class TextProposalConnector:
def __init__(self):
self.graph_builder = TextProposalGraphBuilder()
def group_text_proposals(self, text_proposals, scores, im_size):
graph = self.graph_builder.build_graph(text_proposals, scores, im_size)
return graph.sub_graphs_connected()
def fit_y(self, X, Y, x1, x2):
len(X) != 0
# if X only include one point, the function will get line y=Y[0]
if np.sum(X == X[0]) == len(X):
return Y[0], Y[0]
p = np.poly1d(np.polyfit(X, Y, 1))
return p(x1), p(x2)
def get_text_lines(self, text_proposals, scores, im_size):
# tp=text proposal
tp_groups = self.group_text_proposals(text_proposals, scores, im_size)
text_lines = np.zeros((len(tp_groups), 5), np.float32)
for index, tp_indices in enumerate(tp_groups):
text_line_boxes = text_proposals[list(tp_indices)]
x0 = np.min(text_line_boxes[:, 0])
x1 = np.max(text_line_boxes[:, 2])
offset = (text_line_boxes[0, 2] - text_line_boxes[0, 0]) * 0.5
lt_y, rt_y = self.fit_y(text_line_boxes[:, 0], text_line_boxes[:, 1], x0 + offset, x1 - offset)
lb_y, rb_y = self.fit_y(text_line_boxes[:, 0], text_line_boxes[:, 3], x0 + offset, x1 - offset)
# the score of a text line is the average score of the scores
# of all text proposals contained in the text line
score = scores[list(tp_indices)].sum() / float(len(tp_indices))
text_lines[index, 0] = x0
text_lines[index, 1] = min(lt_y, rt_y)
text_lines[index, 2] = x1
text_lines[index, 3] = max(lb_y, rb_y)
text_lines[index, 4] = score
text_lines = clip_boxes(text_lines, im_size)
text_recs = np.zeros((len(text_lines), 9), np.float)
index = 0
for line in text_lines:
xmin, ymin, xmax, ymax = line[0], line[1], line[2], line[3]
text_recs[index, 0] = xmin
text_recs[index, 1] = ymin
text_recs[index, 2] = xmax
text_recs[index, 3] = ymin
text_recs[index, 4] = xmax
text_recs[index, 5] = ymax
text_recs[index, 6] = xmin
text_recs[index, 7] = ymax
text_recs[index, 8] = line[4]
index = index + 1
return text_recs
class TextProposalConnector:
"""
Connect text proposals into text lines
"""
def __init__(self):
self.graph_builder = TextProposalGraphBuilder()
def group_text_proposals(self, text_proposals, scores, im_size):
graph = self.graph_builder.build_graph(text_proposals, scores, im_size)
return graph.sub_graphs_connected()
def fit_y(self, X, Y, x1, x2):
len(X) != 0
# if X only include one point, the function will get line y=Y[0]
if np.sum(X == X[0]) == len(X):
return Y[0], Y[0]
p = np.poly1d(np.polyfit(X, Y, 1))
return p(x1), p(x2)
def get_text_lines(self, text_proposals, scores, im_size):
"""
text_proposals:boxes
"""
# tp=text proposal
tp_groups = self.group_text_proposals(text_proposals, scores, im_size) # 首先还是建图,获取到文本行由哪几个小框构成
text_lines = np.zeros((len(tp_groups), 8), np.float32)
for index, tp_indices in enumerate(tp_groups):
text_line_boxes = text_proposals[list(tp_indices)] # 每个文本行的全部小框
X = (text_line_boxes[:, 0] + text_line_boxes[:, 2]) / 2 # 求每一个小框的中心x,y坐标
Y = (text_line_boxes[:, 1] + text_line_boxes[:, 3]) / 2
z1 = np.polyfit(X, Y, 1) # 多项式拟合,根据之前求的中心店拟合一条直线(最小二乘)
x0 = np.min(text_line_boxes[:, 0]) # 文本行x坐标最小值
x1 = np.max(text_line_boxes[:, 2]) # 文本行x坐标最大值
offset = (text_line_boxes[0, 2] - text_line_boxes[0, 0]) * 0.5 # 小框宽度的一半
# 以全部小框的左上角这个点去拟合一条直线,然后计算一下文本行x坐标的极左极右对应的y坐标
lt_y, rt_y = self.fit_y(text_line_boxes[:, 0], text_line_boxes[:, 1], x0 + offset, x1 - offset)
# 以全部小框的左下角这个点去拟合一条直线,然后计算一下文本行x坐标的极左极右对应的y坐标
lb_y, rb_y = self.fit_y(text_line_boxes[:, 0], text_line_boxes[:, 3], x0 + offset, x1 - offset)
score = scores[list(tp_indices)].sum() / float(len(tp_indices)) # 求全部小框得分的均值作为文本行的均值
text_lines[index, 0] = x0
text_lines[index, 1] = min(lt_y, rt_y) # 文本行上端 线段 的y坐标的小值
text_lines[index, 2] = x1
text_lines[index, 3] = max(lb_y, rb_y) # 文本行下端 线段 的y坐标的大值
text_lines[index, 4] = score # 文本行得分
text_lines[index, 5] = z1[0] # 根据中心点拟合的直线的k,b
text_lines[index, 6] = z1[1]
height = np.mean((text_line_boxes[:, 3] - text_line_boxes[:, 1])) # 小框平均高度
text_lines[index, 7] = height + 2.5
text_recs = np.zeros((len(text_lines), 9), np.float)
index = 0
for line in text_lines:
b1 = line[6] - line[7] / 2 # 根据高度和文本行中心线,求取文本行上下两条线的b值
b2 = line[6] + line[7] / 2
x1 = line[0]
y1 = line[5] * line[0] + b1 # 左上
x2 = line[2]
y2 = line[5] * line[2] + b1 # 右上
x3 = line[0]
y3 = line[5] * line[0] + b2 # 左下
x4 = line[2]
y4 = line[5] * line[2] + b2 # 右下
disX = x2 - x1
disY = y2 - y1
width = np.sqrt(disX * disX + disY * disY) # 文本行宽度
fTmp0 = y3 - y1 # 文本行高度
fTmp1 = fTmp0 * disY / width
x = np.fabs(fTmp1 * disX / width) # 做补偿
y = np.fabs(fTmp1 * disY / width)
if line[5] < 0:
x1 -= x
y1 += y
x4 += x
y4 -= y
else:
x2 += x
y2 += y
x3 -= x
y3 -= y
text_recs[index, 0] = x1
text_recs[index, 1] = y1
text_recs[index, 2] = x2
text_recs[index, 3] = y2
text_recs[index, 4] = x4
text_recs[index, 5] = y4
text_recs[index, 6] = x3
text_recs[index, 7] = y3
text_recs[index, 8] = line[4]
index = index + 1
return text_recs
def __init__(self):
self.graph_builder = TextProposalGraphBuilder()