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import random
import argparse
import numpy as np
import torch
from tqdm import tqdm
from segment_anything import SamAutomaticMaskGenerator, sam_model_registry
import cv2
from dataclasses import dataclass, field
from typing import Tuple, Type
from copy import deepcopy
import torch
import torchvision
from torch import nn
try:
import open_clip
except ImportError:
assert False, "open_clip is not installed, install it with `pip install open-clip-torch`"
@dataclass
class OpenCLIPNetworkConfig:
_target: Type = field(default_factory=lambda: OpenCLIPNetwork)
clip_model_type: str = "ViT-B-16"
clip_model_pretrained: str = "laion2b_s34b_b88k"
clip_n_dims: int = 512
negatives: Tuple[str] = ("object", "things", "stuff", "texture")
positives: Tuple[str] = ("",)
class OpenCLIPNetwork(nn.Module):
def __init__(self, config: OpenCLIPNetworkConfig):
super().__init__()
self.config = config
self.process = torchvision.transforms.Compose(
[
torchvision.transforms.Resize((224, 224)),
torchvision.transforms.Normalize(
mean=[0.48145466, 0.4578275, 0.40821073],
std=[0.26862954, 0.26130258, 0.27577711],
),
]
)
model, _, _ = open_clip.create_model_and_transforms(
self.config.clip_model_type, # e.g., ViT-B-16
pretrained=self.config.clip_model_pretrained, # e.g., laion2b_s34b_b88k
precision="fp16",
)
model.eval()
self.tokenizer = open_clip.get_tokenizer(self.config.clip_model_type)
self.model = model.to("cuda")
self.clip_n_dims = self.config.clip_n_dims
self.positives = self.config.positives
self.negatives = self.config.negatives
with torch.no_grad():
tok_phrases = torch.cat([self.tokenizer(phrase) for phrase in self.positives]).to("cuda")
self.pos_embeds = model.encode_text(tok_phrases)
tok_phrases = torch.cat([self.tokenizer(phrase) for phrase in self.negatives]).to("cuda")
self.neg_embeds = model.encode_text(tok_phrases)
self.pos_embeds /= self.pos_embeds.norm(dim=-1, keepdim=True)
self.neg_embeds /= self.neg_embeds.norm(dim=-1, keepdim=True)
assert (
self.pos_embeds.shape[1] == self.neg_embeds.shape[1]
), "Positive and negative embeddings must have the same dimensionality"
assert (
self.pos_embeds.shape[1] == self.clip_n_dims
), "Embedding dimensionality must match the model dimensionality"
@property
def name(self) -> str:
return "openclip_{}_{}".format(self.config.clip_model_type, self.config.clip_model_pretrained)
@property
def embedding_dim(self) -> int:
return self.config.clip_n_dims
def gui_cb(self,element):
self.set_positives(element.value.split(";"))
def set_positives(self, text_list):
self.positives = text_list
with torch.no_grad():
tok_phrases = torch.cat([self.tokenizer(phrase) for phrase in self.positives]).to("cuda")
self.pos_embeds = self.model.encode_text(tok_phrases)
self.pos_embeds /= self.pos_embeds.norm(dim=-1, keepdim=True)
def get_relevancy(self, embed: torch.Tensor, positive_id: int) -> torch.Tensor:
phrases_embeds = torch.cat([self.pos_embeds, self.neg_embeds], dim=0)
p = phrases_embeds.to(embed.dtype) # phrases x 512
output = torch.mm(embed, p.T) # rays x phrases
positive_vals = output[..., positive_id : positive_id + 1] # rays x 1
negative_vals = output[..., len(self.positives) :] # rays x N_phrase
repeated_pos = positive_vals.repeat(1, len(self.negatives)) # rays x N_phrase
sims = torch.stack((repeated_pos, negative_vals), dim=-1) # rays x N-phrase x 2
softmax = torch.softmax(10 * sims, dim=-1) # rays x n-phrase x 2
