# coding=utf-8 # Copyright 2024 Microsoft and The HuggingFace Inc. team. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. """ Processor class for Florence-2. """ import re import logging from typing import List, Optional, Union import numpy as np import torch from transformers.feature_extraction_utils import BatchFeature from transformers.image_utils import ImageInput, is_valid_image from transformers.processing_utils import ProcessorMixin from transformers.tokenization_utils_base import ( PaddingStrategy, PreTokenizedInput, TextInput, TruncationStrategy, ) from transformers.utils import TensorType logger = logging.getLogger(__name__) # Copied from transformers.models.idefics2.processing_idefics2.is_url def is_url(val) -> bool: return isinstance(val, str) and val.startswith("http") # Copied from transformers.models.idefics2.processing_idefics2.is_image_or_image_url def is_image_or_image_url(elem): return is_url(elem) or is_valid_image(elem) def _is_str_or_image(elem): return isinstance(elem, (str)) or is_image_or_image_url(elem) class Florence2Processor(ProcessorMixin): r""" Constructs a Florence2 processor which wraps a Florence2 image processor and a Florence2 tokenizer into a single processor. [`Florence2Processor`] offers all the functionalities of [`CLIPImageProcessor`] and [`BartTokenizerFast`]. See the [`~Florence2Processor.__call__`] and [`~Florence2Processor.decode`] for more information. Args: image_processor ([`CLIPImageProcessor`], *optional*): The image processor is a required input. tokenizer ([`BartTokenizerFast`], *optional*): The tokenizer is a required input. """ attributes = ["image_processor", "tokenizer"] image_processor_class = "CLIPImageProcessor" tokenizer_class = ("BartTokenizer", "BartTokenizerFast") def __init__( self, image_processor=None, tokenizer=None, ): if image_processor is None: raise ValueError("You need to specify an `image_processor`.") if tokenizer is None: raise ValueError("You need to specify a `tokenizer`.") if not hasattr(image_processor, "image_seq_length"): raise ValueError("Image processor is missing an `image_seq_length` attribute.") self.image_seq_length = image_processor.image_seq_length tokens_to_add = { 'additional_special_tokens': \ tokenizer.additional_special_tokens + \ ['', '', '', ''] + \ [f'' for x in range(1000)] + \ ['', '', '', '','', '', '', '', '', '', '', '', '', '', '', '', '', '', '', ''] } tokenizer.add_special_tokens(tokens_to_add) self.tasks_answer_post_processing_type = { '': 'pure_text', '': 'ocr', '': 'pure_text', '': 'pure_text', '': 'pure_text', '': 'description_with_bboxes', '': 'description_with_bboxes', '': "phrase_grounding", '': 'polygons', '': 'polygons', '': 'description_with_bboxes_or_polygons', '': 'pure_text', '': 'pure_text', '': 'pure_text', '': 'bboxes' } self.task_prompts_without_inputs = { '': 'What is the text in the image?', '': 'What is the text in the image, with regions?', '': 'What does the image describe?', '': 'Describe in detail what is shown in the image.', '': 'Describe with a paragraph what is shown in the image.', '': 'Locate the objects with category name in the image.', '': 'Locate the objects in the image, with their descriptions.', '': 'Locate the region proposals in the image.' } self.task_prompts_with_input = { '': "Locate the phrases in the caption: {input}", '': 'Locate {input} in the image with mask', '': 'What is the polygon mask of region {input}', '': 'Locate {input} in the image.', '': 'What is the region {input}?', '': 'What does the region {input} describe?', '': 'What text is in the region {input}?', } self.image_mean = image_processor.image_mean self.image_std = image_processor.image_std self.crop_size = image_processor.crop_size self.post_processor = Florence2PostProcesser(tokenizer=tokenizer) super().