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import cv2
from PIL import Image
import numpy as np
import functools
import time
def calTime(mark):
"""
一个输出函数时间的装饰器.
:param mark: str, 可选填, 如果填了就会在print开头加上mark标签。
"""
if isinstance(mark, str):
def decorater(func):
@functools.wraps(func)
def wrapper(*args, **kw):
start_time = time.time()
return_param = func(*args, **kw)
print("[Mark-{}] {} 函数花费的时间为 {:.2f}.".format(mark, func.__name__, time.time() - start_time))
return return_param
return wrapper
return decorater
else:
func = mark
@functools.wraps(func)
def wrapper(*args, **kw):
start_time = time.time()
return_param = func(*args, **kw)
print("{} 函数花费的时间为 {:.2f}.".format(func.__name__, time.time() - start_time))
return return_param
return wrapper
def ChangeImageDPI(input_path, output_path, dpi=300):
"""
改变输入图像的dpi.
input_path: 输入图像路径
output_path: 输出图像路径
dpi:打印分辨率
"""
image = Image.open(input_path)
image.save(output_path, dpi=(dpi, dpi))
# print(1)
print("Your Image's DPI have been changed. The last DPI = ({},{}) ".format(dpi,dpi))
def IDphotos_cut(x1, y1, x2, y2, img):
"""
在图片上进行滑动裁剪,输入输出为
输入:一张图片img,和裁剪框信息(x1,x2,y1,y2)
输出: 裁剪好的图片,然后裁剪框超出了图像范围,那么将用0矩阵补位
------------------------------------
x:裁剪框左上的横坐标
y:裁剪框左上的纵坐标
x2:裁剪框右下的横坐标
y2:裁剪框右下的纵坐标
crop_size:裁剪框大小
img:裁剪图像(numpy.array)
output_path:裁剪图片的输出路径
------------------------------------
"""
crop_size = (y2-y1, x2-x1)
"""
------------------------------------
temp_x_1:裁剪框左边超出图像部分
temp_y_1:裁剪框上边超出图像部分
temp_x_2:裁剪框右边超出图像部分
temp_y_2:裁剪框下边超出图像部分
------------------------------------
"""
temp_x_1 = 0
temp_y_1 = 0
temp_x_2 = 0
temp_y_2 = 0
if y1 < 0:
temp_y_1 = abs(y1)
y1 = 0
if y2 > img.shape[0]:
temp_y_2 = y2
y2 = img.shape[0]
temp_y_2 = temp_y_2 - y2
if x1 < 0:
temp_x_1 = abs(x1)
x1 = 0
if x2 > img.shape[1]:
temp_x_2 = x2
x2 = img.shape[1]
temp_x_2 = temp_x_2 - x2
# 生成一张全透明背景
print("crop_size:", crop_size)
background_bgr = np.full((crop_size[0], crop_size[1]), 255, dtype=np.uint8)
background_a = np.full((crop_size[0], crop_size[1]), 0, dtype=np.uint8)
background = cv2.merge((background_bgr, background_bgr, background_bgr, background_a))
background[temp_y_1: crop_size[0] - temp_y_2, temp_x_1: crop_size[1] - temp_x_2] = img[y1:y2, x1:x2]
return background
def resize_image_esp(input_image, esp=2000):
"""
输入:
input_path:numpy图片
esp:限制的最大边长
"""
# resize函数=>可以让原图压缩到最大边为esp的尺寸(不改变比例)
width = input_image.shape[0]
length = input_image.shape[1]
max_num = max(width, length)
if max_num > esp:
print("Image resizing...")