best_id = softmax[..., 0].argmin(dim=1) # rays x 2
return torch.gather(softmax, 1, best_id[..., None, None].expand(best_id.shape[0], len(self.negatives), 2))[:, 0, :]
def encode_image(self, input):
processed_input = self.process(input).half()
return self.model.encode_image(processed_input)
def create(image_list, data_list, save_folder):
assert image_list is not None, "image_list must be provided to generate features"
embed_size=512
seg_maps = []
total_lengths = []
timer = 0
img_embeds = torch.zeros((len(image_list), 300, embed_size))
seg_maps = torch.zeros((len(image_list), 4, *image_list[0].shape[1:]))
mask_generator.predictor.model.to('cuda')
for i, img in tqdm(enumerate(image_list), desc="Embedding images", leave=False):
timer += 1
try:
img_embed, seg_map = _embed_clip_sam_tiles(img.unsqueeze(0), sam_encoder)
except:
raise ValueError(timer)
lengths = [len(v) for k, v in img_embed.items()]
total_length = sum(lengths)
total_lengths.append(total_length)
if total_length > img_embeds.shape[1]:
pad = total_length - img_embeds.shape[1]
img_embeds = torch.cat([
img_embeds,
torch.zeros((len(image_list), pad, embed_size))
], dim=1)
img_embed = torch.cat([v for k, v in img_embed.items()], dim=0)
assert img_embed.shape[0] == total_length
img_embeds[i, :total_length] = img_embed
seg_map_tensor = []
lengths_cumsum = lengths.copy()
for j in range(1, len(lengths)):
lengths_cumsum[j] += lengths_cumsum[j-1]
for j, (k, v) in enumerate(seg_map.items()):
if j == 0:
seg_map_tensor.append(torch.from_numpy(v))
continue
assert v.max() == lengths[j] - 1, f"{j}, {v.max()}, {lengths[j]-1}"
v[v != -1] += lengths_cumsum[j-1]
seg_map_tensor.append(torch.from_numpy(v))
seg_map = torch.stack(seg_map_tensor, dim=0)
seg_maps[i] = seg_map
mask_generator.predictor.model.to('cpu')
for i in range(img_embeds.shape[0]):
save_path = os.path.join(save_folder, data_list[i].split('.')[0])
assert total_lengths[i] == int(seg_maps[i].max() + 1)
curr = {
'feature': img_embeds[i, :total_lengths[i]],
'seg_maps': seg_maps[i]
}
sava_numpy(save_path, curr)
def sava_numpy(save_path, data):
save_path_s = save_path + '_s.npy'
save_path_f = save_path + '_f.npy'
np.save(save_path_s, data['seg_maps'].numpy())
np.save(save_path_f, data['feature'].numpy())
def _embed_clip_sam_tiles(image, sam_encoder):
aug_imgs = torch.cat([image])
seg_images, seg_map = sam_encoder(aug_imgs)
clip_embeds = {}
for mode in ['default', 's', 'm', 'l']:
tiles = seg_images[mode]
tiles = tiles.to("cuda")
with torch.no_grad():
clip_embed = model.encode_image(tiles)
clip_embed /= clip_embed.norm(dim=-1, keepdim=True)
clip_embeds[mode] = clip_embed.detach().cpu().half()
return clip_embeds, seg_map
def get_seg_img(mask, image):
image = image.copy()
image[mask['segmentation']==0] = np.array([0, 0, 0], dtype=np.uint8)
x,y,w,h = np.int32(mask['bbox'])
seg_img = image[y:y+h, x:x+w, ...]
return seg_img
def pad_img(img):
h, w, _ = img.shape
l = max(w,h)
pad = np.zeros((l,l,3), dtype=np.uint8)
if h > w:
pad[:,(h-w)//2:(h-w)//2 + w, :] = img
else:
pad[(w-h)//2:(w-h)//2 + h, :, :] = img
return pad
def filter(keep: torch.Tensor, masks_result) -> None:
keep = keep.int().cpu().numpy()
result_keep = []
for i, m in enumerate(masks_result):
if i in keep: result_keep.append(m)
return result_keep
def mask_nms(masks, scores, iou_thr=0.7, score_thr=0.1, inner_thr=0.2, **kwargs):
"""
Perform mask non-maximum suppression (NMS) on a set of masks based on their scores.
Args:
masks (torch.Tensor): has shape (num_masks, H, W)
scores (torch.Tensor): The scores of the masks, has shape (num_masks,)
iou_thr (float, optional): The threshold for IoU.
score_thr (float, optional): The threshold for the mask scores.
inner_thr (float, optional): The threshold for the overlap rate.
**kwargs: Additional keyword arguments.
Returns:
selected_idx (torch.Tensor): A tensor representing the selected indices of the masks after NMS.
"""
scores, idx = scores.sort(0, descending=True)
num_masks = idx.shape[0]
masks_ord = masks[idx.view(-1), :]
masks_area = torch.sum(masks_ord, dim=(1, 2), dtype=torch.float)
iou_matrix = torch.zeros((num_masks,) * 2, dtype=torch.float, device=masks.device)
inner_iou_matrix = torch.zeros((num_masks,) * 2, dtype=torch.float, device=masks.device)
for i in range(num_masks):
for j in range(i, num_masks):
intersection = torch.sum(torch.logical_and(masks_ord[i], masks_ord[j]), dtype=torch.float)
union = torch.sum(torch.logical_or(masks_ord[i], masks_ord[j]), dtype=torch.float)
iou = intersection / union
iou_matrix[i, j] = iou
# select mask pairs that may have a severe internal relationship
if intersection / masks_area[i] < 0.5 and intersection / masks_area[j] >= 0.85:
inner_iou = 1 - (intersection / masks_area[j]) * (intersection / masks_area[i])
inner_iou_matrix[i, j] = inner_iou
if intersection / masks_area[i] >= 0.85 and intersection / masks_area[j] < 0.5:
inner_iou = 1 - (intersection / masks_area[j]) * (intersection / masks_area[i])
inner_iou_matrix[j, i] = inner_iou
iou_matrix.triu_(diagonal=1)
iou_max, _ = iou_matrix.max(dim=0)
inner_iou_matrix_u = torch.triu(inner_iou_matrix, diagonal=1)
inner_iou_max_u, _ = inner_iou_matrix_u.max(dim=0)
inner_iou_matrix_l = torch.tril(inner_iou_matrix, diagonal=1)
inner_iou_max_l, _ = inner_iou_matrix_l.max(dim=0)
keep = iou_max <= iou_thr
keep_conf = scores > score_thr
keep_inner_u = inner_iou_max_u <= 1 - inner_thr
keep_inner_l = inner_iou_max_l <= 1 - inner_thr
# If there are no masks with scores above threshold, the top 3 masks are selected
if keep_conf.sum() == 0:
index = scores.topk(3).indices
keep_conf[index, 0] = True
if keep_inner_u.sum() == 0:
index = scores.topk(3).indices
keep_inner_u[index, 0] = True
if keep_inner_l.sum() == 0:
index = scores.topk(3).indices
keep_inner_l[index, 0] = True
keep *= keep_conf
keep *= keep_inner_u
keep *= keep_inner_l
selected_idx = idx[keep]
return selected_idx
def masks_update(*args, **kwargs):
# remove redundant masks based on the scores and overlap rate between masks
masks_new = ()
for masks_lvl in (args):
seg_pred = torch.from_numpy(np.stack([m['segmentation'] for m in masks_lvl], axis=0))
iou_pred = torch.from_numpy(np.stack([m['predicted_iou'] for m in masks_lvl], axis=0))
stability = torch.from_numpy(np.stack([m['stability_score'] for m in masks_lvl], axis=0))
scores = stability * iou_pred
keep_mask_nms = mask_nms(seg_pred, scores, **kwargs)
masks_lvl = filter(keep_mask_nms, masks_lvl)
masks_new += (masks_lvl,)
return masks_new
def sam_encoder(image):
image = cv2.cvtColor(image[0].permute(1,2,0).numpy().astype(np.uint8), cv2.COLOR_BGR2RGB)
# pre-compute masks
masks_default, masks_s, masks_m, masks_l = mask_generator.generate(image)
# pre-compute postprocess
masks_default, masks_s, masks_m, masks_l = \
masks_update(masks_default, masks_s, masks_m, masks_l, iou_thr=0.8, score_thr=0.7, inner_thr=0.5)
def mask2segmap(masks, image):
seg_img_list = []
seg_map = -np.ones(image.shape[:2], dtype=np.int32)
for i in range(len(masks)):
mask = masks[i]
seg_img = get_seg_img(mask, image)
pad_seg_img = cv2.resize(pad_img(seg_img), (224,224))
seg_img_list.append(pad_seg_img)
seg_map[masks[i]['segmentation']] = i
seg_imgs = np.stack(seg_img_list, axis=0) # b,H,W,3
seg_imgs = (torch.from_numpy(seg_imgs.astype("float32")).permute(0,3,1,2) / 255.0).to('cuda')
return seg_imgs, seg_map
seg_images, seg_maps = {}, {}
seg_images['default'], seg_maps['default'] = mask2segmap(masks_default, image)
if len(masks_s) != 0:
seg_images['s'], seg_maps['s'] = mask2segmap(masks_s, image)
if len(masks_m) != 0:
seg_images['m'], seg_maps['m'] = mask2segmap(masks_m, image)
if len(masks_l) != 0:
seg_images['l'], seg_maps['l'] = mask2segmap(masks_l, image)
# 0:default 1:s 2:m 3:l
return seg_images, seg_maps
def seed_everything(seed_value):
random.seed(seed_value)
np.random.seed(seed_value)
torch.manual_seed(seed_value)
os.environ['PYTHONHASHSEED'] = str(seed_value)
if torch.cuda.is_available():
torch.cuda.manual_seed(seed_value)
torch.cuda.manual_seed_all(seed_value)
torch.backends.cudnn.deterministic = True
torch.backends.cudnn.benchmark = True
if __name__ == '__main__':
seed_num = 42
seed_everything(seed_num)
parser = argparse.ArgumentParser()
parser.add_argument('--dataset_path', type=str, required=True)
parser.add_argument('--resolution', type=int, default=-1)
parser.add_argument('--sam_ckpt_path', type=str, default="ckpts/sam_vit_h_4b8939.pth")
args = parser.parse_args()
torch.set_default_dtype(torch.float32)
dataset_path = args.dataset_path
sam_ckpt_path = args.sam_ckpt_path
img_folder = os.path.join(dataset_path, 'images')
data_list = os.listdir(img_folder)
data_list.sort()
model = OpenCLIPNetwork(OpenCLIPNetworkConfig)
sam = sam_model_registry["vit_h"](checkpoint=sam_ckpt_path).to('cuda')
mask_generator = SamAutomaticMaskGenerator(
model=sam,
points_per_side=32,
pred_iou_thresh=0.7,
box_nms_thresh=0.7,
stability_score_thresh=0.85,
crop_n_layers=1,
crop_n_points_downscale_factor=1,
min_mask_region_area=100,
)
img_list = []
WARNED = False
for data_path in data_list:
image_path = os.path.join(img_folder, data_path)
image = cv2.imread(image_path)
orig_w, orig_h = image.shape[1], image.shape[0]
if args.resolution == -1:
if orig_h > 1080:
if not WARNED:
print("[ INFO ] Encountered quite large input images (>1080P), rescaling to 1080P.\n "
"If this is not desired, please explicitly specify '--resolution/-r' as 1")
WARNED = True
global_down = orig_h / 1080
else:
global_down = 1
else:
global_down = orig_w / args.resolution
scale = float(global_down)
resolution = (int( orig_w / scale), int(orig_h / scale))
image = cv2.resize(image, resolution)
image = torch.from_numpy(image)
img_list.append(image)
images = [img_list[i].permute(2, 0, 1)[None, ...] for i in range(len(img_list))]
imgs = torch.cat(images)
save_folder = os.path.join(dataset_path, 'language_features')
os.makedirs(save_folder, exist_ok=True)
create(imgs, data_list, save_folder) |