__init__(image_processor, tokenizer) def _construct_prompts(self, text): # replace the task tokens with the task prompts if task token is in the text prompts = [] for _text in text: # 1. fixed task prompts without additional inputs for task_token, task_prompt in self.task_prompts_without_inputs.items(): if task_token in _text: assert _text == task_token, f"Task token {task_token} should be the only token in the text." _text = task_prompt break # 2. task prompts with additional inputs for task_token, task_prompt in self.task_prompts_with_input.items(): if task_token in _text: _text = task_prompt.format(input=_text.replace(task_token, '')) break prompts.append(_text) return prompts def __call__( self, text: Union[TextInput, PreTokenizedInput, List[TextInput], List[PreTokenizedInput]] = None, images: ImageInput = None, tokenize_newline_separately: bool = True, padding: Union[bool, str, PaddingStrategy] = False, truncation: Union[bool, str, TruncationStrategy] = None, max_length=None, return_tensors: Optional[Union[str, TensorType]] = TensorType.PYTORCH, do_resize: bool = None, do_normalize: bool = None, image_mean: Optional[Union[float, List[float]]] = None, image_std: Optional[Union[float, List[float]]] = None, data_format: Optional["ChannelDimension"] = "channels_first", # noqa: F821 input_data_format: Optional[ Union[str, "ChannelDimension"] # noqa: F821 ] = None, resample: "PILImageResampling" = None, # noqa: F821 do_convert_rgb: bool = None, do_thumbnail: bool = None, do_align_long_axis: bool = None, do_rescale: bool = None, ) -> BatchFeature: """ Main method to prepare for the model one or several sequences(s) and image(s). This method forwards the `text` and `kwargs` arguments to BartTokenizerFast's [`~BartTokenizerFast.__call__`] if `text` is not `None` to encode the text. To prepare the image(s), this method forwards the `images` and `kwrags` arguments to CLIPImageProcessor's [`~CLIPImageProcessor.__call__`] if `images` is not `None`. Please refer to the doctsring of the above two methods for more information. Args: text (`str`, `List[str]`, `List[List[str]]`): The sequence or batch of sequences to be encoded. Each sequence can be a string or a list of strings (pretokenized string). If the sequences are provided as list of strings (pretokenized), you must set `is_split_into_words=True` (to lift the ambiguity with a batch of sequences). images (`PIL.Image.Image`, `np.ndarray`, `torch.Tensor`, `List[PIL.Image.Image]`, `List[np.ndarray]`, `List[torch.Tensor]`): The image or batch of images to be prepared. Each image can be a PIL image, NumPy array or PyTorch tensor. In case of a NumPy array/PyTorch tensor, each image should be of shape (C, H, W), where C is a number of channels, H and W are image height and width. tokenize_newline_separately (`bool`, defaults to `True`): Adds a separately tokenized '\n' at the end of the prompt. padding (`bool`, `str` or [`~utils.PaddingStrategy`], *optional*, defaults to `False`): Select a strategy to pad the returned sequences (according to the model's padding side and padding index) among: - `True` or `'longest'`: Pad to the longest sequence in the batch (or no padding if only a single sequence if provided). - `'max_length'`: Pad to a maximum length specified with the argument `max_length` or to the maximum acceptable input length for the model if that argument is not provided. - `False` or `'do_not_pad'` (default): No padding (i.e., can output a batch with sequences of different lengths). max_length (`int`, *optional*): Maximum length of the returned list and optionally padding length (see above). truncation (`bool`, *optional*): Activates truncation to cut input sequences longer than `max_length` to `max_length`. return_tensors (`str` or [`~utils.TensorType`], *optional*): If set, will return tensors of a particular framework. Acceptable values are: - `'tf'`: Return TensorFlow `tf.constant` objects. - `'pt'`: Return PyTorch `torch.Tensor` objects. - `'np'`: Return NumPy `np.ndarray` objects. - `'jax'`: Return JAX `jnp.ndarray` objects. Returns: [`BatchFeature`]: A [`BatchFeature`] with the following fields: - **input_ids** -- List of token ids to be fed to a model. Returned when `text` is not `None`. If `suffix` is provided, the `input_ids` will also contain the suffix input ids. - **attention_mask** -- List of indices specifying which tokens should be attended to by the model (when `return_attention_mask=True` or if *"attention_mask"* is in `self.model_input_names` and if `text` is not `None`). - **pixel_values** -- Pixel values to be fed to a model. Returned when `images` is not `None`. - **labels** -- Labels compatible with training if `suffix` is not None """ return_token_type_ids = False if images is None: raise ValueError("`images` are expected as arguments to a `Florence2Processor` instance.") if text is None: logger.warning_once( "You are using Florence-2 without a text prompt." ) text = "" if isinstance(text, List) and isinstance(images, List): if len(images) < len(text): raise ValueError( f"Received {len(images)} images for {len(text)} prompts. Each prompt should be associated with an image." ) if _is_str_or_image(text): text = [text] elif isinstance(text, list) and _is_str_or_image(text[0]): pass try: pixel_values = self.image_processor( images, do_resize=do_resize, do_normalize=do_normalize, return_tensors=return_tensors, image_mean=image_mean, image_std=image_std, input_data_format=input_data_format, data_format=data_format, resample=resample, do_convert_rgb=do_convert_rgb, )["pixel_values"] except ValueError as e: try: pixel_values = self.image_processor( images, do_resize=do_resize, do_normalize=do_normalize, return_tensors=return_tensors, image_mean=image_mean[1], image_std=image_std[1], input_data_format=input_data_format, data_format=data_format, resample=resample, do_convert_rgb=do_convert_rgb, )["pixel_values"] print("Grayscale processing succeeded") except ValueError as e: print(f"Grayscale processing failed: {e}") # pixel_values = self.image_processor( # images, # do_resize=do_resize, # do_normalize=do_normalize, # return_tensors=return_tensors, # image_mean=image_mean, # image_std=image_std, # input_data_format=input_data_format, # data_format=data_format, # resample=resample, # do_convert_rgb=do_convert_rgb, # )["pixel_values"] if max_length is not None: max_length -= self.image_seq_length # max_length has to account for the image tokens text = self._construct_prompts(text) inputs = self.tokenizer( text, return_tensors=return_tensors, padding=padding, max_length=max_length, truncation=truncation, return_token_type_ids=return_token_type_ids, ) return_data = {**inputs, "pixel_values": pixel_values} if return_token_type_ids: labels = inputs["input_ids"].masked_fill(inputs["token_type_ids"] == 0, -100) return_data.update({"labels": labels}) return BatchFeature(data=return_data) # Copied from transformers.models.clip.processing_clip.CLIPProcessor.batch_decode with CLIP->Florence2 def batch_decode(self, *args, **kwargs): """ This method forwards all its arguments to BartTokenizerFast's [`~PreTrainedTokenizer.batch_decode`]. Please refer to the docstring of this method for more information. """ return self.tokenizer.batch_decode(*args, **kwargs) # Copied from transformers.models.clip.processing_clip.CLIPProcessor.decode with CLIP->Florence2 def decode(self, *args, **kwargs): """ This method forwards all its arguments to BartTokenizerFast's [`~PreTrainedTokenizer.decode`]. Please refer to the docstring of this method for more information. """ return self.tokenizer.decode(*args, **kwargs) @property # Copied from transformers.models.clip.processing_clip.CLIPProcessor.model_input_names with CLIP->Florence2 def model_input_names(self): tokenizer_input_names = self.tokenizer.model_input_names image_processor_input_names = self.image_processor.model_input_names return list(dict.fromkeys(tokenizer_input_names + image_processor_input_names)) def post_process_generation(self, text, task, image_size): """ Post-process the output of the model to each of the task outputs. Args: text (`str`): The text to post-process. task (`str`): The task to post-process the text for. image_size (`Tuple[int, int]`): The size of the image. height x width. """ task_answer_post_processing_type = self.tasks_answer_post_processing_type.get(task, 'pure_text') task_answer = self.post_processor( text=text, image_size=image_size, parse_tasks=task_answer_post_processing_type, )[task_answer_post_processing_type] if task_answer_post_processing_type == 'pure_text': final_answer = task_answer # remove the special tokens final_answer = final_answer.replace('', '').replace('', '') elif task_answer_post_processing_type in ['od', 'description_with_bboxes', 'bboxes']: od_instances = task_answer bboxes_od = [_od_instance['bbox'] for _od_instance