if width == max_num:
length = int((esp / width) * length)
width = esp
else:
width = int((esp / length) * width)
length = esp
print(length, width)
im_resize = cv2.resize(input_image, (length, width), interpolation=cv2.INTER_AREA)
return im_resize
else:
return input_image
def resize_image_by_min(input_image, esp=600):
"""
将图像缩放为最短边至少为esp的图像。
:param input_image: 输入图像(OpenCV矩阵)
:param esp: 缩放后的最短边长
:return: 缩放后的图像,缩放倍率
"""
height, width = input_image.shape[0], input_image.shape[1]
min_border = min(height, width)
if min_border < esp:
if height >= width:
new_width = esp
new_height = height * esp // width
else:
new_height = esp
new_width = width * esp // height
return cv2.resize(input_image, (new_width, new_height), interpolation=cv2.INTER_AREA), new_height / height
else:
return input_image, 1
def detect_distance(value, crop_heigh, max=0.06, min=0.04):
"""
检测人头顶与照片顶部的距离是否在适当范围内。
输入:与顶部的差值
输出:(status, move_value)
status=0 不动
status=1 人脸应向上移动(裁剪框向下移动)
status-2 人脸应向下移动(裁剪框向上移动)
---------------------------------------
value:头顶与照片顶部的距离·
crop_heigh: 裁剪框的高度
max: 距离的最大值
min: 距离的最小值
---------------------------------------
"""
value = value / crop_heigh # 头顶往上的像素占图像的比例
if min <= value <= max:
return 0, 0
elif value > max:
# 头顶往上的像素比例高于max
move_value = value - max
move_value = int(move_value * crop_heigh)
# print("上移{}".format(move_value))
return 1, move_value
else:
# 头顶往上的像素比例低于min
move_value = min - value
move_value = int(move_value * crop_heigh)
# print("下移{}".format(move_value))
return -1, move_value
def draw_picture_dots(image, dots, pen_size=10, pen_color=(0, 0, 255)):
"""
给一张照片上绘制点。
image: Opencv图像矩阵
dots: 一堆点,形如[(100,100),(150,100)]
pen_size: 画笔的大小
pen_color: 画笔的颜色
"""
if isinstance(dots, dict):
dots = [v for u, v in dots.items()]
image = image.copy()
for x, y in dots:
cv2.circle(image, (int(x), int(y)), pen_size, pen_color, -1)
return image
def draw_picture_rectangle(image, bbox, pen_size=2, pen_color=(0, 0, 255)):
image = image.copy()
x1 = int(bbox[0])
y1 = int(bbox[1])
x2 = int(bbox[2])
y2 = int(bbox[3])
cv2.rectangle(image, (x1,y1), (x2, y2), pen_color, pen_size)
return image
def generate_gradient(start_color, width, height, mode="updown"):
# 定义背景颜色
end_color = (255, 255, 255) # 白色
# 创建一个空白图像
r_out = np.zeros((height, width), dtype=int)
g_out = np.zeros((height, width), dtype=int)
b_out = np.zeros((height, width), dtype=int)
if mode == "updown":
# 生成上下渐变色
for y in range(height):
r = int((y / height) * end_color[0] + ((height - y) / height) * start_color[0])
g = int((y / height) * end_color[1] + ((height - y) / height) * start_color[1])
b = int((y / height) * end_color[2] + ((height - y) / height) * start_color[2])
r_out[y, :] = r
g_out[y, :] = g
b_out[y, :] = b
else:
# 生成中心渐变色
img = np.zeros((height, width, 3))
# 定义椭圆中心和半径
center = (width//2, height//2)
end_axies = max(height, width)
# 定义渐变色
end_color = (255, 255, 255)
# 绘制椭圆
for y in range(end_axies):
axes = (end_axies - y, end_axies - y)
r = int((y / end_axies) * end_color[0] + ((end_axies - y) / end_axies) * start_color[0])
g = int((y / end_axies) * end_color[1] + ((end_axies - y) / end_axies) * start_color[1])
b = int((y / end_axies) * end_color[2] + ((end_axies - y) / end_axies) * start_color[2])
cv2.ellipse(img, center, axes, 0, 0, 360, (b, g, r), -1)
b_out, g_out, r_out = cv2.split(np.uint64(img))
return r_out, g_out, b_out
