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compare: btl143:25e3b60cd8d54b8e1ba295cf8c833866583311c5
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6 Commits
v1 ... 25e3b60cd8

Author SHA1 Message Date
bmy
25e3b60cd8 feat: 增加扫黑除暴假动作 2024-08-06 15:20:46 +08:00
bmy
2e6ce3e1f7 pref: 增加llm异步请求 2024-08-04 11:20:34 +08:00
bmy
f3bb720bed feat: 增加base64传入动作指令 
feat: 换用 deepseek 大模型
pref: 修改应急避险2停车条件
 2024-08-04 10:04:27 +08:00
bmy
55f5b13d8c fix: 修复上次提交中的错误和删除测试代码 2024-08-01 23:30:37 +08:00
bmy
d0b02a66e6 feat: 启用llm任务初版 2024-08-01 22:54:05 +08:00
bmy
e51c126f1f 新结构动作修改 2024-08-01 14:40:53 +08:00
12 changed files with 875 additions and 236 deletions
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19
app.py
View File

@@ -10,14 +10,14 @@ import os
import time
import subprocess
import signal
import importlib
import base64
import json
from main_upper import main_func
server_command = [
{"path": "/home/evan/Workplace/project_capture/build/", "script": "./capture"},
{"path": "/home/evan/Workplace/project_infer/lane_server/", "script": "lane_infer_server.py"},
# {"path": "/home/evan/Workplace/project_infer/lane_server/", "script": "lane_infer_server1.py"},
{"path": "/home/evan/Workplace/project_infer/yolo_server/", "script": "yolo_infer_server.py"},
{"path": "/home/evan/Workplace/project_infer/ocr_server/", "script": "ocr_infer_server.py"},
]
processes = []
@@ -52,7 +52,7 @@ logger.add(handler, format="{time:MM-DD HH:mm:ss} {message}", level="DEBUG")
fileOptions_path = '/home/evan/Workplace/project_main'
fileOptions_list = ['cfg_args.toml','cfg_main.toml', 'cfg_subtask.toml']
cfg_args_path = os.path.join(fileOptions_path, 'cfg_args.toml')
cfg_move_area_path = os.path.join(fileOptions_path, 'cfg_move_area.json')
@app.route('/')
def index():
@@ -65,6 +65,17 @@ def run():
config_args['lane_mode']['mode_index'] = int(mode_index)
with open(cfg_args_path, 'w') as config_file:
toml.dump(config_args, config_file)
try:
action_base64 = request.args.get('action')
decoded_bytes = base64.b64decode(action_base64)
decoded_str = decoded_bytes.decode('utf-8')
json_data = json.loads(decoded_str)
with open(cfg_move_area_path, 'w') as json_file:
json.dump(json_data, json_file)
except:
# 当该字段没有传入参数时 清空配置文件 该任务按照正常流程去做
with open(cfg_move_area_path, 'w') as json_file:
pass
return render_template('index2.html')
# @app.route('/csdn')

2
cfg_args.toml
View File

@@ -10,5 +10,5 @@ UpTower_enable = true
GetRBall_enable = true
PutBBall_enable = true
PutHanoi_enable = true
MoveArea_enable = false
MoveArea_enable = true
KickAss_enable = true

6
cfg_main.toml
View File

@@ -1,6 +1,6 @@
[debug]
logger_filename = "log/file_{time}.log"
logger_format = "{time} {level} {message}"
logger_format = "[{level}] {file}:{line} <{time}> {message}"
@@ -13,7 +13,7 @@ GetRBall_counts = 10
PutBBall_counts = 15
PutHanoi1_counts = 7
PutHanoi2_counts = 2
PutHanoi3_counts = 5
PutHanoi3_counts = 2
MoveArea1_counts = 6
MoveArea2_counts = 1700
MoveArea2_counts = 10
KickAss_counts = 10

0
cfg_move_area.json Normal file
View File

10
cfg_subtask.toml
View File

@@ -20,17 +20,17 @@ pid_ki = 0
pid_kd = 0
[get_rball]
pid_kp = 1.5
pid_kp = 1.0
pid_ki = 0
pid_kd = 0
[put_bball]
pid_kp = 2.0
pid_kp = 1.5
pid_ki = 0
pid_kd = 0
[put_hanoi1]
pid_kp = 0.7
pid_kp = 0.5
pid_ki = 0
pid_kd = 0
@@ -42,7 +42,7 @@ pos_gap = 160
first_target = "mp"
[put_hanoi3]
pid_kp = 1.7
pid_kp = 1.5
pid_ki = 0
pid_kd = 0
@@ -50,7 +50,7 @@ pid_kd = 0
pid_kp = 1.2
pid_ki = 0
pid_kd = 0
llm_enable = false
llm_enable = true
[kick_ass]
pid_kp = 0.8