in od_instances] labels_od = [str(_od_instance['cat_name']) for _od_instance in od_instances] final_answer = {'bboxes': bboxes_od, 'labels': labels_od} elif task_answer_post_processing_type in ['ocr']: bboxes = [_od_instance['quad_box'] for _od_instance in task_answer] labels = [str(_od_instance['text']) for _od_instance in task_answer] final_answer = {'quad_boxes': bboxes, 'labels': labels} elif task_answer_post_processing_type in ['phrase_grounding']: bboxes = [] labels = [] for _grounded_phrase in task_answer: for _bbox in _grounded_phrase['bbox']: bboxes.append(_bbox) labels.append(_grounded_phrase['cat_name']) final_answer = {'bboxes': bboxes, 'labels': labels} elif task_answer_post_processing_type in ['description_with_polygons', 'polygons']: labels = [] polygons = [] for result in task_answer: label = result['cat_name'] _polygons = result['polygons'] labels.append(label) polygons.append(_polygons) final_answer = {'polygons': polygons, 'labels': labels} elif task_answer_post_processing_type in ['description_with_bboxes_or_polygons']: bboxes = [] bboxes_labels = [] polygons = [] polygons_labels = [] for result in task_answer: label = result['cat_name'] if 'polygons' in result: _polygons = result['polygons'] polygons.append(_polygons) polygons_labels.append(label) else: _bbox = result['bbox'] bboxes.append(_bbox) bboxes_labels.append(label) final_answer = {'bboxes': bboxes, 'bboxes_labels': bboxes_labels, 'polygons': polygons, 'polygons_labels': polygons_labels} else: raise ValueError('Unknown task answer post processing type: {}'.format(task_answer_post_processing_type)) final_answer = { task: final_answer} return final_answer class BoxQuantizer(object): def __init__(self, mode, bins): self.mode = mode self.bins = bins def quantize(self, boxes: torch.Tensor, size): bins_w, bins_h = self.bins # Quantization bins. size_w, size_h = size # Original image size. size_per_bin_w = size_w / bins_w size_per_bin_h = size_h / bins_h xmin, ymin, xmax, ymax = boxes.split(1, dim=-1) # Shape: 4 * [N, 1]. if self.mode == 'floor': quantized_xmin = ( xmin / size_per_bin_w).floor().clamp(0, bins_w - 1) quantized_ymin = ( ymin / size_per_bin_h).floor().clamp(0, bins_h - 1) quantized_xmax = ( xmax / size_per_bin_w).floor().clamp(0, bins_w - 1) quantized_ymax = ( ymax / size_per_bin_h).floor().clamp(0, bins_h - 1) elif self.mode == 'round': raise NotImplementedError() else: raise ValueError('Incorrect quantization type.') quantized_boxes = torch.cat( (quantized_xmin, quantized_ymin, quantized_xmax, quantized_ymax), dim=-1 ).int() return quantized_boxes def dequantize(self, boxes: torch.Tensor, size): bins_w, bins_h = self.bins # Quantization bins. size_w, size_h = size # Original image size. size_per_bin_w = size_w / bins_w size_per_bin_h = size_h / bins_h xmin, ymin, xmax, ymax = boxes.split(1, dim=-1) # Shape: 4 * [N, 1]. if self.mode == 'floor': # Add 0.5 to use the center position of the bin as the coordinate. dequantized_xmin = (xmin + 0.5) * size_per_bin_w dequantized_ymin = (ymin + 0.5) * size_per_bin_h dequantized_xmax = (xmax + 0.5) * size_per_bin_w dequantized_ymax = (ymax + 0.5) * size_per_bin_h elif self.mode == 'round': raise NotImplementedError() else: raise ValueError('Incorrect quantization type.') dequantized_boxes = torch.cat( (dequantized_xmin, dequantized_ymin, dequantized_xmax, dequantized_ymax), dim=-1 ) return dequantized_boxes class CoordinatesQuantizer(object): """ Quantize coornidates (Nx2) """ def __init__(self, mode, bins): self.mode = mode self.bins = bins def quantize(self, coordinates: torch.Tensor, size): bins_w, bins_h = self.bins # Quantization bins. size_w, size_h = size # Original image size. size_per_bin_w = size_w / bins_w size_per_bin_h = size_h / bins_h assert coordinates.shape[-1] == 2, 'coordinates should be shape (N, 2)' x, y = coordinates.split(1, dim=-1) # Shape: 4 * [N, 1]. if self.mode == 'floor': quantized_x = (x / size_per_bin_w).floor().clamp(0, bins_w - 1) quantized_y = (y / size_per_bin_h).floor().clamp(0, bins_h - 1) elif self.mode == 'round': raise NotImplementedError() else: raise ValueError('Incorrect quantization type.') quantized_coordinates = torch.cat( (quantized_x, quantized_y), dim=-1 ).int() return quantized_coordinates def dequantize(self, coordinates: torch.Tensor, size): bins_w, bins_h = self.bins # Quantization bins. size_w, size_h = size # Original image size. size_per_bin_w = size_w / bins_w size_per_bin_h = size_h / bins_h assert coordinates.shape[-1] == 2, 'coordinates should be shape (N, 2)' x, y = coordinates.split(1, dim=-1) # Shape: 4 * [N, 1]. if self.mode == 'floor': # Add 0.5 to use the center position of the bin as the coordinate. dequantized_x = (x + 0.5) * size_per_bin_w dequantized_y = (y + 0.5) * size_per_bin_h elif self.mode == 'round': raise NotImplementedError() else: raise ValueError('Incorrect quantization type.') dequantized_coordinates = torch.cat( (dequantized_x, dequantized_y), dim=-1 ) return dequantized_coordinates class Florence2PostProcesser(object): """ Florence-2 post process for converting text prediction to various tasks results. Args: config: A dict of configs. tokenizer: A tokenizer for decoding text to spans. sample config: UNIFIED_POST_PROCESS: # commom configs NUM_BBOX_HEIGHT_BINS: 1000 NUM_BBOX_WIDTH_BINS: 1000 COORDINATES_HEIGHT_BINS: 1000 COORDINATES_WIDTH_BINS: 1000 # task specific configs, override the common configs PRASE_TASKS: - TASK_NAME: 'video_dense_caption' PATTERN: 'r([a-zA-Z0-9 ]+)' SCORE_MODE: 'avg_cat_name_scores' NUM_BINS: 100 - TASK_NAME: 'od' PATTERN: 'r([a-zA-Z0-9 ]+)' SCORE_MODE: 'avg_cat_name_scores' Returns: parsed_dict (dict): A dict of parsed results. """ def __init__( self, tokenizer=None ): parse_tasks = [] parse_task_configs = {} config = self._create_default_config() for task in config['PARSE_TASKS']: parse_tasks.append(task['TASK_NAME']) parse_task_configs[task['TASK_NAME']] = task self.config = config self.parse_tasks = parse_tasks self.parse_tasks_configs = parse_task_configs self.tokenizer = tokenizer if self.tokenizer is not None: self.all_special_tokens = set(self.tokenizer.all_special_tokens) self.init_quantizers() self.black_list_of_phrase_grounding = self._create_black_list_of_phrase_grounding() def _create_black_list_of_phrase_grounding(self): black_list = {} if 'phrase_grounding' in self.parse_tasks and self.parse_tasks_configs['phrase_grounding']['FILTER_BY_BLACK_LIST']: black_list = set( ['it', 'I', 'me', 'mine', 'you', 'your', 'yours', 'he', 'him', 'his', 'she', 'her', 'hers', 'they', 'them', 'their', 'theirs', 'one', 'oneself', 'we', 'us', 'our', 'ours', 'you', 'your', 'yours', 'they', 'them', 'their', 'theirs', 'mine', 'yours', 'his', 'hers', 'its', 'ours', 'yours', 'theirs', 'myself', 'yourself', 'himself', 'herself', 'itself', 'ourselves', 'yourselves', 'themselves', 'this', 'that', 'these', 'those', 'who', 'whom', 'whose', 'which', 'what', 'who', 'whom', 'whose', 'which', 'that', 'all', 'another', 'any', 'anybody', 'anyone', 'anything', 'each', 'everybody', 'everyone', 'everything', 'few', 'many', 'nobody', 'none', 'one', 'several', 'some', 'somebody', 'someone', 'something', 'each other', 'one another', 'myself', 'yourself', 'himself', 'herself', 'itself', 'ourselves', 'yourselves', 'themselves', 'the image', 'image', 'images', 'the', 'a', 'an', 'a group', 'other objects', 'lots', 'a set', ] ) return black_list def _create_default_config(self): config = { 'NUM_BBOX_HEIGHT_BINS': 1000, 'NUM_BBOX_WIDTH_BINS': 1000, 'BOX_QUANTIZATION_MODE': 'floor', 'COORDINATES_HEIGHT_BINS': 1000, 'COORDINATES_WIDTH_BINS': 1000, 'COORDINATES_QUANTIZATION_MODE': 'floor', 'PARSE_TASKS': [ { 'TASK_NAME': 'od', 'PATTERN': r'([a-zA-Z0-9 ]+)' }, { 'TASK_NAME': 'ocr', 'PATTERN': r'(.+?)', 'AREA_THRESHOLD': 0.01 }, { 'TASK_NAME': 'phrase_grounding', 'FILTER_BY_BLACK_LIST': True }, { 'TASK_NAME': 'pure_text', }, { 'TASK_NAME': 'description_with_bboxes', }, { 'TASK_NAME': 'description_with_polygons', }, { 'TASK_NAME': 'polygons', }, { 'TASK_NAME': 'bboxes', }, { 'TASK_NAME': 'description_with_bboxes_or_polygons', } ] } return config def init_quantizers(self): # we have box_quantizer (od, grounding) and coordinates_quantizer (ocr, referring_segmentation) num_bbox_height_bins = self.config.get('NUM_BBOX_HEIGHT_BINS', 1000) num_bbox_width_bins = self.config.get('NUM_BBOX_WIDTH_BINS', 1000) box_quantization_mode = self.config.get('BOX_QUANTIZATION_MODE', 