Automatic Speech Recognition
Transformers
Safetensors
phi4mm
text-generation
nlp
code
audio
speech-summarization
speech-translation
visual-question-answering
phi-4-multimodal
phi
phi-4-mini
custom_code
Instructions to use FriendliAI/Phi-4-multimodal-instruct with libraries, inference providers, notebooks, and local apps. Follow these links to get started.
- Libraries
- Transformers
How to use FriendliAI/Phi-4-multimodal-instruct with Transformers:
# Use a pipeline as a high-level helper from transformers import pipeline pipe = pipeline("automatic-speech-recognition", model="FriendliAI/Phi-4-multimodal-instruct", trust_remote_code=True)# Load model directly from transformers import AutoModelForCausalLM model = AutoModelForCausalLM.from_pretrained("FriendliAI/Phi-4-multimodal-instruct", trust_remote_code=True, dtype="auto") - Notebooks
- Google Colab
- Kaggle
| """ | |
| finetune Phi-4-multimodal-instruct on an image task | |
| scipy==1.15.1 | |
| peft==0.13.2 | |
| backoff==2.2.1 | |
| transformers==4.47.0 | |
| accelerate==1.3.0 | |
| """ | |
| import argparse | |
| import json | |
| import os | |
| import tempfile | |
| import zipfile | |
| from pathlib import Path | |
| import torch | |
| from accelerate import Accelerator | |
| from accelerate.utils import gather_object | |
| from datasets import load_dataset | |
| from huggingface_hub import hf_hub_download | |
| from PIL import Image | |
| from torch.utils.data import Dataset | |
| from tqdm import tqdm | |
| from transformers import ( | |
| AutoModelForCausalLM, | |
| AutoProcessor, | |
| BatchFeature, | |
| Trainer, | |
| TrainingArguments, | |
| ) | |
| DEFAULT_INSTSRUCTION = "Answer with the option's letter from the given choices directly." | |
| _IGNORE_INDEX = -100 | |
| _TRAIN_SIZE = 8000 | |
| _EVAL_SIZE = 500 | |
| _MAX_TRAINING_LENGTH = 8192 | |
| class PmcVqaTrainDataset(Dataset): | |
| def __init__(self, processor, data_size, instruction=DEFAULT_INSTSRUCTION): | |
| # Download the file | |
| file_path = hf_hub_download( | |
| repo_id='xmcmic/PMC-VQA', # repository name | |
| filename='images_2.zip', # file to download | |
| repo_type='dataset', # specify it's a dataset repo | |
| ) | |
| # file_path will be the local path where the file was downloaded | |
| print(f'File downloaded to: {file_path}') | |
| # unzip to temp folder | |
| self.image_folder = Path(tempfile.mkdtemp()) | |
| with zipfile.ZipFile(file_path, 'r') as zip_ref: | |
| zip_ref.extractall(self.image_folder) | |
| data_files = { | |
| 'train': 'https://huggingface.co/datasets/xmcmic/PMC-VQA/resolve/main/train_2.csv', | |
| } | |
| split = 'train' if data_size is None else f'train[:{data_size}]' | |
| self.annotations = load_dataset('xmcmic/PMC-VQA', data_files=data_files, split=split) | |
| self.processor = processor | |
| self.instruction = instruction | |
| def __len__(self): | |
| return len(self.annotations) | |
| def __getitem__(self, idx): | |
| """ | |
| {'index': 35, | |
| 'Figure_path': 'PMC8253797_Fig4_11.jpg', | |
| 'Caption': 'A slightly altered cell . (c-c‴) A highly altered cell as seen from 4 different angles . Note mitochondria/mitochondrial networks (green), Golgi complexes (red), cell nuclei (light blue) and the cell outline (yellow).', | |
| 'Question': ' What color is used to label the Golgi complexes in the image?', | |
