161 lines
6.3 KiB
Python
161 lines
6.3 KiB
Python
import numpy as np
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from PIL import Image
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from skimage import color, exposure
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from scipy.optimize import minimize
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import os
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import time
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from concurrent.futures import ProcessPoolExecutor, as_completed
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# ================= 配置区域 =================
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# 1. 输入与输出文件夹
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SRC_DIR = "去雾图像-北航合作-Result_Baidu" # 待处理图片文件夹
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REF_DIR = "去雾图像-北航合作" # 参考图(GT)文件夹
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OUT_DIR = "去雾图像-北航合作-Result_Baidu_Own_V3" # 结果输出文件夹
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# 2. 功能开关
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ENABLE_HIST_MATCH = True # 【开关】 True: 开启直方图匹配; False: 关闭
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MAX_WORKERS = 4 # 【并行】 并行处理的进程数 (建议设为 CPU 核心数,如 4, 8, 16)
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# ===========================================
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def process_single_image(file_info):
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"""
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单个图片处理函数 (用于并行调用)
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file_info: (filename, src_dir, ref_dir, out_dir, enable_hist)
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"""
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filename, src_folder, ref_folder, output_folder, use_hist = file_info
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source_path = os.path.join(src_folder, filename)
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# 1. 寻找对应的参考图
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# 逻辑:去除文件名后缀 "_result" (例如 "image01_result.png" -> "image01.png")
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name_no_ext, ext = os.path.splitext(filename)
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if name_no_ext.endswith("_result"):
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ref_name_no_ext = name_no_ext[:-7] # 去掉 "_result"
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else:
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ref_name_no_ext = name_no_ext
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ref_filename = ref_name_no_ext + ext
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ref_path = os.path.join(ref_folder, ref_filename)
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if not os.path.exists(ref_path):
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return f"[跳过] 找不到参考图: {filename}"
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try:
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# 2. 读取图片并归一化 (0-1 float)
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img_src_pil = Image.open(source_path).convert('RGB')
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img_src = np.array(img_src_pil) / 255.0
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img_ref_pil = Image.open(ref_path).convert('RGB')
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if img_src_pil.size != img_ref_pil.size:
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img_ref_pil = img_ref_pil.resize(img_src_pil.size, Image.BILINEAR)
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img_ref = np.array(img_ref_pil) / 255.0
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# 3. RGB -> HSV
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hsv_src = color.rgb2hsv(img_src)
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hsv_ref = color.rgb2hsv(img_ref)
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# === 新增功能: 直方图匹配 (Histogram Matching) ===
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if use_hist:
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# 分离通道
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s_h, s_s, s_v = hsv_src[:,:,0], hsv_src[:,:,1], hsv_src[:,:,2]
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r_h, r_s, r_v = hsv_ref[:,:,0], hsv_ref[:,:,1], hsv_ref[:,:,2]
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# 对 S 和 V 通道进行直方图匹配
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# 这会将 src 的分布形状强行调整为 ref 的分布形状
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matched_s = exposure.match_histograms(s_s, r_s)
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matched_v = exposure.match_histograms(s_v, r_v)
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# 更新 hsv_src,后续的 minimize 将在此基础上进一步微调系数
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hsv_src = np.stack([s_h, matched_s, matched_v], axis=-1)
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# 4. 优化 S/V 乘数因子
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# 即使做了直方图匹配,我们依然计算一个最佳的整体缩放系数,以确保整体误差最小
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def loss_function(params):
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ks, kv = params
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adj_s = np.clip(hsv_src[:,:,1] * ks, 0, 1)
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adj_v = np.clip(hsv_src[:,:,2] * kv, 0, 1)
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loss_s = np.mean((adj_s - hsv_ref[:,:,1])**2)
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loss_v = np.mean((adj_v - hsv_ref[:,:,2])**2)
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return loss_s + loss_v
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# 初始猜测 [1.0, 1.0]
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res = minimize(loss_function, [1.0, 1.0], method='Nelder-Mead', tol=1e-4)
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best_s, best_v = res.x
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s_percent = int(best_s * 100)
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v_percent = int(best_v * 100)
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# 5. 应用最终参数
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hsv_final = hsv_src.copy()
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hsv_final[:, :, 1] = np.clip(hsv_final[:, :, 1] * best_s, 0, 1)
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hsv_final[:, :, 2] = np.clip(hsv_final[:, :, 2] * best_v, 0, 1)
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# 6. 保存结果
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img_result_rgb = color.hsv2rgb(hsv_final)
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img_save = Image.fromarray((img_result_rgb * 255).astype(np.uint8))
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# 命名增加标识,如果开启了直方图匹配,可以在文件名加个标记(可选),
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# 这里保持您要求的格式: 原文件名_S_XX_V_XX.png
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new_filename = f"{name_no_ext}_S_{s_percent}_V_{v_percent}{ext}"
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save_path = os.path.join(output_folder, new_filename)
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img_save.save(save_path)
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match_tag = "[HistMatch]" if use_hist else "[Raw]"
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return f"{match_tag} 完成: {new_filename} (S={s_percent}%, V={v_percent}%)"
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except Exception as e:
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return f"[错误] {filename}: {str(e)}"
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def main():
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# 1. 检查文件夹
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if not os.path.exists(SRC_DIR) or not os.path.exists(REF_DIR):
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print("错误: 输入或参考文件夹不存在。")
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return
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if not os.path.exists(OUT_DIR):
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os.makedirs(OUT_DIR)
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# 2. 获取文件列表
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valid_extensions = ('.png', '.jpg', '.jpeg', '.bmp', '.tif')
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file_list = [f for f in os.listdir(SRC_DIR) if f.lower().endswith(valid_extensions)]
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total_files = len(file_list)
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if total_files == 0:
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print("源文件夹为空。")
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return
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print(f"=== 开始处理 ===")
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print(f"模式: {'直方图匹配 + 参数优化' if ENABLE_HIST_MATCH else '仅参数优化'}")
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print(f"并行: {MAX_WORKERS} 线程")
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print(f"数量: {total_files} 张图片")
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print("-" * 30)
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# 3. 准备任务参数
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tasks = []
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for f in file_list:
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# 打包参数传给 worker
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tasks.append((f, SRC_DIR, REF_DIR, OUT_DIR, ENABLE_HIST_MATCH))
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# 4. 并行执行
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start_time = time.time()
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with ProcessPoolExecutor(max_workers=MAX_WORKERS) as executor:
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# 提交所有任务
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futures = [executor.submit(process_single_image, task) for task in tasks]
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# 获取结果 (as_completed 会在任务完成时立即返回)
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for i, future in enumerate(as_completed(futures)):
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result = future.result()
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print(f"[{i+1}/{total_files}] {result}")
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end_time = time.time()
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print("-" * 30)
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print(f"全部完成! 耗时: {end_time - start_time:.2f} 秒")
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print(f"结果保存在: {OUT_DIR}")
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if __name__ == "__main__":
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# Windows 下使用多进程必须放在 if __name__ == "__main__": 之下
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main() |