'floor') self.box_quantizer = BoxQuantizer( box_quantization_mode, (num_bbox_width_bins, num_bbox_height_bins), ) num_bbox_height_bins = self.config['COORDINATES_HEIGHT_BINS'] if 'COORDINATES_HEIGHT_BINS' in self.config else self.config.get('NUM_BBOX_HEIGHT_BINS', 1000) num_bbox_width_bins = self.config['COORDINATES_WIDTH_BINS'] if 'COORDINATES_WIDTH_BINS' in self.config else self.config.get('NUM_BBOX_WIDTH_BINS', 1000) box_quantization_mode = self.config.get('COORDINATES_QUANTIZATION_MODE') if 'COORDINATES_QUANTIZATION_MODE' in self.config else self.config.get('BOX_QUANTIZATION_MODE', 'floor') self.coordinates_quantizer = CoordinatesQuantizer( box_quantization_mode, (num_bbox_width_bins, num_bbox_height_bins), ) def decode_with_spans(self, tokenizer, token_ids): filtered_tokens = tokenizer.convert_ids_to_tokens( token_ids, skip_special_tokens=False) assert len(filtered_tokens) == len(token_ids) # To avoid mixing byte-level and unicode for byte-level BPT # we need to build string separately for added tokens and byte-level tokens # cf. https://github.com/huggingface/transformers/issues/1133 sub_texts = [] for token in filtered_tokens: if token in self.all_special_tokens: sub_texts.append(token) else: if isinstance(tokenizer, (BartTokenizer, BartTokenizerFast)): sub_text = tokenizer.convert_tokens_to_string([token]) elif isinstance(tokenizer, (T5Tokenizer, T5TokenizerFast)): # Ref: https://github.com/google/sentencepiece#whitespace-is-treated-as-a-basic-symbol # Note: Do not strip sub_text as it may have functional whitespace sub_text = token.replace('▁', ' ') else: raise ValueError(f'type {type(tokenizer)} not supported') sub_texts.append(sub_text) text = '' spans = [] for sub_text in sub_texts: span = (len(text), len(text) + len(sub_text)) # [start index, end index). text += sub_text spans.append(span) # Text format: # 1. T5Tokenizer/T5TokenizerFast: # " transplanting dog cat" # Equivalent to t5_tokenizer.decode(input_ids, skip_special_tokens=False, clean_up_tokenization_spaces=False, spaces_between_special_tokens=False) # 2. BartTokenizer (need to double check): # "transplanting dogcat" # Equivalent to bart_tokenizer.decode(input_ids, skip_special_tokens=False, clean_up_tokenization_spaces=False, spaces_between_special_tokens=False) return text, spans def parse_od_from_text_and_spans( self, text, pattern, image_size, phrase_centric=False ): parsed = list(re.finditer(pattern, text)) instances = [] for i in range(len(parsed)): # Prepare instance. instance = {} if phrase_centric: bbox_bins = [int(parsed[i].group(j)) for j in range(2, 6)] else: bbox_bins = [int(parsed[i].group(j)) for j in range(1, 5)] instance['bbox'] = self.box_quantizer.dequantize( boxes=torch.tensor(bbox_bins), size=image_size ).tolist() if phrase_centric: instance['cat_name'] = parsed[i].group(1).lower().strip() else: instance['cat_name'] = parsed[i].group(5).lower().strip() instances.append(instance) return instances def parse_ocr_from_text_and_spans(self, text, pattern, image_size, area_threshold=-1.0, ): bboxes = [] labels = [] text = text.replace('', '') # ocr with regions parsed = re.findall(pattern, text) instances = [] image_width, image_height = image_size for ocr_line in parsed: ocr_content = ocr_line[0] quad_box = ocr_line[1:] quad_box = [int(i) for i in quad_box] quad_box = self.coordinates_quantizer.dequantize( torch.tensor(np.array(quad_box).reshape(-1, 2)), size=image_size ).reshape(-1).tolist() if area_threshold > 0: x_coords = [i for i in quad_box[0::2]] y_coords = [i for i in quad_box[1::2]] # apply the Shoelace formula area = 0.5 * abs(sum(x_coords[i] * y_coords[i + 1] - x_coords[i + 1] * y_coords[i] for i in range(4 - 1))) if area < (image_width * image_height) * area_threshold: continue bboxes.append(quad_box) labels.append(ocr_content) instances.append({ 'quad_box': quad_box, 'text': ocr_content, }) return instances def parse_phrase_grounding_from_text_and_spans(self, text, pattern, image_size): # ignore and cur_span = 0 if text.startswith(''): cur_span += 3 text = text.replace('', '') text = text.replace('', '') text = text.replace('', '') pattern = r"([^<]+(?:){4,})" phrases = re.findall(pattern, text) # pattern should be text pattern and od pattern pattern = r'^\s*(.