| 'Choice A': ' A: Green ', | |
| 'Choice B': ' B: Red ', | |
| 'Choice C': ' C: Light blue ', | |
| 'Choice D': ' D: Yellow', | |
| 'Answer': 'B', | |
| 'split': 'train'} | |
| """ | |
| annotation = self.annotations[idx] | |
| image = Image.open(self.image_folder / 'figures' / annotation['Figure_path']) | |
| question = annotation['Question'] | |
| choices = [annotation[f'Choice {chr(ord("A") + i)}'] for i in range(4)] | |
| user_message = { | |
| 'role': 'user', | |
| 'content': '<|image_1|>' + '\n'.join([question] + choices + [self.instruction]), | |
| } | |
| prompt = self.processor.tokenizer.apply_chat_template( | |
| [user_message], tokenize=False, add_generation_prompt=True | |
| ) | |
| answer = f'{annotation["Answer"]}<|end|><|endoftext|>' | |
| inputs = self.processor(prompt, images=[image], return_tensors='pt') | |
| answer_ids = self.processor.tokenizer(answer, return_tensors='pt').input_ids | |
| input_ids = torch.cat([inputs.input_ids, answer_ids], dim=1) | |
| labels = torch.full_like(input_ids, _IGNORE_INDEX) | |
| labels[:, -answer_ids.shape[1] :] = answer_ids | |
| if input_ids.size(1) > _MAX_TRAINING_LENGTH: | |
| input_ids = input_ids[:, :_MAX_TRAINING_LENGTH] | |
| labels = labels[:, :_MAX_TRAINING_LENGTH] | |
| if torch.all(labels == _IGNORE_INDEX).item(): | |
| # workaround to make sure loss compute won't fail | |
| labels[:, -1] = self.processor.tokenizer.eos_token_id | |
| return { | |
| 'input_ids': input_ids, | |
| 'labels': labels, | |
| 'input_image_embeds': inputs.input_image_embeds, | |
| 'image_attention_mask': inputs.image_attention_mask, | |
| 'image_sizes': inputs.image_sizes, | |
| } | |
| def __del__(self): | |
| __import__('shutil').rmtree(self.image_folder) | |
| class PmcVqaEvalDataset(Dataset): | |
| def __init__( | |
| self, processor, data_size, instruction=DEFAULT_INSTSRUCTION, rank=0, world_size=1 | |
| ): | |
| # Download the file | |
| file_path = hf_hub_download( | |
| repo_id='xmcmic/PMC-VQA', # repository name | |
| filename='images_2.zip', # file to download | |
| repo_type='dataset', # specify it's a dataset repo | |
| ) | |
| # file_path will be the local path where the file was downloaded | |
| print(f'File downloaded to: {file_path}') | |
| # unzip to temp folder | |
| self.image_folder = Path(tempfile.mkdtemp()) | |
| with zipfile.ZipFile(file_path, 'r') as zip_ref: | |
| zip_ref.extractall(self.image_folder) | |
| data_files = { | |
| 'test': 'https://huggingface.co/datasets/xmcmic/PMC-VQA/resolve/main/test_2.csv', | |
| } | |
| split = 'test' if data_size is None else f'test[:{data_size}]' | |
| self.annotations = load_dataset( | |
| 'xmcmic/PMC-VQA', data_files=data_files, split=split | |
| ).shard(num_shards=world_size, index=rank) | |
| self.processor = processor | |
| self.instruction = instruction | |
| def __len__(self): | |
| return len(self.annotations) | |
| def __getitem__(self, idx): | |
| """ | |
| {'index': 62, | |
| 'Figure_path': 'PMC8253867_Fig2_41.jpg', | |
| 'Caption': 'CT pulmonary angiogram reveals encasement and displacement of the left anterior descending coronary artery ( blue arrows ).', | |
| 'Question': ' What is the name of the artery encased and displaced in the image? ', | |
| 'Choice A': ' A: Right Coronary Artery ', | |
| 'Choice B': ' B: Left Anterior Descending Coronary Artery ', | |
