from typing import List, Optional, Tuple, Type import pytest from vllm.multimodal.utils import rescale_image_size from vllm.sequence import SampleLogprobs from vllm.utils import is_cpu from ..conftest import IMAGE_ASSETS, HfRunner, VllmRunner, _ImageAssets from .utils import check_logprobs_close pytestmark = pytest.mark.vlm HF_IMAGE_PROMPTS = IMAGE_ASSETS.prompts({ "stop_sign": "What's the content of the image?\n", "cherry_blossom": "What is the season?\n", }) models = ["adept/fuyu-8b"] def vllm_to_hf_output(vllm_output: Tuple[List[int], str, Optional[SampleLogprobs]]): """Sanitize vllm output to be comparable with hf output.""" output_ids, output_str, out_logprobs = vllm_output hf_output_str = output_str.lstrip() + "|ENDOFTEXT|" return output_ids, hf_output_str, out_logprobs def run_test( hf_runner: Type[HfRunner], vllm_runner: Type[VllmRunner], image_assets: _ImageAssets, model: str, *, size_factors: List[float], dtype: str, max_tokens: int, num_logprobs: int, tensor_parallel_size: int, distributed_executor_backend: Optional[str] = None, ): """Inference result should be the same between hf and vllm. All the image fixtures for the test is under tests/images. For huggingface runner, we provide the PIL images as input. For vllm runner, we provide MultiModalDataDict objects and corresponding vision language config as input. Note, the text input is also adjusted to abide by vllm contract. The text output is sanitized to be able to compare with hf. """ images = [asset.pil_image for asset in image_assets] inputs_per_image = [( [prompt for _ in size_factors], [rescale_image_size(image, factor) for factor in size_factors], ) for image, prompt in zip(images, HF_IMAGE_PROMPTS)] # NOTE: take care of the order. run vLLM first, and then run HF. # vLLM needs a fresh new process without cuda initialization. # if we run HF first, the cuda initialization will be done and it # will hurt multiprocessing backend with fork method (the default method). # max_model_len should be greater than image_feature_size with vllm_runner(model, max_model_len=2560, max_num_seqs=1, dtype=dtype, tensor_parallel_size=tensor_parallel_size, distributed_executor_backend=distributed_executor_backend, enforce_eager=True) as vllm_model: vllm_outputs_per_image = [ vllm_model.generate_greedy_logprobs(prompts, max_tokens, num_logprobs=num_logprobs, images=vllm_images) for prompts, vllm_images in inputs_per_image ] with hf_runner(model, dtype=dtype) as hf_model: hf_model.model.get_output_embeddings = lambda: \ hf_model.model.language_model.get_output_embeddings() eos_token_id = hf_model.processor.tokenizer.eos_token_id hf_outputs_per_image = [ hf_model.generate_greedy_logprobs_limit(prompts, max_tokens, num_logprobs=num_logprobs, images=hf_images, eos_token_id=eos_token_id) for prompts, hf_images in inputs_per_image ] for hf_outputs, vllm_outputs in zip(hf_outputs_per_image, vllm_outputs_per_image): check_logprobs_close( outputs_0_lst=hf_outputs, outputs_1_lst=[ vllm_to_hf_output(vllm_output) for vllm_output in vllm_outputs ], name_0="hf", name_1="vllm", ) target_dtype = "half" if is_cpu(): target_dtype = "bfloat16" @pytest.mark.parametrize("model", models) @pytest.mark.parametrize( "size_factors", [ # No image [], # Single-scale [0.25], # Single-scale, batched [0.25, 0.25, 0.25], # Multi-scale [0.25, 0.2, 0.15], ], ) @pytest.mark.parametrize("dtype", [target_dtype]) @pytest.mark.parametrize("max_tokens", [128]) @pytest.mark.parametrize("num_logprobs", [10]) def test_models(hf_runner, vllm_runner, image_assets, model, size_factors, dtype: str, max_tokens: int, num_logprobs: int) -> None: run_test( hf_runner, vllm_runner, image_assets, model, size_factors=size_factors, dtype=dtype, max_tokens=max_tokens, num_logprobs=num_logprobs, tensor_parallel_size=1, )