*?)(?=||||||' instances = [] for pharse_text in phrases: phrase_text_strip = pharse_text.replace('', '', 1) phrase_text_strip = pharse_text.replace('', '', 1) if phrase_text_strip == '': cur_span += len(pharse_text) continue # Prepare instance. instance = {} # parse phrase, get string phrase = re.search(pattern, phrase_text_strip) if phrase is None: cur_span += len(pharse_text) continue # parse bboxes by box_pattern bboxes_parsed = list(re.finditer(box_pattern, pharse_text)) if len(bboxes_parsed) == 0: cur_span += len(pharse_text) continue phrase = phrase.group() # remove leading and trailing spaces phrase = phrase.strip() if phrase in self.black_list_of_phrase_grounding: cur_span += len(pharse_text) continue # a list of list bbox_bins = [[int(_bboxes_parsed.group(j)) for j in range(1, 5)] for _bboxes_parsed in bboxes_parsed] instance['bbox'] = self.box_quantizer.dequantize( boxes=torch.tensor(bbox_bins), size=image_size ).tolist() # exclude non-ascii characters phrase = phrase.encode('ascii',errors='ignore').decode('ascii') instance['cat_name'] = phrase instances.append(instance) return instances def parse_description_with_bboxes_from_text_and_spans(self, text, pattern, image_size, allow_empty_phrase=False): # temporary parse solution, split by '.' # ignore and text = text.replace('', '') text = text.replace('', '') text = text.replace('', '') if allow_empty_phrase: pattern = rf"(?:(?:){{4,}})" else: pattern = r"([^<]+(?:){4,})" phrases = re.findall(pattern, text) # pattern should be text pattern and od pattern pattern = r'^\s*(.*?)(?=||||||' instances = [] for pharse_text in phrases: phrase_text_strip = pharse_text.replace('', '', 1) phrase_text_strip = pharse_text.replace('', '', 1) if phrase_text_strip == '' and not allow_empty_phrase: continue # parse phrase, get string phrase = re.search(pattern, phrase_text_strip) if phrase is None: continue phrase = phrase.group() # remove leading and trailing spaces phrase = phrase.strip() # parse bboxes by box_pattern bboxes_parsed = list(re.finditer(box_pattern, pharse_text)) if len(bboxes_parsed) == 0: continue # a list of list bbox_bins = [[int(_bboxes_parsed.group(j)) for j in range(1, 5)] for _bboxes_parsed in bboxes_parsed] bboxes = self.box_quantizer.dequantize( boxes=torch.tensor(bbox_bins), size=image_size ).tolist() phrase = phrase.encode('ascii',errors='ignore').decode('ascii') for _bboxes in bboxes: # Prepare instance. instance = {} instance['bbox'] = _bboxes # exclude non-ascii characters instance['cat_name'] = phrase instances.append(instance) return instances def parse_description_with_polygons_from_text_and_spans(self, text, pattern, image_size, allow_empty_phrase=False, polygon_sep_token='', polygon_start_token='', polygon_end_token='', with_box_at_start=False, ): # ref_seg format: '<><><><><><>' # ignore and text = text.replace('', '') text = text.replace('', '') text = text.replace('', '') if allow_empty_phrase: pattern = rf"(?:(?:|{re.escape(polygon_sep_token)}|{re.escape(polygon_start_token)}|{re.escape(polygon_end_token)}){{4,}})" else: # [^<]+: This part matches one or more characters that are not the < symbol. # The ^ inside the square brackets [] is a negation, meaning it matches anything except <. # pattern = rf"([^<]+(?:|{re.escape(polygon_sep_token)}|{re.escape(polygon_start_token)}|{re.escape(polygon_end_token)}){{4,}})" phrases = re.findall(pattern, text) phrase_string_pattern = r'^\s*(.*?)(?=||||||)' box_pattern = rf'((?:)+)(?:{re.escape(polygon_sep_token)}|$)' # one polygons instance is separated by polygon_start_token and polygon_end_token polygons_instance_pattern = rf'{re.escape(polygon_start_token)}(.