| 'Choice C': ' C: Circumflex Coronary Artery ', | |
| 'Choice D': ' D: Superior Mesenteric Artery ', | |
| 'Answer': 'B', | |
| 'split': 'test'} | |
| """ | |
| annotation = self.annotations[idx] | |
| image = Image.open(self.image_folder / 'figures' / annotation['Figure_path']) | |
| question = annotation['Question'] | |
| choices = [annotation[f'Choice {chr(ord("A") + i)}'] for i in range(4)] | |
| user_message = { | |
| 'role': 'user', | |
| 'content': '<|image_1|>' + '\n'.join([question] + choices + [self.instruction]), | |
| } | |
| prompt = self.processor.tokenizer.apply_chat_template( | |
| [user_message], tokenize=False, add_generation_prompt=True | |
| ) | |
| answer = annotation['Answer'] | |
| inputs = self.processor(prompt, images=[image], return_tensors='pt') | |
| unique_id = f'{annotation["index"]:010d}' | |
| return { | |
| 'id': unique_id, | |
| 'input_ids': inputs.input_ids, | |
| 'input_image_embeds': inputs.input_image_embeds, | |
| 'image_attention_mask': inputs.image_attention_mask, | |
| 'image_sizes': inputs.image_sizes, | |
| 'answer': answer, | |
| } | |
| def __del__(self): | |
| __import__('shutil').rmtree(self.image_folder) | |
| def pad_sequence(sequences, padding_side='right', padding_value=0): | |
| """ | |
| Pad a list of sequences to the same length. | |
| sequences: list of tensors in [seq_len, *] shape | |
| """ | |
| assert padding_side in ['right', 'left'] | |
| max_size = sequences[0].size() | |
| trailing_dims = max_size[1:] | |
| max_len = max(len(seq) for seq in sequences) | |
| batch_size = len(sequences) | |
| output = sequences[0].new_full((batch_size, max_len) + trailing_dims, padding_value) | |
| for i, seq in enumerate(sequences): | |
| length = seq.size(0) | |
| if padding_side == 'right': | |
| output.data[i, :length] = seq | |
| else: | |
| output.data[i, -length:] = seq | |
| return output | |
| def cat_with_pad(tensors, dim, padding_value=0): | |
| """ | |
| cat along dim, while pad to max for all other dims | |
| """ | |
| ndim = tensors[0].dim() | |
| assert all( | |
| t.dim() == ndim for t in tensors[1:] | |
| ), 'All tensors must have the same number of dimensions' | |
| out_size = [max(t.shape[i] for t in tensors) for i in range(ndim)] | |
| out_size[dim] = sum(t.shape[dim] for t in tensors) | |
| output = tensors[0].new_full(out_size, padding_value) | |
| index = 0 | |
| for t in tensors: | |
| # Create a slice list where every dimension except dim is full slice | |
| slices = [slice(0, t.shape[d]) for d in range(ndim)] | |
| # Update only the concat dimension slice | |
| slices[dim] = slice(index, index + t.shape[dim]) | |
| output[slices] = t | |
| index += t.shape[dim] | |
| return output | |
| def pmc_vqa_collate_fn(batch): | |
| input_ids_list = [] | |
| labels_list = [] | |
| input_image_embeds_list = [] | |
| image_attention_mask_list = [] | |
| image_sizes_list = [] | |
| for inputs in batch: | |
| input_ids_list.append(inputs['input_ids'][0]) | |
| labels_list.append(inputs['labels'][0]) | |
| input_image_embeds_list.append(inputs['input_image_embeds']) | |
| image_attention_mask_list.append(inputs['image_attention_mask']) | |
| image_sizes_list.append(inputs['image_sizes']) | |
| input_ids = pad_sequence(input_ids_list, padding_side='right', padding_value=0) | |