509
subtask.py
View File

@@ -2,7 +2,8 @@ from enum import Enum
from loguru import logger
from utils import label_filter
from utils import tlabel
from utils import LLM
# from utils import LLM
from utils import LLM_deepseek
from utils import CountRecord
import utils
import toml
@@ -11,10 +12,14 @@ import time
import variable as var
import action as act
import re
import threading
import ctypes
import math
import json
import json5
# import threading
# import ctypes
cfg = None
cfg_args = None
cfg_move_area = None
by_cmd = None
filter = None
llm_bot = None
@@ -47,9 +52,15 @@ def import_obj(_by_cmd, skip_queue):
global cfg
global cfg_args
global cfg_move_area
global global_skip_queue
cfg = toml.load('/home/evan/Workplace/project_main/cfg_subtask.toml') # 加载任务配置
cfg_args = toml.load('/home/evan/Workplace/project_main/cfg_args.toml')
try:
with open('/home/evan/Workplace/project_main/cfg_move_area.json', 'r') as f:
cfg_move_area = json.load(f)
except:
cfg_move_area = None
by_cmd = _by_cmd
global_skip_queue = skip_queue
@@ -60,14 +71,14 @@ def import_obj(_by_cmd, skip_queue):
logger.info("subtask yolo client init")
# ocr socket 客户端
# context1 = zmq.Context()
# ocr_socket = context1.socket(zmq.REQ)
# ocr_socket.connect("tcp://localhost:6668")
# logger.info("subtask ocr client init")
context1 = zmq.Context()
ocr_socket = context1.socket(zmq.REQ)
ocr_socket.connect("tcp://localhost:6668")
logger.info("subtask ocr client init")
filter = label_filter(socket)
if cfg['move_area']['llm_enable']:
llm_bot = LLM()
llm_bot = LLM_deepseek()
def car_stop():
for _ in range(3):
by_cmd.send_speed_x(0)
@@ -452,26 +463,26 @@ class get_block1():
calibrate_new(var.first_block, offset = 16, run = True, run_speed = 5)
logger.info("抓取块")
by_cmd.send_position_axis_z(30, 60)
by_cmd.send_position_axis_z(30, 80)
time.sleep(1)
by_cmd.send_angle_claw(63)
by_cmd.send_position_axis_x(1, 20)
time.sleep(1)
by_cmd.send_angle_claw(25)
time.sleep(0.5)
by_cmd.send_position_axis_z(30, 90)
by_cmd.send_position_axis_z(30, 110)
time.sleep(0.5)
by_cmd.send_angle_claw_arm(175)
time.sleep(0.1)
by_cmd.send_position_axis_x(1, 100)
time.sleep(1)
by_cmd.send_position_axis_z(30, 70)
by_cmd.send_position_axis_z(30, 100)
time.sleep(0.5)
by_cmd.send_angle_claw(63)
time.sleep(0.5)
by_cmd.send_position_axis_z(30, 130)
by_cmd.send_position_axis_z(30, 150)
time.sleep(1)
by_cmd.send_position_axis_x(1, 140)
by_cmd.send_angle_claw_arm(225)
@@ -565,18 +576,18 @@ class put_block():
# 放置第二個塊
by_cmd.send_angle_storage(20)
by_cmd.send_position_axis_x(1, 110)
by_cmd.send_position_axis_z(30, 120)
by_cmd.send_position_axis_z(30, 140)
time.sleep(1.5)
by_cmd.send_angle_claw_arm(180)
by_cmd.send_angle_claw(85)
# by_cmd.send_angle_storage(0)
time.sleep(1)
by_cmd.send_position_axis_z(30,70)
by_cmd.send_position_axis_z(30,100)
time.sleep(1)
by_cmd.send_angle_claw(25)
by_cmd.send_distance_x(-10, 110)
time.sleep(1)
by_cmd.send_position_axis_z(30, 110)
by_cmd.send_position_axis_z(30, 130)
time.sleep(1)
by_cmd.send_angle_claw_arm(225)
time.sleep(1)
@@ -592,7 +603,7 @@ class put_block():
def after(self):
var.pid_turning.set(cfg["put_block"]["pid_kp"], cfg["put_block"]["pid_ki"], cfg["put_block"]["pid_kd"])
# 下一动作预备位置
while by_cmd.send_position_axis_z(30, 130) == -1:
while by_cmd.send_position_axis_z(30, 150) == -1:
pass
time.sleep(1)
while by_cmd.send_position_axis_x(1, 0) == -1:
@@ -661,7 +672,7 @@ class get_bball():
time.sleep(0.5)
by_cmd.send_angle_claw_arm(45)
time.sleep(1)
by_cmd.send_position_axis_z(30, 135)
by_cmd.send_position_axis_z(30, 155)
# 继续向前走
# by_cmd.send_speed_x(4)
pass
@@ -671,10 +682,10 @@ class get_bball():
var.pid_turning.set(cfg["get_bball"]["pid_kp"], cfg["get_bball"]["pid_ki"], cfg["get_bball"]["pid_kd"])
# 下一动作预备位置
by_cmd.send_angle_claw(30)
time.sleep(0.5)
# time.sleep(0.5)
while by_cmd.send_position_axis_z(30, 0) == -1:
pass
time.sleep(1)
time.sleep(0.5)
# # 任务检查间隔
# time.sleep(1)
@@ -702,13 +713,13 @@ class up_tower():
by_cmd.send_distance_x(-10, 120)
time.sleep(1)
# 上古參數
by_cmd.send_distance_y(-10, 80)
by_cmd.send_distance_y(-10, 50) # 80
# 6_9 模型參數
# by_cmd.send_distance_y(-10, 40)
# 7_12_3 模型參數
# by_cmd.send_distance_y(-10, 50)
time.sleep(2)
car_stop()
# time.sleep(2)
# car_stop()
# FIXME 如果下發 distance 後直接 car_stop則 distance 執行時間僅由指令間處理延時決定
# time.sleep(3)
# by_cmd.send_speed_y(-10)
@@ -758,21 +769,22 @@ class get_rball():
# 靠近塔
by_cmd.send_angle_scoop(20)
# 上古參數
by_cmd.send_distance_y(-15, 70) # 50
# by_cmd.send_distance_y(-15, 50) # 50 # 70
by_cmd.send_distance_y(-15, 40) # 50 # 70
# 6_9 參數
# by_cmd.send_distance_y(-15, 35)
# time.sleep(2)
# 7_12_3 參數
# by_cmd.send_distance_y(-15, 45)
time.sleep(2)
car_stop()
# time.sleep(2)
# car_stop()
calibrate_new(tlabel.RBALL,offset = 44, run = True)
time.sleep(1)
logger.info("抓红球")
# by_cmd.send_angle_scoop(12)
time.sleep(0.5)
by_cmd.send_position_axis_z(30, 170)
time.sleep(2.5)
by_cmd.send_position_axis_z(30, 200)
time.sleep(3)
by_cmd.send_angle_scoop(12)
time.sleep(0.5)
by_cmd.send_angle_scoop(7)
@@ -863,7 +875,7 @@ class put_hanoi1():
by_cmd.send_speed_omega(0)
time.sleep(0.2)
by_cmd.send_position_axis_z(30, 130)
by_cmd.send_position_axis_z(30, 150)
# 校准牌子
if utils.direction_right > utils.direction_left:
@@ -1005,7 +1017,7 @@ class put_hanoi2():
time.sleep(0.5)
logger.info("抓大平台")
if utils.direction is tlabel.RMARK:
by_cmd.send_position_axis_z(30, 10)
by_cmd.send_position_axis_z(30, 30)
by_cmd.send_position_axis_x(1, 150)
by_cmd.send_angle_claw(63)
time.sleep(2)
@@ -1017,7 +1029,7 @@ class put_hanoi2():
time.sleep(1)
pass
else:
by_cmd.send_position_axis_z(30, 10)
by_cmd.send_position_axis_z(30, 30)
by_cmd.send_position_axis_x(1, 40)
by_cmd.send_angle_claw(63)
time.sleep(2)
@@ -1065,7 +1077,7 @@ class put_hanoi2():
time.sleep(0.5)
logger.info("抓中平台")
if utils.direction is tlabel.RMARK:
by_cmd.send_position_axis_z(30, 10)
by_cmd.send_position_axis_z(30, 30)
by_cmd.send_position_axis_x(1, 150)
by_cmd.send_angle_claw(55)
time.sleep(2)
@@ -1077,7 +1089,7 @@ class put_hanoi2():
time.sleep(1)
pass
else:
by_cmd.send_position_axis_z(30, 10)
by_cmd.send_position_axis_z(30, 30)
by_cmd.send_position_axis_x(1, 40)
by_cmd.send_angle_claw(55)
time.sleep(2)
@@ -1096,7 +1108,7 @@ class put_hanoi2():
time.sleep(0.5)
logger.info("放中平台")
if utils.direction is tlabel.RMARK:
by_cmd.send_position_axis_z(30, 120)
by_cmd.send_position_axis_z(30, 140)
time.sleep(2)
by_cmd.send_position_axis_x(1, 150)
time.sleep(2)
@@ -1108,7 +1120,7 @@ class put_hanoi2():
time.sleep(1)
pass
else:
by_cmd.send_position_axis_z(30, 120)
by_cmd.send_position_axis_z(30, 140)
time.sleep(2)
by_cmd.send_position_axis_x(1, 40)
time.sleep(2)
@@ -1126,7 +1138,7 @@ class put_hanoi2():
time.sleep(0.5)
logger.info("抓小平台")
if utils.direction is tlabel.RMARK:
by_cmd.send_position_axis_z(30, 10)
by_cmd.send_position_axis_z(30, 30)
by_cmd.send_position_axis_x(1, 150)
by_cmd.send_angle_claw(50)
time.sleep(2)
@@ -1138,7 +1150,7 @@ class put_hanoi2():
time.sleep(2)
pass
else:
by_cmd.send_position_axis_z(30, 10)
by_cmd.send_position_axis_z(30, 30)
by_cmd.send_position_axis_x(1, 40)
by_cmd.send_angle_claw(50)
time.sleep(2)