*?){re.escape(polygon_end_token)}' instances = [] for phrase_text in phrases: # exclude loc_\d+> # need to get span if want to include category score phrase_text_strip = re.sub(r'^loc_\d+>', '', phrase_text, count=1) # phrase = phrase.replace('', '') # phrase = phrase.replace('poly>', '') if phrase_text_strip == '' and not allow_empty_phrase: continue # parse phrase, get string phrase = re.search(phrase_string_pattern, phrase_text_strip) if phrase is None: continue phrase = phrase.group() # remove leading and trailing spaces phrase = phrase.strip() # parse bboxes by box_pattern # split by polygon_start_token and polygon_end_token first using polygons_instance_pattern if polygon_start_token in phrase_text and polygon_end_token in phrase_text: polygons_instances_parsed = list(re.finditer(polygons_instance_pattern, phrase_text)) else: polygons_instances_parsed = [phrase_text] for _polygons_instances_parsed in polygons_instances_parsed: # Prepare instance. instance = {} # polygons_parsed= list(re.finditer(box_pattern, phrase_text)) if isinstance(_polygons_instances_parsed, str): polygons_parsed= list(re.finditer(box_pattern, _polygons_instances_parsed)) else: polygons_parsed= list(re.finditer(box_pattern, _polygons_instances_parsed.group(1))) if len(polygons_parsed) == 0: continue # a list of list (polygon) bbox = [] polygons = [] for _polygon_parsed in polygons_parsed: # group 1: whole ... _polygon = _polygon_parsed.group(1) # parse into list of int _polygon = [int(_loc_parsed.group(1)) for _loc_parsed in re.finditer(r'', _polygon)] if with_box_at_start and len(bbox) == 0: if len(_polygon) > 4: # no valid bbox prediction bbox = _polygon[:4] _polygon = _polygon[4:] else: bbox = [0, 0, 0, 0] # abandon last element if is not paired if len(_polygon) % 2 == 1: _polygon = _polygon[:-1] # reshape into (n, 2) _polygon = self.coordinates_quantizer.dequantize( torch.tensor(np.array(_polygon).reshape(-1, 2)), size=image_size ).reshape(-1).tolist() # reshape back polygons.append(_polygon) instance['cat_name'] = phrase instance['polygons'] = polygons if len(bbox) != 0: instance['bbox'] = self.box_quantizer.dequantize( boxes=torch.tensor([bbox]), size=image_size ).tolist()[0] instances.append(instance) return instances def __call__( self, text=None, image_size=None, parse_tasks=None, ): """ Args: text: model outputs image_size: (width, height) parse_tasks: a list of tasks to parse, if None, parse all tasks. """ if parse_tasks is not None: if isinstance(parse_tasks, str): parse_tasks = [parse_tasks] for _parse_task in parse_tasks: assert _parse_task in self.parse_tasks, f'parse task {_parse_task} not supported' # sequence or text should be provided assert text is not None, 'text should be provided' parsed_dict = { 'text': text } for task in self.parse_tasks: if parse_tasks is not None and task not in parse_tasks: continue pattern = self.parse_tasks_configs[task].get('PATTERN', None) if task == 'ocr': instances = self.parse_ocr_from_text_and_spans( text, pattern=pattern, image_size=image_size, area_threshold=self.parse_tasks_configs[task].get('AREA_THRESHOLD', 0.01), ) parsed_dict['ocr'] = instances elif task == 'phrase_grounding': instances = self.parse_phrase_grounding_from_text_and_spans( text, pattern=pattern, image_size=image_size, ) parsed_dict['phrase_grounding'] = instances elif task == 'pure_text': parsed_dict['pure_text'] = text elif task == 'description_with_bboxes': instances = self.parse_description_with_bboxes_from_text_and_spans( text, pattern=pattern, image_size=image_size, ) parsed_dict['description_with_bboxes'] = instances elif task == 'description_with_polygons': instances = self.parse_description_with_polygons_from_text_and_spans( text, pattern=pattern, image_size=image_size, ) parsed_dict['description_with_polygons'] = instances elif task == 'polygons': instances = self.parse_description_with_polygons_from_text_and_spans( text, pattern=pattern, image_size=image_size, allow_empty_phrase=True, ) parsed_dict['polygons'] = instances elif task == 'bboxes': instances = self.parse_description_with_bboxes_from_text_and_spans( text, pattern=pattern, image_size=image_size, allow_empty_phrase=True, ) parsed_dict['bboxes'] = instances elif task == 'description_with_bboxes_or_polygons': if '' in text: # only support either polygons or bboxes, not both at the same time instances = self.parse_description_with_polygons_from_text_and_spans( text, pattern=pattern, image_size=image_size, ) else: instances = self.parse_description_with_bboxes_from_text_and_spans( text, pattern=pattern, image_size=image_size, ) parsed_dict['description_with_bboxes_or_polygons'] = instances else: raise ValueError("task {} is not supported".format(task)) return parsed_dict