| labels = pad_sequence(labels_list, padding_side='right', padding_value=0) | |
| attention_mask = (input_ids != 0).long() | |
| input_image_embeds = cat_with_pad(input_image_embeds_list, dim=0) | |
| image_attention_mask = cat_with_pad(image_attention_mask_list, dim=0) | |
| image_sizes = torch.cat(image_sizes_list) | |
| return BatchFeature( | |
| { | |
| 'input_ids': input_ids, | |
| 'labels': labels, | |
| 'attention_mask': attention_mask, | |
| 'input_image_embeds': input_image_embeds, | |
| 'image_attention_mask': image_attention_mask, | |
| 'image_sizes': image_sizes, | |
| 'input_mode': 1, # vision mode | |
| } | |
| ) | |
| def pmc_vqa_eval_collate_fn(batch): | |
| input_ids_list = [] | |
| input_image_embeds_list = [] | |
| image_attention_mask_list = [] | |
| image_sizes_list = [] | |
| all_unique_ids = [] | |
| all_answers = [] | |
| for inputs in batch: | |
| input_ids_list.append(inputs['input_ids'][0]) | |
| input_image_embeds_list.append(inputs['input_image_embeds']) | |
| image_attention_mask_list.append(inputs['image_attention_mask']) | |
| image_sizes_list.append(inputs['image_sizes']) | |
| all_unique_ids.append(inputs['id']) | |
| all_answers.append(inputs['answer']) | |
| input_ids = pad_sequence(input_ids_list, padding_side='left', padding_value=0) | |
| attention_mask = (input_ids != 0).long() | |
| input_image_embeds = cat_with_pad(input_image_embeds_list, dim=0) | |
| image_attention_mask = cat_with_pad(image_attention_mask_list, dim=0) | |
| image_sizes = torch.cat(image_sizes_list) | |
| return ( | |
| all_unique_ids, | |
| all_answers, | |
| BatchFeature( | |
| { | |
| 'input_ids': input_ids, | |
| 'attention_mask': attention_mask, | |
| 'input_image_embeds': input_image_embeds, | |
| 'image_attention_mask': image_attention_mask, | |
| 'image_sizes': image_sizes, | |
| 'input_mode': 1, # vision mode | |
| } | |
| ), | |
| ) | |
| def create_model(model_name_or_path, use_flash_attention=False): | |
| model = AutoModelForCausalLM.from_pretrained( | |
| model_name_or_path, | |
| torch_dtype=torch.bfloat16 if use_flash_attention else torch.float32, | |
| _attn_implementation='flash_attention_2' if use_flash_attention else 'sdpa', | |
| trust_remote_code=True, | |
| ).to('cuda') | |
| # remove parameters irrelevant to vision tasks | |
| del model.model.embed_tokens_extend.audio_embed # remove audio encoder | |
| for layer in model.model.layers: | |
| # remove audio lora | |
| del layer.mlp.down_proj.lora_A.speech | |
| del layer.mlp.down_proj.lora_B.speech | |
| del layer.mlp.gate_up_proj.lora_A.speech | |
| del layer.mlp.gate_up_proj.lora_B.speech | |
| del layer.self_attn.o_proj.lora_A.speech | |
| del layer.self_attn.o_proj.lora_B.speech | |
| del layer.self_attn.qkv_proj.lora_A.speech | |
| del layer.self_attn.qkv_proj.lora_B.speech | |
| # TODO remove unused vision layers? | |
| return model | |
| def evaluate( | |
| model, processor, eval_dataset, save_path=None, disable_tqdm=False, eval_batch_size=1 | |
| ): | |
| rank = int(os.environ.get('RANK', 0)) | |
| local_rank = int(os.environ.get('LOCAL_RANK', 0)) | |
| model.eval() | |
| all_answers = [] | |
| all_generated_texts = [] | |
| eval_dataloader = torch.utils.data.DataLoader( | |
| eval_dataset, | |
| batch_size=eval_batch_size, | |
| collate_fn=pmc_vqa_eval_collate_fn, | |
| shuffle=False, | |
| drop_last=False, | |