@@ -1157,7 +1169,7 @@ class put_hanoi2():
time.sleep(0.5)
logger.info("放小平台")
if utils.direction is tlabel.RMARK:
by_cmd.send_position_axis_z(30, 190) # 170
by_cmd.send_position_axis_z(30, 200) # 170 #190(new)
time.sleep(1.5)
by_cmd.send_position_axis_x(1, 150)
time.sleep(2)
@@ -1173,7 +1185,7 @@ class put_hanoi2():
# car_stop()
pass
else:
by_cmd.send_position_axis_z(30, 190)
by_cmd.send_position_axis_z(30, 200)
time.sleep(1.5)
by_cmd.send_position_axis_x(1, 40)
time.sleep(2)
@@ -1201,7 +1213,7 @@ class put_hanoi2():
class put_hanoi3():
def init(self):
while by_cmd.send_position_axis_z(30, 130) == -1:
while by_cmd.send_position_axis_z(30, 150) == -1:
pass
time.sleep(3)
logger.info("完成任务,爪回左侧")
@@ -1219,14 +1231,16 @@ class put_hanoi3():
time.sleep(1)
return True
def exec(self):
while by_cmd.send_position_axis_z(30, 100) == -1:
while by_cmd.send_position_axis_z(30, 120) == -1:
pass
pass
def nexec(self):
pass
def after(self):
by_cmd.send_angle_storage(20)
by_cmd.send_position_axis_x(1, 150)
var.pid_turning.set(cfg["put_hanoi3"]["pid_kp"], cfg["put_hanoi3"]["pid_ki"], cfg["put_hanoi3"]["pid_kd"])
var.pid_turning.set(cfg["put_hanoi3"]["pid_kp"] - 0.2, cfg["put_hanoi3"]["pid_ki"], cfg["put_hanoi3"]["pid_kd"])
# FIXME 此处 -0.2 在 `2e6ce3e1f7d326d6ce8110855e2339ebc03ab2da` 前没有
# 应急避险 第一阶段 找目标牌
class move_area1():
@@ -1234,6 +1248,7 @@ class move_area1():
logger.info("应急避险第一阶段初始化")
while (by_cmd.send_angle_camera(0) == -1):
by_cmd.send_angle_camera(0)
filter.switch_camera(1)
def find(self):
ret = filter.find(tlabel.SIGN)
if ret:
@@ -1245,7 +1260,7 @@ class move_area1():
car_stop()
time.sleep(1)
# calibrate_new(tlabel.SIGN, offset = 8, run = True)
calibrate_new(tlabel.SIGN, offset = -30, run = True, run_speed = 5)
calibrate_new(tlabel.SIGN, offset = -1, run = True, run_speed = 5)
time.sleep(1)
by_cmd.send_position_axis_x(1, 50)
@@ -1253,33 +1268,42 @@ class move_area1():
# filter_w = (148, 560)
# filter_h = (165, 390)
if cfg_move_area == None:
counts = 0
while True:
ocr_socket.send_string("")
resp = ocr_socket.recv_pyobj()
var.llm_text = ''
counts += 1
if resp.get('code') == 0:
for item in resp.get('content'):
counts = 0
while True:
ocr_socket.send_string("")
resp = ocr_socket.recv_pyobj()
var.llm_text = ''
counts += 1
if resp.get('code') == 0:
for item in resp.get('content'):
if item['probability']['average'] < 0.80:
continue
# box = item['location']
# center_x = box['left'] + box['width'] / 2
# center_y = box['top'] + box['height'] / 2
# if center_x < filter_w[0] or center_x > filter_w[1] \
# or center_y < filter_h[0] or center_y > filter_h[1]:
# continue
var.llm_text += item['words']
break
if counts >= 2:
var.skip_llm_task_flag = True
return
logger.error(f"OCR 检出字符:\"{var.llm_text}\"")
if item['probability']['average'] < 0.80:
continue
# box = item['location']
# center_x = box['left'] + box['width'] / 2
# center_y = box['top'] + box['height'] / 2
# if center_x < filter_w[0] or center_x > filter_w[1] \
# or center_y < filter_h[0] or center_y > filter_h[1]:
# continue
var.llm_text += item['words']
break
if counts >= 2:
if len(var.llm_text) < 5:
var.skip_llm_task_flag = True
return
logger.error(var.llm_text)
if len(var.llm_text) < 3:
var.skip_llm_task_flag = True
return
else:
# 当有效字符大于 5 个文字时 才请求大模型
llm_bot.request(var.llm_text)
else:
# 不需要文字识别 直接使用传入的参数执行 action
pass
var.task_speed = 9 # 12
@@ -1296,133 +1320,247 @@ class move_area1():
# 应急避险 第二阶段 找停车区域
class move_area2():
def __init__(self):
self.action_dict = {
'beep_seconds': self.beep_seconds,
'beep_counts': self.beep_counts,
'light_seconds': self.light_seconds,
'light_counts': self.light_counts,
'beep_light_counts': self.beep_light_counts,
'beep_light_seconds': self.beep_light_seconds,
'go_front': self.go_front,
'go_back': self.go_back,
'go_left': self.go_left,
'go_right': self.go_right,
'go_left_rotate': self.go_left_rotate,
'go_right_rotate': self.go_right_rotate,
'go_sleep': self.go_sleep
}
self.front_time = 0
self.back_time = 0
self.left_time = 0
self.right_time = 0
self.sum_rotate_angle = 0
self.abs_x = 0 # 为了和程序指令适配,其中 x y 方向互换
self.abs_y = 0
self.abs_w = 0
pass
def init(self):
logger.info("应急避险第二阶段初始化")
self.offset = 15
self.offset = 60
self.delta_x = 0
self.delta_y = 0
self.delta_omage = 0
def find(self):
# time.sleep(0.001)
if var.skip_llm_task_flag:
if var.skip_llm_task_flag and cfg_move_area == None:
return 5000
ret, box = filter.get(tlabel.SHELTER)
if ret:
error = (box[0][2] + box[0][0] - 320) / 2 + self.offset
if abs(error) < 20:
# 增加了一个宽度过滤
if abs(error) < 30 and abs(box[0][2] - box[0][0]) > 180:
return 5000
return False
def sub_light(self, delay_time):
by_cmd.send_light(1)
time.sleep(delay_time)
by_cmd.send_light(0)
def sub_beep(self,delay_time):
def add_item(self, item):
# FIXME 没有对传入参数的范围进行校验,如果出现单位错误,可能会导致无法回位的问题
try:
return self.action_dict[item.get('action')](item.get('time'))
except:
pass
return False
def beep_seconds(self, _time):
by_cmd.send_beep(1)
time.sleep(delay_time)
time.sleep(_time * 0.7)
by_cmd.send_beep(0)
def sub_move(self, x, y):
# FIXME 如果同時有 xy是否會造成 delay 不足
self.delta_x += x
self.delta_y += y
if x != 0:
delay_time = int(abs(x) * 500)
if x > 0:
by_cmd.send_distance_x(15, delay_time)
else:
by_cmd.send_distance_x(-15, delay_time)
elif y != 0:
delay_time = int(abs(y) * 500)
if y > 0: # 向左
by_cmd.send_distance_y(-15, delay_time)
else:
by_cmd.send_distance_y(15, delay_time)
time.sleep(delay_time / 500)
car_stop()
pass
def sub_turn(self, angle):
self.delta_omage += angle
delay_time = int(abs(angle) * 400 / 90)
if angle < 0:
# 左转
by_cmd.send_angle_omega(+55, delay_time)
return True
def beep_counts(self, _time):
for _ in range(_time):
by_cmd.send_beep(1)
time.sleep(0.3)
by_cmd.send_beep(0)
time.sleep(0.2)
return True
def light_seconds(self, _time):
by_cmd.send_light(1)
time.sleep(_time * 0.7)
by_cmd.send_light(0)
return True
def light_counts(self, _time):
for _ in range(_time):
by_cmd.send_light(1)
time.sleep(0.3)
by_cmd.send_light(0)
time.sleep(0.2)
return True
def beep_light_counts(self, _time):
for _ in range(_time):
by_cmd.send_beep(1)
by_cmd.send_light(1)
time.sleep(0.3)
by_cmd.send_beep(0)
by_cmd.send_light(0)
time.sleep(0.2)
return True
def beep_light_seconds(self, _time):
by_cmd.send_beep(1)
by_cmd.send_light(1)
time.sleep(_time * 0.3)
by_cmd.send_beep(0)
by_cmd.send_light(0)
return True
def go_front(self, _time):
self.abs_y -= math.sin(self.abs_w) * _time
self.abs_x += math.cos(self.abs_w) * _time
logger.info(f"向前移动:[目标位置 ({self.abs_y:.2f}, {self.abs_x:.2f}) - 角度 {math.degrees(self.abs_w)} ]")
speed_time = int(abs(_time) * 750)
by_cmd.send_distance_x(10, speed_time)
time.sleep(speed_time / 100)
self.front_time += speed_time
return True
def go_back(self, _time):
self.abs_y += math.sin(self.abs_w) * _time
self.abs_x -= math.cos(self.abs_w) * _time
logger.info(f"向后移动:[目标位置 ({self.abs_y:.2f}, {self.abs_x:.2f}) - 角度 {math.degrees(self.abs_w)} ]")
speed_time = int(abs(_time) * 750)
by_cmd.send_distance_x(-10, speed_time)
time.sleep(speed_time / 100)
self.back_time += speed_time
return True
def go_left(self, _time):
self.abs_y -= math.cos(self.abs_w) * _time
self.abs_x -= math.sin(self.abs_w) * _time
