app.py

# ------------------------------------------------------------------------
# Modified from Grounded-SAM (https://github.com/IDEA-Research/Grounded-Segment-Anything)
# ------------------------------------------------------------------------
import os
import sys
import random
import warnings

os.system("export BUILD_WITH_CUDA=True")
os.system("python -m pip install -e segment-anything")
os.system("python -m pip install -e GroundingDINO")
os.system("pip install --upgrade diffusers[torch]")
#os.system("pip install opencv-python pycocotools matplotlib")
sys.path.insert(0, './GroundingDINO')
sys.path.insert(0, './segment-anything')
warnings.filterwarnings("ignore")

import cv2
from scipy import ndimage

import gradio as gr
import argparse

import numpy as np
import torch
from torch.nn import functional as F
import torchvision
import networks
import utils

# Grounding DINO
from groundingdino.util.inference import Model

# SAM
from segment_anything.utils.transforms import ResizeLongestSide

# SD
from diffusers import StableDiffusionPipeline

transform = ResizeLongestSide(1024)
# Green Screen
PALETTE_back = (51, 255, 146)

GROUNDING_DINO_CONFIG_PATH = "GroundingDINO/groundingdino/config/GroundingDINO_SwinT_OGC.py"
GROUNDING_DINO_CHECKPOINT_PATH = "checkpoints/groundingdino_swint_ogc.pth"
mam_checkpoint="checkpoints/mam_sam_vitb.pth"
output_dir="outputs"
device = 'cuda'
background_list = os.listdir('assets/backgrounds')

#groundingdino_model = None
#mam_predictor = None
#generator = None

# initialize MAM
mam_model = networks.get_generator_m2m(seg='sam', m2m='sam_decoder_deep')
mam_model.to(device)
checkpoint = torch.load(mam_checkpoint, map_location=device)
mam_model.load_state_dict(utils.remove_prefix_state_dict(checkpoint['state_dict']), strict=True)
mam_model = mam_model.eval()

# initialize GroundingDINO
grounding_dino_model = Model(model_config_path=GROUNDING_DINO_CONFIG_PATH, model_checkpoint_path=GROUNDING_DINO_CHECKPOINT_PATH, device=device)

# initialize StableDiffusionPipeline
generator = StableDiffusionPipeline.from_pretrained("runwayml/stable-diffusion-v1-5", torch_dtype=torch.float16)
generator.to(device)

def run_grounded_sam(input_image, text_prompt, task_type, background_prompt, background_type, box_threshold, text_threshold, iou_threshold, scribble_mode, guidance_mode):

    #global groundingdino_model, sam_predictor, generator

    # make dir
    os.makedirs(output_dir, exist_ok=True)

    #if mam_predictor is None:
        # initialize MAM
        # build model
    #    mam_model = networks.get_generator_m2m(seg='sam', m2m='sam_decoder_deep')
    #    mam_model.to(device)

        # load checkpoint
    #    checkpoint = torch.load(mam_checkpoint, map_location=device)
    #    mam_model.load_state_dict(utils.remove_prefix_state_dict(checkpoint['state_dict']), strict=True)

        # inference
    #    mam_model = mam_model.eval()

    #if groundingdino_model is None:
    #    grounding_dino_model = Model(model_config_path=GROUNDING_DINO_CONFIG_PATH, model_checkpoint_path=GROUNDING_DINO_CHECKPOINT_PATH, device=device)

    #if generator is None:
    #    generator = StableDiffusionPipeline.from_pretrained("runwayml/stable-diffusion-v1-5", torch_dtype=torch.float16)
    #    generator.to(device)

    # load image
    image_ori = input_image["image"]
    scribble = input_image["mask"]
    original_size = image_ori.shape[:2]

    if task_type == 'text':
        if text_prompt is None:
            print('Please input non-empty text prompt')
        with torch.no_grad():
            detections, phrases = grounding_dino_model.predict_with_caption(
                image=cv2.cvtColor(image_ori, cv2.COLOR_RGB2BGR),
                caption=text_prompt,
                box_threshold=box_threshold,
                text_threshold=text_threshold
            )

        if len(detections.xyxy) > 1:
            nms_idx = torchvision.ops.nms(
                torch.from_numpy(detections.xyxy), 
                torch.from_numpy(detections.confidence), 
                iou_threshold,
            ).numpy().tolist()

            detections.xyxy = detections.xyxy[nms_idx]
            detections.confidence = detections.confidence[nms_idx]
    
        bbox = detections.xyxy[np.argmax(detections.confidence)]
        bbox = transform.apply_boxes(bbox, original_size)
        bbox = torch.as_tensor(bbox, dtype=torch.float).to(device)

    image = transform.apply_image(image_ori)
    image = torch.as_tensor(image).to(device)
    image = image.permute(2, 0, 1).contiguous()