| num_workers=4, | |
| prefetch_factor=2, | |
| pin_memory=True, | |
| ) | |
| for ids, answers, inputs in tqdm( | |
| eval_dataloader, disable=(rank != 0) or disable_tqdm, desc='running eval' | |
| ): | |
| all_answers.extend({'id': i, 'answer': a.strip().lower()} for i, a in zip(ids, answers)) | |
| inputs = inputs.to(f'cuda:{local_rank}') | |
| generated_ids = model.generate( | |
| **inputs, eos_token_id=processor.tokenizer.eos_token_id, max_new_tokens=64 | |
| ) | |
| input_len = inputs.input_ids.size(1) | |
| generated_texts = processor.batch_decode( | |
| generated_ids[:, input_len:], | |
| skip_special_tokens=True, | |
| clean_up_tokenization_spaces=False, | |
| ) | |
| all_generated_texts.extend( | |
| {'id': i, 'generated_text': g.strip().lower()} for i, g in zip(ids, generated_texts) | |
| ) | |
| # gather outputs from all ranks | |
| all_answers = gather_object(all_answers) | |
| all_generated_texts = gather_object(all_generated_texts) | |
| if rank == 0: | |
| assert len(all_answers) == len(all_generated_texts) | |
| acc = sum( | |
| a['answer'] == g['generated_text'] for a, g in zip(all_answers, all_generated_texts) | |
| ) / len(all_answers) | |
| if save_path: | |
| with open(save_path, 'w') as f: | |
| save_dict = { | |
| 'answers_unique': all_answers, | |
| 'generated_texts_unique': all_generated_texts, | |
| 'accuracy': acc, | |
| } | |
| json.dump(save_dict, f) | |
| return acc | |
| return None | |
| def main(): | |
| parser = argparse.ArgumentParser() | |
| parser.add_argument( | |
| '--model_name_or_path', | |
| type=str, | |
| default='microsoft/Phi-4-multimodal-instruct', | |
| help='Model name or path to load from', | |
| ) | |
| parser.add_argument('--use_flash_attention', action='store_true', help='Use Flash Attention') | |
| parser.add_argument('--output_dir', type=str, default='./output/', help='Output directory') | |
| parser.add_argument('--batch_size', type=int, default=16, help='Batch size') | |
| parser.add_argument( | |
| '--batch_size_per_gpu', | |
| type=int, | |
| default=1, | |
| help='Batch size per GPU (adjust this to fit in GPU memory)', | |
| ) | |
| parser.add_argument( | |
| '--dynamic_hd', | |
| type=int, | |
| default=36, | |
| help='Number of maximum image crops', | |
| ) | |
| parser.add_argument( | |
| '--num_train_epochs', type=int, default=1, help='Number of training epochs' | |
| ) | |
| parser.add_argument('--learning_rate', type=float, default=4.0e-5, help='Learning rate') | |
| parser.add_argument('--wd', type=float, default=0.01, help='Weight decay') | |
| parser.add_argument('--no_tqdm', dest='tqdm', action='store_false', help='Disable tqdm') | |
| parser.add_argument('--full_run', action='store_true', help='Run the full training and eval') | |
| args = parser.parse_args() | |
| accelerator = Accelerator() | |
| with accelerator.local_main_process_first(): | |
| processor = AutoProcessor.from_pretrained( | |
| args.model_name_or_path, | |
| trust_remote_code=True, | |
| dynamic_hd=args.dynamic_hd, | |
| ) | |
| model = create_model( | |
| args.model_name_or_path, | |
| use_flash_attention=args.use_flash_attention, | |
| ) | |
| # tune vision encoder and lora | |
| model.set_lora_adapter('vision') | |
| for param in model.model.embed_tokens_extend.image_embed.parameters(): | |
| param.requires_grad = True | |
