axis=1)) texts = ["how many percent of data are books?", "evaluation results between models"] images = [ fetch_image("https://upload.wikimedia.org/wikipedia/commons/8/89/US-original-Declaration-1776.jpg"), fetch_image("https://upload.wikimedia.org/wikipedia/commons/thumb/4/4c/Romeoandjuliet1597.jpg/500px-Romeoandjuliet1597.jpg"), ] query_embeddings = [embed_query(text) for text in texts] image_embeddings = [embed_image(image) for image in images] scores = [[float(maxsim(q, d)) for d in image_embeddings] for q in query_embeddings] print([embedding.shape for embedding in query_embeddings]) print([embedding.shape for embedding in image_embeddings]) print(scores) ``` ## Model Conversion ### Converting Hugging Face Models to MLX Format You can convert Hugging Face models to MLX format using the `mlx-embeddings` conversion tool: ```bash python -m mlx_embeddings.convert \ --hf-path \ --mlx-path ``` ### Quantization The conversion tool supports quantization to reduce model size and improve inference speed: ```bash # Default affine quantization (group_size=64, bits=4) python -m mlx_embeddings.convert \ --hf-path \ --mlx-path \ --quantize ``` #### Quantization Modes The `--q-mode` option specifies which quantization mode to use. Supported modes are: | Mode | Group Size | Bits | Use Case | |------|-----------|------|----------| | `affine` (default) | 64 | 4 | General-purpose quantization | | `mxfp4` | 32 | 4 | MLX floating-point 4-bit | | `nvfp4` | 16 | 4 | NVIDIA floating-point 4-bit | | `mxfp8` | 32 | 8 | MLX floating-point 8-bit (higher precision) | **Examples:** ```bash # mxfp4 quantization with default settings python -m mlx_embeddings.convert \ --hf-path \ --mlx-path \ --quantize \ --q-mode mxfp4 # nvfp4 quantization with custom group size and bits python -m mlx_embeddings.convert \ --hf-path \ --mlx-path \ --quantize \ --q-mode nvfp4 \ --q-group-size 32 \ --q-bits 6 # mxfp8 for higher precision (8-bit) python -m mlx_embeddings.convert \ --hf-path \ --mlx-path \ --quantize \ --q-mode mxfp8 ``` **Note:** User-specified `--q-group-size` and `--q-bits` values override mode defaults. ### Other Conversion Options - `--dtype`: Convert to specific dtype (`float16`, `bfloat16`, `float32`). Defaults to `float16`. - `--dequantize`: Dequantize a previously quantized model. - `--upload-repo`: Upload converted model to Hugging Face Hub. ## Contributing Contributions to MLX-Embeddings are welcome! Please refer to our contribution guidelines for more information. ## License This project is licensed under the GNU General Public License v3. ## Contact For any questions or issues, please open an issue on the [GitHub repository](https://github.com/Blaizzy/mlx-embeddings).