Python&Appium实现安卓手机图形解锁

首先,在解锁状态下,建立一个Session,打开APP。然后,调用press_keycode()方法传入整型数值"26",锁定屏幕。通过implicitly_wait()方法等待两秒后,再次调用press_keycode()方法按下电源键,点亮屏幕。这时候看到的手机界面如下所示:

Python&Appium实现安卓手机图形解锁

此时,我们需要调用login_unlock()方法绘制图案解锁手机(预先设置好的解锁图形如上图所示)。

login_unlock()方法的详细介绍如下:

1、通过find_element_by_id()方法找到九宫格的View。

lock_pattern = self.driver.find_element_by_id("com.android.keyguard:id/lockPatternView")

2、通过lock_pattern变量获取View的初始坐标值和宽度高度。

x = lock_pattern.location.get('x') y = lock_pattern.location.get('y') width = lock_pattern.size.get('width') height = lock_pattern.size.get('height')

3、通过宽度计算偏移量。

offset = width / 6

4、通过偏移量计算九宫格内九个点各自的x,y坐标值。

p11 = int(x + width / 6), int(y + height / 6) p12 = int(x + width / 2), int(y + height / 6) p13 = int(x + width - offset), int(y + height / 6) p21 = int(x + width / 6), int(y + height / 2) p22 = int(x + width / 2), int(y + height / 2) p23 = int(x + width - offset), int(y + height / 2) p31 = int(x + width / 6), int(y + height - offset) p32 = int(x + width / 2), int(y + height - offset) p33 = int(x + width - offset), int(y + height - offset)

5、计算从当前点移动到下一个点的偏移量。

p3 = p13[0] - p11[0]

6、执行移动操作。

TouchAction(self.driver).press(x=p11[0], y=p11[1]).move_to(x=p3, y=0).wait(1000).move_to(x=0, y=p3).wait(1000).release().perform()

完整代码如下:

import unittest from appium import webdriver from appium.webdriver.common.touch_action import TouchAction from time import sleep # 图形解锁 class unlockTest(unittest.TestCase): def test_unlock(self): desired_caps = {} desired_caps['platformName'] = 'Android' desired_caps['platformVersion'] = '4.4.4' desired_caps['app'] = '/Users/a140/Downloads/test.apk' desired_caps['deviceName'] = '03083025d0250909' self.driver = webdriver.Remote('http://localhost:4723/wd/hub', desired_caps) # 按电源键,锁屏 self.driver.press_keycode(26) self.driver.implicitly_wait(2) # 按电源键,解锁 self.driver.press_keycode(26) # 调用解锁的方法 self.login_unlock() # 解锁 def login_unlock(self): # 通过ID找到九宫格的View lock_pattern = self.driver.find_element_by_id("com.android.keyguard:id/lockPatternView") # 获取View的x,y坐标值 x = lock_pattern.location.get('x') y = lock_pattern.location.get('y') # 获取View的宽度和高度 width = lock_pattern.size.get('width') height = lock_pattern.size.get('height') # 偏移量 offset = width / 6 # 计算九宫格内九个点的x,y坐标值 p11 = int(x + width / 6), int(y + height / 6) p12 = int(x + width / 2), int(y + height / 6) p13 = int(x + width - offset), int(y + height / 6) p21 = int(x + width / 6), int(y + height / 2) p22 = int(x + width / 2), int(y + height / 2) p23 = int(x + width - offset), int(y + height / 2) p31 = int(x + width / 6), int(y + height - offset) p32 = int(x + width / 2), int(y + height - offset) p33 = int(x + width - offset), int(y + height - offset) # 计算移动到下一个点的偏移量 p3 = p13[0] - p11[0] sleep(3) # 执行移动操作 TouchAction(self.driver).press(x=p11[0], y=p11[1]).move_to(x=p3, y=0).wait(1000).move_to(x=0, y=p3).wait( 1000).release().perform() if __name__ == '__main__': suite = unittest.TestLoader().loadTestsFromTestCase(unlockTest) unittest.TextTestRunner(verbosity=2).run(suite)

内容版权声明:除非注明,否则皆为本站原创文章。

转载注明出处:https://www.heiqu.com/zyzgxd.html