| | import argparse |
| | import json |
| | import tqdm |
| | import cv2 |
| | import os |
| | import numpy as np |
| | from pycocotools import mask as mask_utils |
| | import random |
| | from PIL import Image |
| |
|
| | EVALMODE = "test" |
| |
|
| |
|
| | def blend_mask(input_img, binary_mask, alpha=0.5, color="g"): |
| | if input_img.ndim == 2: |
| | return input_img |
| | mask_image = np.zeros(input_img.shape, np.uint8) |
| | if color == "r": |
| | mask_image[:, :, 0] = 255 |
| | if color == "g": |
| | mask_image[:, :, 1] = 255 |
| | if color == "b": |
| | mask_image[:, :, 2] = 255 |
| | if color == "o": |
| | mask_image[:, :, 0] = 255 |
| | mask_image[:, :, 1] = 165 |
| | mask_image[:, :, 2] = 0 |
| | if color == "c": |
| | mask_image[:, :, 0] = 0 |
| | mask_image[:, :, 1] = 255 |
| | mask_image[:, :, 2] = 255 |
| | if color == "p": |
| | mask_image[:, :, 0] = 128 |
| | mask_image[:, :, 1] = 0 |
| | mask_image[:, :, 2] = 128 |
| | if color == "l": |
| | mask_image[:, :, 0] = 128 |
| | mask_image[:, :, 1] = 128 |
| | mask_image[:, :, 2] = 0 |
| | if color == "m": |
| | mask_image[:, :, 0] = 128 |
| | mask_image[:, :, 1] = 128 |
| | mask_image[:, :, 2] = 128 |
| | if color == "q": |
| | mask_image[:, :, 0] = 165 |
| | mask_image[:, :, 1] = 80 |
| | mask_image[:, :, 2] = 30 |
| | |
| |
|
| | mask_image = mask_image * np.repeat(binary_mask[:, :, np.newaxis], 3, axis=2) |
| | blend_image = input_img[:, :, :].copy() |
| | pos_idx = binary_mask > 0 |
| | for ind in range(input_img.ndim): |
| | ch_img1 = input_img[:, :, ind] |
| | ch_img2 = mask_image[:, :, ind] |
| | ch_img3 = blend_image[:, :, ind] |
| | ch_img3[pos_idx] = alpha * ch_img1[pos_idx] + (1 - alpha) * ch_img2[pos_idx] |
| | blend_image[:, :, ind] = ch_img3 |
| | return blend_image |
| |
|
| |
|
| | def upsample_mask(mask, frame): |
| | H, W = frame.shape[:2] |
| | mH, mW = mask.shape[:2] |
| |
|
| | if W > H: |
| | ratio = mW / W |
| | h = H * ratio |
| | diff = int((mH - h) // 2) |
| | if diff == 0: |
| | mask = mask |
| | else: |
| | mask = mask[diff:-diff] |
| | else: |
| | ratio = mH / H |
| | w = W * ratio |
| | diff = int((mW - w) // 2) |
| | if diff == 0: |
| | mask = mask |
| | else: |
| | mask = mask[:, diff:-diff] |
| |
|
| | mask = cv2.resize(mask, (W, H)) |
| | return mask |
| |
|
| |
|
| | def downsample(mask, frame): |
| | H, W = frame.shape[:2] |
| | mH, mW = mask.shape[:2] |
| |
|
| | mask = cv2.resize(mask, (W, H)) |
| | return mask |
| |
|
| |
|
| | |
| | |
| | |
| | |
| | if __name__ == "__main__": |
| |
|
| | color = ['g', 'r', 'b', 'o', 'c', 'p', 'l', 'm', 'q'] |
| | |
| | frame = cv2.imread( |
| | "/home/yuqian_fu/Projects/sam2/teacup/JPEGImages/000345.png" |
| | ) |
| | mask = Image.open("/home/yuqian_fu/Projects/sam2/results/3.png") |
| | mask = np.array(mask) |
| |
|
| | |
| | |
| | |
| | |
| | |
| | out_path = "/home/yuqian_fu/Projects/sam2/predicted_mask" |
| | unique_instances = np.unique(mask) |
| | unique_instances = unique_instances[unique_instances != 0] |
| |
|
| | vis_mode = "fuse" |
| | if vis_mode == "fuse": |
| | for i,instance_value in enumerate(unique_instances): |
| | binary_mask = (mask == instance_value).astype(np.uint8) |
| | binary_mask = cv2.resize(binary_mask, (frame.shape[1], frame.shape[0])) |
| | try: |
| | binary_mask = upsample_mask(binary_mask, frame) |
| | frame = blend_mask(frame, binary_mask, color=color[i]) |
| | except: |
| | breakpoint() |
| |
|
| | |
| |
|
| | cv2.imwrite( |
| | f"{out_path}/new.jpg", |
| | frame, |
| | ) |
| |
|
| | elif vis_mode == "split": |
| | for i,instance_value in enumerate(unique_instances): |
| | binary_mask = (mask == instance_value).astype(np.uint8) |
| | binary_mask = cv2.resize(binary_mask, (frame.shape[1], frame.shape[0])) |
| | binary_mask = upsample_mask(binary_mask, frame) |
| | out = blend_mask(frame, binary_mask, color=color[0]) |
| | cv2.imwrite( |
| | f"{out_path}/obj_{i}.jpg", |
| | out, |
| | ) |
| |
|
| | else: |
| | print("error") |