logger.info(f"向左移动:[目标位置 ({self.abs_y:.2f}, {self.abs_x:.2f}) - 角度 {math.degrees(self.abs_w)} ]")
speed_time = int(abs(_time) * 750)
by_cmd.send_distance_y(-10, speed_time)
time.sleep(speed_time / 100)
self.left_time += speed_time
return True
def go_right(self, _time):
self.abs_y += math.cos(self.abs_w) * _time
self.abs_x += math.sin(self.abs_w) * _time
logger.info(f"向右移动:[目标位置 ({self.abs_y:.2f}, {self.abs_x:.2f}) - 角度 {math.degrees(self.abs_w)} ]")
speed_time = int(abs(_time) * 750)
by_cmd.send_distance_y(10, speed_time)
time.sleep(speed_time / 100)
self.right_time += speed_time
return True
def go_shift(self, _dis_x, _dis_y):
direct_x = 1.0 if (_dis_x > 0) else -1.0
direct_y = 1.0 if (_dis_y > 0) else -1.0
self.abs_y -= math.sin(self.abs_w) * _dis_x
self.abs_x += math.cos(self.abs_w) * _dis_x
self.abs_y += math.cos(self.abs_w) * _dis_y
self.abs_x += math.sin(self.abs_w) * _dis_y
logger.info(f"水平移动:[目标位置 ({self.abs_y:.2f}, {self.abs_x:.2f}) - 角度 {math.degrees(self.abs_w)} ]")
speed_time_x = int(abs(_dis_x) * 750)
speed_time_y = int(abs(_dis_y) * 750)
by_cmd.send_distance_x(10 * direct_x, speed_time_x)
by_cmd.send_distance_y(10 * direct_y, speed_time_y)
time.sleep(max(speed_time_x, speed_time_y) / 150) #FIXME 除以 100 是否正确
return True
def go_left_rotate(self, _time):
self.abs_w += math.radians(_time) # 弧度制
logger.info(f"向左旋转:[目标位置 ({self.abs_y:.2f}, {self.abs_x:.2f}) - 角度 {math.degrees(self.abs_w)} ]")
self.sum_rotate_angle -= _time
speed_time = int(abs(_time) * 3.8)
by_cmd.send_angle_omega(50, speed_time)
time.sleep(speed_time / 200 + 0.5)
return True
def go_right_rotate(self, _time):
self.abs_w -= math.radians(_time) # 弧度制
logger.info(f"向右旋转:[目标位置 ({self.abs_y:.2f}, {self.abs_x:.2f}) - 角度 {math.degrees(self.abs_w)} ]")
self.sum_rotate_angle += _time
speed_time = int(abs(_time) * 3.8)
by_cmd.send_angle_omega(-50, speed_time)
time.sleep(speed_time / 200 + 0.5)
return True
def go_sleep(self, _time):
time.sleep(_time*0.7)
return True
def reset(self):
logger.info(f"开始复位:[当前位置 ({self.abs_y:.2f}, {self.abs_x:.2f}) - 角度 {math.degrees(self.abs_w)}]")
# 归一化角度到 0-2pi
left_dregee = math.degrees(self.abs_w % (2 * math.pi))
# 确定旋转方向 (寻找回正角度最小旋转方向)
if math.sin(self.abs_w) < 0:
logger.info(f"需要左旋 {360.0 - left_dregee} 回正")
self.go_left_rotate(360.0 - left_dregee)
else:
# 右转
by_cmd.send_angle_omega(-55, delay_time)
time.sleep(delay_time / 300 * 1.5)
logger.info(f"需要右旋 {left_dregee} 回正")
self.go_right_rotate(left_dregee)
time.sleep(0.1)
# 在框中原点添加向左 0.6m 的偏移值,以便直接回到赛道
self.go_shift(self.abs_x * -1.0, self.abs_y * -1.0 - 0.6)
logger.info(f"回正后最终位置: ({self.abs_y:.2f}, {self.abs_x:.2f}), 角度: {math.degrees(self.abs_w % (2 * math.pi))}")
def exec(self):
var.task_speed = 0
if var.skip_llm_task_flag:
logger.error("ocr 识别出错 直接跳过任务")
if var.skip_llm_task_flag and cfg_move_area == None:
logger.error("ocr 识别出错 直接跳过任务")
return
logger.info("开始寻找停车区域")
car_stop()
calibrate_new(tlabel.SHELTER, offset = 15, run = True)
calibrate_new(tlabel.SHELTER, offset = 30, run = True)
time.sleep(0.5)
# 调用大模型 然后执行动作
try:
resp = llm_bot.get_command_json(var.llm_text)
logger.info(resp)
except:
logger.error("大模型超时,跳过任务")
return
if cfg_move_area == None:
resp = None
# 调用大模型 然后执行动作
try:
logger.info("llm 阻塞等待服务器返回中")
start_wait_time = time.perf_counter()
while True:
if llm_bot.success_status.isSet():
resp = llm_bot.response.choices[0].message.content
logger.info(f"llm 返回原数据 {resp}")
break
now_time = time.perf_counter()
if llm_bot.error_status.isSet() or (now_time - start_wait_time) > 6.5 :
logger.error("大模型 llm_bot 超时,跳过任务")
return
try:
resp_commands = eval(re.findall("```json(.*?)```", resp, re.S)[0])
if len(resp_commands) == 0:
except:
logger.error("大模型 llm_bot 未知错误,跳过任务")
return
# 进入停车区域
# by_cmd.send_speed_y(15)
by_cmd.send_distance_y(25, 180)
time.sleep(1)
# time.sleep(1.25)
car_stop()
logger.info(resp_commands)
for command in resp_commands:
logger.info(command)
if command['func'] == 'move':
self.sub_move(float(command['x']), float(command['y']))
elif command['func'] == 'light':
self.sub_light(int(command['time']))
elif command['func'] == 'beep':
self.sub_beep(int(command['time']))
elif command['func'] == 'turn':
self.sub_turn(int(command['angle']))
pass
try:
json_text = re.findall("```json(.*?)```", resp, re.S)
if len(json_text) == 0:
# 返回的内容不带'''json
resp_commands = eval(resp)
else:
continue
resp_commands = json5.loads(json_text[0])
logger.info(f"解析后的动作序列 {resp_commands}")
if len(resp_commands) == 0:
return
action_list = resp_commands
# 进入停车区域
by_cmd.send_distance_y(10, 450)
time.sleep((450 * 5 / 1000) + 0.5)
for action in action_list:
self.add_item(action)
time.sleep(0.1)
time.sleep(0.5)
except:
self.reset()
except:
logger.warning("任务解析失败并退出,文心一言真是废物 (毋庸置疑)")
pass
else:
# 无需调用大模型 直接开始执行传入的参数
try:
by_cmd.send_distance_y(10, 450)
time.sleep((450 * 5 / 1000) + 0.5)
for action in cfg_move_area:
self.add_item(action)
time.sleep(0.1)
time.sleep(0.5)
self.reset()
except:
pass
pass
time.sleep(1)
# 回到原位
delay_time = int(abs(self.delta_omage) * 400 / 90)
if int(abs(self.delta_omage)) == 360:
delay_time = 0
if self.delta_omage < 0:
# 左转
by_cmd.send_angle_omega(-55, delay_time)
else:
# 右转
by_cmd.send_angle_omega(55, delay_time)
time.sleep(delay_time / 300 * 1.5)
if self.delta_y > 0:
# 向左移动的距离就要比进入的时候少一些 因为 action 已经向左运动了
delay_time = 180 - (self.delta_y * 500)
else:
delay_time = 180 + (abs(self.delta_y) * 500)
# 离开停车区域
by_cmd.send_distance_y(-25, delay_time)
time.sleep(delay_time * 5e-3)
car_stop()
# FIXME 移动距离指令下发后未完成,再发送速度指令,将不会清除未完成的速度值
# by_cmd.send_distance_y(-15, 300)
pass
def nexec(self):
logger.warning("正在跳過大模型任務")
time.sleep(2)
@@ -1460,18 +1598,43 @@ class kick_ass():
calibrate_new(tlabel.SIGN, offset = 8, run = True)
by_cmd.send_angle_claw(15)
time.sleep(0.5)
by_cmd.send_position_axis_z(30, 60)
by_cmd.send_position_axis_z(30, 80)
by_cmd.send_position_axis_x(1, 130)
# 移动到中间
by_cmd.send_distance_x(10, 295)
time.sleep(4)
if self.target_person == 1:
target_distance = self.pos_gap1
by_cmd.send_distance_x(-10, 150)
time.sleep(1.5)
car_stop()
elif self.target_person == 2:
by_cmd.send_distance_x(-10, 50)
time.sleep(1.5)
car_stop()
elif self.target_person == 3:
by_cmd.send_distance_x(10, 50)
time.sleep(1.5)
car_stop()
else:
target_distance = self.pos_gap1 + (self.target_person - 1) * self.pos_gap2 + (self.target_person - 1) * 10
by_cmd.send_distance_x(10, target_distance)
by_cmd.send_distance_x(10, 150)
time.sleep(1.5)
car_stop()
logger.info(f"target distance {target_distance}")
time.sleep(1.5 + (self.target_person - 1) * 0.7 )
car_stop()
# 先移动到第一个人的地方 假动作
# by_cmd.send_distance_x(10, self.pos_gap1)
# time.sleep(1.5)
# if self.target_person == 1:
# # target_distance = self.pos_gap1
# pass
# else:
# # target_distance = self.pos_gap1 + (self.target_person - 1) * self.pos_gap2 + (self.target_person - 1) * 10
# target_distance = (self.target_person - 1) * self.pos_gap2 + (self.target_person - 1) * 10
# by_cmd.send_distance_x(10, target_distance)
# logger.info(f"target distance {target_distance}")
# time.sleep(1.5 + (self.target_person - 1) * 0.7 )
# car_stop()
# by_cmd.send_angle_claw_arm(225)
# time.sleep(0.5)