| rank = int(os.environ.get('RANK', 0)) | |
| world_size = int(os.environ.get('WORLD_SIZE', 1)) | |
| train_dataset = PmcVqaTrainDataset(processor, data_size=None if args.full_run else _TRAIN_SIZE) | |
| eval_dataset = PmcVqaEvalDataset( | |
| processor, | |
| data_size=None if args.full_run else _EVAL_SIZE, | |
| rank=rank, | |
| world_size=world_size, | |
| ) | |
| num_gpus = accelerator.num_processes | |
| print(f'training on {num_gpus} GPUs') | |
| assert ( | |
| args.batch_size % (num_gpus * args.batch_size_per_gpu) == 0 | |
| ), 'Batch size must be divisible by the number of GPUs' | |
| gradient_accumulation_steps = args.batch_size // (num_gpus * args.batch_size_per_gpu) | |
| if args.use_flash_attention: | |
| fp16 = False | |
| bf16 = True | |
| else: | |
| fp16 = True | |
| bf16 = False | |
| # hard coded training args | |
| training_args = TrainingArguments( | |
| num_train_epochs=args.num_train_epochs, | |
| per_device_train_batch_size=args.batch_size_per_gpu, | |
| gradient_checkpointing=True, | |
| gradient_checkpointing_kwargs={'use_reentrant': False}, | |
| gradient_accumulation_steps=gradient_accumulation_steps, | |
| optim='adamw_torch', | |
| adam_beta1=0.9, | |
| adam_beta2=0.95, | |
| adam_epsilon=1e-7, | |
| learning_rate=args.learning_rate, | |
| weight_decay=args.wd, | |
| max_grad_norm=1.0, | |
| lr_scheduler_type='linear', | |
| warmup_steps=50, | |
| logging_steps=10, | |
| output_dir=args.output_dir, | |
| save_strategy='no', | |
| save_total_limit=10, | |
| save_only_model=True, | |
| bf16=bf16, | |
| fp16=fp16, | |
| remove_unused_columns=False, | |
| report_to='none', | |
| deepspeed=None, | |
| disable_tqdm=not args.tqdm, | |
| dataloader_num_workers=4, | |
| ddp_find_unused_parameters=True, # for unused SigLIP layers | |
| ) | |
| # eval before fine-tuning | |
| out_path = Path(training_args.output_dir) | |
| out_path.mkdir(parents=True, exist_ok=True) | |
| acc = evaluate( | |
| model, | |
| processor, | |
| eval_dataset, | |
| save_path=out_path / 'eval_before.json', | |
| disable_tqdm=not args.tqdm, | |
| eval_batch_size=args.batch_size_per_gpu, | |
| ) | |
| if accelerator.is_main_process: | |
| print(f'Accuracy before finetuning: {acc}') | |
| trainer = Trainer( | |
| model=model, | |
| args=training_args, | |
| data_collator=pmc_vqa_collate_fn, | |
| train_dataset=train_dataset, | |
| ) | |
| trainer.train() | |
| trainer.save_model() | |
| accelerator.wait_for_everyone() | |
| # eval after fine-tuning (load saved checkpoint) | |
| # first try to clear GPU memory | |
| del model | |
| del trainer | |
| __import__('gc').collect() | |
| torch.cuda.empty_cache() | |
| # reload the model for inference | |
| model = AutoModelForCausalLM.from_pretrained( | |
| training_args.output_dir, | |
| torch_dtype=torch.bfloat16 if args.use_flash_attention else torch.float32, | |
| trust_remote_code=True, | |
| _attn_implementation='flash_attention_2' if args.use_flash_attention else 'sdpa', | |
| ).to('cuda') | |
| acc = evaluate( | |
| model, | |
| processor, | |
| eval_dataset, | |
| save_path=out_path / 'eval_after.json', | |
| disable_tqdm=not args.tqdm, | |
| eval_batch_size=args.batch_size_per_gpu, | |
| ) | |
| if accelerator.is_main_process: | |
| print(f'Accuracy after finetuning: {acc}') | |
| if __name__ == '__main__': | |
| main() |