model-conversion : add support for SentenceTransformers (#16387)

* model-conversion : add support for SentenceTransformers

This commit adds support for models that use SentenceTransformer layers.

The motivation for this is that if converted model includes any of the
numbered layers specified in the original models repository then these
changes enable these models to be used and verified. Currently the
model-conversion only support the base model output without any of
the additional transformation layers.

Usage:
Convert the model that also includes the SentenceTransformer layers:
```console
(venv) $ export EMBEDDING_MODEL_PATH="~/google/embeddinggemma-300M"
(venv) make embedding-convert-model
```

Verify the produced embeddings from the converted model against the
original model embeddings:
```console
(venv) make embedding-verify-logits-st
```

The original model can be run using SentenceTransformer:
```console
(venv) make embedding-run-original-model-st
```

Run the converted model using "SentenceTransformer" layers whic
enables pooling and normalization:
```console
(venv) make embedding-run-converted-model-st
```

* add model-conversion example requirements

* add support for -st flag in embedding model conversion

This commit add support for the -st flag in the embedding model
conversion script. This will enable models to be converted using
sentence transformers dense layers.

examples/model-conversion/scripts/embedding/convert-model.sh

@@ -2,6 +2,21 @@
 
 set -e
 
+# Parse command line arguments
+SENTENCE_TRANSFORMERS=""
+while [[ $# -gt 0 ]]; do
+    case $1 in
+        -st|--sentence-transformers)
+            SENTENCE_TRANSFORMERS="--sentence-transformers-dense-modules"
+            shift
+            ;;
+        *)
+            echo "Unknown option: $1"
+            exit 1
+            ;;
+    esac
+done
+
 MODEL_NAME="${MODEL_NAME:-$(basename "$EMBEDDING_MODEL_PATH")}"
 OUTPUT_DIR="${OUTPUT_DIR:-../../models}"
 TYPE="${OUTTYPE:-f16}"
@@ -15,7 +30,8 @@ echo "Converted model path:: ${CONVERTED_MODEL}"
 python ../../convert_hf_to_gguf.py --verbose \
     ${EMBEDDING_MODEL_PATH} \
     --outfile ${CONVERTED_MODEL} \
-    --outtype ${TYPE}
+    --outtype ${TYPE} \
+    ${SENTENCE_TRANSFORMERS}
 
 echo ""
 echo "The environment variable CONVERTED_EMBEDDING MODEL can be set to this path using:"

examples/model-conversion/scripts/embedding/run-converted-model.sh

@@ -5,6 +5,7 @@ set -e
 # Parse command line arguments
 CONVERTED_MODEL=""
 PROMPTS_FILE=""
+USE_POOLING=""
 
 while [[ $# -gt 0 ]]; do
     case $1 in
@@ -12,6 +13,10 @@ while [[ $# -gt 0 ]]; do
             PROMPTS_FILE="$2"
             shift 2
             ;;
+        --pooling)
+            USE_POOLING="1"
+            shift
+            ;;
         *)
             if [ -z "$CONVERTED_MODEL" ]; then
                 CONVERTED_MODEL="$1"
@@ -47,4 +52,8 @@ echo $CONVERTED_MODEL
 
 cmake --build ../../build --target llama-logits -j8
 # TODO: update logits.cpp to accept a --file/-f option for the prompt
-../../build/bin/llama-logits -m "$CONVERTED_MODEL" -embd-mode "$PROMPT"
+if [ -n "$USE_POOLING" ]; then
+    ../../build/bin/llama-logits -m "$CONVERTED_MODEL" -embd-mode -pooling "$PROMPT"
+else
+    ../../build/bin/llama-logits -m "$CONVERTED_MODEL" -embd-mode "$PROMPT"
+fi

examples/model-conversion/scripts/embedding/run-original-model.py

@@ -14,6 +14,8 @@ unreleased_model_name = os.getenv('UNRELEASED_MODEL_NAME')
 parser = argparse.ArgumentParser(description='Process model with specified path')
 parser.add_argument('--model-path', '-m', help='Path to the model')
 parser.add_argument('--prompts-file', '-p', help='Path to file containing prompts (one per line)')
+parser.add_argument('--use-sentence-transformers', action='store_true',
+                    help='Use SentenceTransformer to apply all numbered layers (01_Pooling, 02_Dense, 03_Dense, 04_Normalize)')
 args = parser.parse_args()
 
 def read_prompt_from_file(file_path):
@@ -31,41 +33,52 @@ model_path = os.environ.get('EMBEDDING_MODEL_PATH', args.model_path)
 if model_path is None:
     parser.error("Model path must be specified either via --model-path argument or EMBEDDING_MODEL_PATH environment variable")
 
