225 lines
11 KiB
Python
225 lines
11 KiB
Python
# Copyright (c) 2025 ByteDance Ltd. and/or its affiliates.
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#
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# Licensed under the Apache License, Version 2.0 (the "License");
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# you may not use this file except in compliance with the License.
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# You may obtain a copy of the License at
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#
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# http://www.apache.org/licenses/LICENSE-2.0
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#
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# Unless required by applicable law or agreed to in writing, software
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# distributed under the License is distributed on an "AS IS" BASIS,
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# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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# See the License for the specific language governing permissions and
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# limitations under the License.
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# coding: utf-8
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import json
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import torch
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import random
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import io
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from einops import rearrange
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from typing import List
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import torch.nn.functional as F
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import re
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import numpy as np
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RE_ZH = re.compile(r"[\u4e00-\u9fff]")
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RE_EN = re.compile(r"[A-Za-z]")
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def generate_system_prompt(system_prompt_type="caption", vision_type="video"):
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if system_prompt_type == "caption":
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str_list = [
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f"Generate a detailed and accurate description of the {vision_type}, including all the key moments and visual details.",
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f"Write an in-depth depiction of the {vision_type}, covering all its aspects.",
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f"Write an exhaustive depiction of the given {vision_type}, capturing its essence and key moments.",
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f"Describe the key features of the input {vision_type}, including color, shape, size, texture, objects, background.",
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]
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elif system_prompt_type == "t2v" or system_prompt_type == "i2v":
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str_list = [f"Describe the {vision_type} by detailing the color, quantity, visible text, shape, size, texture, spatial relationships and motion/camera movements of the objects and background:"]
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elif system_prompt_type == "t2i":
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str_list = [f"Describe the {vision_type} by detailing the color, quantity, text, shape, size, texture, spatial relationships of the objects and background:"]
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elif "edit" in system_prompt_type:
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str_list = [f"Describe the key features of the input {vision_type} (color, shape, size, texture, objects, background), then explain how the user’s text instruction should alter or modify the {vision_type}. Generate a new {vision_type} that meets the user’s requirements while maintaining consistency with the original input where appropriate."]
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elif "idip" in system_prompt_type:
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str_list = [f"Describe the key features of the input image (color, shape, size, texture, objects, background, style), then incorporate the user’s text description to generate a new {vision_type} that satisfies the user’s requirements while preserving the essential identity and object or style information from the reference input."]
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elif 'maze' in system_prompt_type:
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str_list = [
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"Describe the key elements of the input maze image (layout, white path, black walls, blue star, red flag, and overall background), then generate a 2D animation. The blue star should slide smoothly along the white path, stop exactly on the red flag, and then acquire a trophy. Ensure the blue star never crosses or enters the black maze walls. Keep the camera as a static top-down view showing the entire maze."
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]
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return random.choice(str_list)
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def shift_position_ids(
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position_ids: torch.Tensor,
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pos_shift: any,
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attn_modes: List[str],
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split_lens: int,
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shift_attn_mode=["full_noise", "full"],
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pro_type=None,
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i_sample_task=None,
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i_sample_modality=None,
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) -> torch.Tensor:
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curr_split = 0
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for i, attn_mode in enumerate(attn_modes):
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if attn_mode in shift_attn_mode:
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if pro_type == 10: # Related to sample_modality.
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if position_ids[:, :, i_sample_modality == 4].sum() != 0:
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pos_shift_type4 = 1000 - position_ids[:, :, i_sample_modality == 4][0, 0, 0]
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position_ids[0, :, i_sample_modality == 4] += pos_shift_type4
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if position_ids[:, :, i_sample_modality == 3].sum() != 0:
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pos_shift_type3 = 2000 - position_ids[:, :, i_sample_modality == 3][0, 0, 0]
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position_ids[0, :, i_sample_modality == 3] += pos_shift_type3
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if position_ids[:, :, i_sample_modality == 2].sum() != 0 and sum(i_sample_modality == 2) == sum(i_sample_modality == 1):
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position_ids[:, :, i_sample_modality == 1] = position_ids[:, :, i_sample_modality == 2]
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curr_split += split_lens[i]
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return position_ids
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def detect_lang_simple(s: str) -> str:
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"""
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Fast heuristic: return 'zh' if Chinese is present, 'en' if English letters are present, otherwise 'other'.
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Useful for quick routing. If both are present, this returns 'zh'; adjust if needed.
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"""
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# Remove digits before detection
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s_without_digits = re.sub(r'\d+', '', s)
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if RE_ZH.search(s_without_digits):
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return "zh"
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if RE_EN.search(s_without_digits):
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return "en"
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return "other"
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def map_to_nearest_aspect_ratio(h, w, target_resolution=256):
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"""
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Map h and w to the closest preset aspect ratio and return adjusted h and w near the target resolution.
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Preset ratios: ["21:9", "16:9", "4:3", "1:1", "3:4", "9:16"].
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target_resolution: Base target resolution, default 256.