241
test/test_action.py Normal file
View File

@@ -0,0 +1,241 @@
import os
import sys
import math
parent_dir = os.path.dirname(os.path.dirname(os.path.abspath(__file__)))
sys.path.append(parent_dir)
from by_cmd_py import by_cmd_py
import time
import zmq
import numpy as np
context = zmq.Context()
socket = context.socket(zmq.REQ)
socket.connect("tcp://localhost:6666")
def car_stop():
for _ in range(3):
cmd_py_obj.send_speed_x(0)
time.sleep(0.2)
cmd_py_obj.send_speed_y(0)
time.sleep(0.2)
cmd_py_obj.send_speed_omega(0)
class LLM_Action:
def __init__(self,cmd_py_obj):
self.by_cmd = cmd_py_obj
self.action_dict = {
'beep_seconds': self.beep_seconds,
'beep_counts': self.beep_counts,
'light_seconds': self.light_seconds,
'light_counts': self.light_counts,
'beep_light_counts': self.beep_light_counts,
'beep_light_seconds': self.beep_light_seconds,
'go_front': self.go_front,
'go_back': self.go_back,
'go_left': self.go_left,
'go_right': self.go_right,
'go_left_rotate': self.go_left_rotate,
'go_right_rotate': self.go_right_rotate,
'go_sleep': self.go_sleep
}
self.front_time = 0
self.back_time = 0
self.left_time = 0
self.right_time = 0
self.sum_rotate_angle = 0
self.abs_x = 0 # 为了和程序指令适配,其中 x y 方向互换
self.abs_y = 0
self.abs_w = 0
pass
def __call__(self, item):
try:
return self.action_dict[item.get('action')](item.get('time'))
except:
pass
return False
def beep_seconds(self, _time):
self.by_cmd.send_beep(1)
time.sleep(_time * 0.7)
self.by_cmd.send_beep(0)
return True
def beep_counts(self, _time):
for _ in range(_time):
self.by_cmd.send_beep(1)
time.sleep(0.3)
self.by_cmd.send_beep(0)
time.sleep(0.2)
return True
def light_seconds(self, _time):
self.by_cmd.send_light(1)
time.sleep(_time * 0.7)
self.by_cmd.send_light(0)
return True
def light_counts(self, _time):
for _ in range(_time):
self.by_cmd.send_light(1)
time.sleep(0.3)
self.by_cmd.send_light(0)
time.sleep(0.2)
return True
def beep_light_counts(self, _time):
for _ in range(_time):
self.by_cmd.send_beep(1)
self.by_cmd.send_light(1)
time.sleep(0.3)
self.by_cmd.send_beep(0)
self.by_cmd.send_light(0)
time.sleep(0.2)
return True
def beep_light_seconds(self, _time):
self.by_cmd.send_beep(1)
self.by_cmd.send_light(1)
time.sleep(_time * 0.3)
self.by_cmd.send_beep(0)
self.by_cmd.send_light(0)
return True
def go_front(self, _time):
self.abs_y -= math.sin(self.abs_w) * _time
self.abs_x += math.cos(self.abs_w) * _time
print(f"abs postion ({self.abs_y:.2f}, {self.abs_x:.2f}) - angle {math.degrees(self.abs_w)} drgee")
speed_time = int(abs(_time) * 750)
self.by_cmd.send_distance_x(10, speed_time)
time.sleep(speed_time / 100)
self.front_time += speed_time
return True
def go_back(self, _time):
self.abs_y += math.sin(self.abs_w) * _time
self.abs_x -= math.cos(self.abs_w) * _time
print(f"abs postion ({self.abs_y:.2f}, {self.abs_x:.2f}) - angle {math.degrees(self.abs_w)} drgee")
speed_time = int(abs(_time) * 750)
self.by_cmd.send_distance_x(-10, speed_time)
time.sleep(speed_time / 100)
self.back_time += speed_time
return True
def go_left(self, _time):
self.abs_y -= math.cos(self.abs_w) * _time
self.abs_x -= math.sin(self.abs_w) * _time
print(f"abs postion ({self.abs_y:.2f}, {self.abs_x:.2f}) - angle {math.degrees(self.abs_w)} drgee")
speed_time = int(abs(_time) * 750)
self.by_cmd.send_distance_y(-10, speed_time)
time.sleep(speed_time / 100)
self.left_time += speed_time
return True
def go_right(self, _time):
self.abs_y += math.cos(self.abs_w) * _time
self.abs_x += math.sin(self.abs_w) * _time
print(f"abs postion ({self.abs_y:.2f}, {self.abs_x:.2f}) - angle {math.degrees(self.abs_w)} drgee")
speed_time = int(abs(_time) * 750)
self.by_cmd.send_distance_y(10, speed_time)
time.sleep(speed_time / 100)
self.right_time += speed_time
return True
def go_shift(self, _dis_x, _dis_y):
direct_x = 1.0 if (_dis_x > 0) else -1.0
direct_y = 1.0 if (_dis_y > 0) else -1.0
self.abs_y -= math.sin(self.abs_w) * _dis_x
self.abs_x += math.cos(self.abs_w) * _dis_x
self.abs_y += math.cos(self.abs_w) * _dis_y
self.abs_x += math.sin(self.abs_w) * _dis_y
print(f"abs postion ({self.abs_y:.2f}, {self.abs_x:.2f}) - angle {math.degrees(self.abs_w)} drgee")
speed_time_x = int(abs(_dis_x) * 750)
speed_time_y = int(abs(_dis_y) * 750)
self.by_cmd.send_distance_x(10 * direct_x, speed_time_x)
self.by_cmd.send_distance_y(10 * direct_y, speed_time_y)
time.sleep(max(speed_time_x, speed_time_y) / 100) #FIXME 除以 100 是否正确
return True
def go_left_rotate(self, _time):
self.abs_w += math.radians(_time) # 弧度制
print(f"abs postion ({self.abs_y:.2f}, {self.abs_x:.2f}) - angle {math.degrees(self.abs_w)} drgee")
self.sum_rotate_angle -= _time
speed_time = int(abs(_time) * 4.35)
self.by_cmd.send_angle_omega(50, speed_time)
time.sleep(speed_time / 200 + 0.5)
# time.sleep(speed_time / _time / 2)
return True
def go_right_rotate(self, _time):
self.abs_w -= math.radians(_time) # 弧度制
print(f"abs postion ({self.abs_y:.2f}, {self.abs_x:.2f}) - angle {math.degrees(self.abs_w)} drgee")
self.sum_rotate_angle += _time
speed_time = int(abs(_time) * 4.35)
self.by_cmd.send_angle_omega(-50, speed_time)
time.sleep(speed_time / 200 + 0.5)
# time.sleep(speed_time / _time / 2)
return True
def go_sleep(self, _time):
time.sleep(_time*0.7)
return True
def reset(self):
print(f"开始复位:[当前位置 ({self.abs_y:.2f}, {self.abs_x:.2f}) - 角度 {math.degrees(self.abs_w)}]")
# 先复位角度
# if self.sum_rotate_angle > 0:
# self.sum_rotate_angle = self.sum_rotate_angle % 360
# else:
# self.sum_rotate_angle = -(abs(self.sum_rotate_angle) % 360)
# if self.sum_rotate_angle > 0:
# # 采用左转回正
# self.go_left_rotate(self.sum_rotate_angle)
# # speed_time = int(abs(self.sum_rotate_angle) * 7.25)
# # self.by_cmd.send_angle_omega(30, speed_time)
# pass
# else:
# # 采用右转回正
# self.go_right_rotate(abs(self.sum_rotate_angle))
# # speed_time = int(abs(self.sum_rotate_angle) * 7.25)
# # self.by_cmd.send_angle_omega(-30, speed_time)
left_dregee = math.degrees(self.abs_w % (2 * math.pi)) #归一化角度到 0-2pi
if math.sin(self.abs_w) < 0:
print(f"需要左旋 {360.0 - left_dregee} 回正")
self.go_left_rotate(360.0 - left_dregee)
else:
print(f"需要右旋 {left_dregee} 回正")
self.go_right_rotate(left_dregee)
time.sleep(0.1)
self.go_shift(self.abs_x * -1.0, self.abs_y * -1.0 - 0.6) # 左移 0.6m 回到赛道
# # 再回正 x 轴
# if self.front_time > self.back_time:
# # 采用后退回正
# speed_time = self.front_time - self.back_time
# self.by_cmd.send_distance_x(-10, speed_time)
# else:
# speed_time = self.back_time - self.front_time
# self.by_cmd.send_distance_x(10, speed_time)
# time.sleep(speed_time / 100)
# time.sleep(0.1)
# # 最后回正 y 轴
# speed_time = self.left_time - self.right_time
# if speed_time < 0:
# speed_time = 4500 + abs(speed_time)
# else:
# speed_time = 4500 - speed_time
# self.by_cmd.send_distance_y(-10, speed_time / 15 + 100)
# print(speed_time * 1e-3 * 0.9)
# time.sleep(speed_time * 1e-3 * 0.9)
print(f"回正后最终位置: ({self.abs_y:.2f}, {self.abs_x:.2f}), 角度: {math.degrees(self.abs_w % (2 * math.pi))}")
if __name__ == "__main__":
cmd_py_obj = by_cmd_py()
# cmd_py_obj.send_angle_omega(-30, 20 * 7.25)
# time.sleep(20 * 7.25 / 20 / 2)
llm_act = LLM_Action(cmd_py_obj)
action_list = [{"index":0,"action":"go_left_rotate","time":270},{"index":1,"action":"go_back","time":0.2},{"index":2,"action":"go_left","time":0.2},{"index":2,"action":"beep_counts","time":3}]
cmd_py_obj.send_distance_y(10, 450)
time.sleep((450 * 5 / 1000) + 0.5)
# time.sleep(15 * 300 * 1e-3 * 0.7)
# car_stop()
for action in action_list:
llm_act(action)
time.sleep(0.1)
pass
time.sleep(1)
llm_act.reset()
# car_stop()