-tokenizer = AutoTokenizer.from_pretrained(model_path)
+# Determine if we should use SentenceTransformer
+use_sentence_transformers = args.use_sentence_transformers or os.environ.get('USE_SENTENCE_TRANSFORMERS', '').lower() in ('1', 'true', 'yes')
 
-config = AutoConfig.from_pretrained(model_path)
-
-# This can be used to override the sliding window size for manual testing. This
-# can be useful to verify the sliding window attention mask in the original model
-# and compare it with the converted .gguf model.
-if hasattr(config, 'sliding_window'):
-    original_sliding_window = config.sliding_window
-    #original_sliding_window = 6
-    print(f"Modified sliding window: {original_sliding_window} -> {config.sliding_window}")
-
-print(f"Using unreleased model: {unreleased_model_name}")
-if unreleased_model_name:
-    model_name_lower = unreleased_model_name.lower()
-    unreleased_module_path = f"transformers.models.{model_name_lower}.modular_{model_name_lower}"
-    class_name = f"{unreleased_model_name}Model"
-    print(f"Importing unreleased model module: {unreleased_module_path}")
-
-    try:
-        model_class = getattr(importlib.import_module(unreleased_module_path), class_name)
-        model = model_class.from_pretrained(model_path, config=config)
-    except (ImportError, AttributeError) as e:
-        print(f"Failed to import or load model: {e}")
-        exit(1)
+if use_sentence_transformers:
+    from sentence_transformers import SentenceTransformer
+    print("Using SentenceTransformer to apply all numbered layers")
+    model = SentenceTransformer(model_path)
+    tokenizer = model.tokenizer
+    config = model[0].auto_model.config  # type: ignore
 else:
-    model = AutoModel.from_pretrained(model_path, config=config)
-print(f"Model class: {type(model)}")
-print(f"Model file: {type(model).__module__}")
+    tokenizer = AutoTokenizer.from_pretrained(model_path)
+
+    config = AutoConfig.from_pretrained(model_path)
+
+    # This can be used to override the sliding window size for manual testing. This
+    # can be useful to verify the sliding window attention mask in the original model
+    # and compare it with the converted .gguf model.
+    if hasattr(config, 'sliding_window'):
+        original_sliding_window = config.sliding_window
+        #original_sliding_window = 6
+        print(f"Modified sliding window: {original_sliding_window} -> {config.sliding_window}")
+
+    print(f"Using unreleased model: {unreleased_model_name}")
+    if unreleased_model_name:
+        model_name_lower = unreleased_model_name.lower()
+        unreleased_module_path = f"transformers.models.{model_name_lower}.modular_{model_name_lower}"
+        class_name = f"{unreleased_model_name}Model"
+        print(f"Importing unreleased model module: {unreleased_module_path}")
+
+        try:
+            model_class = getattr(importlib.import_module(unreleased_module_path), class_name)
+            model = model_class.from_pretrained(model_path, config=config)
+        except (ImportError, AttributeError) as e:
+            print(f"Failed to import or load model: {e}")
+            exit(1)
+    else:
+        model = AutoModel.from_pretrained(model_path, config=config)
+    print(f"Model class: {type(model)}")
+    print(f"Model file: {type(model).__module__}")
 
 # Verify the model is using the correct sliding window
-if hasattr(model.config, 'sliding_window'):
-    print(f"Model's sliding_window: {model.config.sliding_window}")
-else:
-    print("Model config does not have sliding_window attribute")
+if not use_sentence_transformers:
+    if hasattr(model.config, 'sliding_window'):  # type: ignore
+        print(f"Model's sliding_window: {model.config.sliding_window}")  # type: ignore
+    else:
+        print("Model config does not have sliding_window attribute")
 
 model_name = os.path.basename(model_path)
 
@@ -75,34 +88,56 @@ if args.prompts_file:
 else:
     texts = ["Hello world today"]
 
-encoded = tokenizer(
-    texts,
-    padding=True,
-    truncation=True,
-    return_tensors="pt"
-)
-
-tokens = encoded['input_ids'][0]
-token_strings = tokenizer.convert_ids_to_tokens(tokens)
-for i, (token_id, token_str) in enumerate(zip(tokens, token_strings)):
-    print(f"{token_id:6d} -> '{token_str}'")
-
 with torch.no_grad():
-    outputs = model(**encoded)
-    hidden_states = outputs.last_hidden_state  # Shape: [batch_size, seq_len, hidden_size]
+    if use_sentence_transformers:
+        embeddings = model.encode(texts, convert_to_numpy=True)
+        all_embeddings = embeddings  # Shape: [batch_size, hidden_size]
 
-    # Extract embeddings for each token (matching LLAMA_POOLING_TYPE_NONE behavior)
-    all_embeddings = hidden_states[0].cpu().numpy()  # Shape: [seq_len, hidden_size]
+        encoded = tokenizer(
+            texts,
+            padding=True,
+            truncation=True,
+            return_tensors="pt"
+        )
+        tokens = encoded['input_ids'][0]
+        token_strings = tokenizer.convert_ids_to_tokens(tokens)
+        for i, (token_id, token_str) in enumerate(zip(tokens, token_strings)):
+            print(f"{token_id:6d} -> '{token_str}'")
 
-    print(f"Hidden states shape: {hidden_states.shape}")
-    print(f"All embeddings shape: {all_embeddings.shape}")
-    print(f"Embedding dimension: {all_embeddings.shape[1]}")
+        print(f"Embeddings shape (after all SentenceTransformer layers): {all_embeddings.shape}")
+        print(f"Embedding dimension: {all_embeddings.shape[1] if len(all_embeddings.shape) > 1 else all_embeddings.shape[0]}")  # type: ignore
+    else:
+        # Standard approach: use base model output only
+        encoded = tokenizer(
+            texts,
+            padding=True,
+            truncation=True,
+            return_tensors="pt"
+        )
 
-    # Print embeddings exactly like embedding.cpp does for LLAMA_POOLING_TYPE_NONE
-    n_embd = all_embeddings.shape[1]
-    n_embd_count = all_embeddings.shape[0]
+        tokens = encoded['input_ids'][0]
+        token_strings = tokenizer.convert_ids_to_tokens(tokens)
+        for i, (token_id, token_str) in enumerate(zip(tokens, token_strings)):
+            print(f"{token_id:6d} -> '{token_str}'")
 
-    print()  # Empty line to match C++ output
+        outputs = model(**encoded)
+        hidden_states = outputs.last_hidden_state  # Shape: [batch_size, seq_len, hidden_size]
+
+        all_embeddings = hidden_states[0].cpu().numpy()  # Shape: [seq_len, hidden_size]
+
+        print(f"Hidden states shape: {hidden_states.shape}")
+        print(f"All embeddings shape: {all_embeddings.shape}")
+        print(f"Embedding dimension: {all_embeddings.shape[1]}")
+
+    if len(all_embeddings.shape) == 1:
+        n_embd = all_embeddings.shape[0]  # type: ignore
+        n_embd_count = 1
+        all_embeddings = all_embeddings.reshape(1, -1)
+    else:
+        n_embd = all_embeddings.shape[1]  # type: ignore
+        n_embd_count = all_embeddings.shape[0]  # type: ignore
+
+    print()
 
     for j in range(n_embd_count):
         embedding = all_embeddings[j]
@@ -120,29 +155,23 @@ with torch.no_grad():
 
         print()  # New line
 
-    print()  # Final empty line to match C++ output
+    print()
 
     data_dir = Path("data")
     data_dir.mkdir(exist_ok=True)
     bin_filename = data_dir / f"pytorch-{model_name}-embeddings.bin"
     txt_filename = data_dir / f"pytorch-{model_name}-embeddings.txt"
 
-    # Save all embeddings flattened (matching what embedding.cpp would save if it did)
     flattened_embeddings = all_embeddings.flatten()
     flattened_embeddings.astype(np.float32).tofile(bin_filename)
 
     with open(txt_filename, "w") as f:
-        f.write(f"# Model class: {model_name}\n")
-        f.write(f"# Tokens: {token_strings}\n")
-        f.write(f"# Shape: {all_embeddings.shape}\n")
-        f.write(f"# n_embd_count: {n_embd_count}, n_embd: {n_embd}\n\n")
-
+        idx = 0
         for j in range(n_embd_count):
-            f.write(f"# Token {j} ({token_strings[j]}):\n")
-            for i, value in enumerate(all_embeddings[j]):
-                f.write(f"{j}_{i}: {value:.6f}\n")
-            f.write("\n")
-    print(f"Total values: {len(flattened_embeddings)} ({n_embd_count} tokens × {n_embd} dimensions)")
+            for value in all_embeddings[j]:
+                f.write(f"{idx}: {value:.6f}\n")
+                idx += 1
+    print(f"Total values: {len(flattened_embeddings)} ({n_embd_count} embeddings × {n_embd} dimensions)")
     print("")
     print(f"Saved bin embeddings to: {bin_filename}")
     print(f"Saved txt embeddings to: {txt_filename}")