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"""
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# Precompute all preset aspect ratios as width / height
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PRESET_RATIOS = [21 / 9, 16 / 9, 4 / 3, 1 / 1, 3 / 4, 9 / 16]
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# Compute the original aspect ratio
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original_ratio = w / h
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# Find the closest preset ratio
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min_index = min(range(len(PRESET_RATIOS)), key=lambda i: abs(original_ratio - PRESET_RATIOS[i]))
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best_ratio = PRESET_RATIOS[min_index]
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# Compute scale so the longer side is close to the target resolution
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if best_ratio >= 1: # Landscape: width >= height
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scale = target_resolution / best_ratio
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adjusted_w = round(target_resolution)
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adjusted_h = round(scale)
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else: # Portrait: height > width
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scale = target_resolution
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adjusted_h = round(target_resolution)
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adjusted_w = round(scale * best_ratio)
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return adjusted_h, adjusted_w
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def concat_resize_tensor_list(video_latents: List[torch.Tensor], dim: int = 0, is_offline: bool = False, max_num_frames: int = 121) -> torch.Tensor:
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"""
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Concatenate tensors along dim; resize H/W of tensors with different sizes to match target.
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- tensors: Non-empty list; all tensors must have the same ndim.
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- dim: Concatenation axis; negative values are supported.
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- pad_value: Padding value, default 0.0.
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Returns: Concatenated tensor.
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"""
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if is_offline:
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H, W = video_latents[-1].shape[-3], video_latents[-1].shape[-2]
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else:
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H, W = video_latents[-1].shape[-2], video_latents[-1].shape[-1]
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padded_video_latents = []
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num_frames_target = video_latents[-1].shape[dim]
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num_frames_all = num_frames_target
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for index, video_latent in enumerate(video_latents):
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if index != len(video_latents) - 1 and num_frames_all + video_latent.shape[dim] > max_num_frames: # Avoid producing videos longer than MAX_NUM_FRAMES
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continue
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num_frames_all += video_latent.shape[dim]
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if is_offline:
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# video_latent:[t,h,w,c] -> [t,c,h,w]
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video_latent = rearrange(video_latent, "t h w c -> t c h w")
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h, w = video_latent.shape[-2], video_latent.shape[-1]
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if h != H or w != W:
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video_latent = F.interpolate(video_latent, size=(H, W), mode="bilinear", align_corners=False)
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padded_video_latents.append(video_latent)
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padded_video_latents = torch.cat(padded_video_latents, dim=dim)
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if is_offline:
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# padded_video_latents: [t,c,h,w] -> [t,h,w,c]
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padded_video_latents = rearrange(padded_video_latents, "t c h w -> t h w c")
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return padded_video_latents
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def concat_pad_tensor_list(video_latents: List[torch.Tensor], dim: int = 0, pad_value: float = 0.0, max_num_frames: int = 121) -> torch.Tensor:
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"""
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Concatenate tensors along dim; pad other axes to the maximum length on each axis with pad_value.
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- tensors: Non-empty list; all tensors must have the same ndim.
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- dim: Concatenation axis; negative values are supported.
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- pad_value: Padding value, default 0.0.
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Returns: Concatenated tensor.
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"""
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video_sizes = [item.shape for item in video_latents]
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max_video_size = [max(item) for item in list(zip(*video_sizes))]
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padded_video_latents = []
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num_frames_target = video_latents[-1].shape[dim]
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num_frames_all = num_frames_target
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for index, video_latent in enumerate(video_latents):
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if index != len(video_latents) - 1 and num_frames_all + video_latent.shape[dim] > max_num_frames: # Avoid producing videos longer than MAX_NUM_FRAMES
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continue
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num_frames_all += video_latent.shape[dim]
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max_video_size[dim] = video_latent.shape[dim]
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padded_video_latent = torch.zeros(max_video_size)
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n1, n2, n3, n4 = video_latent.shape
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padded_video_latent[:n1, :n2, :n3, :n4] = video_latent
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padded_video_latents.append(padded_video_latent)
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padded_video_latents = torch.cat(padded_video_latents, dim=dim)
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return padded_video_latents
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def parse_videochat2it_doubao_caption(row):
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try:
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IQA_i = "View the video attentively and provide a suitable answer to the posed question."
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rewrite_VQA = json.loads(row['rewrite_VQA'])
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IQA_q = rewrite_VQA['question'] if 'question' in rewrite_VQA.keys() else rewrite_VQA['Question']
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IQA_a = rewrite_VQA['final_answer']
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IQA_resoning = rewrite_VQA['reasoning']
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# Combine reasoning and final_answer as the final answer
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# if random.random() < 0.5: # 50% chance to include the reasoning process
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# IQA_a = IQA_a + '\n' + IQA_resoning
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# IQA_i = IQA_i + ' Please provide the reasoning process for selecting the correct answer.'
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if 'options' not in IQA_q and 'Options' not in IQA_q: # When the question does not contain options
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try:
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options = rewrite_VQA['options']
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except:
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options = rewrite_VQA['Options']
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if options == []:
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return [IQA_i, IQA_q, IQA_a]
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elif isinstance(options,list):
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options = '\n'.join(options)
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elif isinstance(options,dict):
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options_str = [key + ' ' + value if value not in key else key for key,value in options.items()]
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options = '\n'.join(options_str)
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IQA_q = IQA_q + '\nOptions:\n' + options # Add options to the question
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return [IQA_i, IQA_q, IQA_a]
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except:
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if 'rewrite_VQA' in row.keys():
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raise ValueError(f"wrong rewrite_VQA in {row['rewrite_VQA']}")
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else:
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raise ValueError(f"wrong rewrite_VQA in {row}") |