7
test/test_filter.py
View File

@@ -16,7 +16,7 @@ socket.connect("tcp://localhost:6667")
logger.info("subtask yolo client init")
filter = label_filter(socket)
filter.switch_camera(2)
filter.switch_camera(1)
# find_counts = 0
@@ -25,10 +25,13 @@ filter.switch_camera(2)
# label = tlabel.TPLATFORM
while True:
time.sleep(0.2)
ret, box = filter.get(tlabel.BASE)
ret, box = filter.get(tlabel.SIGN)
if ret:
error = (box[0][2] + box[0][0] - 320) / 2
logger.error(error)
# if abs(error) < 30 and abs(box[0][2] - box[0][0]) > 180:
# # height = box[0][3] - box[0][1]
# logger.error(111)
# label = tlabel.HOSPITAL
# ret, box = filter.get(label)

52
test/test_llm.py
View File

@@ -13,18 +13,48 @@ class LLM:
def __init__(self):
self.model = 'ernie-3.5'
self.prompt = '''你是一个机器人动作规划者,需要把我的话翻译成机器人动作规划并生成对应的 json 结果,机器人工作空间参考右手坐标系。
严格按照下面的描述生成给定格式 json从现在开始你仅仅给我返回 json 数据'''
self.prompt += '''正确的示例如下:
向左移 0.1m, 向左转弯 85 度 [{'func': 'move', 'x': 0, 'y': 0.1},{'func': 'turn','angle': -85}],
向右移 0.2m, 向前 0.1m [{'func': 'move', 'x': 0, 'y': -0.2},{'func': 'move', 'x': 0.1, 'y': 0}],
向右转 85 度,向右移 0.1m [{'func': 'turn','angle': 85},{'func': 'move', 'x': 0, 'y': -0.1}],
原地左转 38 度 [{'func': 'turn','angle': -38}],
蜂鸣器发声 5 秒 [{'func': 'beep', 'time': 5}]
发光或者照亮 5 秒 [{'func': 'light', 'time': 5}]
向右走 30cm照亮 2s [{'func': 'move', 'x': 0, 'y': -0.3}, {'func': 'light', 'time': 2}],
向左移 0.2m, 向后 0.1m [{'func': 'move', 'x': 0, 'y': 0.2},{'func': 'move', 'x': -0.1, 'y': 0}],
self.prompt = '''
你是一个机器人动作规划者,需要把我的话翻译成机器人动作规划并生成对应的 JSON 结果。请注意,只能使用以下指定的动作,不能创造新的动作:
允许的动作及其对应格式如下:
- 向左移:{"index":N,"action":"go_left","time":T}
- 向右移{"index":N,"action":"go_right","time":T}
- 向前移:{"index":N,"action":"go_front","time":T}
- 向后移:{"index":N,"action":"go_back","time":T}
- 向左转:{"index":N,"action":"go_left_rotate","time":T}
- 向右转:{"index":N,"action":"go_right_rotate","time":T}
- 蜂鸣器发声:{"index":N,"action":"beep_seconds","time":T}
- 蜂鸣器发声次数:{"index":N,"action":"beep_counts","time":T}
- 发光或者照亮:{"index":N,"action":"light_seconds","time":T}
- 发光次数或者闪烁次数:{"index":N,"action":"light_counts","time":T}
- 发光并伴随蜂鸣器:{"index":N,"action":"beep_light_counts","time":T}
- 等待{"index":N,"action":"go_sleep","time":T}
示例输入输出如下:
输入:向左移 0.1m, 向左转弯 85 度
输出:[{"index":0,"action":"go_left","time":0.1},{"index":1,"action":"go_left_rotate","time":85}]
输入:向右移 0.2m, 向前 0.1m
输出:[{"index":0,"action":"go_right","time":0.2},{"index":1,"action":"go_front","time":0.1}]
输入:向右转 90 度,向右移 0.1m
输出:[{"index":0,"action":"go_right_rotate","time":90},{"index":1,"action":"go_right","time":0.1}]
输入:原地左转 38 度
输出:[{"index":0,"action":"go_left_rotate","time":38}]
输入:蜂鸣器发声 5 秒
输出:[{"index":0,"action":"beep_seconds","time":5}]
输入:发光或者照亮 5 秒
输出:[{"index":0,"action":"light_seconds","time":5}]
输入:向右走 30cm, 照亮 2s
输出:[{"index":0,"action":"go_right","time":0.3},{"index":1,"action":"light_seconds","time":2}]
输入:向左移 0.2m, 向后 0.1m
输出:[{"index":0,"action":"go_left","time":0.2},{"index":1,"action":"go_back","time":0.1}]
输入:鸣叫 3 声
输出:[{"index":0,"action":"beep_counts","time":3}]
输入:前行零点五米
输出:[{"index":0,"action":"go_front","time":0.5}]
输入:闪烁灯光 1 次并伴有蜂鸣器
输出:[{"index":0,"action":"beep_light_counts","time": 1}]
输入:灯光闪烁 3 次同时蜂鸣器也叫 3 次
输出:[{"index":0,"action":"beep_light_counts","time": 3}]
'''
self.prompt += '''请根据上面的示例,解析该任务文本,并返回相应的 JSON 字段。确保 JSON 中包含了键 index action 和 time 以及相应的值'''
self.messages = []
self.resp = None
self.reset()