    pixel_mean = torch.tensor([123.675, 116.28, 103.53]).view(3,1,1).to(device)
    pixel_std = torch.tensor([58.395, 57.12, 57.375]).view(3,1,1).to(device)

    image = (image - pixel_mean) / pixel_std

    h, w = image.shape[-2:]
    pad_size = image.shape[-2:]
    padh = 1024 - h
    padw = 1024 - w
    image = F.pad(image, (0, padw, 0, padh))

    if task_type == 'scribble_point':
        scribble = scribble.transpose(2, 1, 0)[0]
        labeled_array, num_features = ndimage.label(scribble >= 255)
        centers = ndimage.center_of_mass(scribble, labeled_array, range(1, num_features+1))
        centers = np.array(centers)
        ### (x,y)
        centers = transform.apply_coords(centers, original_size)
        point_coords = torch.from_numpy(centers).to(device)
        point_coords = point_coords.unsqueeze(0).to(device)
        point_labels = torch.from_numpy(np.array([1] * len(centers))).unsqueeze(0).to(device)
        if scribble_mode == 'split':
            point_coords = point_coords.permute(1, 0, 2)
            point_labels = point_labels.permute(1, 0)
            
        sample = {'image': image.unsqueeze(0), 'point': point_coords, 'label': point_labels, 'ori_shape': original_size, 'pad_shape': pad_size}
    elif task_type == 'scribble_box':
        scribble = scribble.transpose(2, 1, 0)[0]
        labeled_array, num_features = ndimage.label(scribble >= 255)
        centers = ndimage.center_of_mass(scribble, labeled_array, range(1, num_features+1))
        centers = np.array(centers)
        ### (x1, y1, x2, y2)
        x_min = centers[:, 0].min()
        x_max = centers[:, 0].max()
        y_min = centers[:, 1].min()
        y_max = centers[:, 1].max()
        bbox = np.array([x_min, y_min, x_max, y_max])
        bbox = transform.apply_boxes(bbox, original_size)
        bbox = torch.as_tensor(bbox, dtype=torch.float).to(device)

        sample = {'image': image.unsqueeze(0), 'bbox': bbox.unsqueeze(0), 'ori_shape': original_size, 'pad_shape': pad_size}
    elif task_type == 'text':
        sample = {'image': image.unsqueeze(0), 'bbox': bbox.unsqueeze(0), 'ori_shape': original_size, 'pad_shape': pad_size}
    else:
        print("task_type:{} error!".format(task_type))

    with torch.no_grad():
        feas, pred, post_mask = mam_model.forward_inference(sample)

        alpha_pred_os1, alpha_pred_os4, alpha_pred_os8 = pred['alpha_os1'], pred['alpha_os4'], pred['alpha_os8']
        alpha_pred_os8 = alpha_pred_os8[..., : sample['pad_shape'][0], : sample['pad_shape'][1]]
        alpha_pred_os4 = alpha_pred_os4[..., : sample['pad_shape'][0], : sample['pad_shape'][1]]
        alpha_pred_os1 = alpha_pred_os1[..., : sample['pad_shape'][0], : sample['pad_shape'][1]]

        alpha_pred_os8 = F.interpolate(alpha_pred_os8, sample['ori_shape'], mode="bilinear", align_corners=False)
        alpha_pred_os4 = F.interpolate(alpha_pred_os4, sample['ori_shape'], mode="bilinear", align_corners=False)
        alpha_pred_os1 = F.interpolate(alpha_pred_os1, sample['ori_shape'], mode="bilinear", align_corners=False)
        
        if guidance_mode == 'mask':
            weight_os8 = utils.get_unknown_tensor_from_mask_oneside(post_mask, rand_width=10, train_mode=False)
            post_mask[weight_os8>0] = alpha_pred_os8[weight_os8>0]
            alpha_pred = post_mask.clone().detach()
        else:
            weight_os8 = utils.get_unknown_box_from_mask(post_mask)
            alpha_pred_os8[weight_os8>0] = post_mask[weight_os8>0]
            alpha_pred = alpha_pred_os8.clone().detach()


        weight_os4 = utils.get_unknown_tensor_from_pred_oneside(alpha_pred, rand_width=20, train_mode=False)
        alpha_pred[weight_os4>0] = alpha_pred_os4[weight_os4>0]
        
        weight_os1 = utils.get_unknown_tensor_from_pred_oneside(alpha_pred, rand_width=10, train_mode=False)
        alpha_pred[weight_os1>0] = alpha_pred_os1[weight_os1>0]
       
        alpha_pred = alpha_pred[0][0].cpu().numpy()

    #### draw
    ### alpha matte
    alpha_rgb = cv2.cvtColor(np.uint8(alpha_pred*255), cv2.COLOR_GRAY2RGB)
    ### com img with background
    if background_type == 'real_world_sample':
        background_img_file = os.path.join('assets/backgrounds', random.choice(background_list))
        background_img = cv2.imread(background_img_file)
        background_img = cv2.cvtColor(background_img, cv2.COLOR_BGR2RGB)
        background_img = cv2.resize(background_img, (image_ori.shape[1], image_ori.shape[0]))
        com_img = alpha_pred[..., None] * image_ori + (1 - alpha_pred[..., None]) * np.uint8(background_img)
        com_img = np.uint8(com_img)
    else:
        if background_prompt is None:
            print('Please input non-empty background prompt')
        else:
            background_img = generator(background_prompt).images[0]
            background_img = np.array(background_img)
            background_img = cv2.resize(background_img, (image_ori.shape[1], image_ori.shape[0]))
            com_img = alpha_pred[..., None] * image_ori + (1 - alpha_pred[..., None]) * np.uint8(background_img)
            com_img = np.uint8(com_img)
    ### com img with green screen
    green_img = alpha_pred[..., None] * image_ori + (1 - alpha_pred[..., None]) * np.array([PALETTE_back], dtype='uint8')
    green_img = np.uint8(green_img)
    return [(com_img, 'composite with background'), (green_img, 'green screen'), (alpha_rgb, 'alpha matte')]

if __name__ == "__main__":
    parser = argparse.ArgumentParser("MAM demo", add_help=True)
    parser.add_argument("--debug", action="store_true", help="using debug mode")
    parser.add_argument("--share", action="store_true", help="share the app")
    parser.add_argument('--port', type=int, default=7589, help='port to run the server')
    parser.add_argument('--no-gradio-queue', action="store_true", help='path to the SAM checkpoint')
    args = parser.parse_args()

    print(args)

    block = gr.Blocks()
    if not args.no_gradio_queue:
        block = block.queue()

    with block:
        gr.Markdown(
        """
        # MAM Demo
        Welcome to the MAM demo and upload your image to get started <br/> You may select different prompt types to get the alpha matte of target instance, and select different backgrounds for image composition.
        ## Usage
        You may check the <a href='https://www.youtube.com/watch?v=XY2Q0HATGOk'>video</a> to see how to play with the demo, or check the details below.
        <details>
        You may upload an image to start, we support 3 prompt types to get the alpha matte of the target instance：

        **scribble_point**: Click an point on the target instance.

        **scribble_box**: Click on two points, the top-left point and the bottom-right point to represent a bounding box of the target instance.

        **text**: Send text prompt to identify the target instance in the `Text prompt` box.

        We also support 2 background types to support image composition with the alpha matte output:

        **real_world_sample**: Randomly select a real-world image from `assets/backgrounds` for composition.

        **generated_by_text**: Send background text prompt to create a background image with stable diffusion model in the `Background prompt` box.
        </details>
        """)
   
        with gr.Row():
            with gr.Column():
                input_image = gr.Image(source='upload', type="numpy", value="assets/demo.jpg", tool="sketch")
                task_type = gr.Dropdown(["scribble_point", "scribble_box", "text"], value="text", label="Prompt type")
                text_prompt = gr.Textbox(label="Text prompt", placeholder="the girl in the middle")
                background_type = gr.Dropdown(["generated_by_text", "real_world_sample"], value="generated_by_text", label="Background type")
                background_prompt = gr.Textbox(label="Background prompt", placeholder="downtown area in New York")
                run_button = gr.Button(label="Run")
                with gr.Accordion("Advanced options", open=False):
                    box_threshold = gr.Slider(
                        label="Box Threshold", minimum=0.0, maximum=1.0, value=0.25, step=0.05
                    )
                    text_threshold = gr.Slider(
                        label="Text Threshold", minimum=0.0, maximum=1.0, value=0.25, step=0.05
                    )
                    iou_threshold = gr.Slider(
                        label="IOU Threshold", minimum=0.0, maximum=1.0, value=0.5, step=0.05
                    )
                    scribble_mode = gr.Dropdown(
                        ["merge", "split"], value="split", label="scribble_mode"
                    )
                    guidance_mode = gr.Dropdown(
                        ["mask", "alpha"], value="alpha", label="guidance_mode", info="mask guidance is for complex scenes with multiple instances, alpha guidance is for simple scene with single instance"
                    )

            with gr.Column():
                gallery = gr.Gallery(
                    label="Generated images", show_label=True, elem_id="gallery"
                ).style(preview=True, grid=3, object_fit="scale-down")

        run_button.click(fn=run_grounded_sam, inputs=[
                        input_image, text_prompt, task_type, background_prompt, background_type, box_threshold, text_threshold, iou_threshold, scribble_mode, guidance_mode], outputs=gallery)

    block.launch(debug=args.debug, share=args.share, show_error=True)
    #block.queue(concurrency_count=100)
    #block.launch(server_name='0.0.0.0', server_port=args.port, debug=args.debug, share=args.share)