screencoder/UIED/detect_compo/ip_region_proposal.py

import cv2
from os.path import join as pjoin
import time
import json
import numpy as np

import detect_compo.lib_ip.ip_preprocessing as pre
import detect_compo.lib_ip.ip_draw as draw
import detect_compo.lib_ip.ip_detection as det
import detect_compo.lib_ip.file_utils as file
import detect_compo.lib_ip.Component as Compo
from config.CONFIG_UIED import Config
C = Config()


def resolve_uicompo_containment(uicompos):
    """
    Resolves containment issues among UI components.
    If a component's bounding box is fully contained within another's, it is removed.
    """
    
    def contains(bbox_a, bbox_b):
        """Checks if bbox_a completely contains bbox_b."""
        return bbox_a.col_min <= bbox_b.col_min and \
               bbox_a.row_min <= bbox_b.row_min and \
               bbox_a.col_max >= bbox_b.col_max and \
               bbox_a.row_max >= bbox_b.row_max

    compos_to_remove = set()
    for i, compo1 in enumerate(uicompos):
        for j, compo2 in enumerate(uicompos):
            if i == j:
                continue
            
            # Check if compo1 contains compo2
            if contains(compo1.bbox, compo2.bbox):
                compos_to_remove.add(j)

    # Filter out the contained components
    final_compos = [compo for i, compo in enumerate(uicompos) if i not in compos_to_remove]
    
    if len(final_compos) < len(uicompos):
        print(f"Containment resolved: Removed {len(uicompos) - len(final_compos)} contained components.")
        
    return final_compos


def nesting_inspection(org, grey, compos, ffl_block):
    '''
    Inspect all big compos through block division by flood-fill
    :param ffl_block: gradient threshold for flood-fill
    :return: nesting compos
    '''
    nesting_compos = []
    for i, compo in enumerate(compos):
        if compo.height > 50:
            replace = False
            clip_grey = compo.compo_clipping(grey)
            n_compos = det.nested_components_detection(clip_grey, org, grad_thresh=ffl_block, show=False)
            Compo.cvt_compos_relative_pos(n_compos, compo.bbox.col_min, compo.bbox.row_min)

            for n_compo in n_compos:
                if n_compo.redundant:
                    compos[i] = n_compo
                    replace = True
                    break
            if not replace:
                nesting_compos += n_compos
    return nesting_compos


def compo_detection(input_img_path, output_root, uied_params,
                    resize_by_height=800, classifier=None, show=False, wai_key=0):

    start = time.perf_counter()
    name = input_img_path.split('/')[-1][:-4] if '/' in input_img_path else input_img_path.split('\\')[-1][:-4]
    ip_root = file.build_directory(pjoin(output_root, "ip"))

    # *** Step 1 *** pre-processing: read img -> get binary map
    org, grey = pre.read_img(input_img_path, resize_by_height)
    binary = pre.binarization(org, grad_min=int(uied_params['min-grad']))

    # *** Step 2 *** element detection
    det.rm_line(binary, show=show, wait_key=wai_key)
    uicompos = det.component_detection(binary, min_obj_area=int(uied_params['min-ele-area']))

    # *** Step 3 *** results refinement
    uicompos = det.compo_filter(uicompos, min_area=int(uied_params['min-ele-area']), img_shape=binary.shape)
    uicompos = det.merge_intersected_compos(uicompos)
    det.compo_block_recognition(binary, uicompos)
    if uied_params['merge-contained-ele']:
        uicompos = det.rm_contained_compos_not_in_block(uicompos)
    Compo.compos_update(uicompos, org.shape)
    Compo.compos_containment(uicompos)

    # *** Step 4 ** nesting inspection: check if big compos have nesting element
    uicompos += nesting_inspection(org, grey, uicompos, ffl_block=uied_params['ffl-block'])
    Compo.compos_update(uicompos, org.shape)
    draw.draw_bounding_box(org, uicompos, show=show, name='merged compo', write_path=pjoin(ip_root, name + '.jpg'), wait_key=wai_key)

    # *** Step 5 *** image inspection: recognize image -> remove noise in image -> binarize with larger threshold and reverse -> rectangular compo detection
    # if classifier is not None:
    #     classifier['Image'].predict(seg.clipping(org, uicompos), uicompos)
    #     draw.draw_bounding_box_class(org, uicompos, show=show)
    #     uicompos = det.rm_noise_in_large_img(uicompos, org)
    #     draw.draw_bounding_box_class(org, uicompos, show=show)
    #     det.detect_compos_in_img(uicompos, binary_org, org)
    #     draw.draw_bounding_box(org, uicompos, show=show)
    # if classifier is not None:
    #     classifier['Noise'].predict(seg.clipping(org, uicompos), uicompos)
    #     draw.draw_bounding_box_class(org, uicompos, show=show)
    #     uicompos = det.rm_noise_compos(uicompos)

    # *** Step 6 *** element classification: all category classification
    # if classifier is not None:
    #     classifier['Elements'].predict([compo.compo_clipping(org) for compo in uicompos], uicompos)
    #     draw.draw_bounding_box_class(org, uicompos, show=show, name='cls', write_path=pjoin(ip_root, 'result.jpg'))
    #     draw.draw_bounding_box_class(org, uicompos, write_path=pjoin(output_root, 'result.jpg'))

    # *** Step 7 *** save detection result
    Compo.compos_update(uicompos, org.shape)
    
    # *** Step 8 *** Resolve containment before saving
    uicompos = resolve_uicompo_containment(uicompos)

    file.save_corners_json(pjoin(ip_root, name + '.json'), uicompos)
    print("[Compo Detection Completed in %.3f s] Input: %s Output: %s" % (time.perf_counter() - start, input_img_path, pjoin(ip_root, name + '.json')))
    return uicompos