8
test/test_ocr.py
View File

@@ -17,13 +17,7 @@ while True:
if resp.get('code') == 0:
text = ''
for item in resp.get('content'):
if item['probability']['average'] < 0.90:
continue
box = item['location']
center_x = box['left'] + box['width'] / 2
center_y = box['top'] + box['height'] / 2
if center_x < filter_w[0] or center_x > filter_w[1] \
or center_y < filter_h[0] or center_y > filter_h[1]:
if item['probability']['average'] < 0.80:
continue
text += item['words']
print(text)

17
test/test_ocr_camera.py Normal file
View File

@@ -0,0 +1,17 @@
import cv2
import time
cap = cv2.VideoCapture(20)
cap.set(cv2.CAP_PROP_AUTOFOCUS, 0)
cap.set(cv2.CAP_PROP_FOCUS, 280)
cap.set(cv2.CAP_PROP_FRAME_WIDTH, 640)
cap.set(cv2.CAP_PROP_FRAME_HEIGHT, 480)
while True:
ret, frame = cap.read()
if ret:
cv2.imshow('src', frame)
time.sleep(0.2)
if cv2.waitKey(25) & 0xFF == ord('q'):
break

230
utils.py
View File

@@ -2,6 +2,7 @@
from enum import Enum
import numpy as np
import erniebot
from openai import OpenAI
from simple_pid import PID
from loguru import logger
import threading
@@ -372,55 +373,234 @@ class label_filter:
error = (boxes[center_x_index][4] + boxes[center_x_index][2] - self.img_size[0]) / 2
return (True, error)
return (False, 0)
class LLM_deepseek:
def __init__(self):
self.response = None
self.success_status = threading.Event()
self.error_status = threading.Event()
self.success_status.clear()
self.error_status.clear()
self.chat = ''
self.client = OpenAI(api_key="sk-c2e1073883304143981a9750b97c3518", base_url="https://api.deepseek.com")
self.prompt = '''
你是一个机器人动作规划者,请把我的话翻译成机器人动作规划并生成对应的 JSON 结果。请注意,只能使用以下指定的动作,不能创造新的动作:
允许的动作及其对应格式如下:
[{'properties': {'index': {'title': 'Index', 'type': 'integer'}, 'action': {'title': 'Action', 'type': 'string'}, 'time': {'title': 'Time', 'type': 'number'}}, 'required': ['index', 'action', 'time'], 'title': 'Action', 'type': 'object'}]
我不允许你自我创造出新的 action,action 字段仅仅包括以下内容:
go_right 向右移动
go_left 向左移动
go_front 向前移动
go_back 向后移动
go_left_rotate 向左旋转
go_right_rotate 向右旋转
beep_seconds 蜂鸣器鸣叫的时间
beep_counts 蜂鸣器鸣叫的次数
light_seconds 灯光发光的时间
light_counts 灯光闪烁的次数
beep_light_counts 灯光和蜂鸣器一起闪烁的次数
go_sleep 什么都不做
我的话和你的回复示例如下:
我的话:向左移 0.1m, 向左转弯 85 度
你的回复:[{"index":0,"action":"go_left","time":0.1},{"index":1,"action":"go_left_rotate","time":85}]
我的话:向右移 0.2m, 向前 0.1m
你的回复:[{"index":0,"action":"go_right","time":0.2},{"index":1,"action":"go_front","time":0.1}]
我的话:向右转 90 度,向右移 0.1m
你的回复:[{"index":0,"action":"go_right_rotate","time":90},{"index":1,"action":"go_right","time":0.1}]
我的话:原地左转 38 度
你的回复:[{"index":0,"action":"go_left_rotate","time":38}]
我的话:蜂鸣器发声 5 秒
你的回复:[{"index":0,"action":"beep_seconds","time":5}]
我的话:发光或者照亮 5 秒
你的回复:[{"index":0,"action":"light_seconds","time":5}]
我的话:向右走 30cm照亮 2s
你的回复:[{"index":0,"action":"go_right","time":0.3},{"index":1,"action":"light_seconds","time":2}]
我的话:向左移 0.2m, 向后 0.1m
你的回复:[{"index":0,"action":"go_left","time":0.2},{"index":1,"action":"go_back","time":0.1}]
我的话:鸣叫 3 声
你的回复:[{"index":0,"action":"beep_counts","time":3}]
我的话:前行零点五米
你的回复:[{"index":0,"action":"go_front","time":0.5}]
我的话:闪烁灯光 1 次并伴有蜂鸣器
你的回复:[{"index":0,"action":"beep_light_counts","time": 1}]
我的话:灯光闪烁 3 次同时蜂鸣器也叫 3 次
你的回复:[{"index":0,"action":"beep_light_counts","time": 3}]
强调一下,对于‘离开’这个指令,请忽略,这对我很重要!
'''
def request_thread(self):
logger.info("llm 请求远程服务器中 (request_thread)")
try:
self.response = self.client.chat.completions.create(
model="deepseek-chat",
messages=[
{"role": "system", "content": self.prompt},
{"role": "user", "content": '我的话如下:' + self.chat},
],
stream=False,
temperature=0.7
)
logger.info("llm 远程服务器正常返回 (request_thread)")
self.success_status.set()
except:
logger.warning("llm 请求失败或返回异常,先检查网络连接 (request_thread)")
self.error_status.set()
def request(self, _chat):
self.chat = _chat
thread = threading.Thread(target=self.request_thread, daemon=True)
thread.start()
logger.info("llm 开启请求线程")
def get_command_json(self,chat = ''):
# response = self.client.chat.completions.create(
# model="deepseek-chat",
# messages=[
# {"role": "system", "content": self.prompt},
# {"role": "user", "content": '我的话如下:' + chat},
# ],
# stream=False,
# temperature=0.7
# )
logger.info("llm 阻塞等待服务器返回中")
while not self.status: # FIXME 阻塞等待是否合适
pass
logger.info("llm 收到返回")
return self.response.choices[0].message.content
class LLM:
def __init__(self):
self.init_done_flag = False
erniebot.api_type = "qianfan"
erniebot.ak = "jReawMtWhPu0wrxN9Rp1MzZX"
erniebot.sk = "eowS1BqsNgD2i0C9xNnHUVOSNuAzVTh6"
self.model = 'ernie-3.5'
self.prompt = '''你是一个机器人动作规划者,需要把我的话翻译成机器人动作规划并生成对应的 json 结果,机器人工作空间参考右手坐标系。
严格按照下面的描述生成给定格式 json从现在开始你仅仅给我返回 json 数据!'''
self.prompt += '''正确的示例如下:
向左移 0.1m, 向左转弯 85 度 [{'func': 'move', 'x': 0, 'y': 0.1},{'func': 'turn','angle': -85}],
向右移 0.2m, 向前 0.1m [{'func': 'move', 'x': 0, 'y': -0.2},{'func': 'move', 'x': 0.1, 'y': 0}],
向右转 85 度,向右移 0.1m [{'func': 'turn','angle': 85},{'func': 'move', 'x': 0, 'y': -0.1}],
原地左转 38 度 [{'func': 'turn','angle': -38}],
蜂鸣器发声 5 秒 [{'func': 'beep', 'time': 5}]
发光或者照亮 5 秒 [{'func': 'light', 'time': 5}]
向右走 30cm照亮 2s [{'func': 'move', 'x': 0, 'y': -0.3}, {'func': 'light', 'time': 2}],
向左移 0.2m, 向后 0.1m [{'func': 'move', 'x': 0, 'y': 0.2},{'func': 'move', 'x': -0.1, 'y': 0}],
鸣叫 3 声 [{'func': 'beep', 'time': 3}]
前行零点五米 [{'func': 'move', 'x': 0.5, 'y': 0}]
self.model = 'ernie-lite'