def add_background(input_image, bgr=(0, 0, 0), mode="pure_color"):
"""
本函数的功能为为透明图像加上背景。
:param input_image: numpy.array(4 channels), 透明图像
:param bgr: tuple, 合成纯色底时的BGR值
:param new_background: numpy.array(3 channels),合成自定义图像底时的背景图
:return: output: 合成好的输出图像
"""
height, width = input_image.shape[0], input_image.shape[1]
b, g, r, a = cv2.split(input_image)
a_cal = a / 255
if mode == "pure_color":
# 纯色填充
b2 = np.full([height, width], bgr[0], dtype=int)
g2 = np.full([height, width], bgr[1], dtype=int)
r2 = np.full([height, width], bgr[2], dtype=int)
elif mode == "updown_gradient":
b2, g2, r2 = generate_gradient(bgr, width, height, mode="updown")
else:
b2, g2, r2 = generate_gradient(bgr, width, height, mode="center")
output = cv2.merge(((b - b2) * a_cal + b2, (g - g2) * a_cal + g2, (r - r2) * a_cal + r2))
return output
def rotate_bound(image, angle):
"""
一个旋转函数,输入一张图片和一个旋转角,可以实现不损失图像信息的旋转。
- image: numpy.array(3 channels)
- angle: 旋转角(度)
"""
(h, w) = image.shape[:2]
(cX, cY) = (w / 2, h / 2)
M = cv2.getRotationMatrix2D((cX, cY), -angle, 1.0)
cos = np.abs(M[0, 0])
sin = np.abs(M[0, 1])
nW = int((h * sin) + (w * cos))
nH = int((h * cos) + (w * sin))
M[0, 2] += (nW / 2) - cX
M[1, 2] += (nH / 2) - cY
return cv2.warpAffine(image, M, (nW, nH)), cos, sin
def rotate_bound_4channels(image, a, angle):
"""
【rotate_bound_4channels的4通道版本】
一个旋转函数,输入一张图片和一个旋转角,可以实现不损失图像信息的旋转。
Inputs:
- image: numpy.array(3 channels), 输入图像
- a: numpy.array(1 channels), 输入图像的A矩阵
- angle: 旋转角(度)
Returns:
- input_image: numpy.array(3 channels), 对image进行旋转后的图像
- result_image: numpy.array(4 channels), 旋转且透明的图像
- cos: float, 旋转角的余弦值
- sin: float, 旋转角的正弦值
"""
input_image, cos, sin = rotate_bound(image, angle)
new_a, _, _ = rotate_bound(a, angle) # 对做matte旋转,以便之后merge
b, g, r = cv2.split(input_image)
result_image = cv2.merge((b, g, r, new_a)) # 得到抠图结果图的无损旋转结果
return input_image, result_image, cos, sin
def cover_image(image, background, x, y, mode=1):
"""
mode = 1: directly cover
mode = 2: cv2.add
mode = 3: bgra cover
"""
image = image.copy()
background = background.copy()
height1, width1 = background.shape[0], background.shape[1]
height2, width2 = image.shape[0], image.shape[1]
wuqiong_bg_y = height1 + 1
wuqiong_bg_x = width1 + 1
wuqiong_img_y = height2 + 1
wuqiong_img_x = width2 + 1
def cover_mode(image, background, imgy1=0, imgy2=-1, imgx1=0, imgx2=-1, bgy1=0, bgy2=-1, bgx1=0, bgx2=-1, mode=1):
if mode == 1:
background[bgy1:bgy2, bgx1:bgx2] = image[imgy1:imgy2, imgx1:imgx2]
elif mode == 2:
background[bgy1:bgy2, bgx1:bgx2] = cv2.add(background[bgy1:bgy2, bgx1:bgx2], image[imgy1:imgy2, imgx1:imgx2])
elif mode == 3:
b, g, r, a = cv2.split(image[imgy1:imgy2, imgx1:imgx2])
b2, g2, r2, a2 = cv2.split(background[bgy1:bgy2, bgx1:bgx2])
background[bgy1:bgy2, bgx1:bgx2, 0] = b * (a / 255) + b2 * (1 - a / 255)
background[bgy1:bgy2, bgx1:bgx2, 1] = g * (a / 255) + g2 * (1 - a / 255)
background[bgy1:bgy2, bgx1:bgx2, 2] = r * (a / 255) + r2 * (1 - a / 255)
background[bgy1:bgy2, bgx1:bgx2, 3] = cv2.add(a, a2)
return background
if x >= 0 and y >= 0:
x2 = x + width2
y2 = y + height2
if x2 <= width1 and y2 <= height1:
background = cover_mode(image, background,0,wuqiong_img_y,0,wuqiong_img_x,y,y2,x,x2,mode)
elif x2 > width1 and y2 <= height1:
# background[y:y2, x:] = image[:, :width1 - x]
background = cover_mode(image, background, 0, wuqiong_img_y, 0, width1-x, y, y2, x, wuqiong_bg_x,mode)
elif x2 <= width1 and y2 > height1:
# background[y:, x:x2] = image[:height1 - y, :]
background = cover_mode(image, background, 0, height1-y, 0, wuqiong_img_x, y, wuqiong_bg_y, x, x2,mode)
else:
# background[y:, x:] = image[:height1 - y, :width1 - x]
background = cover_mode(image, background, 0, height1-y, 0, width1-x, y, wuqiong_bg_y, x, wuqiong_bg_x,mode)
elif x < 0 and y >= 0:
x2 = x + width2
y2 = y + height2
if x2 <= width1 and y2 <= height1:
# background[y:y2, :x + width2] = image[:, abs(x):]
background = cover_mode(image, background, 0, wuqiong_img_y, abs(x), wuqiong_img_x, y, y2, 0, x+width2,mode)
elif x2 > width1 and y2 <= height1:
background = cover_mode(image, background, 0, wuqiong_img_y, abs(x), width1+abs(x), y, y2, 0, wuqiong_bg_x,mode)
elif x2 <= 0:
pass
elif x2 <= width1 and y2 > height1:
background = cover_mode(image, background, 0, height1-y, abs(x), wuqiong_img_x, y, wuqiong_bg_y, 0, x2, mode)
else:
# background[y:, :] = image[:height1 - y, abs(x):width1 + abs(x)]
background = cover_mode(image, background, 0, height1-y, abs(x), width1+abs(x), y, wuqiong_bg_y, 0, wuqiong_bg_x,mode)
elif x >= 0 and y < 0:
x2 = x + width2
y2 = y + height2
if y2 <= 0:
pass
if x2 <= width1 and y2 <= height1:
# background[:y2, x:x2] = image[abs(y):, :]
background = cover_mode(image, background, abs(y), wuqiong_img_y, 0, wuqiong_img_x, 0, y2, x, x2,mode)
elif x2 > width1 and y2 <= height1:
# background[:y2, x:] = image[abs(y):, :width1 - x]
background = cover_mode(image, background, abs(y), wuqiong_img_y, 0, width1-x, 0, y2, x, wuqiong_bg_x,mode)
elif x2 <= width1 and y2 > height1:
# background[:, x:x2] = image[abs(y):height1 + abs(y), :]
background = cover_mode(image, background, abs(y), height1+abs(y), 0, wuqiong_img_x, 0, wuqiong_bg_y, x, x2,mode)
else:
# background[:, x:] = image[abs(y):height1 + abs(y), :width1 - abs(x)]
background = cover_mode(image, background, abs(y), height1+abs(y), 0, width1-abs(x), 0, wuqiong_bg_x, x, wuqiong_bg_x,mode)
else:
x2 = x + width2
y2 = y + height2
if y2 <= 0 or x2 <= 0:
pass
if x2 <= width1 and y2 <= height1:
# background[:y2, :x2] = image[abs(y):, abs(x):]
background = cover_mode(image, background, abs(y), wuqiong_img_y, abs(x), wuqiong_img_x, 0, y2, 0, x2,mode)
elif x2 > width1 and y2 <= height1:
# background[:y2, :] = image[abs(y):, abs(x):width1 + abs(x)]
background = cover_mode(image, background, abs(y), wuqiong_img_y, abs(x), width1+abs(x), 0, y2, 0, wuqiong_bg_x,mode)
elif x2 <= width1 and y2 > height1:
# background[:, :x2] = image[abs(y):height1 + abs(y), abs(x):]
background = cover_mode(image, background, abs(y), height1+abs(y), abs(x), wuqiong_img_x, 0, wuqiong_bg_y, 0, x2,mode)
else:
# background[:, :] = image[abs(y):height1 - abs(y), abs(x):width1 + abs(x)]
background = cover_mode(image, background, abs(y), height1-abs(y), abs(x), width1+abs(x), 0, wuqiong_bg_y, 0, wuqiong_bg_x,mode)
return background
def image2bgr(input_image):
if len(input_image.shape) == 2:
input_image = input_image[:, :, None]
if input_image.shape[2] == 1:
result_image = np.repeat(input_image, 3, axis=2)
elif input_image.shape[2] == 4:
result_image = input_image[:, :, 0:3]
else:
result_image = input_image
return result_image
if __name__ == "__main__":
image = cv2.imread("./03.png", -1)
result_image = add_background(image, bgr=(255, 255, 255))
cv2.imwrite("test.jpg", result_image)