# self.prompt = '''你是一个机器人动作规划者,需要把我的话翻译成机器人动作规划并生成对应的 json 结果,机器人工作空间参考右手坐标系。
# 严格按照下面的描述生成给定格式 json从现在开始你仅仅给我返回 json 数据!'''
# self.prompt += '''正确的示例如下:
# 向左移 0.1m, 向左转弯 85 度 [{'func': 'move', 'x': 0, 'y': 0.1},{'func': 'turn','angle': -85}],
# 向右移 0.2m, 向前 0.1m [{'func': 'move', 'x': 0, 'y': -0.2},{'func': 'move', 'x': 0.1, 'y': 0}],
# 向右转 85 度,向右移 0.1m [{'func': 'turn','angle': 85},{'func': 'move', 'x': 0, 'y': -0.1}],
# 原地左转 38 度 [{'func': 'turn','angle': -38}],
# 蜂鸣器发声 5 秒 [{'func': 'beep', 'time': 5}]
# 发光或者照亮 5 秒 [{'func': 'light', 'time': 5}]
# 向右走 30cm照亮 2s [{'func': 'move', 'x': 0, 'y': -0.3}, {'func': 'light', 'time': 2}],
# 向左移 0.2m, 向后 0.1m [{'func': 'move', 'x': 0, 'y': 0.2},{'func': 'move', 'x': -0.1, 'y': 0}],
# 鸣叫 3 声 [{'func': 'beep', 'time': 3}]
# 前行零点五米 [{'func': 'move', 'x': 0.5, 'y': 0}]
# '''
# self.prompt = '''
# 你是一个机器人动作规划者,需要把我的话翻译成机器人动作规划并生成对应的 JSON 结果。请注意,只能使用以下指定的动作,不能创造新的动作:
# 允许的动作及其对应格式如下:
# - 向左移:{"index":N,"action":"go_left","time":T}
# - 向右移:{"index":N,"action":"go_right","time":T}
# - 向前移:{"index":N,"action":"go_front","time":T}
# - 向后移:{"index":N,"action":"go_back","time":T}
# - 向左转:{"index":N,"action":"go_left_rotate","time":T}
# - 向右转:{"index":N,"action":"go_right_rotate","time":T}
# - 蜂鸣器发声:{"index":N,"action":"beep_seconds","time":T}
# - 蜂鸣器发声次数:{"index":N,"action":"beep_counts","time":T}
# - 发光或者照亮:{"index":N,"action":"light_seconds","time":T}
# - 发光次数或者闪烁次数:{"index":N,"action":"light_counts","time":T}
# - 发光并伴随蜂鸣器:{"index":N,"action":"beep_light_counts","time":T}
# - 等待{"index":N,"action":"go_sleep","time":T}
# 示例输入输出如下:
# 输入:向左移 0.1m, 向左转弯 85 度
# 输出:[{"index":0,"action":"go_left","time":0.1},{"index":1,"action":"go_left_rotate","time":85}]
# 输入:向右移 0.2m, 向前 0.1m
# 输出:[{"index":0,"action":"go_right","time":0.2},{"index":1,"action":"go_front","time":0.1}]
# 输入:向右转 90 度,向右移 0.1m
# 输出:[{"index":0,"action":"go_right_rotate","time":90},{"index":1,"action":"go_right","time":0.1}]
# 输入:原地左转 38 度
# 输出:[{"index":0,"action":"go_left_rotate","time":38}]
# 输入:蜂鸣器发声 5 秒
# 输出:[{"index":0,"action":"beep_seconds","time":5}]
# 输入:发光或者照亮 5 秒
# 输出:[{"index":0,"action":"light_seconds","time":5}]
# 输入:向右走 30cm, 照亮 2s
# 输出:[{"index":0,"action":"go_right","time":0.3},{"index":1,"action":"light_seconds","time":2}]
# 输入:向左移 0.2m, 向后 0.1m
# 输出:[{"index":0,"action":"go_left","time":0.2},{"index":1,"action":"go_back","time":0.1}]
# 输入:鸣叫 3 声
# 输出:[{"index":0,"action":"beep_counts","time":3}]
# 输入:前行零点五米
# 输出:[{"index":0,"action":"go_front","time":0.5}]
# 输入:闪烁灯光 1 次并伴有蜂鸣器
# 输出:[{"index":0,"action":"beep_light_counts","time": 1}]
# 输入:灯光闪烁 3 次同时蜂鸣器也叫 3 次
# 输出:[{"index":0,"action":"beep_light_counts","time": 3}]
# '''
# self.prompt += '''请根据上面的示例,解析该任务文本,并返回相应的 JSON 字段。确保 JSON 中包含了键 index action 和 time 以及相应的值。不要附带其他的解释和注释,只需要 JSON 字段。'''
self.prompt = '''
你是一个机器人动作规划者,需要把我的话翻译成机器人动作规划并生成对应的 JSON 结果。请注意,只能使用以下指定的动作,不能创造新的动作:
允许的动作及其对应格式如下:
[{'properties': {'index': {'title': 'Index', 'type': 'integer'}, 'action': {'title': 'Action', 'type': 'string'}, 'time': {'title': 'Time', 'type': 'number'}}, 'required': ['index', 'action', 'time'], 'title': 'Action', 'type': 'object'}]
我不允许你自我创造出新的 action,action 字段仅仅包括以下内容:
go_right 向右移动
go_left 向左移动
go_front 向前移动
go_back 向后移动
go_left_rotate 向左旋转
go_right_rotate 向右旋转
beep_seconds 蜂鸣器鸣叫的时间
beep_counts 蜂鸣器鸣叫的次数
light_seconds 灯光发光的时间
light_counts 灯光闪烁的次数
beep_light_counts 灯光和蜂鸣器一起闪烁的次数
go_sleep 什么都不做
我的话和你的回复示例如下:
我的话:向左移 0.1m, 向左转弯 85 度
你的回复:[{"index":0,"action":"go_left","time":0.1},{"index":1,"action":"go_left_rotate","time":85}]
我的话:向右移 0.2m, 向前 0.1m
你的回复:[{"index":0,"action":"go_right","time":0.2},{"index":1,"action":"go_front","time":0.1}]
我的话:向右转 90 度,向右移 0.1m
你的回复:[{"index":0,"action":"go_right_rotate","time":90},{"index":1,"action":"go_right","time":0.1}]
我的话:原地左转 38 度
你的回复:[{"index":0,"action":"go_left_rotate","time":38}]
我的话:蜂鸣器发声 5 秒
你的回复:[{"index":0,"action":"beep_seconds","time":5}]
我的话:发光或者照亮 5 秒
你的回复:[{"index":0,"action":"light_seconds","time":5}]
我的话:向右走 30cm照亮 2s
你的回复:[{"index":0,"action":"go_right","time":0.3},{"index":1,"action":"light_seconds","time":2}]
我的话:向左移 0.2m, 向后 0.1m
你的回复:[{"index":0,"action":"go_left","time":0.2},{"index":1,"action":"go_back","time":0.1}]
我的话:鸣叫 3 声
你的回复:[{"index":0,"action":"beep_counts","time":3}]
我的话:前行零点五米
你的回复:[{"index":0,"action":"go_front","time":0.5}]
我的话:闪烁灯光 1 次并伴有蜂鸣器
你的回复:[{"index":0,"action":"beep_light_counts","time": 1}]
我的话:灯光闪烁 3 次同时蜂鸣器也叫 3 次
你的回复:[{"index":0,"action":"beep_light_counts","time": 3}]
我的话如下:
'''
self.prompt += '''你只需要根据我的示例解析出指令即可,不要给我其他多余的回复;再次强调 你无需给我其他多余的回复 这对我很重要'''
self.messages = []
self.resp = None
worker = threading.Thread(target=self.reset, daemon=True)
worker.start()
def reset(self):
self.messages = [self.make_message(self.prompt)]
self.resp = erniebot.ChatCompletion.create(
model=self.model,
messages=self.messages,
)
self.messages.append(self.resp.to_message())
self.init_done_flag = True
logger.info("LLM init done")
try:
self.messages = [self.make_message(self.prompt)]
self.resp = erniebot.ChatCompletion.create(
model=self.model,
messages=self.messages,
)
self.messages.append(self.resp.to_message())
self.init_done_flag = True
logger.info("LLM init done")
except:
logger.error("LLM init error")
def make_message(self,content):
return {'role': 'user', 'content': content}
def get_command_json(self,chat):
while self.init_done_flag == False: # 等待初始化 (要是等到调用还没初始化,那就是真寄了)
pass
chat = '我的话如下:' + chat
self.messages.append(self.make_message(chat))
self.resp = erniebot.ChatCompletion.create(
model=self.model,
messages=self.messages,
)
self.messages.append(self.resp.to_message())
resp = self.resp.get_result().replace(' ', '').replace('\n', '').replace('\t', '')
resp = self.resp.get_result().replace(' ', '')
return resp
class CountRecord: