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open_pub:main open_pub:dev open_pub:prcix9320 open_pub:feat/samples open_pub:feature/organic-extraction open_pub:feat/add_unilabos_class open_pub:feat/unilabos-full-version open_pub:fix/workstation-yb-revision open_pub:workstation_YB_merge_dev_ready_260113 open_pub:feat/add_custom_widget open_pub:workstation_dev_YB_260113 open_pub:workstation_dev_YB4_0110 open_pub:workstation_dev_YB4_0107 open_pub:workstation_dev_YB4 open_pub:workstation_dev_YB5 open_pub:workflow_uploader open_pub:workstation_dev_YB2 open_pub:clean
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open_pub:dev open_pub:prcix9320 open_pub:feat/samples open_pub:feature/organic-extraction open_pub:main open_pub:feat/add_unilabos_class open_pub:feat/unilabos-full-version open_pub:fix/workstation-yb-revision open_pub:workstation_YB_merge_dev_ready_260113 open_pub:feat/add_custom_widget open_pub:workstation_dev_YB_260113 open_pub:workstation_dev_YB4_0110 open_pub:workstation_dev_YB4_0107 open_pub:workstation_dev_YB4 open_pub:workstation_dev_YB5 open_pub:workflow_uploader open_pub:workstation_dev_YB2 open_pub:clean
open_pub:v0.10.17 open_pub:v0.10.14 open_pub:v0.10.13 open_pub:v0.10.12 open_pub:v0.10.7 open_pub:v0.10.3 open_pub:v0.10.1 open_pub:v0.9.7 open_pub:v0.9.5 open_pub:v0.9.1 open_pub:v0.9.0 open_pub:v0.8.0

53 Commits
v0.10.14 ... 58d1cc4720

Author SHA1 Message Date
Guangxin Zhang
58d1cc4720 Add set_group and transfer_group methods to PRCXI9300Handler and update liquid_handler.yaml 2025-09-10 21:23:15 +08:00
Guangxin Zhang
5676dd6589 Add LiquidHandlerSetGroup and LiquidHandlerTransferGroup actions to CMakeLists 2025-09-10 20:57:22 +08:00
Guangxin Zhang
1ae274a833 Add action definitions for LiquidHandlerSetGroup and LiquidHandlerTransferGroup 
- Created LiquidHandlerSetGroup.action with fields for group name, wells, and volumes.
- Created LiquidHandlerTransferGroup.action with fields for source and target group names and unit volume.
- Both actions include response fields for return information and success status.
 2025-09-10 20:57:16 +08:00
Xuwznln
22b88c8441 取消labid 和 强制config输入 2025-09-10 20:55:24 +08:00
Xuwznln
81bcc1907d fix: addr param 2025-09-10 20:14:33 +08:00
Xuwznln
8cffd3dc21 fix: addr param 2025-09-10 20:13:44 +08:00
Xuwznln
a722636938 增加addr参数 2025-09-10 20:01:10 +08:00
Xuwznln
f68340d932 修复status密集发送时,消息出错 2025-09-10 18:52:23 +08:00
Xuwznln
361eae2f6d 注册表编辑器 2025-09-07 20:57:48 +08:00
Xuwznln
c25283ae04 主机节点信息等支持自动刷新 2025-09-07 12:53:00 +08:00
Xuwznln
961752fb0d 更新schema的title字段 2025-09-07 00:43:23 +08:00
Xuwznln
55165024dd 修复async错误 2025-09-04 20:19:15 +08:00
Xuwznln
6ddceb8393 修复edge上报错误 2025-09-04 19:31:19 +08:00
Xuwznln
4e52c7d2f4 修复event loop错误 2025-09-04 17:11:50 +08:00
Xuwznln
0b56efc89d 增加handle检测,增加material edge关系上传 2025-09-04 16:46:25 +08:00
Xuwznln
a27b93396a 修复工站的tracker实例追踪失效问题 2025-09-04 02:51:13 +08:00
Xuwznln
2a60a6c27e 修正物料关系上传 2025-09-03 14:20:37 +08:00
Xuwznln
5dda94044d 增加物料关系上传日志 2025-09-03 12:31:25 +08:00
Xuwznln
0cfc6f45e3 增加物料关系上传日志 2025-09-03 12:20:54 +08:00
Xuwznln
831f4549f9 ws protocol 2025-09-02 18:51:27 +08:00
Xuwznln
f4d4eb06d3 ws test version 2 2025-09-02 18:29:05 +08:00
Xuwznln
e3b8164f6b ws test version 1 2025-09-02 14:32:02 +08:00
Xuwznln
78c04acc2e fix: missing job_id key 2025-09-01 16:34:23 +08:00
Xuwznln
cd0428ea78 fix: build 2025-08-30 12:24:28 +08:00
Xuwznln
68513b5745 feat: action status 2025-08-29 15:38:16 +08:00
Xuwznln
bbbdb06bbc feat: websocket test 2025-08-28 19:57:14 +08:00
Xuwznln
cd84e26126 feat: websocket 2025-08-28 14:34:38 +08:00
Xuwznln
02c79363c1 feat: add sk & ak 2025-08-20 21:23:08 +08:00
Xuwznln
4b7bde6be5 Update recipe.yaml 2025-08-13 16:36:53 +08:00
Xuwznln
8a669ac35a fix: figure_resource 2025-08-13 13:23:02 +08:00
Junhan Chang
a1538da39e use call_async in all service to avoid deadlock 2025-08-13 04:25:51 +08:00
Xuwznln
0063df4cf3 fix: prcxi import error 2025-08-12 19:31:52 +08:00
Xuwznln
e570ba4976 临时兼容错误的driver写法 2025-08-12 19:20:53 +08:00
Xuwznln
e8c1f76dbb fix protocol node 2025-08-12 17:08:59 +08:00
Junhan Chang
f791c1a342 fix filter protocol 2025-08-12 16:48:32 +08:00
Junhan Chang
ea60cbe891 bugfixes on organic protocols 2025-08-12 14:50:01 +08:00
Junhan Chang
eac9b8ab3d fix and remove redundant info 2025-08-11 20:52:03 +08:00
Xuwznln
573bcf1a6c feat: 新增use_remote_resource参数 2025-08-11 16:09:27 +08:00
Junhan Chang
50e93cb1af fix all protocol_compilers and remove deprecated devices 2025-08-11 15:01:04 +08:00
Xuwznln
fe1a029a9b feat: 优化protocol node节点运行日志 2025-08-10 17:31:44 +08:00
Junhan Chang
662c063f50 fix pumps and liquid_handler handle 2025-08-07 20:59:57 +08:00
Xuwznln
01cbbba0b3 feat: workstation example 2025-08-07 15:26:17 +08:00
Xuwznln
e6c556cf19 add: prcxi res 
fix: startup slow
 2025-08-07 01:26:33 +08:00
Xuwznln
0605f305ed fix: prcxi_res 2025-08-06 23:06:22 +08:00
Xuwznln
37d8108ec4 fix: discard_tips 2025-08-06 19:27:10 +08:00
Xuwznln
6081dac561 fix: discard_tips error 2025-08-06 19:18:35 +08:00
Xuwznln
5b2d066127 fix: drop_tips not using auto resource select 2025-08-06 19:10:04 +08:00
ZiWei
06e66765e7 feat: 添加ChinWe设备控制类,支持串口通信和电机控制功能 (#79) 2025-08-06 18:49:37 +08:00
Xuwznln
98ce360088 feat: add trace log level 2025-08-04 20:27:02 +08:00
Xuwznln
5cd0f72fbd modify default discovery_interval to 15s 2025-08-04 14:10:43 +08:00
Xuwznln
343f394203 fix: working dir error when input config path 
feat: report publish topic when error
 2025-08-04 14:04:31 +08:00
Junhan Chang
46aa7a7bd2 fix: workstation handlers and vessel_id parsing 2025-08-04 10:24:42 +08:00
Junhan Chang
a66369e2c3 Cleanup registry to be easy-understanding (#76) 
* delete deprecated mock devices

* rename categories

* combine chromatographic devices

* rename rviz simulation nodes

* organic virtual devices

* parse vessel_id

* run registry completion before merge

---------

Co-authored-by: Xuwznln <18435084+Xuwznln@users.noreply.github.com>
 2025-08-03 11:21:37 +08:00
126 changed files with 13514 additions and 167192 deletions
Expand all files Collapse all files

5
.conda/recipe.yaml
View File

@@ -36,6 +36,7 @@ requirements:
- conda-forge::python ==3.11.11
- compilers
- cmake
- zstd
- ninja
- if: unix
then:
@@ -60,7 +61,7 @@ requirements:
- uvicorn
- gradio
- flask
- websocket
- websockets
- ipython
- jupyter
- jupyros
@@ -85,5 +86,5 @@ requirements:
about:
repository: https://github.com/dptech-corp/Uni-Lab-OS
license: GPL-3.0
license: GPL-3.0-only
description: "Uni-Lab-OS"

3
README.md
View File

@@ -5,6 +5,7 @@
# Uni-Lab-OS
<!-- Language switcher -->
**English** | [中文](README_zh.md)
[![GitHub Stars](https://img.shields.io/github/stars/dptech-corp/Uni-Lab-OS.svg)](https://github.com/dptech-corp/Uni-Lab-OS/stargazers)
@@ -74,4 +75,4 @@ This project is licensed under GPL-3.0 - see the [LICENSE](LICENSE) file for det
## Contact Us
- GitHub Issues: [https://github.com/dptech-corp/Uni-Lab-OS/issues](https://github.com/dptech-corp/Uni-Lab-OS/issues)
- GitHub Issues: [https://github.com/dptech-corp/Uni-Lab-OS/issues](https://github.com/dptech-corp/Uni-Lab-OS/issues)

9
README_zh.md
View File

@@ -5,6 +5,7 @@
# Uni-Lab-OS
<!-- Language switcher -->
[English](README.md) | **中文**
[![GitHub Stars](https://img.shields.io/github/stars/dptech-corp/Uni-Lab-OS.svg)](https://github.com/dptech-corp/Uni-Lab-OS/stargazers)
@@ -12,7 +13,7 @@
[![GitHub Issues](https://img.shields.io/github/issues/dptech-corp/Uni-Lab-OS.svg)](https://github.com/dptech-corp/Uni-Lab-OS/issues)
[![GitHub License](https://img.shields.io/github/license/dptech-corp/Uni-Lab-OS.svg)](https://github.com/dptech-corp/Uni-Lab-OS/blob/main/LICENSE)
Uni-Lab-OS是一个用于实验室自动化的综合平台旨在连接和控制各种实验设备实现实验流程的自动化和标准化。
Uni-Lab-OS 是一个用于实验室自动化的综合平台,旨在连接和控制各种实验设备,实现实验流程的自动化和标准化。
## 🏆 比赛
@@ -34,7 +35,7 @@ Uni-Lab-OS是一个用于实验室自动化的综合平台旨在连接和控
## 快速开始
1. 配置Conda环境
1. 配置 Conda 环境
Uni-Lab-OS 建议使用 `mamba` 管理环境。根据您的操作系统选择适当的环境文件:
@@ -43,7 +44,7 @@ Uni-Lab-OS 建议使用 `mamba` 管理环境。根据您的操作系统选择适
mamba create -n unilab uni-lab::unilabos -c robostack-staging -c conda-forge
```
2. 安装开发版Uni-Lab-OS:
2. 安装开发版 Uni-Lab-OS:
```bash
# 克隆仓库
@@ -76,4 +77,4 @@ Uni-Lab-OS 使用预构建的 `unilabos_msgs` 进行系统通信。您可以在
## 联系我们
- GitHub Issues: [https://github.com/dptech-corp/Uni-Lab-OS/issues](https://github.com/dptech-corp/Uni-Lab-OS/issues)
- GitHub Issues: [https://github.com/dptech-corp/Uni-Lab-OS/issues](https://github.com/dptech-corp/Uni-Lab-OS/issues)

588
example_devices.py Normal file
View File

@@ -0,0 +1,588 @@
"""
示例设备类文件,用于测试注册表编辑器
"""
import asyncio
from typing import Dict, Any, Optional, List
class SmartPumpController:
"""
智能泵控制器
支持多种泵送模式,具有高精度流量控制和自动校准功能。
适用于实验室自动化系统中的液体处理任务。
"""
def __init__(self, device_id: str = "smart_pump_01", port: str = "/dev/ttyUSB0"):
"""
初始化智能泵控制器
Args:
device_id: 设备唯一标识符
port: 通信端口
"""
self.device_id = device_id
self.port = port
self.is_connected = False
self.current_flow_rate = 0.0
self.total_volume_pumped = 0.0
self.calibration_factor = 1.0
self.pump_mode = "continuous" # continuous, volume, rate
def connect_device(self, timeout: int = 10) -> bool:
"""
连接到泵设备
Args:
timeout: 连接超时时间(秒)
Returns:
bool: 连接是否成功
"""
# 模拟连接过程
self.is_connected = True
return True
def disconnect_device(self) -> bool:
"""
断开设备连接
Returns:
bool: 断开连接是否成功
"""
self.is_connected = False
self.current_flow_rate = 0.0
return True
def set_flow_rate(self, flow_rate: float, units: str = "ml/min") -> bool:
"""
设置泵流速
Args:
flow_rate: 流速值
units: 流速单位
Returns:
bool: 设置是否成功
"""
if not self.is_connected:
return False
self.current_flow_rate = flow_rate
return True
async def pump_volume_async(self, volume: float, flow_rate: float) -> Dict[str, Any]:
"""
异步泵送指定体积的液体
Args:
volume: 目标体积 (mL)
flow_rate: 泵送流速 (mL/min)
Returns:
Dict: 包含操作结果的字典
"""
if not self.is_connected:
return {"success": False, "error": "设备未连接"}
# 计算泵送时间
pump_time = (volume / flow_rate) * 60 # 转换为秒
self.current_flow_rate = flow_rate
await asyncio.sleep(min(pump_time, 3.0)) # 模拟泵送过程
self.total_volume_pumped += volume
self.current_flow_rate = 0.0
return {
"success": True,
"pumped_volume": volume,
"actual_time": min(pump_time, 3.0),
"total_volume": self.total_volume_pumped,
}
def emergency_stop(self) -> bool:
"""
紧急停止泵
Returns:
bool: 停止是否成功
"""
self.current_flow_rate = 0.0
return True
def perform_calibration(self, reference_volume: float, measured_volume: float) -> bool:
"""
执行泵校准
Args:
reference_volume: 参考体积
measured_volume: 实际测量体积
Returns:
bool: 校准是否成功
"""
if measured_volume > 0:
self.calibration_factor = reference_volume / measured_volume
return True
return False
# 状态查询方法
def get_connection_status(self) -> str:
"""获取连接状态"""
return "connected" if self.is_connected else "disconnected"
def get_current_flow_rate(self) -> float:
"""获取当前流速 (mL/min)"""
return self.current_flow_rate
def get_total_volume(self) -> float:
"""获取累计泵送体积 (mL)"""
return self.total_volume_pumped
def get_calibration_factor(self) -> float:
"""获取校准因子"""
return self.calibration_factor
def get_pump_mode(self) -> str:
"""获取泵送模式"""
return self.pump_mode
def get_device_status(self) -> Dict[str, Any]:
"""获取设备完整状态信息"""
return {
"device_id": self.device_id,
"connected": self.is_connected,
"flow_rate": self.current_flow_rate,
"total_volume": self.total_volume_pumped,
"calibration_factor": self.calibration_factor,
"mode": self.pump_mode,
"running": self.current_flow_rate > 0,
}
class AdvancedTemperatureController:
"""
高级温度控制器
支持PID控制、多点温度监控和程序化温度曲线。
适用于需要精确温度控制的化学反应和材料处理过程。
"""
def __init__(self, controller_id: str = "temp_controller_01"):
"""
初始化温度控制器
Args:
controller_id: 控制器ID
"""
self.controller_id = controller_id
self.current_temperature = 25.0
self.target_temperature = 25.0
self.is_heating = False
self.is_cooling = False
self.pid_enabled = True
self.temperature_history: List[Dict] = []
def set_target_temperature(self, temperature: float, rate: float = 10.0) -> bool:
"""
设置目标温度
Args:
temperature: 目标温度 (°C)
rate: 升温/降温速率 (°C/min)
Returns:
bool: 设置是否成功
"""
self.target_temperature = temperature
return True
async def heat_to_temperature_async(
self, temperature: float, tolerance: float = 0.5, timeout: int = 600
) -> Dict[str, Any]:
"""
异步加热到指定温度
Args:
temperature: 目标温度 (°C)
tolerance: 温度容差 (°C)
timeout: 最大等待时间 (秒)
Returns:
Dict: 操作结果
"""
self.target_temperature = temperature
start_temp = self.current_temperature
if temperature > start_temp:
self.is_heating = True
elif temperature < start_temp:
self.is_cooling = True
# 模拟温度变化过程
steps = min(abs(temperature - start_temp) * 2, 20) # 计算步数
step_time = min(timeout / steps if steps > 0 else 1, 2.0) # 每步最多2秒
for step in range(int(steps)):
progress = (step + 1) / steps
self.current_temperature = start_temp + (temperature - start_temp) * progress
# 记录温度历史
self.temperature_history.append(
{
"timestamp": asyncio.get_event_loop().time(),
"temperature": self.current_temperature,
"target": self.target_temperature,
}
)
await asyncio.sleep(step_time)
# 保持历史记录不超过100条
if len(self.temperature_history) > 100:
self.temperature_history.pop(0)
# 最终设置为目标温度
self.current_temperature = temperature
self.is_heating = False
self.is_cooling = False
return {
"success": True,
"final_temperature": self.current_temperature,
"start_temperature": start_temp,
"time_taken": steps * step_time,
}
def enable_pid_control(self, kp: float = 1.0, ki: float = 0.1, kd: float = 0.05) -> bool:
"""
启用PID控制
Args:
kp: 比例增益
ki: 积分增益
kd: 微分增益
Returns:
bool: 启用是否成功
"""
self.pid_enabled = True
return True
def run_temperature_program(self, program: List[Dict]) -> bool:
"""
运行温度程序
Args:
program: 温度程序列表,每个元素包含温度和持续时间
Returns:
bool: 程序启动是否成功
"""
# 模拟程序启动
return True
# 状态查询方法
def get_current_temperature(self) -> float:
"""获取当前温度 (°C)"""
return round(self.current_temperature, 2)
def get_target_temperature(self) -> float:
"""获取目标温度 (°C)"""
return self.target_temperature
def get_heating_status(self) -> bool:
"""获取加热状态"""
return self.is_heating
def get_cooling_status(self) -> bool:
"""获取制冷状态"""
return self.is_cooling
def get_pid_status(self) -> bool:
"""获取PID控制状态"""
return self.pid_enabled
def get_temperature_history(self) -> List[Dict]:
"""获取温度历史记录"""
return self.temperature_history[-10:] # 返回最近10条记录
def get_controller_status(self) -> Dict[str, Any]:
"""获取控制器完整状态"""
return {
"controller_id": self.controller_id,
"current_temp": self.current_temperature,
"target_temp": self.target_temperature,
"is_heating": self.is_heating,
"is_cooling": self.is_cooling,
"pid_enabled": self.pid_enabled,
"history_count": len(self.temperature_history),
}
class MultiChannelAnalyzer:
"""
多通道分析仪
支持同时监测多个通道的信号,提供实时数据采集和分析功能。
常用于光谱分析、电化学测量等应用场景。
"""
def __init__(self, analyzer_id: str = "analyzer_01", channels: int = 8):
"""
初始化多通道分析仪
Args:
analyzer_id: 分析仪ID
channels: 通道数量
"""
self.analyzer_id = analyzer_id
self.channel_count = channels
self.channel_data = {i: {"value": 0.0, "unit": "V", "enabled": True} for i in range(channels)}
self.is_measuring = False
self.sample_rate = 1000 # Hz
def configure_channel(self, channel: int, enabled: bool = True, unit: str = "V") -> bool:
"""
配置通道
Args:
channel: 通道编号
enabled: 是否启用
unit: 测量单位
Returns:
bool: 配置是否成功
"""
if 0 <= channel < self.channel_count:
self.channel_data[channel]["enabled"] = enabled
self.channel_data[channel]["unit"] = unit
return True
return False
async def start_measurement_async(self, duration: int = 10) -> Dict[str, Any]:
"""
开始异步测量
Args:
duration: 测量持续时间(秒)
Returns:
Dict: 测量结果
"""
self.is_measuring = True
# 模拟数据采集
measurements = []
for second in range(duration):
timestamp = asyncio.get_event_loop().time()
frame_data = {}
for channel in range(self.channel_count):
if self.channel_data[channel]["enabled"]:
# 模拟传感器数据
import random
value = random.uniform(-5.0, 5.0)
frame_data[f"channel_{channel}"] = value
self.channel_data[channel]["value"] = value
measurements.append({"timestamp": timestamp, "data": frame_data})
await asyncio.sleep(1.0) # 每秒采集一次
self.is_measuring = False
return {
"success": True,
"duration": duration,
"samples_count": len(measurements),
"measurements": measurements[-5:], # 只返回最后5个样本
"channels_active": len([ch for ch in self.channel_data.values() if ch["enabled"]]),
}
def stop_measurement(self) -> bool:
"""
停止测量
Returns:
bool: 停止是否成功
"""
self.is_measuring = False
return True
def reset_channels(self) -> bool:
"""
重置所有通道
Returns:
bool: 重置是否成功
"""
for channel in self.channel_data:
self.channel_data[channel]["value"] = 0.0
return True
# 状态查询方法
def get_measurement_status(self) -> bool:
"""获取测量状态"""
return self.is_measuring
def get_channel_count(self) -> int:
"""获取通道数量"""
return self.channel_count
def get_sample_rate(self) -> float:
"""获取采样率 (Hz)"""
return self.sample_rate
def get_channel_values(self) -> Dict[int, float]:
"""获取所有通道的当前值"""
return {ch: data["value"] for ch, data in self.channel_data.items() if data["enabled"]}
def get_enabled_channels(self) -> List[int]:
"""获取已启用的通道列表"""
return [ch for ch, data in self.channel_data.items() if data["enabled"]]
def get_analyzer_status(self) -> Dict[str, Any]:
"""获取分析仪完整状态"""
return {
"analyzer_id": self.analyzer_id,
"channel_count": self.channel_count,
"is_measuring": self.is_measuring,
"sample_rate": self.sample_rate,
"active_channels": len(self.get_enabled_channels()),
"channel_data": self.channel_data,
}
class AutomatedDispenser:
"""
自动分配器
精确控制固体和液体材料的分配,支持多种分配模式和容器管理。
集成称重功能,确保分配精度和重现性。
"""
def __init__(self, dispenser_id: str = "dispenser_01"):
"""
初始化自动分配器
Args:
dispenser_id: 分配器ID
"""
self.dispenser_id = dispenser_id
self.is_ready = True
self.current_position = {"x": 0.0, "y": 0.0, "z": 0.0}
self.dispensed_total = 0.0
self.container_capacity = 1000.0 # mL
self.precision_mode = True
def move_to_position(self, x: float, y: float, z: float) -> bool:
"""
移动到指定位置
Args:
x: X坐标 (mm)
y: Y坐标 (mm)
z: Z坐标 (mm)
Returns:
bool: 移动是否成功
"""
self.current_position = {"x": x, "y": y, "z": z}
return True
async def dispense_liquid_async(self, volume: float, container_id: str, viscosity: str = "low") -> Dict[str, Any]:
"""
异步分配液体
Args:
volume: 分配体积 (mL)
container_id: 容器ID
viscosity: 液体粘度等级
Returns:
Dict: 分配结果
"""
if not self.is_ready:
return {"success": False, "error": "设备未就绪"}
if volume <= 0:
return {"success": False, "error": "体积必须大于0"}
# 模拟分配过程
dispense_time = volume * 0.1 # 每mL需要0.1秒
if viscosity == "high":
dispense_time *= 2 # 高粘度液体需要更长时间
await asyncio.sleep(min(dispense_time, 5.0)) # 最多等待5秒
self.dispensed_total += volume
return {
"success": True,
"dispensed_volume": volume,
"container_id": container_id,
"actual_time": min(dispense_time, 5.0),
"total_dispensed": self.dispensed_total,
}
def clean_dispenser(self, wash_volume: float = 5.0) -> bool:
"""
清洗分配器
Args:
wash_volume: 清洗液体积 (mL)
Returns:
bool: 清洗是否成功
"""
# 模拟清洗过程
return True
def calibrate_volume(self, target_volume: float) -> bool:
"""
校准分配体积
Args:
target_volume: 校准目标体积 (mL)
Returns:
bool: 校准是否成功
"""
# 模拟校准过程
return True
# 状态查询方法
def get_ready_status(self) -> bool:
"""获取就绪状态"""
return self.is_ready
def get_current_position(self) -> Dict[str, float]:
"""获取当前位置坐标"""
return self.current_position.copy()
def get_dispensed_total(self) -> float:
"""获取累计分配体积 (mL)"""
return self.dispensed_total
def get_container_capacity(self) -> float:
"""获取容器容量 (mL)"""
return self.container_capacity
def get_precision_mode(self) -> bool:
"""获取精密模式状态"""
return self.precision_mode
def get_dispenser_status(self) -> Dict[str, Any]:
"""获取分配器完整状态"""
return {
"dispenser_id": self.dispenser_id,
"ready": self.is_ready,
"position": self.current_position,
"dispensed_total": self.dispensed_total,
"capacity": self.container_capacity,
"precision_mode": self.precision_mode,
}

1
test/experiments/comprehensive_protocol/comprehensive_slim.json
View File

@@ -17,7 +17,6 @@
"config": {
"protocol_type": [
"AddProtocol",
"TransferProtocol",
"StartStirProtocol",
"StopStirProtocol",
"StirProtocol",

95
test/experiments/comprehensive_protocol/comprehensive_station.json
View File

@@ -49,7 +49,6 @@
"config": {
"protocol_type": [
"AddProtocol",
"TransferProtocol",
"StartStirProtocol",
"StopStirProtocol",
"StirProtocol",
@@ -171,12 +170,15 @@
"z": 0
},
"config": {
"volume": 1000.0,
"reagent": "DMF"
"max_volume": 1000.0
},
"data": {
"current_volume": 1000.0,
"reagent_name": "DMF"
"liquids": [
{
"liquid_type": "DMF",
"liquid_volume": 1000.0
}
]
}
},
{
@@ -192,12 +194,15 @@
"z": 0
},
"config": {
"volume": 1000.0,
"reagent": "ethyl_acetate"
"max_volume": 1000.0
},
"data": {
"current_volume": 1000.0,
"reagent_name": "ethyl_acetate"
"liquids": [
{
"liquid_type": "ethyl_acetate",
"liquid_volume": 1000.0
}
]
}
},
{
@@ -213,12 +218,15 @@
"z": 0
},
"config": {
"volume": 1000.0,
"reagent": "hexane"
"max_volume": 1000.0
},
"data": {
"current_volume": 1000.0,
"reagent_name": "hexane"
"liquids": [
{
"liquid_type": "hexane",
"liquid_volume": 1000.0
}
]
}
},
{
@@ -234,12 +242,15 @@
"z": 0
},
"config": {
"volume": 1000.0,
"reagent": "methanol"
"max_volume": 1000.0
},
"data": {
"current_volume": 1000.0,
"reagent_name": "methanol"
"liquids": [
{
"liquid_type": "methanol",
"liquid_volume": 1000.0
}
]
}
},
{
@@ -255,12 +266,15 @@
"z": 0
},
"config": {
"volume": 1000.0,
"reagent": "water"
"max_volume": 1000.0
},
"data": {
"current_volume": 1000.0,
"reagent_name": "water"
"liquids": [
{
"liquid_type": "water",
"liquid_volume": 1000.0
}
]
}
},
{
@@ -320,15 +334,15 @@
"z": 0
},
"config": {
"volume": 500.0,
"max_volume": 500.0,
"max_temp": 200.0,
"min_temp": -20.0,
"has_stirrer": true,
"has_heater": true
},
"data": {
"current_volume": 0.0,
"current_temp": 25.0
"liquids": [
]
}
},
{
@@ -405,10 +419,11 @@
"z": 0
},
"config": {
"volume": 2000.0
"max_volume": 2000.0
},
"data": {
"current_volume": 0.0
"liquids": [
]
}
},
{
@@ -424,10 +439,11 @@
"z": 0
},
"config": {
"volume": 2000.0
"max_volume": 2000.0
},
"data": {
"current_volume": 0.0
"liquids": [
]
}
},
{
@@ -633,10 +649,11 @@
"z": 0
},
"config": {
"volume": 250.0
"max_volume": 250.0
},
"data": {
"current_volume": 0.0
"liquids": [
]
}
},
{
@@ -652,10 +669,11 @@
"z": 0
},
"config": {
"volume": 250.0
"max_volume": 250.0
},
"data": {
"current_volume": 0.0
"liquids": [
]
}
},
{
@@ -671,10 +689,11 @@
"z": 0
},
"config": {
"volume": 250.0
"max_volume": 250.0
},
"data": {
"current_volume": 0.0
"liquids": [
]
}
},
{
@@ -713,7 +732,7 @@
"z": 0
},
"config": {
"volume": 500.0,
"max_volume": 500.0,
"reagent": "sodium_chloride",
"physical_state": "solid"
},
@@ -1077,7 +1096,7 @@
"target": "solid_dispenser_1",
"type": "resource",
"port": {
"solid_reagent_bottle_1": "top",
"solid_reagent_bottle_1": "bottom",
"solid_dispenser_1": "SolidIn"
}
},
@@ -1087,7 +1106,7 @@
"target": "solid_dispenser_1",
"type": "resource",
"port": {
"solid_reagent_bottle_2": "top",
"solid_reagent_bottle_2": "bottom",
"solid_dispenser_1": "SolidIn"
}
},
@@ -1097,7 +1116,7 @@
"target": "solid_dispenser_1",
"type": "resource",
"port": {
"solid_reagent_bottle_3": "top",
"solid_reagent_bottle_3": "bottom",
"solid_dispenser_1": "SolidIn"
}
}

4
test/experiments/mock_reactor.json
View File

@@ -14,8 +14,8 @@
"type": "device",
"class": "workstation",
"position": {
"x": 620.6111111111111,
"y": 171,
"x": 0,
"y": 0,
"z": 0
},
"config": {

8
test/experiments/plr_test_converted.json
View File

@@ -1,8 +1,8 @@
{
"nodes": [
{
"id": "PLR_STATION",
"name": "PLR_LH_TEST",
"id": "liquid_handler",
"name": "liquid_handler",
"parent": null,
"type": "device",
"class": "liquid_handler",
@@ -37,7 +37,7 @@
"tip_rack",
"plate_well"
],
"parent": "PLR_STATION",
"parent": "liquid_handler",
"type": "deck",
"class": "OTDeck",
"position": {
@@ -9650,7 +9650,7 @@
"children": [],
"parent": null,
"type": "device",
"class": "moveit.arm_slider",
"class": "robotic_arm.SCARA_with_slider.virtual",
"position": {
"x": -500,
"y": 1000,

6
test/experiments/prcxi_9300.json
View File

@@ -21,9 +21,9 @@
"timeout": 10.0,
"axis": "Left",
"channel_num": 8,
"setup": false,
"debug": false,
"simulator": false,
"setup": true,
"debug": true,
"simulator": true,
"matrix_id": "71593"
},
"data": {},

2
test/experiments/test_moveit.json
View File

@@ -8,7 +8,7 @@
"children": [],
"parent": null,
"type": "device",
"class": "moveit.arm_slider",
"class": "robotic_arm.SCARA_with_slider.virtual",
"position": {
"x": -500,
"y": 1000,

949
test/experiments/workshop.json Normal file
View File

@@ -0,0 +1,949 @@
{
"nodes": [
{
"id": "simple_station",
"name": "愚公常量合成工作站",
"children": [
"serial_pump",
"pump_reagents",
"pump_workup",
"flask_CH2Cl2",
"waste_workup",
"separator_controller",
"flask_separator",
"flask_air"
],
"parent": null,
"type": "device",
"class": "workstation",
"position": {
"x": 620.6111111111111,
"y": 171,
"z": 0
},
"config": {
"protocol_type": ["PumpTransferProtocol", "CleanProtocol", "SeparateProtocol", "EvaporateProtocol"]
},
"data": {
}
},
{
"id": "serial_pump",
"name": "serial_pump",
"children": [],
"parent": "simple_station",
"type": "device",
"class": "serial",
"position": {
"x": 620.6111111111111,
"y": 171,
"z": 0
},
"config": {
"port": "COM7",
"baudrate": 9600
},
"data": {
}
},
{
"id": "pump_reagents",
"name": "pump_reagents",
"children": [],
"parent": "simple_station",
"type": "device",
"class": "syringepump.runze",
"position": {
"x": 620.6111111111111,
"y": 171,
"z": 0
},
"config": {
"port": "/devices/PumpBackbone/Serial/serialwrite",
"address": "1",
"max_volume": 25.0
},
"data": {
"max_velocity": 1.0,
"position": 0.0,
"status": "Idle",
"valve_position": "0"
}
},
{
"id": "flask_CH2Cl2",
"name": "flask_CH2Cl2",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 430.4087301587302,
"y": 428,
"z": 0
},
"config": {
"max_volume": 2000.0
},
"data": {
"liquid": [
{
"liquid_type": "CH2Cl2",
"liquid_volume": 1500.0
}
]
}
},
{
"id": "flask_acetone",
"name": "flask_acetone",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 295.36944444444447,
"y": 428,
"z": 0
},
"config": {
"max_volume": 2000.0
},
"data": {
"liquid": [
{
"liquid_type": "acetone",
"liquid_volume": 1500.0
}
]
}
},
{
"id": "flask_NH4Cl",
"name": "flask_NH4Cl",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 165.36944444444444,
"y": 428,
"z": 0
},
"config": {
"max_volume": 2000.0
},
"data": {
"liquid": [
{
"liquid_type": "NH4Cl",
"liquid_volume": 1500.0
}
]
}
},
{
"id": "flask_grignard",
"name": "flask_grignard",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 165.36944444444444,
"y": 428,
"z": 0
},
"config": {
"max_volume": 2000.0
},
"data": {
"liquid": [
{
"liquid_type": "grignard",
"liquid_volume": 1500.0
}
]
}
},
{
"id": "flask_THF",
"name": "flask_THF",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 35,
"y": 428,
"z": 0
},
"config": {
"max_volume": 2000.0
},
"data": {
"liquid": [
{
"liquid_type": "THF",
"liquid_volume": 1500.0
}
]
}
},
{
"id": "reactor",
"name": "reactor",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 698.1111111111111,
"y": 428,
"z": 0
},
"config": {
"max_volume": 5000.0
},
"data": {
"liquid": [
]
}
},
{
"id": "stirrer",
"name": "stirrer",
"children": [],
"parent": "simple_station",
"type": "device",
"class": "heaterstirrer.dalong",
"position": {
"x": 698.1111111111111,
"y": 478,
"z": 0
},
"config": {
"port": "COM43",
"temp_warning": 60.0
},
"data": {
"status": "Idle",
"temp": 0.0,
"stir_speed": 0.0
}
},
{
"id": "pump_workup",
"name": "pump_workup",
"children": [],
"parent": "simple_station",
"type": "device",
"class": "syringepump.runze",
"position": {
"x": 1195.611507936508,
"y": 686,
"z": 0
},
"config": {
"port": "/devices/PumpBackbone/Serial/serialwrite",
"address": "2",
"max_volume": 25.0
},
"data": {
"max_velocity": 1.0,
"position": 0.0,
"status": "Idle",
"valve_position": "0"
}
},
{
"id": "waste_workup",
"name": "waste_workup",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 1587.703373015873,
"y": 1172.5,
"z": 0
},
"config": {
"max_volume": 2000.0
},
"data": {
"liquid": [
]
}
},
{
"id": "separator_controller",
"name": "separator_controller",
"children": [],
"parent": "simple_station",
"type": "device",
"class": "separator.homemade",
"position": {
"x": 1624.4027777777778,
"y": 665.5,
"z": 0
},
"config": {
"port_executor": "/dev/tty.usbserial-11140",
"port_sensor": "/dev/tty.usbserial-11130"
},
"data": {
"sensordata": 0.0,
"status": "Idle"
}
},
{
"id": "flask_separator",
"name": "flask_separator",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 1614.404365079365,
"y": 948,
"z": 0
},
"config": {
"max_volume": 2000.0
},
"data": {
"liquid": [
]
}
},
{
"id": "flask_holding",
"name": "flask_holding",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 1915.7035714285714,
"y": 665.5,
"z": 0
},
"config": {
"max_volume": 2000.0
},
"data": {
"liquid": [
]
}
},
{
"id": "flask_H2O",
"name": "flask_H2O",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 1785.7035714285714,
"y": 665.5,
"z": 0
},
"config": {
"max_volume": 2000.0
},
"data": {
"liquid": [
{
"liquid_type": "H2O",
"liquid_volume": 1500.0
}
]
}
},
{
"id": "flask_NaHCO3",
"name": "flask_NaHCO3",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 2054.0650793650793,
"y": 665.5,
"z": 0
},
"config": {
"max_volume": 2000.0
},
"data": {
"liquid": [
{
"liquid_type": "NaHCO3",
"liquid_volume": 1500.0
}
]
}
},
{
"id": "pump_column",
"name": "pump_column",
"children": [],
"parent": "simple_station",
"type": "device",
"class": "syringepump.runze",
"position": {
"x": 1630.6527777777778,
"y": 448.5,
"z": 0
},
"config": {
"port": "/devices/PumpBackbone/Serial/serialwrite",
"address": "3",
"max_volume": 25.0
},
"data": {
"max_velocity": 1.0,
"position": 0.0,
"status": "Idle",
"valve_position": "0"
}
},
{
"id": "rotavap",
"name": "rotavap",
"children": [],
"parent": "simple_station",
"type": "device",
"class": "rotavap",
"position": {
"x": 1339.7031746031746,
"y": 968.5,
"z": 0
},
"config": {
"port": "COM15"
},
"data": {
"temperature": 0.0,
"rotate_time": 0.0,
"status": "Idle"
}
},
{
"id": "flask_rv",
"name": "flask_rv",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 1339.7031746031746,
"y": 1152,
"z": 0
},
"config": {
"max_volume": 2000.0
},
"data": {
"liquid": [
]
}
},
{
"id": "column",
"name": "column",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 909.722619047619,
"y": 948,
"z": 0
},
"config": {
"max_volume": 200.0
},
"data": {
"liquid": [
]
}
},
{
"id": "flask_column",
"name": "flask_column",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 867.972619047619,
"y": 1152,
"z": 0
},
"config": {
"max_volume": 2000.0
},
"data": {
"liquid": [
]
}
},
{
"id": "flask_air",
"name": "flask_air",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 742.722619047619,
"y": 948,
"z": 0
},
"config": {
"max_volume": 2000.0
},
"data": {
"liquid": [
]
}
},
{
"id": "dry_column",
"name": "dry_column",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 1206.722619047619,
"y": 948,
"z": 0
},
"config": {
"max_volume": 200.0
},
"data": {
"liquid": [
]
}
},
{
"id": "flask_dry_column",
"name": "flask_dry_column",
"children": [],
"parent": "simple_station",
"type": "container",
"class": null,
"position": {
"x": 1148.222619047619,
"y": 1152,
"z": 0
},
"config": {
"max_volume": 2000.0
},
"data": {
"liquid": [
]
}
},
{
"id": "pump_ext",
"name": "pump_ext",
"children": [],
"parent": "simple_station",
"type": "device",
"class": "syringepump.runze",
"position": {
"x": 1469.7031746031746,
"y": 968.5,
"z": 0
},
"config": {
"port": "/devices/PumpBackbone/Serial/serialwrite",
"address": "4",
"max_volume": 25.0
},
"data": {
"max_velocity": 1.0,
"position": 0.0,
"status": "Idle",
"valve_position": "0"
}
},
{
"id": "AGV",
"name": "AGV",
"children": ["zhixing_agv", "zhixing_ur_arm"],
"parent": null,
"type": "device",
"class": "workstation",
"position": {
"x": 698.1111111111111,
"y": 478,
"z": 0
},
"config": {
"protocol_type": ["AGVTransferProtocol"]
},
"data": {
}
},
{
"id": "zhixing_agv",
"name": "zhixing_agv",
"children": [],
"parent": "AGV",
"type": "device",
"class": "zhixing_agv",
"position": {
"x": 698.1111111111111,
"y": 478,
"z": 0
},
"config": {
"host": "192.168.1.42"
},
"data": {
}
},
{
"id": "zhixing_ur_arm",
"name": "zhixing_ur_arm",
"children": [],
"parent": "AGV",
"type": "device",
"class": "zhixing_ur_arm",
"position": {
"x": 698.1111111111111,
"y": 478,
"z": 0
},
"config": {
"host": "192.168.1.178"
},
"data": {
}
}
],
"links": [
{
"source": "pump_reagents",
"target": "serial_pump",
"type": "communication",
"port": {
"pump_reagents": "port",
"serial_pump": "port"
}
},
{
"source": "pump_workup",
"target": "serial_pump",
"type": "communication",
"port": {
"pump_reagents": "port",
"serial_pump": "port"
}
},
{
"source": "pump_column",
"target": "serial_pump",
"type": "communication",
"port": {
"pump_reagents": "port",
"serial_pump": "port"
}
},
{
"source": "pump_ext",
"target": "serial_pump",
"type": "communication",
"port": {
"pump_reagents": "port",
"serial_pump": "port"
}
},
{
"source": "reactor",
"target": "pump_reagents",
"type": "physical",
"port": {
"reactor": "top",
"pump_reagents": "5"
}
},
{
"source": "rotavap",
"target": "flask_rv",
"type": "physical",
"port": {
"rotavap": "bottom",
"flask_rv": "top"
}
},
{
"source": "separator_controller",
"target": "flask_separator",
"type": "physical",
"port": {
"separator_controller": "bottom",
"flask_separator": "top"
}
},
{
"source": "column",
"target": "flask_column",
"type": "physical",
"port": {
"column": "bottom",
"flask_column": "top"
}
},
{
"source": "dry_column",
"target": "flask_dry_column",
"type": "physical",
"port": {
"dry_column": "bottom",
"flask_dry_column": "top"
}
},
{
"source": "pump_ext",
"target": "pump_column",
"type": "physical",
"port": {
"pump_ext": "8",
"pump_column": "1"
}
},
{
"source": "pump_ext",
"target": "waste_workup",
"type": "physical",
"port": {
"pump_ext": "2",
"waste_workup": "-1"
}
},
{
"source": "pump_reagents",
"target": "flask_THF",
"type": "physical",
"port": {
"pump_reagents": "7",
"flask_THF": "top"
}
},
{
"source": "pump_reagents",
"target": "flask_NH4Cl",
"type": "physical",
"port": {
"pump_reagents": "4",
"flask_NH4Cl": "top"
}
},
{
"source": "pump_reagents",
"target": "flask_CH2Cl2",
"type": "physical",
"port": {
"pump_reagents": "2",
"flask_CH2Cl2": "top"
}
},
{
"source": "pump_reagents",
"target": "flask_acetone",
"type": "physical",
"port": {
"pump_reagents": "3",
"flask_acetone": "top"
}
},
{
"source": "pump_reagents",
"target": "pump_workup",
"type": "physical",
"port": {
"pump_reagents": "1",
"pump_workup": "8"
}
},
{
"source": "pump_reagents",
"target": "flask_grignard",
"type": "physical",
"port": {
"pump_reagents": "6",
"flask_grignard": "top"
}
},
{
"source": "pump_reagents",
"target": "reactor",
"type": "physical",
"port": {
"pump_reagents": "5",
"reactor": "top"
}
},
{
"source": "pump_reagents",
"target": "flask_air",
"type": "physical",
"port": {
"pump_reagents": "8",
"flask_air": "-1"
}
},
{
"source": "pump_workup",
"target": "waste_workup",
"type": "physical",
"port": {
"pump_workup": "2",
"waste_workup": "-1"
}
},
{
"source": "pump_workup",
"target": "flask_H2O",
"type": "physical",
"port": {
"pump_workup": "7",
"flask_H2O": "top"
}
},
{
"source": "pump_workup",
"target": "flask_NaHCO3",
"type": "physical",
"port": {
"pump_workup": "6",
"flask_NaHCO3": "top"
}
},
{
"source": "pump_workup",
"target": "pump_reagents",
"type": "physical",
"port": {
"pump_workup": "8",
"pump_reagents": "1"
}
},
{
"source": "pump_workup",
"target": "flask_holding",
"type": "physical",
"port": {
"pump_workup": "5",
"flask_holding": "top"
}
},
{
"source": "pump_workup",
"target": "separator_controller",
"type": "physical",
"port": {
"pump_workup": "4",
"separator_controller": "top"
}
},
{
"source": "pump_workup",
"target": "flask_separator",
"type": "physical",
"port": {
"pump_workup": "3",
"flask_separator": "top"
}
},
{
"source": "pump_workup",
"target": "pump_column",
"type": "physical",
"port": {
"pump_workup": "1",
"pump_column": "8"
}
},
{
"source": "pump_column",
"target": "column",
"type": "physical",
"port": {
"pump_column": "4",
"column": "top"
}
},
{
"source": "pump_column",
"target": "flask_column",
"type": "physical",
"port": {
"pump_column": "3",
"flask_column": "top"
}
},
{
"source": "pump_column",
"target": "rotavap",
"type": "physical",
"port": {
"pump_column": "2",
"rotavap": "-1"
}
},
{
"source": "pump_column",
"target": "pump_workup",
"type": "physical",
"port": {
"pump_column": "8",
"pump_workup": "1"
}
},
{
"source": "pump_column",
"target": "flask_air",
"type": "physical",
"port": {
"pump_column": "5",
"flask_air": "-1"
}
},
{
"source": "pump_column",
"target": "dry_column",
"type": "physical",
"port": {
"pump_column": "7",
"dry_column": "top"
}
},
{
"source": "pump_column",
"target": "flask_dry_column",
"type": "physical",
"port": {
"pump_column": "6",
"flask_dry_column": "top"
}
},
{
"source": "pump_column",
"target": "pump_ext",
"type": "physical",
"port": {
"pump_column": "1",
"pump_ext": "8"
}
}
]
}

2
unilabos-linux-64.yaml
View File

@@ -34,7 +34,7 @@ dependencies:
- uvicorn
- gradio
- flask
- websocket
- websockets
# Notebook
- ipython
- jupyter

2
unilabos-osx-64.yaml
View File

@@ -34,7 +34,7 @@ dependencies:
- uvicorn
- gradio
- flask
- websocket
- websockets
# Notebook
- ipython
- jupyter

3
unilabos-osx-arm64.yaml
View File

@@ -35,8 +35,7 @@ dependencies:
- uvicorn
- gradio
- flask
- websocket
- paho-mqtt
- websockets
# Notebook
- ipython
- jupyter

2
unilabos-win64.yaml
View File

@@ -34,7 +34,7 @@ dependencies:
- uvicorn
- gradio
- flask
- websocket
- websockets
# Notebook
- ipython
- jupyter

204
unilabos/app/communication.py Normal file
View File

@@ -0,0 +1,204 @@
#!/usr/bin/env python
# coding=utf-8
"""
通信模块
提供MQTT和WebSocket的统一接口支持通过配置选择通信协议。
包含通信抽象层基类和通信客户端工厂。
"""
from abc import ABC, abstractmethod
from typing import Optional
from unilabos.config.config import BasicConfig
from unilabos.utils import logger
class BaseCommunicationClient(ABC):
"""
通信客户端抽象基类
定义了所有通信客户端MQTT、WebSocket等需要实现的接口。
"""
def __init__(self):
self.is_disabled = True
self.client_id = ""
@abstractmethod
def start(self) -> None:
"""
启动通信客户端连接
"""
pass
@abstractmethod
def stop(self) -> None:
"""
停止通信客户端连接
"""
pass
@abstractmethod
def publish_device_status(self, device_status: dict, device_id: str, property_name: str) -> None:
"""
发布设备状态信息
Args:
device_status: 设备状态字典
device_id: 设备ID
property_name: 属性名称
"""
pass
@abstractmethod
def publish_job_status(
self, feedback_data: dict, job_id: str, status: str, return_info: Optional[str] = None
) -> None:
"""
发布作业状态信息
Args:
feedback_data: 反馈数据
job_id: 作业ID
status: 作业状态
return_info: 返回信息
"""
pass
@abstractmethod
def send_ping(self, ping_id: str, timestamp: float) -> None:
"""
发送ping消息
Args:
ping_id: ping ID
timestamp: 时间戳
"""
pass
def setup_pong_subscription(self) -> None:
"""
设置pong消息订阅可选实现
"""
pass
@property
def is_connected(self) -> bool:
"""
检查是否已连接
Returns:
是否已连接
"""
return not self.is_disabled
class CommunicationClientFactory:
"""
通信客户端工厂类
根据配置文件中的通信协议设置创建相应的客户端实例。
"""
_client_cache: Optional[BaseCommunicationClient] = None
@classmethod
def create_client(cls, protocol: Optional[str] = None) -> BaseCommunicationClient:
"""
创建通信客户端实例
Args:
protocol: 指定的协议类型如果为None则使用配置文件中的设置
Returns:
通信客户端实例
Raises:
ValueError: 当协议类型不支持时
"""
if protocol is None:
protocol = BasicConfig.communication_protocol
protocol = protocol.lower()
if protocol == "mqtt":
return cls._create_mqtt_client()
elif protocol == "websocket":
return cls._create_websocket_client()
else:
logger.error(f"[CommunicationFactory] Unsupported protocol: {protocol}")
logger.warning(f"[CommunicationFactory] Falling back to MQTT")
return cls._create_mqtt_client()
@classmethod
def get_client(cls, protocol: Optional[str] = None) -> BaseCommunicationClient:
"""
获取通信客户端实例(单例模式)
Args:
protocol: 指定的协议类型如果为None则使用配置文件中的设置
Returns:
通信客户端实例
"""
if cls._client_cache is None:
cls._client_cache = cls.create_client(protocol)
logger.info(f"[CommunicationFactory] Created {type(cls._client_cache).__name__} client")
return cls._client_cache
@classmethod
def _create_mqtt_client(cls) -> BaseCommunicationClient:
"""创建MQTT客户端"""
try:
from unilabos.app.mq import mqtt_client
return mqtt_client
except Exception as e:
logger.error(f"[CommunicationFactory] Failed to create MQTT client: {str(e)}")
raise
@classmethod
def _create_websocket_client(cls) -> BaseCommunicationClient:
"""创建WebSocket客户端"""
try:
from unilabos.app.ws_client import WebSocketClient
return WebSocketClient()
except Exception as e:
logger.error(f"[CommunicationFactory] Failed to create WebSocket client: {str(e)}")
logger.warning(f"[CommunicationFactory] Falling back to MQTT")
return cls._create_mqtt_client()
@classmethod
def reset_client(cls):
"""重置客户端缓存(用于测试或重新配置)"""
if cls._client_cache:
try:
cls._client_cache.stop()
except Exception as e:
logger.warning(f"[CommunicationFactory] Error stopping old client: {str(e)}")
cls._client_cache = None
logger.info("[CommunicationFactory] Client cache reset")
@classmethod
def get_supported_protocols(cls) -> list[str]:
"""
获取支持的协议列表
Returns:
支持的协议列表
"""
return ["mqtt", "websocket"]
def get_communication_client(protocol: Optional[str] = None) -> BaseCommunicationClient:
"""
获取通信客户端实例的便捷函数
Args:
protocol: 指定的协议类型如果为None则使用配置文件中的设置
Returns:
通信客户端实例
"""
return CommunicationClientFactory.get_client(protocol)

101
unilabos/app/main.py
View File

@@ -10,7 +10,6 @@ from copy import deepcopy
import yaml
from unilabos.resources.graphio import modify_to_backend_format
# 首先添加项目根目录到路径
current_dir = os.path.dirname(os.path.abspath(__file__))
@@ -18,11 +17,12 @@ unilabos_dir = os.path.dirname(os.path.dirname(current_dir))
if unilabos_dir not in sys.path:
sys.path.append(unilabos_dir)
from unilabos.config.config import load_config, BasicConfig
from unilabos.config.config import load_config, BasicConfig, HTTPConfig
from unilabos.utils.banner_print import print_status, print_unilab_banner
from unilabos.resources.graphio import modify_to_backend_format
def load_config_from_file(config_path, override_labid=None):
def load_config_from_file(config_path):
if config_path is None:
config_path = os.environ.get("UNILABOS_BASICCONFIG_CONFIG_PATH", None)
if config_path:
@@ -31,10 +31,10 @@ def load_config_from_file(config_path, override_labid=None):
elif not config_path.endswith(".py"):
print_status(f"配置文件 {config_path} 不是Python文件必须以.py结尾", "error")
else:
load_config(config_path, override_labid)
load_config(config_path)
else:
print_status(f"启动 UniLab-OS时配置文件参数未正确传入 --config '{config_path}' 尝试本地配置...", "warning")
load_config(config_path, override_labid)
load_config(config_path)
def convert_argv_dashes_to_underscores(args: argparse.ArgumentParser):
@@ -52,8 +52,6 @@ def parse_args():
"""解析命令行参数"""
parser = argparse.ArgumentParser(description="Start Uni-Lab Edge server.")
parser.add_argument("-g", "--graph", help="Physical setup graph.")
# parser.add_argument("-d", "--devices", help="Devices config file.")
# parser.add_argument("-r", "--resources", help="Resources config file.")
parser.add_argument("-c", "--controllers", default=None, help="Controllers config file.")
parser.add_argument(
"--registry_path",
@@ -95,6 +93,11 @@ def parse_args():
action="store_true",
help="启动unilab时同时报送注册表信息",
)
parser.add_argument(
"--use_remote_resource",
action="store_true",
help="启动unilab时使用远程资源启动",
)
parser.add_argument(
"--config",
type=str,
@@ -124,10 +127,27 @@ def parse_args():
help="选择可视化工具: rviz, web",
)
parser.add_argument(
"--labid",
"--ak",
type=str,
default="",
help="实验室唯一ID也可通过环境变量 UNILABOS_MQCONFIG_LABID 设置或传入--config设置",
help="实验室请求的ak",
)
parser.add_argument(
"--sk",
type=str,
default="",
help="实验室请求的sk",
)
parser.add_argument(
"--addr",
type=str,
default="https://uni-lab.bohrium.com/api/v1",
help="实验室后端地址",
)
parser.add_argument(
"--websocket",
action="store_true",
help="使用websocket而非mqtt作为通信协议",
)
parser.add_argument(
"--skip_env_check",
@@ -162,7 +182,7 @@ def main():
else:
working_dir = os.path.abspath(os.path.join(os.getcwd(), "unilabos_data"))
if args_dict.get("working_dir"):
working_dir = args_dict.get("working_dir")
working_dir = args_dict.get("working_dir", "")
if config_path and not os.path.exists(config_path):
config_path = os.path.join(working_dir, "local_config.py")
if not os.path.exists(config_path):
@@ -171,6 +191,8 @@ def main():
"error",
)
os._exit(1)
elif config_path and os.path.exists(config_path):
working_dir = os.path.dirname(config_path)
elif os.path.exists(working_dir) and os.path.exists(os.path.join(working_dir, "local_config.py")):
config_path = os.path.join(working_dir, "local_config.py")
elif not config_path and (
@@ -185,19 +207,40 @@ def main():
os.path.join(os.path.dirname(os.path.dirname(__file__)), "config", "example_config.py"), config_path
)
print_status(f"已创建 local_config.py 路径: {config_path}", "info")
print_status(f"请在文件夹中配置lab_id放入下载的CA.crt、lab.crt、lab.key重新启动本程序", "info")
os._exit(1)
else:
os._exit(1)
# 加载配置文件
print_status(f"当前工作目录为 {working_dir}", "info")
load_config_from_file(config_path, args_dict["labid"])
load_config_from_file(config_path)
if args_dict["addr"] == "test":
print_status("使用测试环境地址", "info")
HTTPConfig.remote_addr = "https://uni-lab.test.bohrium.com/api/v1"
elif args_dict["addr"] == "local":
print_status("使用本地环境地址", "info")
HTTPConfig.remote_addr = "http://127.0.0.1:48197/api/v1"
else:
HTTPConfig.remote_addr = args_dict.get("addr", "")
if args_dict["use_remote_resource"]:
print_status("使用远程资源启动", "info")
from unilabos.app.web import http_client
res = http_client.resource_get("host_node", False)
if str(res.get("code", 0)) == "0" and len(res.get("data", [])) > 0:
print_status("远程资源已存在,使用云端物料!", "info")
args_dict["graph"] = None
else:
print_status("远程资源不存在,本地将进行首次上报!", "info")
# 设置BasicConfig参数
BasicConfig.ak = args_dict.get("ak", "")
BasicConfig.sk = args_dict.get("sk", "")
BasicConfig.working_dir = working_dir
BasicConfig.is_host_mode = not args_dict.get("without_host", False)
BasicConfig.slave_no_host = args_dict.get("slave_no_host", False)
BasicConfig.upload_registry = args_dict.get("upload_registry", False)
BasicConfig.communication_protocol = "websocket" if args_dict.get("websocket", False) else "mqtt"
machine_name = os.popen("hostname").read().strip()
machine_name = "".join([c if c.isalnum() or c == "_" else "_" for c in machine_name])
BasicConfig.machine_name = machine_name
@@ -210,7 +253,7 @@ def main():
dict_to_nested_dict,
initialize_resources,
)
from unilabos.app.mq import mqtt_client
from unilabos.app.communication import get_communication_client
from unilabos.registry.registry import build_registry
from unilabos.app.backend import start_backend
from unilabos.app.web import http_client
@@ -220,7 +263,7 @@ def main():
print_unilab_banner(args_dict)
# 注册表
build_registry(args_dict["registry_path"])
lab_registry = build_registry(args_dict["registry_path"], False, args_dict["upload_registry"])
if args_dict["graph"] is None:
request_startup_json = http_client.request_startup_json()
if not request_startup_json:
@@ -241,6 +284,27 @@ def main():
graph_res.physical_setup_graph = graph
resource_edge_info = modify_to_backend_format(data["links"])
materials = lab_registry.obtain_registry_resource_info()
materials.extend(lab_registry.obtain_registry_device_info())
materials = {k["id"]: k for k in materials}
nodes = {k["id"]: k for k in data["nodes"]}
edge_info = len(resource_edge_info)
for ind, i in enumerate(resource_edge_info[::-1]):
source_node = nodes[i["source"]]
target_node = nodes[i["target"]]
source_handle = i["sourceHandle"]
target_handle = i["targetHandle"]
source_handler_keys = [h["handler_key"] for h in materials[source_node["class"]]["handles"] if h["io_type"] == 'source']
target_handler_keys = [h["handler_key"] for h in materials[target_node["class"]]["handles"] if h["io_type"] == 'target']
if not source_handle in source_handler_keys:
print_status(f"节点 {source_node['id']} 的source端点 {source_handle} 不存在,请检查,支持的端点 {source_handler_keys}", "error")
resource_edge_info.pop(edge_info - ind - 1)
continue
if not target_handle in target_handler_keys:
print_status(f"节点 {target_node['id']} 的target端点 {target_handle} 不存在,请检查,支持的端点 {target_handler_keys}", "error")
resource_edge_info.pop(edge_info - ind - 1)
continue
devices_and_resources = dict_from_graph(graph_res.physical_setup_graph)
# args_dict["resources_config"] = initialize_resources(list(deepcopy(devices_and_resources).values()))
args_dict["resources_config"] = list(devices_and_resources.values())
@@ -258,19 +322,22 @@ def main():
args_dict["bridges"] = []
# 获取通信客户端根据配置选择MQTT或WebSocket
comm_client = get_communication_client()
if "mqtt" in args_dict["app_bridges"]:
args_dict["bridges"].append(mqtt_client)
args_dict["bridges"].append(comm_client)
if "fastapi" in args_dict["app_bridges"]:
args_dict["bridges"].append(http_client)
if "mqtt" in args_dict["app_bridges"]:
def _exit(signum, frame):
mqtt_client.stop()
comm_client.stop()
sys.exit(0)
signal.signal(signal.SIGINT, _exit)
signal.signal(signal.SIGTERM, _exit)
mqtt_client.start()
comm_client.start()
args_dict["resources_mesh_config"] = {}
args_dict["resources_edge_config"] = resource_edge_info
# web visiualize 2D

7
unilabos/app/model.py
View File

@@ -50,11 +50,16 @@ class Resp(BaseModel):
class JobAddReq(BaseModel):
device_id: str = Field(examples=["Gripper"], description="device id")
data: dict = Field(examples=[{"position": 30, "torque": 5, "action": "push_to"}])
action: str = Field(examples=["_execute_driver_command_async"], description="action name", default="")
action_type: str = Field(examples=["unilabos_msgs.action._str_single_input.StrSingleInput"], description="action name", default="")
action_args: dict = Field(examples=[{'string': 'string'}], description="action name", default="")
task_id: str = Field(examples=["task_id"], description="task uuid")
job_id: str = Field(examples=["job_id"], description="goal uuid")
node_id: str = Field(examples=["node_id"], description="node uuid")
server_info: dict = Field(examples=[{"send_timestamp": 1717000000.0}], description="server info")
data: dict = Field(examples=[{"position": 30, "torque": 5, "action": "push_to"}], default={})
class JobStepFinishReq(BaseModel):
token: str = Field(examples=["030944"], description="token")

18
unilabos/app/mq.py
View File

@@ -15,17 +15,20 @@ import os
from unilabos.config.config import MQConfig
from unilabos.app.controler import job_add
from unilabos.app.model import JobAddReq
from unilabos.app.communication import BaseCommunicationClient
from unilabos.utils import logger
from unilabos.utils.type_check import TypeEncoder
from paho.mqtt.enums import CallbackAPIVersion
class MQTTClient:
class MQTTClient(BaseCommunicationClient):
mqtt_disable = True
def __init__(self):
super().__init__()
self.mqtt_disable = not MQConfig.lab_id
self.is_disabled = self.mqtt_disable # 更新父类属性
self.client_id = f"{MQConfig.group_id}@@@{MQConfig.lab_id}{uuid.uuid4()}"
logger.info("[MQTT] Client_id: " + self.client_id)
self.client = mqtt.Client(CallbackAPIVersion.VERSION2, client_id=self.client_id, protocol=mqtt.MQTTv5)
@@ -166,7 +169,7 @@ class MQTTClient:
status = {"data": device_status.get(device_id, {}), "device_id": device_id, "timestamp": time.time()}
address = f"labs/{MQConfig.lab_id}/devices/"
self.client.publish(address, json.dumps(status), qos=2)
logger.info(f"Device {device_id} status published: address: {address}, {status}")
# logger.info(f"Device {device_id} status published: address: {address}, {status}")
def publish_job_status(self, feedback_data: dict, job_id: str, status: str, return_info: Optional[str] = None):
if self.mqtt_disable:
@@ -208,11 +211,12 @@ class MQTTClient:
self.client.subscribe(pong_topic, 0)
logger.debug(f"Subscribed to pong topic: {pong_topic}")
def handle_pong(self, pong_data: dict):
"""处理pong响应这个方法会在收到pong消息时被调用"""
logger.debug(f"Pong received: {pong_data}")
# 这里会被HostNode的ping-pong处理逻辑调用
pass
@property
def is_connected(self) -> bool:
"""检查MQTT是否已连接"""
if self.is_disabled:
return False
return hasattr(self.client, "is_connected") and self.client.is_connected()
mqtt_client = MQTTClient()

101
unilabos/app/register.py
View File

@@ -1,44 +1,70 @@
import argparse
import json
import time
from unilabos.config.config import BasicConfig
from unilabos.registry.registry import build_registry
from unilabos.app.main import load_config_from_file
from unilabos.utils.log import logger
from unilabos.utils.type_check import TypeEncoder
def register_devices_and_resources(mqtt_client, lab_registry):
def register_devices_and_resources(comm_client, lab_registry):
"""
注册设备和资源到 MQTT
注册设备和资源到通信服务器MQTT/WebSocket
"""
logger.info("[UniLab Register] 开始注册设备和资源...")
# 注册设备信息
for device_info in lab_registry.obtain_registry_device_info():
mqtt_client.publish_registry(device_info["id"], device_info, False)
logger.debug(f"[UniLab Register] 注册设备: {device_info['id']}")
# # 注册资源信息
# for resource_info in lab_registry.obtain_registry_resource_info():
# mqtt_client.publish_registry(resource_info["id"], resource_info, False)
# logger.debug(f"[UniLab Register] 注册资源: {resource_info['id']}")
# 注册资源信息 - 使用HTTP方式
from unilabos.app.web.client import http_client
resources_to_register = {}
for resource_info in lab_registry.obtain_registry_resource_info():
resources_to_register[resource_info["id"]] = resource_info
logger.debug(f"[UniLab Register] 准备注册资源: {resource_info['id']}")
logger.info("[UniLab Register] 开始注册设备和资源...")
if BasicConfig.auth_secret():
# 注册设备信息
devices_to_register = {}
for device_info in lab_registry.obtain_registry_device_info():
devices_to_register[device_info["id"]] = json.loads(
json.dumps(device_info, ensure_ascii=False, cls=TypeEncoder)
)
logger.debug(f"[UniLab Register] 收集设备: {device_info['id']}")
resources_to_register = {}
for resource_info in lab_registry.obtain_registry_resource_info():
resources_to_register[resource_info["id"]] = resource_info
logger.debug(f"[UniLab Register] 收集资源: {resource_info['id']}")
print(
"[UniLab Register] 设备注册",
http_client.resource_registry({"resources": list(devices_to_register.values())}).text,
)
print(
"[UniLab Register] 资源注册",
http_client.resource_registry({"resources": list(resources_to_register.values())}).text,
)
else:
# 注册设备信息
for device_info in lab_registry.obtain_registry_device_info():
comm_client.publish_registry(device_info["id"], device_info, False)
logger.debug(f"[UniLab Register] 注册设备: {device_info['id']}")
if resources_to_register:
start_time = time.time()
response = http_client.resource_registry(resources_to_register)
cost_time = time.time() - start_time
if response.status_code in [200, 201]:
logger.info(f"[UniLab Register] 成功通过HTTP注册 {len(resources_to_register)} 个资源 {cost_time}ms")
else:
logger.error(f"[UniLab Register] HTTP注册资源失败: {response.status_code}, {response.text} {cost_time}ms")
# # 注册资源信息
# for resource_info in lab_registry.obtain_registry_resource_info():
# comm_client.publish_registry(resource_info["id"], resource_info, False)
# logger.debug(f"[UniLab Register] 注册资源: {resource_info['id']}")
resources_to_register = {}
for resource_info in lab_registry.obtain_registry_resource_info():
resources_to_register[resource_info["id"]] = resource_info
logger.debug(f"[UniLab Register] 准备注册资源: {resource_info['id']}")
if resources_to_register:
start_time = time.time()
response = http_client.resource_registry(resources_to_register)
cost_time = time.time() - start_time
if response.status_code in [200, 201]:
logger.info(f"[UniLab Register] 成功通过HTTP注册 {len(resources_to_register)} 个资源 {cost_time}ms")
else:
logger.error(
f"[UniLab Register] HTTP注册资源失败: {response.status_code}, {response.text} {cost_time}ms"
)
logger.info("[UniLab Register] 设备和资源注册完成.")
@@ -60,6 +86,18 @@ def main():
default=None,
help="配置文件路径,支持.py格式的Python配置文件",
)
parser.add_argument(
"--ak",
type=str,
default="",
help="实验室请求的ak",
)
parser.add_argument(
"--sk",
type=str,
default="",
help="实验室请求的sk",
)
parser.add_argument(
"--complete_registry",
action="store_true",
@@ -68,17 +106,20 @@ def main():
)
args = parser.parse_args()
load_config_from_file(args.config)
BasicConfig.ak = args.ak
BasicConfig.sk = args.sk
# 构建注册表
build_registry(args.registry, args.complete_registry)
from unilabos.app.mq import mqtt_client
build_registry(args.registry, args.complete_registry, True)
from unilabos.app.communication import get_communication_client
# 连接mqtt
mqtt_client.start()
# 获取通信客户端并启动连接
comm_client = get_communication_client()
comm_client.start()
from unilabos.registry.registry import lab_registry
# 注册设备和资源
register_devices_and_resources(mqtt_client, lab_registry)
register_devices_and_resources(comm_client, lab_registry)
if __name__ == "__main__":

1221
unilabos/app/web/api.py
View File

File diff suppressed because it is too large Load Diff

52
unilabos/app/web/client.py
View File

@@ -15,6 +15,7 @@ from unilabos.utils import logger
class HTTPClient:
"""HTTP客户端用于与远程服务器通信"""
backend_go = False # 是否使用Go后端
def __init__(self, remote_addr: Optional[str] = None, auth: Optional[str] = None) -> None:
"""
@@ -28,7 +29,13 @@ class HTTPClient:
if auth is not None:
self.auth = auth
else:
self.auth = MQConfig.lab_id
auth_secret = BasicConfig.auth_secret()
if auth_secret:
self.auth = auth_secret
self.backend_go = True
info(f"正在使用ak sk作为授权信息 {auth_secret}")
else:
self.auth = MQConfig.lab_id
info(f"HTTPClient 初始化完成: remote_addr={self.remote_addr}")
def resource_edge_add(self, resources: List[Dict[str, Any]], database_process_later: bool) -> requests.Response:
@@ -43,11 +50,18 @@ class HTTPClient:
"""
database_param = 1 if database_process_later else 0
response = requests.post(
f"{self.remote_addr}/lab/resource/edge/batch_create/?database_process_later={database_param}",
json=resources,
headers={"Authorization": f"lab {self.auth}"},
f"{self.remote_addr}/lab/resource/edge/batch_create/?database_process_later={database_param}"
if not self.backend_go else f"{self.remote_addr}/lab/material/edge",
json={
"edges": resources,
} if self.backend_go else resources,
headers={"Authorization": f"{'lab' if not self.backend_go else 'Lab'} {self.auth}"},
timeout=100,
)
if self.backend_go and response.status_code == 200:
res = response.json()
if "code" in res and res["code"] != 0:
logger.error(f"添加物料关系失败: {response.text}")
if response.status_code != 200 and response.status_code != 201:
logger.error(f"添加物料关系失败: {response.status_code}, {response.text}")
return response
@@ -63,11 +77,15 @@ class HTTPClient:
Response: API响应对象
"""
response = requests.post(
f"{self.remote_addr}/lab/resource/?database_process_later={1 if database_process_later else 0}",
json=resources,
headers={"Authorization": f"lab {self.auth}"},
f"{self.remote_addr}/lab/resource/?database_process_later={1 if database_process_later else 0}" if not self.backend_go else f"{self.remote_addr}/lab/material",
json=resources if not self.backend_go else {"nodes": resources},
headers={"Authorization": f"{'lab' if not self.backend_go else 'Lab'} {self.auth}"},
timeout=100,
)
if self.backend_go and response.status_code == 200:
res = response.json()
if "code" in res and res["code"] != 0:
logger.error(f"添加物料失败: {response.text}")
if response.status_code != 200:
logger.error(f"添加物料失败: {response.text}")
return response
@@ -84,9 +102,9 @@ class HTTPClient:
Dict: 返回的资源数据
"""
response = requests.get(
f"{self.remote_addr}/lab/resource/?edge_format=1",
f"{self.remote_addr}/lab/resource/?edge_format=1" if not self.backend_go else f"{self.remote_addr}/lab/material",
params={"id": id, "with_children": with_children},
headers={"Authorization": f"lab {self.auth}"},
headers={"Authorization": f"{'lab' if not self.backend_go else 'Lab'} {self.auth}"},
timeout=20,
)
return response.json()
@@ -104,7 +122,7 @@ class HTTPClient:
response = requests.delete(
f"{self.remote_addr}/lab/resource/batch_delete/",
params={"id": id},
headers={"Authorization": f"lab {self.auth}"},
headers={"Authorization": f"{'lab' if not self.backend_go else 'Lab'} {self.auth}"},
timeout=20,
)
return response
@@ -122,7 +140,7 @@ class HTTPClient:
response = requests.patch(
f"{self.remote_addr}/lab/resource/batch_update/?edge_format=1",
json=resources,
headers={"Authorization": f"lab {self.auth}"},
headers={"Authorization": f"{'lab' if not self.backend_go else 'Lab'} {self.auth}"},
timeout=100,
)
return response
@@ -146,25 +164,25 @@ class HTTPClient:
response = requests.post(
f"{self.remote_addr}/api/account/file_upload/{scene}",
files=files,
headers={"Authorization": f"lab {self.auth}"},
headers={"Authorization": f"{'lab' if not self.backend_go else 'Lab'} {self.auth}"},
timeout=30, # 上传文件可能需要更长的超时时间
)
return response
def resource_registry(self, registry_data: Dict[str, Any]) -> requests.Response:
def resource_registry(self, registry_data: Dict[str, Any] | List[Dict[str, Any]]) -> requests.Response:
"""
注册资源到服务器
Args:
registry_data: 注册表数据,格式为 {resource_id: resource_info}
registry_data: 注册表数据,格式为 {resource_id: resource_info} / [{resource_info}]
Returns:
Response: API响应对象
"""
response = requests.post(
f"{self.remote_addr}/lab/registry/",
f"{self.remote_addr}/lab/registry/" if not self.backend_go else f"{self.remote_addr}/lab/resource",
json=registry_data,
headers={"Authorization": f"lab {self.auth}"},
headers={"Authorization": f"{'lab' if not self.backend_go else 'Lab'} {self.auth}"},
timeout=30,
)
if response.status_code not in [200, 201]:
@@ -183,7 +201,7 @@ class HTTPClient:
"""
response = requests.get(
f"{self.remote_addr}/lab/resource/graph_info/",
headers={"Authorization": f"lab {self.auth}"},
headers={"Authorization": f"{'lab' if not self.backend_go else 'Lab'} {self.auth}"},
timeout=(3, 30),
)
if response.status_code != 200:

33
unilabos/app/web/pages.py
View File

@@ -78,21 +78,23 @@ def setup_web_pages(router: APIRouter) -> None:
HTMLResponse: 渲染后的HTML页面
"""
try:
# 准备设备数据
# 准备初始数据结构这些数据将通过WebSocket实时更新
devices = []
resources = []
modules = {"names": [], "classes": [], "displayed_count": 0, "total_count": 0}
# 获取在线设备信息
# 获取在线设备信息(用于初始渲染)
ros_node_info = get_ros_node_info()
# 获取主机节点信息
# 获取主机节点信息(用于初始渲染)
host_node_info = get_host_node_info()
# 获取Registry路径信息
# 获取Registry路径信息(静态信息,不需要实时更新)
registry_info = get_registry_info()
# 获取已加载的设备
# 获取初始数据用于页面渲染后续将被WebSocket数据覆盖
if lab_registry:
devices = json.loads(json.dumps(lab_registry.obtain_registry_device_info(), ensure_ascii=False, cls=TypeEncoder))
devices = json.loads(
json.dumps(lab_registry.obtain_registry_device_info(), ensure_ascii=False, cls=TypeEncoder)
)
# 资源类型
for resource_id, resource_info in lab_registry.resource_type_registry.items():
resources.append(
@@ -103,7 +105,7 @@ def setup_web_pages(router: APIRouter) -> None:
}
)
# 获取导入的模块
# 获取导入的模块(初始数据)
if msg_converter_manager:
modules["names"] = msg_converter_manager.list_modules()
all_classes = [i for i in msg_converter_manager.list_classes() if "." in i]
@@ -171,3 +173,20 @@ def setup_web_pages(router: APIRouter) -> None:
except Exception as e:
error(f"打开文件夹时出错: {str(e)}")
return {"status": "error", "message": f"Failed to open folder: {str(e)}"}
@router.get("/registry-editor", response_class=HTMLResponse, summary="Registry Editor")
async def registry_editor_page() -> str:
"""
注册表编辑页面用于导入Python文件并生成注册表
Returns:
HTMLResponse: 渲染后的HTML页面
"""
try:
# 使用模板渲染页面
template = env.get_template("registry_editor.html")
html = template.render()
return html
except Exception as e:
error(f"生成注册表编辑页面时出错: {str(e)}")
raise HTTPException(status_code=500, detail=f"Error generating registry editor page: {str(e)}")

1
unilabos/app/web/templates/base.html
View File

@@ -162,7 +162,6 @@
<body>
<h1>{% block header %}UniLab{% endblock %}</h1>
{% block nav %}
<a href="/unilabos/webtic" class="home-link">Home</a>
{% endblock %}
{% block top_info %}{% endblock %}

45
unilabos/app/web/templates/home.html
View File

@@ -1,22 +1,25 @@
{% extends "base.html" %}
{% block title %}UniLab API{% endblock %}
{% block header %}UniLab API{% endblock %}
{% block nav %}
<a href="/status" class="status-link">System Status</a>
{% endblock %}
{% block content %}
<div class="card">
<h2>Available Endpoints</h2>
{% for route in routes %}
<div class="endpoint">
<span class="method">{{ route.method }}</span>
<a href="{{ route.path }}">{{ route.path }}</a>
<p>{{ route.summary }}</p>
</div>
{% endfor %}
{% extends "base.html" %} {% block title %}UniLab API{% endblock %} {% block
header %}UniLab API{% endblock %} {% block nav %}
<div class="nav-tabs">
<a
href="/"
class="nav-tab"
style="background-color: #2196f3; color: white"
target="_blank"
>主页</a
>
<a href="/status" class="nav-tab">状态</a>
<a href="/registry-editor" class="nav-tab" target="_blank">注册表编辑</a>
</div>
{% endblock %}
{% endblock %} {% block content %}
<div class="card">
<h2>Available Endpoints</h2>
{% for route in routes %}
<div class="endpoint">
<span class="method">{{ route.method }}</span>
<a href="{{ route.path }}">{{ route.path }}</a>
<p>{{ route.summary }}</p>
</div>
{% endfor %}
</div>
{% endblock %}

1411
unilabos/app/web/templates/registry_editor.html Normal file
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3453
unilabos/app/web/templates/status.html
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1023
unilabos/app/ws_client.py Normal file
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3
unilabos/compile/__init__.py
View File

@@ -15,7 +15,6 @@ from .heatchill_protocol import (
generate_heat_chill_to_temp_protocol # 保留导入,但不注册为协议
)
from .stir_protocol import generate_stir_protocol, generate_start_stir_protocol, generate_stop_stir_protocol
from .transfer_protocol import generate_transfer_protocol
from .clean_vessel_protocol import generate_clean_vessel_protocol
from .dissolve_protocol import generate_dissolve_protocol
from .filter_through_protocol import generate_filter_through_protocol
@@ -47,6 +46,7 @@ action_protocol_generators = {
HeatChillStopProtocol: generate_heat_chill_stop_protocol,
HydrogenateProtocol: generate_hydrogenate_protocol,
PumpTransferProtocol: generate_pump_protocol_with_rinsing,
TransferProtocol: generate_pump_protocol,
RecrystallizeProtocol: generate_recrystallize_protocol,
ResetHandlingProtocol: generate_reset_handling_protocol,
RunColumnProtocol: generate_run_column_protocol,
@@ -54,6 +54,5 @@ action_protocol_generators = {
StartStirProtocol: generate_start_stir_protocol,
StirProtocol: generate_stir_protocol,
StopStirProtocol: generate_stop_stir_protocol,
TransferProtocol: generate_transfer_protocol,
WashSolidProtocol: generate_wash_solid_protocol,
}

321
unilabos/compile/add_protocol.py
View File

@@ -1,313 +1,24 @@
from functools import partial
import networkx as nx
import re
import logging
from typing import List, Dict, Any, Union
from .utils.unit_parser import parse_volume_input, parse_mass_input, parse_time_input
from .utils.vessel_parser import get_vessel, find_solid_dispenser, find_connected_stirrer, find_reagent_vessel
from .utils.logger_util import action_log
from .pump_protocol import generate_pump_protocol_with_rinsing
logger = logging.getLogger(__name__)
def debug_print(message):
"""调试输出"""
print(f"[ADD] {message}", flush=True)
logger.info(f"[ADD] {message}")
def parse_volume_input(volume_input: Union[str, float]) -> float:
"""
解析体积输入,支持带单位的字符串
Args:
volume_input: 体积输入(如 "2.7 mL", "2.67 mL", "?", 10.0
Returns:
float: 体积(毫升)
"""
if isinstance(volume_input, (int, float)):
debug_print(f"📏 体积输入为数值: {volume_input}")
return float(volume_input)
if not volume_input or not str(volume_input).strip():
debug_print(f"⚠️ 体积输入为空返回0.0mL")
return 0.0
volume_str = str(volume_input).lower().strip()
debug_print(f"🔍 解析体积输入: '{volume_str}'")
# 处理未知体积
if volume_str in ['?', 'unknown', 'tbd', 'to be determined']:
default_volume = 10.0 # 默认10mL
debug_print(f"❓ 检测到未知体积,使用默认值: {default_volume}mL 🎯")
return default_volume
# 移除空格并提取数字和单位
volume_clean = re.sub(r'\s+', '', volume_str)
# 匹配数字和单位的正则表达式
match = re.match(r'([0-9]*\.?[0-9]+)\s*(ml|l|μl|ul|microliter|milliliter|liter)?', volume_clean)
if not match:
debug_print(f"❌ 无法解析体积: '{volume_str}'使用默认值10mL")
return 10.0
value = float(match.group(1))
unit = match.group(2) or 'ml' # 默认单位为毫升
# 转换为毫升
if unit in ['l', 'liter']:
volume = value * 1000.0 # L -> mL
debug_print(f"🔄 体积转换: {value}L → {volume}mL")
elif unit in ['μl', 'ul', 'microliter']:
volume = value / 1000.0 # μL -> mL
debug_print(f"🔄 体积转换: {value}μL → {volume}mL")
else: # ml, milliliter 或默认
volume = value # 已经是mL
debug_print(f"✅ 体积已为mL: {volume}mL")
return volume
def parse_mass_input(mass_input: Union[str, float]) -> float:
"""
解析质量输入,支持带单位的字符串
Args:
mass_input: 质量输入(如 "19.3 g", "4.5 g", 2.5
Returns:
float: 质量(克)
"""
if isinstance(mass_input, (int, float)):
debug_print(f"⚖️ 质量输入为数值: {mass_input}g")
return float(mass_input)
if not mass_input or not str(mass_input).strip():
debug_print(f"⚠️ 质量输入为空返回0.0g")
return 0.0
mass_str = str(mass_input).lower().strip()
debug_print(f"🔍 解析质量输入: '{mass_str}'")
# 移除空格并提取数字和单位
mass_clean = re.sub(r'\s+', '', mass_str)
# 匹配数字和单位的正则表达式
match = re.match(r'([0-9]*\.?[0-9]+)\s*(g|mg|kg|gram|milligram|kilogram)?', mass_clean)
if not match:
debug_print(f"❌ 无法解析质量: '{mass_str}'返回0.0g")
return 0.0
value = float(match.group(1))
unit = match.group(2) or 'g' # 默认单位为克
# 转换为克
if unit in ['mg', 'milligram']:
mass = value / 1000.0 # mg -> g
debug_print(f"🔄 质量转换: {value}mg → {mass}g")
elif unit in ['kg', 'kilogram']:
mass = value * 1000.0 # kg -> g
debug_print(f"🔄 质量转换: {value}kg → {mass}g")
else: # g, gram 或默认
mass = value # 已经是g
debug_print(f"✅ 质量已为g: {mass}g")
return mass
def parse_time_input(time_input: Union[str, float]) -> float:
"""
解析时间输入,支持带单位的字符串
Args:
time_input: 时间输入(如 "1 h", "20 min", "30 s", 60.0
Returns:
float: 时间(秒)
"""
if isinstance(time_input, (int, float)):
debug_print(f"⏱️ 时间输入为数值: {time_input}")
return float(time_input)
if not time_input or not str(time_input).strip():
debug_print(f"⚠️ 时间输入为空返回0秒")
return 0.0
time_str = str(time_input).lower().strip()
debug_print(f"🔍 解析时间输入: '{time_str}'")
# 处理未知时间
if time_str in ['?', 'unknown', 'tbd']:
default_time = 60.0 # 默认1分钟
debug_print(f"❓ 检测到未知时间,使用默认值: {default_time}s (1分钟) ⏰")
return default_time
# 移除空格并提取数字和单位
time_clean = re.sub(r'\s+', '', time_str)
# 匹配数字和单位的正则表达式
match = re.match(r'([0-9]*\.?[0-9]+)\s*(s|sec|second|min|minute|h|hr|hour|d|day)?', time_clean)
if not match:
debug_print(f"❌ 无法解析时间: '{time_str}'返回0s")
return 0.0
value = float(match.group(1))
unit = match.group(2) or 's' # 默认单位为秒
# 转换为秒
if unit in ['min', 'minute']:
time_sec = value * 60.0 # min -> s
debug_print(f"🔄 时间转换: {value}分钟 → {time_sec}")
elif unit in ['h', 'hr', 'hour']:
time_sec = value * 3600.0 # h -> s
debug_print(f"🔄 时间转换: {value}小时 → {time_sec}")
elif unit in ['d', 'day']:
time_sec = value * 86400.0 # d -> s
debug_print(f"🔄 时间转换: {value}天 → {time_sec}")
else: # s, sec, second 或默认
time_sec = value # 已经是s
debug_print(f"✅ 时间已为秒: {time_sec}")
return time_sec
def find_reagent_vessel(G: nx.DiGraph, reagent: str) -> str:
"""增强版试剂容器查找,支持固体和液体"""
debug_print(f"🔍 开始查找试剂 '{reagent}' 的容器...")
# 🔧 方法1直接搜索 data.reagent_name 和 config.reagent
debug_print(f"📋 方法1: 搜索reagent字段...")
for node in G.nodes():
node_data = G.nodes[node].get('data', {})
node_type = G.nodes[node].get('type', '')
config_data = G.nodes[node].get('config', {})
# 只搜索容器类型的节点
if node_type == 'container':
reagent_name = node_data.get('reagent_name', '').lower()
config_reagent = config_data.get('reagent', '').lower()
# 精确匹配
if reagent_name == reagent.lower() or config_reagent == reagent.lower():
debug_print(f"✅ 通过reagent字段精确匹配到容器: {node} 🎯")
return node
# 模糊匹配
if (reagent.lower() in reagent_name and reagent_name) or \
(reagent.lower() in config_reagent and config_reagent):
debug_print(f"✅ 通过reagent字段模糊匹配到容器: {node} 🔍")
return node
# 🔧 方法2常见的容器命名规则
debug_print(f"📋 方法2: 使用命名规则查找...")
reagent_clean = reagent.lower().replace(' ', '_').replace('-', '_')
possible_names = [
reagent_clean,
f"flask_{reagent_clean}",
f"bottle_{reagent_clean}",
f"vessel_{reagent_clean}",
f"{reagent_clean}_flask",
f"{reagent_clean}_bottle",
f"reagent_{reagent_clean}",
f"reagent_bottle_{reagent_clean}",
f"solid_reagent_bottle_{reagent_clean}",
f"reagent_bottle_1", # 通用试剂瓶
f"reagent_bottle_2",
f"reagent_bottle_3"
]
debug_print(f"🔍 尝试的容器名称: {possible_names[:5]}... (共{len(possible_names)}个)")
for name in possible_names:
if name in G.nodes():
node_type = G.nodes[name].get('type', '')
if node_type == 'container':
debug_print(f"✅ 通过命名规则找到容器: {name} 📝")
return name
# 🔧 方法3节点名称模糊匹配
debug_print(f"📋 方法3: 节点名称模糊匹配...")
for node_id in G.nodes():
node_data = G.nodes[node_id]
if node_data.get('type') == 'container':
# 检查节点名称是否包含试剂名称
if reagent_clean in node_id.lower():
debug_print(f"✅ 通过节点名称模糊匹配到容器: {node_id} 🔍")
return node_id
# 检查液体类型匹配
vessel_data = node_data.get('data', {})
liquids = vessel_data.get('liquid', [])
for liquid in liquids:
if isinstance(liquid, dict):
liquid_type = liquid.get('liquid_type') or liquid.get('name', '')
if liquid_type.lower() == reagent.lower():
debug_print(f"✅ 通过液体类型匹配到容器: {node_id} 💧")
return node_id
# 🔧 方法4使用第一个试剂瓶作为备选
debug_print(f"📋 方法4: 查找备选试剂瓶...")
for node_id in G.nodes():
node_data = G.nodes[node_id]
if (node_data.get('type') == 'container' and
('reagent' in node_id.lower() or 'bottle' in node_id.lower())):
debug_print(f"⚠️ 未找到专用容器,使用备选试剂瓶: {node_id} 🔄")
return node_id
debug_print(f"❌ 所有方法都失败了,无法找到容器!")
raise ValueError(f"找不到试剂 '{reagent}' 对应的容器")
def find_connected_stirrer(G: nx.DiGraph, vessel: str) -> str:
"""查找连接到指定容器的搅拌器"""
debug_print(f"🔍 查找连接到容器 '{vessel}' 的搅拌器...")
stirrer_nodes = []
for node in G.nodes():
node_class = G.nodes[node].get('class', '').lower()
if 'stirrer' in node_class:
stirrer_nodes.append(node)
debug_print(f"📋 发现搅拌器: {node}")
debug_print(f"📊 共找到 {len(stirrer_nodes)} 个搅拌器")
# 查找连接到容器的搅拌器
for stirrer in stirrer_nodes:
if G.has_edge(stirrer, vessel) or G.has_edge(vessel, stirrer):
debug_print(f"✅ 找到连接的搅拌器: {stirrer} 🔗")
return stirrer
# 返回第一个搅拌器
if stirrer_nodes:
debug_print(f"⚠️ 未找到直接连接的搅拌器,使用第一个: {stirrer_nodes[0]} 🔄")
return stirrer_nodes[0]
debug_print(f"❌ 未找到任何搅拌器")
return ""
def find_solid_dispenser(G: nx.DiGraph) -> str:
"""查找固体加样器"""
debug_print(f"🔍 查找固体加样器...")
for node in G.nodes():
node_class = G.nodes[node].get('class', '').lower()
if 'solid_dispenser' in node_class or 'dispenser' in node_class:
debug_print(f"✅ 找到固体加样器: {node} 🥄")
return node
debug_print(f"❌ 未找到固体加样器")
return ""
# 🆕 创建进度日志动作
def create_action_log(message: str, emoji: str = "📝") -> Dict[str, Any]:
"""创建一个动作日志"""
full_message = f"{emoji} {message}"
debug_print(full_message)
logger.info(full_message)
print(f"[ACTION] {full_message}", flush=True)
return {
"action_name": "wait",
"action_kwargs": {
"time": 0.1,
"log_message": full_message
}
}
create_action_log = partial(action_log, prefix="[ADD]")
def generate_add_protocol(
G: nx.DiGraph,
@@ -346,16 +57,7 @@ def generate_add_protocol(
"""
# 🔧 核心修改从字典中提取容器ID
# 统一处理vessel参数
if isinstance(vessel, dict):
if "id" not in vessel:
vessel_id = list(vessel.values())[0].get("id", "")
else:
vessel_id = vessel.get("id", "")
vessel_data = vessel.get("data", {})
else:
vessel_id = str(vessel)
vessel_data = G.nodes[vessel_id].get("data", {}) if vessel_id in G.nodes() else {}
vessel_id, vessel_data = get_vessel(vessel)
# 🔧 修改:更新容器的液体体积(假设有 liquid_volume 字段)
if "data" in vessel and "liquid_volume" in vessel["data"]:
@@ -406,12 +108,7 @@ def generate_add_protocol(
final_time = parse_time_input(time)
debug_print(f"📊 解析结果:")
debug_print(f" 📏 体积: {final_volume}mL")
debug_print(f" ⚖️ 质量: {final_mass}g")
debug_print(f" ⏱️ 时间: {final_time}s")
debug_print(f" 🧬 摩尔: '{mol}'")
debug_print(f" 🎯 事件: '{event}'")
debug_print(f" ⚡ 速率: '{rate_spec}'")
debug_print(f" 体积: {final_volume}mL, 质量: {final_mass}g, 时间: {final_time}s, 摩尔: '{mol}', 事件: '{event}', 速率: '{rate_spec}'")
# === 判断添加类型 ===
debug_print("🔍 步骤3: 判断添加类型...")

29
unilabos/compile/adjustph_protocol.py
View File

@@ -1,31 +1,15 @@
import networkx as nx
import logging
from typing import List, Dict, Any, Union
from .utils.vessel_parser import get_vessel
from .pump_protocol import generate_pump_protocol_with_rinsing
logger = logging.getLogger(__name__)
def debug_print(message):
"""调试输出"""
print(f"[ADJUST_PH] {message}", flush=True)
logger.info(f"[ADJUST_PH] {message}")
# 🆕 创建进度日志动作
def create_action_log(message: str, emoji: str = "📝") -> Dict[str, Any]:
"""创建一个动作日志"""
full_message = f"{emoji} {message}"
debug_print(full_message)
logger.info(full_message)
print(f"[ACTION] {full_message}", flush=True)
return {
"action_name": "wait",
"action_kwargs": {
"time": 0.1,
"log_message": full_message
}
}
def find_acid_base_vessel(G: nx.DiGraph, reagent: str) -> str:
"""
查找酸碱试剂容器,支持多种匹配模式
@@ -235,16 +219,7 @@ def generate_adjust_ph_protocol(
List[Dict[str, Any]]: 动作序列
"""
# 统一处理vessel参数
if isinstance(vessel, dict):
if "id" not in vessel:
vessel_id = list(vessel.values())[0].get("id", "")
else:
vessel_id = vessel.get("id", "")
vessel_data = vessel.get("data", {})
else:
vessel_id = str(vessel)
vessel_data = G.nodes[vessel_id].get("data", {}) if vessel_id in G.nodes() else {}
vessel_id, vessel_data = get_vessel(vessel)
if not vessel_id:
debug_print(f"❌ vessel 参数无效必须包含id字段或直接提供容器ID. vessel: {vessel}")

105
unilabos/compile/clean_vessel_protocol.py
View File

@@ -1,101 +1,9 @@
from typing import List, Dict, Any
import networkx as nx
from .utils.vessel_parser import get_vessel, find_solvent_vessel
from .pump_protocol import generate_pump_protocol
def find_solvent_vessel(G: nx.DiGraph, solvent: str) -> str:
"""
查找溶剂容器,支持多种匹配模式:
1. 容器名称匹配(如 flask_water, reagent_bottle_1-DMF
2. 容器内液体类型匹配(如 liquid_type: "DMF", "ethanol"
"""
print(f"CLEAN_VESSEL: 正在查找溶剂 '{solvent}' 的容器...")
# 第一步:通过容器名称匹配
possible_names = [
f"flask_{solvent}", # flask_water, flask_ethanol
f"bottle_{solvent}", # bottle_water, bottle_ethanol
f"vessel_{solvent}", # vessel_water, vessel_ethanol
f"{solvent}_flask", # water_flask, ethanol_flask
f"{solvent}_bottle", # water_bottle, ethanol_bottle
f"{solvent}", # 直接用溶剂名
f"solvent_{solvent}", # solvent_water, solvent_ethanol
f"reagent_bottle_{solvent}", # reagent_bottle_DMF
]
# 尝试名称匹配
for vessel_name in possible_names:
if vessel_name in G.nodes():
print(f"CLEAN_VESSEL: 通过名称匹配找到容器: {vessel_name}")
return vessel_name
# 第二步:通过模糊名称匹配(名称中包含溶剂名)
for node_id in G.nodes():
if G.nodes[node_id].get('type') == 'container':
# 检查节点ID或名称中是否包含溶剂名
node_name = G.nodes[node_id].get('name', '').lower()
if (solvent.lower() in node_id.lower() or
solvent.lower() in node_name):
print(f"CLEAN_VESSEL: 通过模糊名称匹配找到容器: {node_id} (名称: {node_name})")
return node_id
# 第三步:通过液体类型匹配
for node_id in G.nodes():
if G.nodes[node_id].get('type') == 'container':
vessel_data = G.nodes[node_id].get('data', {})
liquids = vessel_data.get('liquid', [])
for liquid in liquids:
if isinstance(liquid, dict):
# 支持两种格式的液体类型字段
liquid_type = liquid.get('liquid_type') or liquid.get('name', '')
reagent_name = vessel_data.get('reagent_name', '')
config_reagent = G.nodes[node_id].get('config', {}).get('reagent', '')
# 检查多个可能的字段
if (liquid_type.lower() == solvent.lower() or
reagent_name.lower() == solvent.lower() or
config_reagent.lower() == solvent.lower()):
print(f"CLEAN_VESSEL: 通过液体类型匹配找到容器: {node_id}")
print(f" - liquid_type: {liquid_type}")
print(f" - reagent_name: {reagent_name}")
print(f" - config.reagent: {config_reagent}")
return node_id
# 第四步:列出所有可用的容器信息帮助调试
available_containers = []
for node_id in G.nodes():
if G.nodes[node_id].get('type') == 'container':
vessel_data = G.nodes[node_id].get('data', {})
config_data = G.nodes[node_id].get('config', {})
liquids = vessel_data.get('liquid', [])
container_info = {
'id': node_id,
'name': G.nodes[node_id].get('name', ''),
'liquid_types': [],
'reagent_name': vessel_data.get('reagent_name', ''),
'config_reagent': config_data.get('reagent', '')
}
for liquid in liquids:
if isinstance(liquid, dict):
liquid_type = liquid.get('liquid_type') or liquid.get('name', '')
if liquid_type:
container_info['liquid_types'].append(liquid_type)
available_containers.append(container_info)
print(f"CLEAN_VESSEL: 可用容器列表:")
for container in available_containers:
print(f" - {container['id']}: {container['name']}")
print(f" 液体类型: {container['liquid_types']}")
print(f" 试剂名称: {container['reagent_name']}")
print(f" 配置试剂: {container['config_reagent']}")
raise ValueError(f"未找到溶剂 '{solvent}' 的容器。尝试了名称匹配: {possible_names}")
def find_solvent_vessel_by_any_match(G: nx.DiGraph, solvent: str) -> str:
"""
增强版溶剂容器查找,支持各种匹配方式的别名函数
@@ -181,16 +89,7 @@ def generate_clean_vessel_protocol(
clean_protocol = generate_clean_vessel_protocol(G, {"id": "main_reactor"}, "water", 100.0, 60.0, 2)
"""
# 🔧 核心修改从字典中提取容器ID
# 统一处理vessel参数
if isinstance(vessel, dict):
if "id" not in vessel:
vessel_id = list(vessel.values())[0].get("id", "")
else:
vessel_id = vessel.get("id", "")
vessel_data = vessel.get("data", {})
else:
vessel_id = str(vessel)
vessel_data = G.nodes[vessel_id].get("data", {}) if vessel_id in G.nodes() else {}
vessel_id, vessel_data = get_vessel(vessel)
action_sequence = []

23
unilabos/compile/dissolve_protocol.py
View File

@@ -1,31 +1,22 @@
from functools import partial
import networkx as nx
import re
import logging
from typing import List, Dict, Any, Union
from .utils.vessel_parser import get_vessel
from .utils.logger_util import action_log
from .pump_protocol import generate_pump_protocol_with_rinsing
logger = logging.getLogger(__name__)
def debug_print(message):
"""调试输出"""
print(f"[DISSOLVE] {message}", flush=True)
logger.info(f"[DISSOLVE] {message}")
# 🆕 创建进度日志动作
def create_action_log(message: str, emoji: str = "📝") -> Dict[str, Any]:
"""创建一个动作日志"""
full_message = f"{emoji} {message}"
debug_print(full_message)
logger.info(full_message)
print(f"[ACTION] {full_message}", flush=True)
return {
"action_name": "wait",
"action_kwargs": {
"time": 0.1,
"log_message": full_message
}
}
create_action_log = partial(action_log, prefix="[DISSOLVE]")
def parse_volume_input(volume_input: Union[str, float]) -> float:
"""
@@ -446,7 +437,7 @@ def generate_dissolve_protocol(
"""
# 🔧 核心修改从字典中提取容器ID
vessel_id = vessel["id"]
vessel_id, vessel_data = get_vessel(vessel)
debug_print("=" * 60)
debug_print("🧪 开始生成溶解协议")

4
unilabos/compile/dry_protocol.py
View File

@@ -1,6 +1,8 @@
import networkx as nx
from typing import List, Dict, Any
from unilabos.compile.utils.vessel_parser import get_vessel
def find_connected_heater(G: nx.DiGraph, vessel: str) -> str:
"""
@@ -63,7 +65,7 @@ def generate_dry_protocol(
List[Dict[str, Any]]: 动作序列
"""
# 🔧 核心修改从字典中提取容器ID
vessel_id = vessel["id"]
vessel_id, vessel_data = get_vessel(vessel)
action_sequence = []

48
unilabos/compile/evacuateandrefill_protocol.py
View File

@@ -1,8 +1,12 @@
from functools import partial
import networkx as nx
import logging
import uuid
import sys
from typing import List, Dict, Any, Optional
from .utils.vessel_parser import get_vessel
from .utils.logger_util import action_log
from .pump_protocol import generate_pump_protocol_with_rinsing, generate_pump_protocol
# 设置日志
@@ -21,48 +25,17 @@ def debug_print(message):
try:
# 确保消息是字符串格式
safe_message = str(message)
print(f"[抽真空充气] {safe_message}", flush=True)
logger.info(f"[抽真空充气] {safe_message}")
except UnicodeEncodeError:
# 如果编码失败,尝试替换不支持的字符
safe_message = str(message).encode('utf-8', errors='replace').decode('utf-8')
print(f"[抽真空充气] {safe_message}", flush=True)
logger.info(f"[抽真空充气] {safe_message}")
except Exception as e:
# 最后的安全措施
fallback_message = f"日志输出错误: {repr(message)}"
print(f"[抽真空充气] {fallback_message}", flush=True)
logger.info(f"[抽真空充气] {fallback_message}")
def create_action_log(message: str, emoji: str = "📝") -> Dict[str, Any]:
"""创建一个动作日志 - 支持中文和emoji"""
try:
full_message = f"{emoji} {message}"
debug_print(full_message)
logger.info(full_message)
return {
"action_name": "wait",
"action_kwargs": {
"time": 0.1,
"log_message": full_message,
"progress_message": full_message
}
}
except Exception as e:
# 如果emoji有问题使用纯文本
safe_message = f"[日志] {message}"
debug_print(safe_message)
logger.info(safe_message)
return {
"action_name": "wait",
"action_kwargs": {
"time": 0.1,
"log_message": safe_message,
"progress_message": safe_message
}
}
create_action_log = partial(action_log, prefix="[抽真空充气]")
def find_gas_source(G: nx.DiGraph, gas: str) -> str:
"""
@@ -288,16 +261,7 @@ def generate_evacuateandrefill_protocol(
"""
# 🔧 核心修改从字典中提取容器ID
# 统一处理vessel参数
if isinstance(vessel, dict):
if "id" not in vessel:
vessel_id = list(vessel.values())[0].get("id", "")
else:
vessel_id = vessel.get("id", "")
vessel_data = vessel.get("data", {})
else:
vessel_id = str(vessel)
vessel_data = G.nodes[vessel_id].get("data", {}) if vessel_id in G.nodes() else {}
vessel_id, vessel_data = get_vessel(vessel)
# 硬编码重复次数为 3
repeats = 3

75
unilabos/compile/evaporate_protocol.py
View File

@@ -2,75 +2,15 @@ from typing import List, Dict, Any, Optional, Union
import networkx as nx
import logging
import re
from .utils.vessel_parser import get_vessel
from .utils.unit_parser import parse_time_input
logger = logging.getLogger(__name__)
def debug_print(message):
"""调试输出"""
print(f"🧪 [EVAPORATE] {message}", flush=True)
logger.info(f"[EVAPORATE] {message}")
def parse_time_input(time_input: Union[str, float]) -> float:
"""
解析时间输入,支持带单位的字符串
Args:
time_input: 时间输入(如 "3 min", "180", "0.5 h" 等)
Returns:
float: 时间(秒)
"""
if isinstance(time_input, (int, float)):
debug_print(f"⏱️ 时间输入为数字: {time_input}s ✨")
return float(time_input) # 🔧 确保返回float
if not time_input or not str(time_input).strip():
debug_print(f"⚠️ 时间输入为空,使用默认值: 180s (3分钟) 🕐")
return 180.0 # 默认3分钟
time_str = str(time_input).lower().strip()
debug_print(f"🔍 解析时间输入: '{time_str}' 📝")
# 处理未知时间
if time_str in ['?', 'unknown', 'tbd']:
default_time = 180.0 # 默认3分钟
debug_print(f"❓ 检测到未知时间,使用默认值: {default_time}s (3分钟) 🤷‍♀️")
return default_time
# 移除空格并提取数字和单位
time_clean = re.sub(r'\s+', '', time_str)
# 匹配数字和单位的正则表达式
match = re.match(r'([0-9]*\.?[0-9]+)\s*(s|sec|second|min|minute|h|hr|hour|d|day)?', time_clean)
if not match:
# 如果无法解析,尝试直接转换为数字(默认秒)
try:
value = float(time_str)
debug_print(f"✅ 时间解析成功: {time_str}{value}s无单位默认秒")
return float(value) # 🔧 确保返回float
except ValueError:
debug_print(f"❌ 无法解析时间: '{time_str}'使用默认值180s (3分钟) 😅")
return 180.0
value = float(match.group(1))
unit = match.group(2) or 's' # 默认单位为秒
# 转换为秒
if unit in ['min', 'minute']:
time_sec = value * 60.0 # min -> s
debug_print(f"🕐 时间转换: {value} 分钟 → {time_sec}s ⏰")
elif unit in ['h', 'hr', 'hour']:
time_sec = value * 3600.0 # h -> s
debug_print(f"🕐 时间转换: {value} 小时 → {time_sec}s ({time_sec/60:.1f}分钟) ⏰")
elif unit in ['d', 'day']:
time_sec = value * 86400.0 # d -> s
debug_print(f"🕐 时间转换: {value} 天 → {time_sec}s ({time_sec/3600:.1f}小时) ⏰")
else: # s, sec, second 或默认
time_sec = value # 已经是s
debug_print(f"🕐 时间转换: {value}s → {time_sec}s (已是秒) ⏰")
return float(time_sec) # 🔧 确保返回float
def find_rotavap_device(G: nx.DiGraph, vessel: str = None) -> Optional[str]:
"""
@@ -201,16 +141,7 @@ def generate_evaporate_protocol(
"""
# 🔧 核心修改从字典中提取容器ID
# 统一处理vessel参数
if isinstance(vessel, dict):
if "id" not in vessel:
vessel_id = list(vessel.values())[0].get("id", "")
else:
vessel_id = vessel.get("id", "")
vessel_data = vessel.get("data", {})
else:
vessel_id = str(vessel)
vessel_data = G.nodes[vessel_id].get("data", {}) if vessel_id in G.nodes() else {}
vessel_id, vessel_data = get_vessel(vessel)
debug_print("🌟" * 20)
debug_print("🌪️ 开始生成蒸发协议(支持单位和体积运算)✨")

49
unilabos/compile/filter_protocol.py
View File

@@ -1,13 +1,13 @@
from typing import List, Dict, Any, Optional
import networkx as nx
import logging
from .utils.vessel_parser import get_vessel
from .pump_protocol import generate_pump_protocol_with_rinsing
logger = logging.getLogger(__name__)
def debug_print(message):
"""调试输出"""
print(f"🧪 [FILTER] {message}", flush=True)
logger.info(f"[FILTER] {message}")
def find_filter_device(G: nx.DiGraph) -> str:
@@ -51,7 +51,7 @@ def validate_vessel(G: nx.DiGraph, vessel: str, vessel_type: str = "容器") ->
def generate_filter_protocol(
G: nx.DiGraph,
vessel: dict, # 🔧 修改:从字符串改为字典类型
filtrate_vessel: str = "",
filtrate_vessel: dict = {"id": "waste"},
**kwargs
) -> List[Dict[str, Any]]:
"""
@@ -68,16 +68,8 @@ def generate_filter_protocol(
"""
# 🔧 核心修改从字典中提取容器ID
# 统一处理vessel参数
if isinstance(vessel, dict):
if "id" not in vessel:
vessel_id = list(vessel.values())[0].get("id", "")
else:
vessel_id = vessel.get("id", "")
vessel_data = vessel.get("data", {})
else:
vessel_id = str(vessel)
vessel_data = G.nodes[vessel_id].get("data", {}) if vessel_id in G.nodes() else {}
vessel_id, vessel_data = get_vessel(vessel)
filtrate_vessel_id, filtrate_vessel_data = get_vessel(filtrate_vessel)
debug_print("🌊" * 20)
debug_print("🚀 开始生成过滤协议(支持体积运算)✨")
@@ -111,7 +103,7 @@ def generate_filter_protocol(
# 验证可选参数
debug_print(" 🔍 验证可选参数...")
if filtrate_vessel:
validate_vessel(G, filtrate_vessel, "滤液容器")
validate_vessel(G, filtrate_vessel_id, "滤液容器")
debug_print(" 🌊 模式: 过滤并收集滤液 💧")
else:
debug_print(" 🧱 模式: 过滤并收集固体 🔬")
@@ -168,8 +160,8 @@ def generate_filter_protocol(
# 使用pump protocol转移液体到过滤器
transfer_actions = generate_pump_protocol_with_rinsing(
G=G,
from_vessel=vessel_id, # 🔧 使用 vessel_id
to_vessel=filter_device,
from_vessel={"id": vessel_id}, # 🔧 使用 vessel_id
to_vessel={"id": filter_device},
volume=0.0, # 转移所有液体
amount="",
time=0.0,
@@ -220,8 +212,8 @@ def generate_filter_protocol(
# 构建过滤动作参数
debug_print(" ⚙️ 构建过滤参数...")
filter_kwargs = {
"vessel": filter_device, # 过滤器设备
"filtrate_vessel": filtrate_vessel, # 滤液容器(可能为空)
"vessel": {"id": filter_device}, # 过滤器设备
"filtrate_vessel": {"id": filtrate_vessel_id}, # 滤液容器(可能为空)
"stir": kwargs.get("stir", False),
"stir_speed": kwargs.get("stir_speed", 0.0),
"temp": kwargs.get("temp", 25.0),
@@ -252,8 +244,8 @@ def generate_filter_protocol(
# === 收集滤液(如果需要)===
debug_print("📍 步骤5: 收集滤液... 💧")
if filtrate_vessel:
debug_print(f" 🧪 收集滤液: {filter_device}{filtrate_vessel} 💧")
if filtrate_vessel_id and filtrate_vessel_id not in G.neighbors(filter_device):
debug_print(f" 🧪 收集滤液: {filter_device}{filtrate_vessel_id} 💧")
try:
debug_print(" 🔄 开始执行收集操作...")
@@ -282,20 +274,20 @@ def generate_filter_protocol(
debug_print(" 🔧 更新滤液容器体积...")
# 更新filtrate_vessel在图中的体积如果它是节点
if filtrate_vessel in G.nodes():
if 'data' not in G.nodes[filtrate_vessel]:
G.nodes[filtrate_vessel]['data'] = {}
if filtrate_vessel_id in G.nodes():
if 'data' not in G.nodes[filtrate_vessel_id]:
G.nodes[filtrate_vessel_id]['data'] = {}
current_filtrate_volume = G.nodes[filtrate_vessel]['data'].get('liquid_volume', 0.0)
current_filtrate_volume = G.nodes[filtrate_vessel_id]['data'].get('liquid_volume', 0.0)
if isinstance(current_filtrate_volume, list):
if len(current_filtrate_volume) > 0:
G.nodes[filtrate_vessel]['data']['liquid_volume'][0] += expected_filtrate_volume
G.nodes[filtrate_vessel_id]['data']['liquid_volume'][0] += expected_filtrate_volume
else:
G.nodes[filtrate_vessel]['data']['liquid_volume'] = [expected_filtrate_volume]
G.nodes[filtrate_vessel_id]['data']['liquid_volume'] = [expected_filtrate_volume]
else:
G.nodes[filtrate_vessel]['data']['liquid_volume'] = current_filtrate_volume + expected_filtrate_volume
G.nodes[filtrate_vessel_id]['data']['liquid_volume'] = current_filtrate_volume + expected_filtrate_volume
debug_print(f" 📊 滤液容器 {filtrate_vessel} 体积增加 {expected_filtrate_volume:.2f}mL")
debug_print(f" 📊 滤液容器 {filtrate_vessel_id} 体积增加 {expected_filtrate_volume:.2f}mL")
else:
debug_print(" ⚠️ 收集协议返回空序列 🤔")
@@ -360,7 +352,7 @@ def generate_filter_protocol(
debug_print(f"📊 总动作数: {len(action_sequence)} 个 📝")
debug_print(f"🥽 过滤容器: {vessel_id} 🧪")
debug_print(f"🌊 过滤器设备: {filter_device} 🔧")
debug_print(f"💧 滤液容器: {filtrate_vessel or '无(保留固体)'} 🧱")
debug_print(f"💧 滤液容器: {filtrate_vessel_id or '无(保留固体)'} 🧱")
debug_print(f"⏱️ 预计总时间: {(len(action_sequence) * 5):.0f} 秒 ⌛")
if original_liquid_volume > 0:
debug_print(f"📊 体积变化统计:")
@@ -372,4 +364,3 @@ def generate_filter_protocol(
debug_print("🎊" * 20)
return action_sequence

92
unilabos/compile/heatchill_protocol.py
View File

@@ -2,81 +2,15 @@ from typing import List, Dict, Any, Union
import networkx as nx
import logging
import re
from .utils.vessel_parser import get_vessel
from .utils.unit_parser import parse_time_input
logger = logging.getLogger(__name__)
def debug_print(message):
"""调试输出"""
print(f"🌡️ [HEATCHILL] {message}", flush=True)
logger.info(f"[HEATCHILL] {message}")
def parse_time_input(time_input: Union[str, float, int]) -> float:
"""
解析时间输入(统一函数)
Args:
time_input: 时间输入(如 "30 min", "1 h", "300", "?", 60.0
Returns:
float: 时间(秒)
"""
if not time_input:
return 300.0
# 🔢 处理数值输入
if isinstance(time_input, (int, float)):
result = float(time_input)
debug_print(f"⏰ 数值时间: {time_input}{result}s")
return result
# 📝 处理字符串输入
time_str = str(time_input).lower().strip()
debug_print(f"🔍 解析时间: '{time_str}'")
# ❓ 特殊值处理
special_times = {
'?': 300.0, 'unknown': 300.0, 'tbd': 300.0,
'overnight': 43200.0, 'several hours': 10800.0,
'few hours': 7200.0, 'long time': 3600.0, 'short time': 300.0
}
if time_str in special_times:
result = special_times[time_str]
debug_print(f"🎯 特殊时间: '{time_str}'{result}s ({result/60:.1f}分钟)")
return result
# 🔢 纯数字处理
try:
result = float(time_str)
debug_print(f"⏰ 纯数字: {time_str}{result}s")
return result
except ValueError:
pass
# 📐 正则表达式解析
pattern = r'(\d+\.?\d*)\s*([a-z]*)'
match = re.match(pattern, time_str)
if not match:
debug_print(f"⚠️ 无法解析时间: '{time_str}',使用默认值: 300s")
return 300.0
value = float(match.group(1))
unit = match.group(2) or 's'
# 📏 单位转换
unit_multipliers = {
's': 1.0, 'sec': 1.0, 'second': 1.0, 'seconds': 1.0,
'm': 60.0, 'min': 60.0, 'mins': 60.0, 'minute': 60.0, 'minutes': 60.0,
'h': 3600.0, 'hr': 3600.0, 'hrs': 3600.0, 'hour': 3600.0, 'hours': 3600.0,
'd': 86400.0, 'day': 86400.0, 'days': 86400.0
}
multiplier = unit_multipliers.get(unit, 1.0)
result = value * multiplier
debug_print(f"✅ 时间解析: '{time_str}'{value} {unit}{result}s ({result/60:.1f}分钟)")
return result
def parse_temp_input(temp_input: Union[str, float], default_temp: float = 25.0) -> float:
"""
@@ -217,16 +151,7 @@ def generate_heat_chill_protocol(
"""
# 🔧 核心修改从字典中提取容器ID
# 统一处理vessel参数
if isinstance(vessel, dict):
if "id" not in vessel:
vessel_id = list(vessel.values())[0].get("id", "")
else:
vessel_id = vessel.get("id", "")
vessel_data = vessel.get("data", {})
else:
vessel_id = str(vessel)
vessel_data = G.nodes[vessel_id].get("data", {}) if vessel_id in G.nodes() else {}
vessel_id, vessel_data = get_vessel(vessel)
debug_print("🌡️" * 20)
debug_print("🚀 开始生成加热冷却协议支持vessel字典")
@@ -295,7 +220,7 @@ def generate_heat_chill_protocol(
"device_id": heatchill_id,
"action_name": "heat_chill",
"action_kwargs": {
"vessel": vessel_id, # 🔧 使用 vessel_id
"vessel": vessel,
"temp": float(final_temp),
"time": float(final_time),
"stir": bool(stir),
@@ -329,7 +254,7 @@ def generate_heat_chill_to_temp_protocol(
**kwargs
) -> List[Dict[str, Any]]:
"""生成加热到指定温度的协议(简化版)"""
vessel_id = vessel["id"]
vessel_id, _ = get_vessel(vessel)
debug_print(f"🌡️ 生成加热到温度协议: {vessel_id}{temp}°C")
return generate_heat_chill_protocol(G, vessel, temp, time, **kwargs)
@@ -343,7 +268,7 @@ def generate_heat_chill_start_protocol(
"""生成开始加热操作的协议序列"""
# 🔧 核心修改从字典中提取容器ID
vessel_id = vessel["id"]
vessel_id, _ = get_vessel(vessel)
debug_print("🔥 开始生成启动加热协议 ✨")
debug_print(f"🥽 vessel: {vessel} (ID: {vessel_id}), 🌡️ temp: {temp}°C")
@@ -361,7 +286,6 @@ def generate_heat_chill_start_protocol(
"device_id": heatchill_id,
"action_name": "heat_chill_start",
"action_kwargs": {
"vessel": vessel_id, # 🔧 使用 vessel_id
"temp": temp,
"purpose": purpose or f"开始加热到 {temp}°C"
}
@@ -378,7 +302,7 @@ def generate_heat_chill_stop_protocol(
"""生成停止加热操作的协议序列"""
# 🔧 核心修改从字典中提取容器ID
vessel_id = vessel["id"]
vessel_id, _ = get_vessel(vessel)
debug_print("🛑 开始生成停止加热协议 ✨")
debug_print(f"🥽 vessel: {vessel} (ID: {vessel_id})")
@@ -396,10 +320,8 @@ def generate_heat_chill_stop_protocol(
"device_id": heatchill_id,
"action_name": "heat_chill_stop",
"action_kwargs": {
"vessel": vessel_id # 🔧 使用 vessel_id
}
}]
debug_print(f"✅ 停止加热协议生成完成 🎯")
return action_sequence

12
unilabos/compile/hydrogenate_protocol.py
View File

@@ -1,5 +1,6 @@
import networkx as nx
from typing import List, Dict, Any, Optional
from .utils.vessel_parser import get_vessel
def parse_temperature(temp_str: str) -> float:
@@ -170,16 +171,7 @@ def generate_hydrogenate_protocol(
"""
# 🔧 核心修改从字典中提取容器ID
# 统一处理vessel参数
if isinstance(vessel, dict):
if "id" not in vessel:
vessel_id = list(vessel.values())[0].get("id", "")
else:
vessel_id = vessel.get("id", "")
vessel_data = vessel.get("data", {})
else:
vessel_id = str(vessel)
vessel_data = G.nodes[vessel_id].get("data", {}) if vessel_id in G.nodes() else {}
vessel_id, vessel_data = get_vessel(vessel)
action_sequence = []

1508
unilabos/compile/pump_protocol.py
View File

File diff suppressed because it is too large Load Diff

218
unilabos/compile/recrystallize_protocol.py
View File

@@ -2,91 +2,17 @@ import networkx as nx
import re
import logging
from typing import List, Dict, Any, Tuple, Union
from .utils.vessel_parser import get_vessel, find_solvent_vessel
from .utils.unit_parser import parse_volume_input
from .pump_protocol import generate_pump_protocol_with_rinsing
logger = logging.getLogger(__name__)
def debug_print(message):
"""调试输出"""
print(f"💎 [RECRYSTALLIZE] {message}", flush=True)
logger.info(f"[RECRYSTALLIZE] {message}")
def parse_volume_with_units(volume_input: Union[str, float, int], default_unit: str = "mL") -> float:
"""
解析带单位的体积输入
Args:
volume_input: 体积输入(如 "100 mL", "2.5 L", "500", "?", 100.0
default_unit: 默认单位(默认为毫升)
Returns:
float: 体积(毫升)
"""
if not volume_input:
debug_print("⚠️ 体积输入为空,返回 0.0mL 📦")
return 0.0
# 处理数值输入
if isinstance(volume_input, (int, float)):
result = float(volume_input)
debug_print(f"🔢 数值体积输入: {volume_input}{result}mL默认单位💧")
return result
# 处理字符串输入
volume_str = str(volume_input).lower().strip()
debug_print(f"🔍 解析体积字符串: '{volume_str}' 📝")
# 处理特殊值
if volume_str in ['?', 'unknown', 'tbd', 'to be determined']:
default_volume = 50.0 # 50mL默认值
debug_print(f"❓ 检测到未知体积,使用默认值: {default_volume}mL 🎯")
return default_volume
# 如果是纯数字,使用默认单位
try:
value = float(volume_str)
if default_unit.lower() in ["ml", "milliliter"]:
result = value
elif default_unit.lower() in ["l", "liter"]:
result = value * 1000.0
elif default_unit.lower() in ["μl", "ul", "microliter"]:
result = value / 1000.0
else:
result = value # 默认mL
debug_print(f"🔢 纯数字输入: {volume_str}{result}mL单位: {default_unit})📏")
return result
except ValueError:
pass
# 移除空格并提取数字和单位
volume_clean = re.sub(r'\s+', '', volume_str)
# 匹配数字和单位的正则表达式
match = re.match(r'([0-9]*\.?[0-9]+)\s*(ml|l|μl|ul|microliter|milliliter|liter)?', volume_clean)
if not match:
debug_print(f"⚠️ 无法解析体积: '{volume_str}',使用默认值: 50mL 🎯")
return 50.0
value = float(match.group(1))
unit = match.group(2) or default_unit.lower()
# 转换为毫升
if unit in ['l', 'liter']:
volume = value * 1000.0 # L -> mL
debug_print(f"📏 升转毫升: {value}L → {volume}mL 💧")
elif unit in ['μl', 'ul', 'microliter']:
volume = value / 1000.0 # μL -> mL
debug_print(f"📏 微升转毫升: {value}μL → {volume}mL 💧")
else: # ml, milliliter 或默认
volume = value # 已经是mL
debug_print(f"📏 毫升单位: {value}mL → {volume}mL 💧")
debug_print(f"✅ 体积解析完成: '{volume_str}'{volume}mL ✨")
return volume
def parse_ratio(ratio_str: str) -> Tuple[float, float]:
"""
解析比例字符串,支持多种格式
@@ -136,131 +62,6 @@ def parse_ratio(ratio_str: str) -> Tuple[float, float]:
return 1.0, 1.0
def find_solvent_vessel(G: nx.DiGraph, solvent: str) -> str:
"""
查找溶剂容器
Args:
G: 网络图
solvent: 溶剂名称
Returns:
str: 溶剂容器ID
"""
debug_print(f"🔍 正在查找溶剂 '{solvent}' 的容器... 🧪")
# 构建可能的容器名称
possible_names = [
f"flask_{solvent}",
f"bottle_{solvent}",
f"reagent_{solvent}",
f"reagent_bottle_{solvent}",
f"{solvent}_flask",
f"{solvent}_bottle",
f"{solvent}",
f"vessel_{solvent}",
]
debug_print(f"📋 候选容器名称: {possible_names[:3]}... (共{len(possible_names)}个) 📝")
# 第一步:通过容器名称匹配
debug_print(" 🎯 步骤1: 精确名称匹配...")
for vessel_name in possible_names:
if vessel_name in G.nodes():
debug_print(f" 🎉 通过名称匹配找到容器: {vessel_name}")
return vessel_name
# 第二步通过模糊匹配节点ID和名称
debug_print(" 🔍 步骤2: 模糊名称匹配...")
for node_id in G.nodes():
if G.nodes[node_id].get('type') == 'container':
node_name = G.nodes[node_id].get('name', '').lower()
if solvent.lower() in node_id.lower() or solvent.lower() in node_name:
debug_print(f" 🎉 通过模糊匹配找到容器: {node_id} (名称: {node_name}) ✨")
return node_id
# 第三步:通过配置中的试剂信息匹配
debug_print(" 🧪 步骤3: 配置试剂信息匹配...")
for node_id in G.nodes():
if G.nodes[node_id].get('type') == 'container':
# 检查 config 中的 reagent 字段
node_config = G.nodes[node_id].get('config', {})
config_reagent = node_config.get('reagent', '').lower()
if config_reagent and solvent.lower() == config_reagent:
debug_print(f" 🎉 通过config.reagent匹配找到容器: {node_id} (试剂: {config_reagent}) ✨")
return node_id
# 第四步:通过数据中的试剂信息匹配
debug_print(" 🧪 步骤4: 数据试剂信息匹配...")
for node_id in G.nodes():
if G.nodes[node_id].get('type') == 'container':
vessel_data = G.nodes[node_id].get('data', {})
# 检查 data 中的 reagent_name 字段
reagent_name = vessel_data.get('reagent_name', '').lower()
if reagent_name and solvent.lower() == reagent_name:
debug_print(f" 🎉 通过data.reagent_name匹配找到容器: {node_id} (试剂: {reagent_name}) ✨")
return node_id
# 检查 data 中的液体信息
liquids = vessel_data.get('liquid', [])
for liquid in liquids:
if isinstance(liquid, dict):
liquid_type = (liquid.get('liquid_type') or liquid.get('name', '')).lower()
if solvent.lower() in liquid_type:
debug_print(f" 🎉 通过液体类型匹配找到容器: {node_id} (液体类型: {liquid_type}) ✨")
return node_id
# 第五步:部分匹配(如果前面都没找到)
debug_print(" 🔍 步骤5: 部分匹配...")
for node_id in G.nodes():
if G.nodes[node_id].get('type') == 'container':
node_config = G.nodes[node_id].get('config', {})
node_data = G.nodes[node_id].get('data', {})
node_name = G.nodes[node_id].get('name', '').lower()
config_reagent = node_config.get('reagent', '').lower()
data_reagent = node_data.get('reagent_name', '').lower()
# 检查是否包含溶剂名称
if (solvent.lower() in config_reagent or
solvent.lower() in data_reagent or
solvent.lower() in node_name or
solvent.lower() in node_id.lower()):
debug_print(f" 🎉 通过部分匹配找到容器: {node_id}")
debug_print(f" - 节点名称: {node_name}")
debug_print(f" - 配置试剂: {config_reagent}")
debug_print(f" - 数据试剂: {data_reagent}")
return node_id
# 调试信息:列出所有容器
debug_print(" 🔎 调试信息:列出所有容器...")
container_list = []
for node_id in G.nodes():
if G.nodes[node_id].get('type') == 'container':
node_config = G.nodes[node_id].get('config', {})
node_data = G.nodes[node_id].get('data', {})
node_name = G.nodes[node_id].get('name', '')
container_info = {
'id': node_id,
'name': node_name,
'config_reagent': node_config.get('reagent', ''),
'data_reagent': node_data.get('reagent_name', '')
}
container_list.append(container_info)
debug_print(f" - 容器: {node_id}, 名称: {node_name}, config试剂: {node_config.get('reagent', '')}, data试剂: {node_data.get('reagent_name', '')}")
debug_print(f"❌ 找不到溶剂 '{solvent}' 对应的容器 😭")
debug_print(f"🔍 查找的溶剂: '{solvent}' (小写: '{solvent.lower()}')")
debug_print(f"📊 总共发现 {len(container_list)} 个容器")
raise ValueError(f"找不到溶剂 '{solvent}' 对应的容器")
def generate_recrystallize_protocol(
G: nx.DiGraph,
vessel: dict, # 🔧 修改:从字符串改为字典类型
@@ -287,16 +88,7 @@ def generate_recrystallize_protocol(
"""
# 🔧 核心修改从字典中提取容器ID
# 统一处理vessel参数
if isinstance(vessel, dict):
if "id" not in vessel:
vessel_id = list(vessel.values())[0].get("id", "")
else:
vessel_id = vessel.get("id", "")
vessel_data = vessel.get("data", {})
else:
vessel_id = str(vessel)
vessel_data = G.nodes[vessel_id].get("data", {}) if vessel_id in G.nodes() else {}
vessel_id, vessel_data = get_vessel(vessel)
action_sequence = []
@@ -330,7 +122,7 @@ def generate_recrystallize_protocol(
# 2. 解析体积(支持单位)
debug_print("📍 步骤2: 解析体积(支持单位)... 💧")
final_volume = parse_volume_with_units(volume, "mL")
final_volume = parse_volume_input(volume, "mL")
debug_print(f"🎯 体积解析完成: {volume}{final_volume}mL ✨")
# 3. 解析比例
@@ -582,7 +374,7 @@ def test_recrystallize_protocol():
debug_print("💧 测试体积解析...")
test_volumes = ["100 mL", "2.5 L", "500", "50.5", "?", "invalid"]
for vol in test_volumes:
parsed = parse_volume_with_units(vol)
parsed = parse_volume_input(vol)
debug_print(f" 📊 体积 '{vol}' -> {parsed}mL")
# 测试比例解析

1
unilabos/compile/run_column_protocol.py
View File

@@ -8,7 +8,6 @@ logger = logging.getLogger(__name__)
def debug_print(message):
"""调试输出"""
print(f"🏛️ [RUN_COLUMN] {message}", flush=True)
logger.info(f"[RUN_COLUMN] {message}")
def parse_percentage(pct_str: str) -> float:

920
unilabos/compile/separate_protocol.py
View File

@@ -1,8 +1,12 @@
from functools import partial
import networkx as nx
import re
import logging
import sys
from typing import List, Dict, Any, Union
from .utils.vessel_parser import get_vessel
from .utils.logger_util import action_log
from .pump_protocol import generate_pump_protocol_with_rinsing
logger = logging.getLogger(__name__)
@@ -20,48 +24,472 @@ def debug_print(message):
try:
# 确保消息是字符串格式
safe_message = str(message)
print(f"🌀 [SEPARATE] {safe_message}", flush=True)
logger.info(f"[SEPARATE] {safe_message}")
except UnicodeEncodeError:
# 如果编码失败,尝试替换不支持的字符
safe_message = str(message).encode('utf-8', errors='replace').decode('utf-8')
print(f"🌀 [SEPARATE] {safe_message}", flush=True)
logger.info(f"[SEPARATE] {safe_message}")
except Exception as e:
# 最后的安全措施
fallback_message = f"日志输出错误: {repr(message)}"
print(f"🌀 [SEPARATE] {fallback_message}", flush=True)
logger.info(f"[SEPARATE] {fallback_message}")
def create_action_log(message: str, emoji: str = "📝") -> Dict[str, Any]:
"""创建一个动作日志 - 支持中文和emoji"""
create_action_log = partial(action_log, prefix="[SEPARATE]")
def generate_separate_protocol(
G: nx.DiGraph,
# 🔧 基础参数支持XDL的vessel参数
vessel: dict = None, # 🔧 修改:从字符串改为字典类型
purpose: str = "separate", # 分离目的
product_phase: str = "top", # 产物相
# 🔧 可选的详细参数
from_vessel: Union[str, dict] = "", # 源容器通常在separate前已经transfer了
separation_vessel: Union[str, dict] = "", # 分离容器与vessel同义
to_vessel: Union[str, dict] = "", # 目标容器(可选)
waste_phase_to_vessel: Union[str, dict] = "", # 废相目标容器
product_vessel: Union[str, dict] = "", # XDL: 产物容器与to_vessel同义
waste_vessel: Union[str, dict] = "", # XDL: 废液容器与waste_phase_to_vessel同义
# 🔧 溶剂相关参数
solvent: str = "", # 溶剂名称
solvent_volume: Union[str, float] = 0.0, # 溶剂体积
volume: Union[str, float] = 0.0, # XDL: 体积与solvent_volume同义
# 🔧 操作参数
through: str = "", # 通过材料
repeats: int = 1, # 重复次数
stir_time: float = 30.0, # 搅拌时间(秒)
stir_speed: float = 300.0, # 搅拌速度
settling_time: float = 300.0, # 沉降时间(秒)
**kwargs
) -> List[Dict[str, Any]]:
"""
生成分离操作的协议序列 - 支持vessel字典和体积运算
支持XDL参数格式
- vessel: 分离容器字典(必需)
- purpose: "wash", "extract", "separate"
- product_phase: "top", "bottom"
- product_vessel: 产物收集容器
- waste_vessel: 废液收集容器
- solvent: 溶剂名称
- volume: "200 mL", "?" 或数值
- repeats: 重复次数
分离流程:
1. (可选)添加溶剂到分离容器
2. 搅拌混合
3. 静置分层
4. 收集指定相到目标容器
5. 重复指定次数
"""
# 🔧 核心修改vessel参数兼容处理
if vessel is None:
if isinstance(separation_vessel, dict):
vessel = separation_vessel
else:
raise ValueError("必须提供vessel字典参数")
# 🔧 核心修改从字典中提取容器ID
vessel_id, vessel_data = get_vessel(vessel)
debug_print("🌀" * 20)
debug_print("🚀 开始生成分离协议支持vessel字典和体积运算")
debug_print(f"📝 输入参数:")
debug_print(f" 🥽 vessel: {vessel} (ID: {vessel_id})")
debug_print(f" 🎯 分离目的: '{purpose}'")
debug_print(f" 📊 产物相: '{product_phase}'")
debug_print(f" 💧 溶剂: '{solvent}'")
debug_print(f" 📏 体积: {volume} (类型: {type(volume)})")
debug_print(f" 🔄 重复次数: {repeats}")
debug_print(f" 🎯 产物容器: '{product_vessel}'")
debug_print(f" 🗑️ 废液容器: '{waste_vessel}'")
debug_print(f" 📦 其他参数: {kwargs}")
debug_print("🌀" * 20)
action_sequence = []
# 🔧 新增:记录分离前的容器状态
debug_print("🔍 记录分离前容器状态...")
original_liquid_volume = get_vessel_liquid_volume(vessel)
debug_print(f"📊 分离前液体体积: {original_liquid_volume:.2f}mL")
# === 参数验证和标准化 ===
debug_print("🔍 步骤1: 参数验证和标准化...")
action_sequence.append(create_action_log(f"开始分离操作 - 容器: {vessel_id}", "🎬"))
action_sequence.append(create_action_log(f"分离目的: {purpose}", "🧪"))
action_sequence.append(create_action_log(f"产物相: {product_phase}", "📊"))
# 统一容器参数 - 支持字典和字符串
def extract_vessel_id(vessel_param):
if isinstance(vessel_param, dict):
return vessel_param.get("id", "")
elif isinstance(vessel_param, str):
return vessel_param
else:
return ""
final_vessel_id, _ = vessel_id
final_to_vessel_id, _ = get_vessel(to_vessel) or get_vessel(product_vessel)
final_waste_vessel_id, _ = get_vessel(waste_phase_to_vessel) or get_vessel(waste_vessel)
# 统一体积参数
final_volume = parse_volume_input(volume or solvent_volume)
# 🔧 修复确保repeats至少为1
if repeats <= 0:
repeats = 1
debug_print(f"⚠️ 重复次数参数 <= 0自动设置为 1")
debug_print(f"🔧 标准化后的参数:")
debug_print(f" 🥼 分离容器: '{final_vessel_id}'")
debug_print(f" 🎯 产物容器: '{final_to_vessel_id}'")
debug_print(f" 🗑️ 废液容器: '{final_waste_vessel_id}'")
debug_print(f" 📏 溶剂体积: {final_volume}mL")
debug_print(f" 🔄 重复次数: {repeats}")
action_sequence.append(create_action_log(f"分离容器: {final_vessel_id}", "🧪"))
action_sequence.append(create_action_log(f"溶剂体积: {final_volume}mL", "📏"))
action_sequence.append(create_action_log(f"重复次数: {repeats}", "🔄"))
# 验证必需参数
if not purpose:
purpose = "separate"
if not product_phase:
product_phase = "top"
if purpose not in ["wash", "extract", "separate"]:
debug_print(f"⚠️ 未知的分离目的 '{purpose}',使用默认值 'separate'")
purpose = "separate"
action_sequence.append(create_action_log(f"未知目的,使用: {purpose}", "⚠️"))
if product_phase not in ["top", "bottom"]:
debug_print(f"⚠️ 未知的产物相 '{product_phase}',使用默认值 'top'")
product_phase = "top"
action_sequence.append(create_action_log(f"未知相别,使用: {product_phase}", "⚠️"))
debug_print("✅ 参数验证通过")
action_sequence.append(create_action_log("参数验证通过", ""))
# === 查找设备 ===
debug_print("🔍 步骤2: 查找设备...")
action_sequence.append(create_action_log("正在查找相关设备...", "🔍"))
# 查找分离器设备
separator_device = find_separator_device(G, final_vessel_id) # 🔧 使用 final_vessel_id
if separator_device:
action_sequence.append(create_action_log(f"找到分离器设备: {separator_device}", "🧪"))
else:
debug_print("⚠️ 未找到分离器设备,可能无法执行分离")
action_sequence.append(create_action_log("未找到分离器设备", "⚠️"))
# 查找搅拌器
stirrer_device = find_connected_stirrer(G, final_vessel_id) # 🔧 使用 final_vessel_id
if stirrer_device:
action_sequence.append(create_action_log(f"找到搅拌器: {stirrer_device}", "🌪️"))
else:
action_sequence.append(create_action_log("未找到搅拌器", "⚠️"))
# 查找溶剂容器(如果需要)
solvent_vessel = ""
if solvent and solvent.strip():
solvent_vessel = find_solvent_vessel(G, solvent)
if solvent_vessel:
action_sequence.append(create_action_log(f"找到溶剂容器: {solvent_vessel}", "💧"))
else:
action_sequence.append(create_action_log(f"未找到溶剂容器: {solvent}", "⚠️"))
debug_print(f"📊 设备配置:")
debug_print(f" 🧪 分离器设备: '{separator_device}'")
debug_print(f" 🌪️ 搅拌器设备: '{stirrer_device}'")
debug_print(f" 💧 溶剂容器: '{solvent_vessel}'")
# === 执行分离流程 ===
debug_print("🔍 步骤3: 执行分离流程...")
action_sequence.append(create_action_log("开始分离工作流程", "🎯"))
# 🔧 新增:体积变化跟踪变量
current_volume = original_liquid_volume
try:
full_message = f"{emoji} {message}"
debug_print(full_message)
logger.info(full_message)
return {
"action_name": "wait",
"action_kwargs": {
"time": 0.1,
"log_message": full_message,
"progress_message": full_message
}
}
for repeat_idx in range(repeats):
cycle_num = repeat_idx + 1
debug_print(f"🔄 第{cycle_num}轮: 开始分离循环 {cycle_num}/{repeats}")
action_sequence.append(create_action_log(f"分离循环 {cycle_num}/{repeats} 开始", "🔄"))
# 步骤3.1: 添加溶剂(如果需要)
if solvent_vessel and final_volume > 0:
debug_print(f"🔄 第{cycle_num}轮 步骤1: 添加溶剂 {solvent} ({final_volume}mL)")
action_sequence.append(create_action_log(f"向分离容器添加 {final_volume}mL {solvent}", "💧"))
try:
# 使用pump protocol添加溶剂
pump_actions = generate_pump_protocol_with_rinsing(
G=G,
from_vessel=solvent_vessel,
to_vessel=final_vessel_id, # 🔧 使用 final_vessel_id
volume=final_volume,
amount="",
time=0.0,
viscous=False,
rinsing_solvent="",
rinsing_volume=0.0,
rinsing_repeats=0,
solid=False,
flowrate=2.5,
transfer_flowrate=0.5,
rate_spec="",
event="",
through="",
**kwargs
)
action_sequence.extend(pump_actions)
debug_print(f"✅ 溶剂添加完成,添加了 {len(pump_actions)} 个动作")
action_sequence.append(create_action_log(f"溶剂转移完成 ({len(pump_actions)} 个操作)", ""))
# 🔧 新增:更新体积 - 添加溶剂后
current_volume += final_volume
update_vessel_volume(vessel, G, current_volume, f"添加{final_volume}mL {solvent}")
except Exception as e:
debug_print(f"❌ 溶剂添加失败: {str(e)}")
action_sequence.append(create_action_log(f"溶剂添加失败: {str(e)}", ""))
else:
debug_print(f"🔄 第{cycle_num}轮 步骤1: 无需添加溶剂")
action_sequence.append(create_action_log("无需添加溶剂", "⏭️"))
# 步骤3.2: 启动搅拌(如果有搅拌器)
if stirrer_device and stir_time > 0:
debug_print(f"🔄 第{cycle_num}轮 步骤2: 开始搅拌 ({stir_speed}rpm持续 {stir_time}s)")
action_sequence.append(create_action_log(f"开始搅拌: {stir_speed}rpm持续 {stir_time}s", "🌪️"))
action_sequence.append({
"device_id": stirrer_device,
"action_name": "start_stir",
"action_kwargs": {
"vessel": final_vessel_id, # 🔧 使用 final_vessel_id
"stir_speed": stir_speed,
"purpose": f"分离混合 - {purpose}"
}
})
# 搅拌等待
stir_minutes = stir_time / 60
action_sequence.append(create_action_log(f"搅拌中,持续 {stir_minutes:.1f} 分钟", "⏱️"))
action_sequence.append({
"action_name": "wait",
"action_kwargs": {"time": stir_time}
})
# 停止搅拌
action_sequence.append(create_action_log("停止搅拌器", "🛑"))
action_sequence.append({
"device_id": stirrer_device,
"action_name": "stop_stir",
"action_kwargs": {"vessel": final_vessel_id} # 🔧 使用 final_vessel_id
})
else:
debug_print(f"🔄 第{cycle_num}轮 步骤2: 无需搅拌")
action_sequence.append(create_action_log("无需搅拌", "⏭️"))
# 步骤3.3: 静置分层
if settling_time > 0:
debug_print(f"🔄 第{cycle_num}轮 步骤3: 静置分层 ({settling_time}s)")
settling_minutes = settling_time / 60
action_sequence.append(create_action_log(f"静置分层 ({settling_minutes:.1f} 分钟)", "⚖️"))
action_sequence.append({
"action_name": "wait",
"action_kwargs": {"time": settling_time}
})
else:
debug_print(f"🔄 第{cycle_num}轮 步骤3: 未指定静置时间")
action_sequence.append(create_action_log("未指定静置时间", "⏭️"))
# 步骤3.4: 执行分离操作
if separator_device:
debug_print(f"🔄 第{cycle_num}轮 步骤4: 执行分离操作")
action_sequence.append(create_action_log(f"执行分离: 收集{product_phase}", "🧪"))
# 🔧 替换为具体的分离操作逻辑基于old版本
# 首先进行分液判断(电导突跃)
action_sequence.append({
"device_id": separator_device,
"action_name": "valve_open",
"action_kwargs": {
"command": "delta > 0.05"
}
})
# 估算每相的体积(假设大致平分)
phase_volume = current_volume / 2
# 智能查找分离容器底部
separation_vessel_bottom = find_separation_vessel_bottom(G, final_vessel_id) # ✅
if product_phase == "bottom":
debug_print(f"🔄 收集底相产物到 {final_to_vessel_id}")
action_sequence.append(create_action_log("收集底相产物", "📦"))
# 产物转移到目标瓶
if final_to_vessel_id:
pump_actions = generate_pump_protocol_with_rinsing(
G=G,
from_vessel=separation_vessel_bottom,
to_vessel=final_to_vessel_id,
volume=current_volume,
flowrate=2.5,
**kwargs
)
action_sequence.extend(pump_actions)
# 放出上面那一相60秒后关阀门
action_sequence.append({
"device_id": separator_device,
"action_name": "valve_open",
"action_kwargs": {
"command": "time > 60"
}
})
# 弃去上面那一相进废液
if final_waste_vessel_id:
pump_actions = generate_pump_protocol_with_rinsing(
G=G,
from_vessel=separation_vessel_bottom,
to_vessel=final_waste_vessel_id,
volume=current_volume,
flowrate=2.5,
**kwargs
)
action_sequence.extend(pump_actions)
elif product_phase == "top":
debug_print(f"🔄 收集上相产物到 {final_to_vessel_id}")
action_sequence.append(create_action_log("收集上相产物", "📦"))
# 弃去下面那一相进废液
if final_waste_vessel_id:
pump_actions = generate_pump_protocol_with_rinsing(
G=G,
from_vessel=separation_vessel_bottom,
to_vessel=final_waste_vessel_id,
volume=phase_volume,
flowrate=2.5,
**kwargs
)
action_sequence.extend(pump_actions)
# 放出上面那一相60秒后关阀门
action_sequence.append({
"device_id": separator_device,
"action_name": "valve_open",
"action_kwargs": {
"command": "time > 60"
}
})
# 产物转移到目标瓶
if final_to_vessel_id:
pump_actions = generate_pump_protocol_with_rinsing(
G=G,
from_vessel=separation_vessel_bottom,
to_vessel=final_to_vessel_id,
volume=phase_volume,
flowrate=2.5,
**kwargs
)
action_sequence.extend(pump_actions)
debug_print(f"✅ 分离操作已完成")
action_sequence.append(create_action_log("分离操作完成", ""))
# 🔧 新增:分离后体积估算
separated_volume = phase_volume * 0.95 # 假设5%损失,只保留产物相体积
update_vessel_volume(vessel, G, separated_volume, f"分离操作后(第{cycle_num}轮)")
current_volume = separated_volume
# 收集结果
if final_to_vessel_id:
action_sequence.append(
create_action_log(f"产物 ({product_phase}相) 收集到: {final_to_vessel_id}", "📦"))
if final_waste_vessel_id:
action_sequence.append(create_action_log(f"废相收集到: {final_waste_vessel_id}", "🗑️"))
else:
debug_print(f"🔄 第{cycle_num}轮 步骤4: 无分离器设备,跳过分离")
action_sequence.append(create_action_log("无分离器设备可用", ""))
# 添加等待时间模拟分离
action_sequence.append({
"action_name": "wait",
"action_kwargs": {"time": 10.0}
})
# 🔧 新增如果不是最后一次从中转瓶转移回分液漏斗基于old版本逻辑
if repeat_idx < repeats - 1 and final_to_vessel_id and final_to_vessel_id != final_vessel_id:
debug_print(f"🔄 第{cycle_num}轮: 产物转移回分离容器准备下一轮")
action_sequence.append(create_action_log("产物转回分离容器,准备下一轮", "🔄"))
pump_actions = generate_pump_protocol_with_rinsing(
G=G,
from_vessel=final_to_vessel_id,
to_vessel=final_vessel_id,
volume=current_volume,
flowrate=2.5,
**kwargs
)
action_sequence.extend(pump_actions)
# 更新体积回到分离容器
update_vessel_volume(vessel, G, current_volume, f"产物转回分离容器(第{cycle_num}轮后)")
# 循环间等待(除了最后一次)
if repeat_idx < repeats - 1:
debug_print(f"🔄 第{cycle_num}轮: 等待下一次循环...")
action_sequence.append(create_action_log("等待下一次循环...", ""))
action_sequence.append({
"action_name": "wait",
"action_kwargs": {"time": 5}
})
else:
action_sequence.append(create_action_log(f"分离循环 {cycle_num}/{repeats} 完成", "🌟"))
except Exception as e:
# 如果emoji有问题使用纯文本
safe_message = f"[日志] {message}"
debug_print(safe_message)
logger.info(safe_message)
return {
"action_name": "wait",
"action_kwargs": {
"time": 0.1,
"log_message": safe_message,
"progress_message": safe_message
}
}
debug_print(f"❌ 分离工作流程执行失败: {str(e)}")
action_sequence.append(create_action_log(f"分离工作流程失败: {str(e)}", ""))
# 🔧 新增:分离完成后的最终状态报告
final_liquid_volume = get_vessel_liquid_volume(vessel)
# === 最终结果 ===
total_time = (stir_time + settling_time + 15) * repeats # 估算总时间
debug_print("🌀" * 20)
debug_print(f"🎉 分离协议生成完成")
debug_print(f"📊 协议统计:")
debug_print(f" 📋 总动作数: {len(action_sequence)}")
debug_print(f" ⏱️ 预计总时间: {total_time:.0f}s ({total_time / 60:.1f} 分钟)")
debug_print(f" 🥼 分离容器: {final_vessel_id}")
debug_print(f" 🎯 分离目的: {purpose}")
debug_print(f" 📊 产物相: {product_phase}")
debug_print(f" 🔄 重复次数: {repeats}")
debug_print(f"💧 体积变化统计:")
debug_print(f" - 分离前体积: {original_liquid_volume:.2f}mL")
debug_print(f" - 分离后体积: {final_liquid_volume:.2f}mL")
if solvent:
debug_print(f" 💧 溶剂: {solvent} ({final_volume}mL × {repeats}轮 = {final_volume * repeats:.2f}mL)")
if final_to_vessel_id:
debug_print(f" 🎯 产物容器: {final_to_vessel_id}")
if final_waste_vessel_id:
debug_print(f" 🗑️ 废液容器: {final_waste_vessel_id}")
debug_print("🌀" * 20)
# 添加完成日志
summary_msg = f"分离协议完成: {final_vessel_id} ({purpose}{repeats} 次循环)"
if solvent:
summary_msg += f",使用 {final_volume * repeats:.2f}mL {solvent}"
action_sequence.append(create_action_log(summary_msg, "🎉"))
return action_sequence
def parse_volume_input(volume_input: Union[str, float]) -> float:
"""
@@ -364,386 +792,54 @@ def update_vessel_volume(vessel: dict, G: nx.DiGraph, new_volume: float, descrip
debug_print(f"📊 容器 '{vessel_id}' 体积已更新为: {new_volume:.2f}mL")
def generate_separate_protocol(
G: nx.DiGraph,
# 🔧 基础参数支持XDL的vessel参数
vessel: dict = None, # 🔧 修改:从字符串改为字典类型
purpose: str = "separate", # 分离目的
product_phase: str = "top", # 产物相
# 🔧 可选的详细参数
from_vessel: Union[str, dict] = "", # 源容器通常在separate前已经transfer了
separation_vessel: Union[str, dict] = "", # 分离容器与vessel同义
to_vessel: Union[str, dict] = "", # 目标容器(可选)
waste_phase_to_vessel: Union[str, dict] = "", # 废相目标容器
product_vessel: Union[str, dict] = "", # XDL: 产物容器与to_vessel同义
waste_vessel: Union[str, dict] = "", # XDL: 废液容器与waste_phase_to_vessel同义
# 🔧 溶剂相关参数
solvent: str = "", # 溶剂名称
solvent_volume: Union[str, float] = 0.0, # 溶剂体积
volume: Union[str, float] = 0.0, # XDL: 体积与solvent_volume同义
# 🔧 操作参数
through: str = "", # 通过材料
repeats: int = 1, # 重复次数
stir_time: float = 30.0, # 搅拌时间(秒)
stir_speed: float = 300.0, # 搅拌速度
settling_time: float = 300.0, # 沉降时间(秒)
**kwargs
) -> List[Dict[str, Any]]:
"""
生成分离操作的协议序列 - 支持vessel字典和体积运算
支持XDL参数格式
- vessel: 分离容器字典(必需)
- purpose: "wash", "extract", "separate"
- product_phase: "top", "bottom"
- product_vessel: 产物收集容器
- waste_vessel: 废液收集容器
- solvent: 溶剂名称
- volume: "200 mL", "?" 或数值
- repeats: 重复次数
分离流程:
1. (可选)添加溶剂到分离容器
2. 搅拌混合
3. 静置分层
4. 收集指定相到目标容器
5. 重复指定次数
"""
# 🔧 核心修改vessel参数兼容处理
if vessel is None:
if isinstance(separation_vessel, dict):
vessel = separation_vessel
else:
raise ValueError("必须提供vessel字典参数")
# 🔧 核心修改从字典中提取容器ID
# 统一处理vessel参数
if isinstance(vessel, dict):
if "id" not in vessel:
vessel_id = list(vessel.values())[0].get("id", "")
else:
vessel_id = vessel.get("id", "")
vessel_data = vessel.get("data", {})
else:
vessel_id = str(vessel)
vessel_data = G.nodes[vessel_id].get("data", {}) if vessel_id in G.nodes() else {}
debug_print("🌀" * 20)
debug_print("🚀 开始生成分离协议支持vessel字典和体积运算")
debug_print(f"📝 输入参数:")
debug_print(f" 🥽 vessel: {vessel} (ID: {vessel_id})")
debug_print(f" 🎯 分离目的: '{purpose}'")
debug_print(f" 📊 产物相: '{product_phase}'")
debug_print(f" 💧 溶剂: '{solvent}'")
debug_print(f" 📏 体积: {volume} (类型: {type(volume)})")
debug_print(f" 🔄 重复次数: {repeats}")
debug_print(f" 🎯 产物容器: '{product_vessel}'")
debug_print(f" 🗑️ 废液容器: '{waste_vessel}'")
debug_print(f" 📦 其他参数: {kwargs}")
debug_print("🌀" * 20)
action_sequence = []
# 🔧 新增:记录分离前的容器状态
debug_print("🔍 记录分离前容器状态...")
original_liquid_volume = get_vessel_liquid_volume(vessel)
debug_print(f"📊 分离前液体体积: {original_liquid_volume:.2f}mL")
# === 参数验证和标准化 ===
debug_print("🔍 步骤1: 参数验证和标准化...")
action_sequence.append(create_action_log(f"开始分离操作 - 容器: {vessel_id}", "🎬"))
action_sequence.append(create_action_log(f"分离目的: {purpose}", "🧪"))
action_sequence.append(create_action_log(f"产物相: {product_phase}", "📊"))
# 统一容器参数 - 支持字典和字符串
def extract_vessel_id(vessel_param):
if isinstance(vessel_param, dict):
return vessel_param.get("id", "")
elif isinstance(vessel_param, str):
return vessel_param
else:
return ""
final_vessel_id = vessel_id
final_to_vessel_id = extract_vessel_id(to_vessel) or extract_vessel_id(product_vessel)
final_waste_vessel_id = extract_vessel_id(waste_phase_to_vessel) or extract_vessel_id(waste_vessel)
# 统一体积参数
final_volume = parse_volume_input(volume or solvent_volume)
# 🔧 修复确保repeats至少为1
if repeats <= 0:
repeats = 1
debug_print(f"⚠️ 重复次数参数 <= 0自动设置为 1")
debug_print(f"🔧 标准化后的参数:")
debug_print(f" 🥼 分离容器: '{final_vessel_id}'")
debug_print(f" 🎯 产物容器: '{final_to_vessel_id}'")
debug_print(f" 🗑️ 废液容器: '{final_waste_vessel_id}'")
debug_print(f" 📏 溶剂体积: {final_volume}mL")
debug_print(f" 🔄 重复次数: {repeats}")
action_sequence.append(create_action_log(f"分离容器: {final_vessel_id}", "🧪"))
action_sequence.append(create_action_log(f"溶剂体积: {final_volume}mL", "📏"))
action_sequence.append(create_action_log(f"重复次数: {repeats}", "🔄"))
# 验证必需参数
if not purpose:
purpose = "separate"
if not product_phase:
product_phase = "top"
if purpose not in ["wash", "extract", "separate"]:
debug_print(f"⚠️ 未知的分离目的 '{purpose}',使用默认值 'separate'")
purpose = "separate"
action_sequence.append(create_action_log(f"未知目的,使用: {purpose}", "⚠️"))
if product_phase not in ["top", "bottom"]:
debug_print(f"⚠️ 未知的产物相 '{product_phase}',使用默认值 'top'")
product_phase = "top"
action_sequence.append(create_action_log(f"未知相别,使用: {product_phase}", "⚠️"))
debug_print("✅ 参数验证通过")
action_sequence.append(create_action_log("参数验证通过", ""))
# === 查找设备 ===
debug_print("🔍 步骤2: 查找设备...")
action_sequence.append(create_action_log("正在查找相关设备...", "🔍"))
# 查找分离器设备
separator_device = find_separator_device(G, final_vessel_id) # 🔧 使用 final_vessel_id
if separator_device:
action_sequence.append(create_action_log(f"找到分离器设备: {separator_device}", "🧪"))
else:
debug_print("⚠️ 未找到分离器设备,可能无法执行分离")
action_sequence.append(create_action_log("未找到分离器设备", "⚠️"))
# 查找搅拌器
stirrer_device = find_connected_stirrer(G, final_vessel_id) # 🔧 使用 final_vessel_id
if stirrer_device:
action_sequence.append(create_action_log(f"找到搅拌器: {stirrer_device}", "🌪️"))
else:
action_sequence.append(create_action_log("未找到搅拌器", "⚠️"))
# 查找溶剂容器(如果需要)
solvent_vessel = ""
if solvent and solvent.strip():
solvent_vessel = find_solvent_vessel(G, solvent)
if solvent_vessel:
action_sequence.append(create_action_log(f"找到溶剂容器: {solvent_vessel}", "💧"))
else:
action_sequence.append(create_action_log(f"未找到溶剂容器: {solvent}", "⚠️"))
debug_print(f"📊 设备配置:")
debug_print(f" 🧪 分离器设备: '{separator_device}'")
debug_print(f" 🌪️ 搅拌器设备: '{stirrer_device}'")
debug_print(f" 💧 溶剂容器: '{solvent_vessel}'")
# === 执行分离流程 ===
debug_print("🔍 步骤3: 执行分离流程...")
action_sequence.append(create_action_log("开始分离工作流程", "🎯"))
# 🔧 新增:体积变化跟踪变量
current_volume = original_liquid_volume
try:
for repeat_idx in range(repeats):
cycle_num = repeat_idx + 1
debug_print(f"🔄 第{cycle_num}轮: 开始分离循环 {cycle_num}/{repeats}")
action_sequence.append(create_action_log(f"分离循环 {cycle_num}/{repeats} 开始", "🔄"))
# 步骤3.1: 添加溶剂(如果需要)
if solvent_vessel and final_volume > 0:
debug_print(f"🔄 第{cycle_num}轮 步骤1: 添加溶剂 {solvent} ({final_volume}mL)")
action_sequence.append(create_action_log(f"向分离容器添加 {final_volume}mL {solvent}", "💧"))
try:
# 使用pump protocol添加溶剂
pump_actions = generate_pump_protocol_with_rinsing(
G=G,
from_vessel=solvent_vessel,
to_vessel=final_vessel_id, # 🔧 使用 final_vessel_id
volume=final_volume,
amount="",
time=0.0,
viscous=False,
rinsing_solvent="",
rinsing_volume=0.0,
rinsing_repeats=0,
solid=False,
flowrate=2.5,
transfer_flowrate=0.5,
rate_spec="",
event="",
through="",
**kwargs
)
action_sequence.extend(pump_actions)
debug_print(f"✅ 溶剂添加完成,添加了 {len(pump_actions)} 个动作")
action_sequence.append(create_action_log(f"溶剂转移完成 ({len(pump_actions)} 个操作)", ""))
# 🔧 新增:更新体积 - 添加溶剂后
current_volume += final_volume
update_vessel_volume(vessel, G, current_volume, f"添加{final_volume}mL {solvent}")
except Exception as e:
debug_print(f"❌ 溶剂添加失败: {str(e)}")
action_sequence.append(create_action_log(f"溶剂添加失败: {str(e)}", ""))
else:
debug_print(f"🔄 第{cycle_num}轮 步骤1: 无需添加溶剂")
action_sequence.append(create_action_log("无需添加溶剂", "⏭️"))
# 步骤3.2: 启动搅拌(如果有搅拌器)
if stirrer_device and stir_time > 0:
debug_print(f"🔄 第{cycle_num}轮 步骤2: 开始搅拌 ({stir_speed}rpm持续 {stir_time}s)")
action_sequence.append(create_action_log(f"开始搅拌: {stir_speed}rpm持续 {stir_time}s", "🌪️"))
action_sequence.append({
"device_id": stirrer_device,
"action_name": "start_stir",
"action_kwargs": {
"vessel": final_vessel_id, # 🔧 使用 final_vessel_id
"stir_speed": stir_speed,
"purpose": f"分离混合 - {purpose}"
}
})
# 搅拌等待
stir_minutes = stir_time / 60
action_sequence.append(create_action_log(f"搅拌中,持续 {stir_minutes:.1f} 分钟", "⏱️"))
action_sequence.append({
"action_name": "wait",
"action_kwargs": {"time": stir_time}
})
# 停止搅拌
action_sequence.append(create_action_log("停止搅拌器", "🛑"))
action_sequence.append({
"device_id": stirrer_device,
"action_name": "stop_stir",
"action_kwargs": {"vessel": final_vessel_id} # 🔧 使用 final_vessel_id
})
else:
debug_print(f"🔄 第{cycle_num}轮 步骤2: 无需搅拌")
action_sequence.append(create_action_log("无需搅拌", "⏭️"))
# 步骤3.3: 静置分层
if settling_time > 0:
debug_print(f"🔄 第{cycle_num}轮 步骤3: 静置分层 ({settling_time}s)")
settling_minutes = settling_time / 60
action_sequence.append(create_action_log(f"静置分层 ({settling_minutes:.1f} 分钟)", "⚖️"))
action_sequence.append({
"action_name": "wait",
"action_kwargs": {"time": settling_time}
})
else:
debug_print(f"🔄 第{cycle_num}轮 步骤3: 未指定静置时间")
action_sequence.append(create_action_log("未指定静置时间", "⏭️"))
# 步骤3.4: 执行分离操作
if separator_device:
debug_print(f"🔄 第{cycle_num}轮 步骤4: 执行分离操作")
action_sequence.append(create_action_log(f"执行分离: 收集{product_phase}", "🧪"))
# 调用分离器设备的separate方法
separate_action = {
"device_id": separator_device,
"action_name": "separate",
"action_kwargs": {
"purpose": purpose,
"product_phase": product_phase,
"from_vessel": extract_vessel_id(from_vessel) or final_vessel_id, # 🔧 使用vessel_id
"separation_vessel": final_vessel_id, # 🔧 使用 final_vessel_id
"to_vessel": final_to_vessel_id or final_vessel_id, # 🔧 使用vessel_id
"waste_phase_to_vessel": final_waste_vessel_id or final_vessel_id, # 🔧 使用vessel_id
"solvent": solvent,
"solvent_volume": final_volume,
"through": through,
"repeats": 1, # 每次调用只做一次分离
"stir_time": 0, # 已经在上面完成
"stir_speed": stir_speed,
"settling_time": 0 # 已经在上面完成
}
}
action_sequence.append(separate_action)
debug_print(f"✅ 分离操作已添加")
action_sequence.append(create_action_log("分离操作完成", ""))
# 🔧 新增:分离后体积估算(分离通常不改变总体积,但会重新分配)
# 假设分离后保持体积(实际情况可能有少量损失)
separated_volume = current_volume * 0.95 # 假设5%损失
update_vessel_volume(vessel, G, separated_volume, f"分离操作后(第{cycle_num}轮)")
current_volume = separated_volume
# 收集结果
if final_to_vessel_id:
action_sequence.append(create_action_log(f"产物 ({product_phase}相) 收集到: {final_to_vessel_id}", "📦"))
if final_waste_vessel_id:
action_sequence.append(create_action_log(f"废相收集到: {final_waste_vessel_id}", "🗑️"))
else:
debug_print(f"🔄 第{cycle_num}轮 步骤4: 无分离器设备,跳过分离")
action_sequence.append(create_action_log("无分离器设备可用", ""))
# 添加等待时间模拟分离
action_sequence.append({
"action_name": "wait",
"action_kwargs": {"time": 10.0}
})
# 循环间等待(除了最后一次)
if repeat_idx < repeats - 1:
debug_print(f"🔄 第{cycle_num}轮: 等待下一次循环...")
action_sequence.append(create_action_log("等待下一次循环...", ""))
action_sequence.append({
"action_name": "wait",
"action_kwargs": {"time": 5}
})
else:
action_sequence.append(create_action_log(f"分离循环 {cycle_num}/{repeats} 完成", "🌟"))
except Exception as e:
debug_print(f"❌ 分离工作流程执行失败: {str(e)}")
action_sequence.append(create_action_log(f"分离工作流程失败: {str(e)}", ""))
# 添加错误日志
action_sequence.append({
"device_id": "system",
"action_name": "log_message",
"action_kwargs": {
"message": f"分离操作失败: {str(e)}"
}
})
# 🔧 新增:分离完成后的最终状态报告
final_liquid_volume = get_vessel_liquid_volume(vessel)
# === 最终结果 ===
total_time = (stir_time + settling_time + 15) * repeats # 估算总时间
debug_print("🌀" * 20)
debug_print(f"🎉 分离协议生成完成")
debug_print(f"📊 协议统计:")
debug_print(f" 📋 总动作数: {len(action_sequence)}")
debug_print(f" ⏱️ 预计总时间: {total_time:.0f}s ({total_time/60:.1f} 分钟)")
debug_print(f" 🥼 分离容器: {final_vessel_id}")
debug_print(f" 🎯 分离目的: {purpose}")
debug_print(f" 📊 产物相: {product_phase}")
debug_print(f" 🔄 重复次数: {repeats}")
debug_print(f"💧 体积变化统计:")
debug_print(f" - 分离前体积: {original_liquid_volume:.2f}mL")
debug_print(f" - 分离后体积: {final_liquid_volume:.2f}mL")
if solvent:
debug_print(f" 💧 溶剂: {solvent} ({final_volume}mL × {repeats}轮 = {final_volume * repeats:.2f}mL)")
if final_to_vessel_id:
debug_print(f" 🎯 产物容器: {final_to_vessel_id}")
if final_waste_vessel_id:
debug_print(f" 🗑️ 废液容器: {final_waste_vessel_id}")
debug_print("🌀" * 20)
# 添加完成日志
summary_msg = f"分离协议完成: {final_vessel_id} ({purpose}{repeats} 次循环)"
if solvent:
summary_msg += f",使用 {final_volume * repeats:.2f}mL {solvent}"
action_sequence.append(create_action_log(summary_msg, "🎉"))
return action_sequence
def find_separation_vessel_bottom(G: nx.DiGraph, vessel_id: str) -> str:
"""
智能查找分离容器的底部容器假设为flask或vessel类型
Args:
G: 网络图
vessel_id: 分离容器ID
Returns:
str: 底部容器ID
"""
debug_print(f"🔍 查找分离容器 {vessel_id} 的底部容器...")
# 方法1根据命名规则推测
possible_bottoms = [
f"{vessel_id}_bottom",
f"flask_{vessel_id}",
f"vessel_{vessel_id}",
f"{vessel_id}_flask",
f"{vessel_id}_vessel"
]
debug_print(f"📋 尝试的底部容器名称: {possible_bottoms}")
for bottom_id in possible_bottoms:
if bottom_id in G.nodes():
node_type = G.nodes[bottom_id].get('type', '')
if node_type == 'container':
debug_print(f"✅ 通过命名规则找到底部容器: {bottom_id}")
return bottom_id
# 方法2查找与分离器相连的容器假设底部容器会与分离器相连
debug_print(f"📋 方法2: 查找连接的容器...")
for node in G.nodes():
node_data = G.nodes[node]
node_class = node_data.get('class', '') or ''
if 'separator' in node_class.lower():
# 检查分离器的输入端
if G.has_edge(node, vessel_id):
for neighbor in G.neighbors(node):
if neighbor != vessel_id:
neighbor_type = G.nodes[neighbor].get('type', '')
if neighbor_type == 'container':
debug_print(f"✅ 通过连接找到底部容器: {neighbor}")
return neighbor
debug_print(f"❌ 无法找到分离容器 {vessel_id} 的底部容器")
return ""

71
unilabos/compile/stir_protocol.py
View File

@@ -3,81 +3,14 @@ import networkx as nx
import logging
import re
from .utils.unit_parser import parse_time_input
logger = logging.getLogger(__name__)
def debug_print(message):
"""调试输出"""
print(f"🌪️ [STIR] {message}", flush=True)
logger.info(f"[STIR] {message}")
def parse_time_input(time_input: Union[str, float, int], default_unit: str = "s") -> float:
"""
统一的时间解析函数(精简版)
Args:
time_input: 时间输入(如 "30 min", "1 h", "300", "?", 60.0
default_unit: 默认单位(默认为秒)
Returns:
float: 时间(秒)
"""
if not time_input:
return 100.0 # 默认100秒
# 🔢 处理数值输入
if isinstance(time_input, (int, float)):
result = float(time_input)
debug_print(f"⏰ 数值时间: {time_input}{result}s")
return result
# 📝 处理字符串输入
time_str = str(time_input).lower().strip()
debug_print(f"🔍 解析时间: '{time_str}'")
# ❓ 特殊值处理
special_times = {
'?': 300.0, 'unknown': 300.0, 'tbd': 300.0,
'briefly': 30.0, 'quickly': 60.0, 'slowly': 600.0,
'several minutes': 300.0, 'few minutes': 180.0, 'overnight': 3600.0
}
if time_str in special_times:
result = special_times[time_str]
debug_print(f"🎯 特殊时间: '{time_str}'{result}s ({result/60:.1f}分钟)")
return result
# 🔢 纯数字处理
try:
result = float(time_str)
debug_print(f"⏰ 纯数字: {time_str}{result}s")
return result
except ValueError:
pass
# 📐 正则表达式解析
pattern = r'(\d+\.?\d*)\s*([a-z]*)'
match = re.match(pattern, time_str)
if not match:
debug_print(f"⚠️ 无法解析时间: '{time_str}',使用默认值: 100s")
return 100.0
value = float(match.group(1))
unit = match.group(2) or default_unit
# 📏 单位转换
unit_multipliers = {
's': 1.0, 'sec': 1.0, 'second': 1.0, 'seconds': 1.0,
'm': 60.0, 'min': 60.0, 'mins': 60.0, 'minute': 60.0, 'minutes': 60.0,
'h': 3600.0, 'hr': 3600.0, 'hrs': 3600.0, 'hour': 3600.0, 'hours': 3600.0,
'd': 86400.0, 'day': 86400.0, 'days': 86400.0
}
multiplier = unit_multipliers.get(unit, 1.0)
result = value * multiplier
debug_print(f"✅ 时间解析: '{time_str}'{value} {unit}{result}s ({result/60:.1f}分钟)")
return result
def find_connected_stirrer(G: nx.DiGraph, vessel: str = None) -> str:
"""查找与指定容器相连的搅拌设备"""

79
unilabos/compile/transfer_protocol.py
View File

@@ -1,79 +0,0 @@
from typing import List, Dict, Any
import networkx as nx
def generate_transfer_protocol(
G: nx.DiGraph,
from_vessel: str,
to_vessel: str,
volume: float,
amount: str = "",
time: float = 0,
viscous: bool = False,
rinsing_solvent: str = "",
rinsing_volume: float = 0.0,
rinsing_repeats: int = 0,
solid: bool = False
) -> List[Dict[str, Any]]:
"""
生成液体转移操作的协议序列
Args:
G: 有向图,节点为设备和容器
from_vessel: 源容器
to_vessel: 目标容器
volume: 转移体积 (mL)
amount: 数量描述 (可选)
time: 转移时间 (秒,可选)
viscous: 是否为粘性液体
rinsing_solvent: 冲洗溶剂 (可选)
rinsing_volume: 冲洗体积 (mL可选)
rinsing_repeats: 冲洗重复次数
solid: 是否涉及固体
Returns:
List[Dict[str, Any]]: 转移操作的动作序列
Raises:
ValueError: 当找不到合适的转移设备时抛出异常
Examples:
transfer_protocol = generate_transfer_protocol(G, "flask_1", "reactor", 10.0)
"""
action_sequence = []
# 查找虚拟转移泵设备用于液体转移 - 修复:应该查找 virtual_transfer_pump
pump_nodes = [node for node in G.nodes()
if G.nodes[node].get('class') == 'virtual_transfer_pump']
if not pump_nodes:
raise ValueError("没有找到可用的转移泵设备进行液体转移")
# 使用第一个可用的泵
pump_id = pump_nodes[0]
# 验证容器是否存在
if from_vessel not in G.nodes():
raise ValueError(f"源容器 {from_vessel} 不存在于图中")
if to_vessel not in G.nodes():
raise ValueError(f"目标容器 {to_vessel} 不存在于图中")
# 执行液体转移操作 - 参数完全匹配Transfer.action
action_sequence.append({
"device_id": pump_id,
"action_name": "transfer",
"action_kwargs": {
"from_vessel": from_vessel,
"to_vessel": to_vessel,
"volume": volume,
"amount": amount,
"time": time,
"viscous": viscous,
"rinsing_solvent": rinsing_solvent,
"rinsing_volume": rinsing_volume,
"rinsing_repeats": rinsing_repeats,
"solid": solid
}
})
return action_sequence

0
unilabos/devices/laiyu_add_solid/__init__.py → unilabos/compile/utils/__init__.py
View File

36
unilabos/compile/utils/logger_util.py Normal file
View File

@@ -0,0 +1,36 @@
# 🆕 创建进度日志动作
import logging
from typing import Dict, Any
logger = logging.getLogger(__name__)
def debug_print(message, prefix="[UNIT_PARSER]"):
"""调试输出"""
logger.info(f"{prefix} {message}")
def action_log(message: str, emoji: str = "📝", prefix="[HIGH-LEVEL OPERATION]") -> Dict[str, Any]:
"""创建一个动作日志 - 支持中文和emoji"""
try:
full_message = f"{prefix} {emoji} {message}"
return {
"action_name": "wait",
"action_kwargs": {
"time": 0.1,
"log_message": full_message,
"progress_message": full_message
}
}
except Exception as e:
# 如果emoji有问题使用纯文本
safe_message = f"{prefix} {message}"
return {
"action_name": "wait",
"action_kwargs": {
"time": 0.1,
"log_message": safe_message,
"progress_message": safe_message
}
}

209
unilabos/compile/utils/unit_parser.py
View File

@@ -4,108 +4,12 @@
"""
import re
import logging
from typing import Union
logger = logging.getLogger(__name__)
from .logger_util import debug_print
def debug_print(message, prefix="[UNIT_PARSER]"):
"""调试输出"""
print(f"{prefix} {message}", flush=True)
logger.info(f"{prefix} {message}")
def parse_time_with_units(time_input: Union[str, float, int], default_unit: str = "s") -> float:
"""
解析带单位的时间输入
Args:
time_input: 时间输入(如 "30 min", "1 h", "300", "?", 60.0
default_unit: 默认单位(默认为秒)
Returns:
float: 时间(秒)
"""
if not time_input:
return 0.0
# 处理数值输入
if isinstance(time_input, (int, float)):
result = float(time_input)
debug_print(f"数值时间输入: {time_input}{result}s默认单位")
return result
# 处理字符串输入
time_str = str(time_input).lower().strip()
debug_print(f"解析时间字符串: '{time_str}'")
# 处理特殊值
if time_str in ['?', 'unknown', 'tbd', 'to be determined']:
default_time = 300.0 # 5分钟默认值
debug_print(f"检测到未知时间,使用默认值: {default_time}s")
return default_time
# 如果是纯数字,使用默认单位
try:
value = float(time_str)
if default_unit == "s":
result = value
elif default_unit in ["min", "minute"]:
result = value * 60.0
elif default_unit in ["h", "hour"]:
result = value * 3600.0
else:
result = value # 默认秒
debug_print(f"纯数字输入: {time_str}{result}s单位: {default_unit}")
return result
except ValueError:
pass
# 使用正则表达式匹配数字和单位
pattern = r'(\d+\.?\d*)\s*([a-z]*)'
match = re.match(pattern, time_str)
if not match:
debug_print(f"⚠️ 无法解析时间: '{time_str}',使用默认值: 60s")
return 60.0
value = float(match.group(1))
unit = match.group(2) or default_unit
# 单位转换映射
unit_multipliers = {
# 秒
's': 1.0,
'sec': 1.0,
'second': 1.0,
'seconds': 1.0,
# 分钟
'm': 60.0,
'min': 60.0,
'mins': 60.0,
'minute': 60.0,
'minutes': 60.0,
# 小时
'h': 3600.0,
'hr': 3600.0,
'hrs': 3600.0,
'hour': 3600.0,
'hours': 3600.0,
# 天
'd': 86400.0,
'day': 86400.0,
'days': 86400.0,
}
multiplier = unit_multipliers.get(unit, 1.0)
result = value * multiplier
debug_print(f"时间解析: '{time_str}'{value} {unit}{result}s")
return result
def parse_volume_with_units(volume_input: Union[str, float, int], default_unit: str = "mL") -> float:
def parse_volume_input(volume_input: Union[str, float, int], default_unit: str = "mL") -> float:
"""
解析带单位的体积输入
@@ -175,6 +79,111 @@ def parse_volume_with_units(volume_input: Union[str, float, int], default_unit:
debug_print(f"体积解析: '{volume_str}'{value} {unit}{volume}mL")
return volume
def parse_mass_input(mass_input: Union[str, float]) -> float:
"""
解析质量输入,支持带单位的字符串
Args:
mass_input: 质量输入(如 "19.3 g", "4.5 g", 2.5
Returns:
float: 质量(克)
"""
if isinstance(mass_input, (int, float)):
debug_print(f"⚖️ 质量输入为数值: {mass_input}g")
return float(mass_input)
if not mass_input or not str(mass_input).strip():
debug_print(f"⚠️ 质量输入为空返回0.0g")
return 0.0
mass_str = str(mass_input).lower().strip()
debug_print(f"🔍 解析质量输入: '{mass_str}'")
# 移除空格并提取数字和单位
mass_clean = re.sub(r'\s+', '', mass_str)
# 匹配数字和单位的正则表达式
match = re.match(r'([0-9]*\.?[0-9]+)\s*(g|mg|kg|gram|milligram|kilogram)?', mass_clean)
if not match:
debug_print(f"❌ 无法解析质量: '{mass_str}'返回0.0g")
return 0.0
value = float(match.group(1))
unit = match.group(2) or 'g' # 默认单位为克
# 转换为克
if unit in ['mg', 'milligram']:
mass = value / 1000.0 # mg -> g
debug_print(f"🔄 质量转换: {value}mg → {mass}g")
elif unit in ['kg', 'kilogram']:
mass = value * 1000.0 # kg -> g
debug_print(f"🔄 质量转换: {value}kg → {mass}g")
else: # g, gram 或默认
mass = value # 已经是g
debug_print(f"✅ 质量已为g: {mass}g")
return mass
def parse_time_input(time_input: Union[str, float]) -> float:
"""
解析时间输入,支持带单位的字符串
Args:
time_input: 时间输入(如 "1 h", "20 min", "30 s", 60.0
Returns:
float: 时间(秒)
"""
if isinstance(time_input, (int, float)):
debug_print(f"⏱️ 时间输入为数值: {time_input}")
return float(time_input)
if not time_input or not str(time_input).strip():
debug_print(f"⚠️ 时间输入为空返回0秒")
return 0.0
time_str = str(time_input).lower().strip()
debug_print(f"🔍 解析时间输入: '{time_str}'")
# 处理未知时间
if time_str in ['?', 'unknown', 'tbd']:
default_time = 60.0 # 默认1分钟
debug_print(f"❓ 检测到未知时间,使用默认值: {default_time}s (1分钟) ⏰")
return default_time
# 移除空格并提取数字和单位
time_clean = re.sub(r'\s+', '', time_str)
# 匹配数字和单位的正则表达式
match = re.match(r'([0-9]*\.?[0-9]+)\s*(s|sec|second|min|minute|h|hr|hour|d|day)?', time_clean)
if not match:
debug_print(f"❌ 无法解析时间: '{time_str}'返回0s")
return 0.0
value = float(match.group(1))
unit = match.group(2) or 's' # 默认单位为秒
# 转换为秒
if unit in ['m', 'min', 'minute', 'mins', 'minutes']:
time_sec = value * 60.0 # min -> s
debug_print(f"🔄 时间转换: {value}分钟 → {time_sec}")
elif unit in ['h', 'hr', 'hour', 'hrs', 'hours']:
time_sec = value * 3600.0 # h -> s
debug_print(f"🔄 时间转换: {value}小时 → {time_sec}")
elif unit in ['d', 'day', 'days']:
time_sec = value * 86400.0 # d -> s
debug_print(f"🔄 时间转换: {value}天 → {time_sec}")
else: # s, sec, second 或默认
time_sec = value # 已经是s
debug_print(f"✅ 时间已为秒: {time_sec}")
return time_sec
# 测试函数
def test_unit_parser():
"""测试单位解析功能"""
@@ -187,7 +196,7 @@ def test_unit_parser():
print("\n时间解析测试:")
for time_input in time_tests:
result = parse_time_with_units(time_input)
result = parse_time_input(time_input)
print(f" {time_input}{result}s ({result/60:.1f}min)")
# 测试体积解析
@@ -197,7 +206,7 @@ def test_unit_parser():
print("\n体积解析测试:")
for volume_input in volume_tests:
result = parse_volume_with_units(volume_input)
result = parse_volume_input(volume_input)
print(f" {volume_input}{result}mL")
print("\n✅ 测试完成")

281
unilabos/compile/utils/vessel_parser.py Normal file
View File

@@ -0,0 +1,281 @@
import networkx as nx
from .logger_util import debug_print
def get_vessel(vessel):
"""
统一处理vessel参数返回vessel_id和vessel_data。
Args:
vessel: 可以是一个字典或字符串表示vessel的ID或数据。
Returns:
tuple: 包含vessel_id和vessel_data。
"""
if isinstance(vessel, dict):
if "id" not in vessel:
vessel_id = list(vessel.values())[0].get("id", "")
else:
vessel_id = vessel.get("id", "")
vessel_data = vessel.get("data", {})
else:
vessel_id = str(vessel)
vessel_data = {}
return vessel_id, vessel_data
def find_reagent_vessel(G: nx.DiGraph, reagent: str) -> str:
"""增强版试剂容器查找,支持固体和液体"""
debug_print(f"🔍 开始查找试剂 '{reagent}' 的容器...")
# 🔧 方法1直接搜索 data.reagent_name 和 config.reagent
debug_print(f"📋 方法1: 搜索reagent字段...")
for node in G.nodes():
node_data = G.nodes[node].get('data', {})
node_type = G.nodes[node].get('type', '')
config_data = G.nodes[node].get('config', {})
# 只搜索容器类型的节点
if node_type == 'container':
reagent_name = node_data.get('reagent_name', '').lower()
config_reagent = config_data.get('reagent', '').lower()
# 精确匹配
if reagent_name == reagent.lower() or config_reagent == reagent.lower():
debug_print(f"✅ 通过reagent字段精确匹配到容器: {node} 🎯")
return node
# 模糊匹配
if (reagent.lower() in reagent_name and reagent_name) or \
(reagent.lower() in config_reagent and config_reagent):
debug_print(f"✅ 通过reagent字段模糊匹配到容器: {node} 🔍")
return node
# 🔧 方法2常见的容器命名规则
debug_print(f"📋 方法2: 使用命名规则查找...")
reagent_clean = reagent.lower().replace(' ', '_').replace('-', '_')
possible_names = [
reagent_clean,
f"flask_{reagent_clean}",
f"bottle_{reagent_clean}",
f"vessel_{reagent_clean}",
f"{reagent_clean}_flask",
f"{reagent_clean}_bottle",
f"reagent_{reagent_clean}",
f"reagent_bottle_{reagent_clean}",
f"solid_reagent_bottle_{reagent_clean}",
f"reagent_bottle_1", # 通用试剂瓶
f"reagent_bottle_2",
f"reagent_bottle_3"
]
debug_print(f"🔍 尝试的容器名称: {possible_names[:5]}... (共{len(possible_names)}个)")
for name in possible_names:
if name in G.nodes():
node_type = G.nodes[name].get('type', '')
if node_type == 'container':
debug_print(f"✅ 通过命名规则找到容器: {name} 📝")
return name
# 🔧 方法3节点名称模糊匹配
debug_print(f"📋 方法3: 节点名称模糊匹配...")
for node_id in G.nodes():
node_data = G.nodes[node_id]
if node_data.get('type') == 'container':
# 检查节点名称是否包含试剂名称
if reagent_clean in node_id.lower():
debug_print(f"✅ 通过节点名称模糊匹配到容器: {node_id} 🔍")
return node_id
# 检查液体类型匹配
vessel_data = node_data.get('data', {})
liquids = vessel_data.get('liquid', [])
for liquid in liquids:
if isinstance(liquid, dict):
liquid_type = liquid.get('liquid_type') or liquid.get('name', '')
if liquid_type.lower() == reagent.lower():
debug_print(f"✅ 通过液体类型匹配到容器: {node_id} 💧")
return node_id
# 🔧 方法4使用第一个试剂瓶作为备选
debug_print(f"📋 方法4: 查找备选试剂瓶...")
for node_id in G.nodes():
node_data = G.nodes[node_id]
if (node_data.get('type') == 'container' and
('reagent' in node_id.lower() or 'bottle' in node_id.lower())):
debug_print(f"⚠️ 未找到专用容器,使用备选试剂瓶: {node_id} 🔄")
return node_id
debug_print(f"❌ 所有方法都失败了,无法找到容器!")
raise ValueError(f"找不到试剂 '{reagent}' 对应的容器")
def find_solvent_vessel(G: nx.DiGraph, solvent: str) -> str:
"""
查找溶剂容器
Args:
G: 网络图
solvent: 溶剂名称
Returns:
str: 溶剂容器ID
"""
debug_print(f"🔍 正在查找溶剂 '{solvent}' 的容器... 🧪")
# 第四步:通过数据中的试剂信息匹配
debug_print(" 🧪 步骤1: 数据试剂信息匹配...")
for node_id in G.nodes():
debug_print(f"查找 id {node_id}, type={G.nodes[node_id].get('type')}, data={G.nodes[node_id].get('data', {})} 的容器...")
if G.nodes[node_id].get('type') == 'container':
vessel_data = G.nodes[node_id].get('data', {})
# 检查 data 中的 reagent_name 字段
reagent_name = vessel_data.get('reagent_name', '').lower()
if reagent_name and solvent.lower() == reagent_name:
debug_print(f" 🎉 通过data.reagent_name匹配找到容器: {node_id} (试剂: {reagent_name}) ✨")
return node_id
# 检查 data 中的液体信息
liquids = vessel_data.get('liquid', []) or vessel_data.get('liquids', [])
for liquid in liquids:
if isinstance(liquid, dict):
liquid_type = (liquid.get('liquid_type') or liquid.get('name', '')).lower()
if solvent.lower() == liquid_type or solvent.lower() in liquid_type:
debug_print(f" 🎉 通过液体类型匹配找到容器: {node_id} (液体类型: {liquid_type}) ✨")
return node_id
# 构建可能的容器名称
possible_names = [
f"flask_{solvent}",
f"bottle_{solvent}",
f"reagent_{solvent}",
f"reagent_bottle_{solvent}",
f"{solvent}_flask",
f"{solvent}_bottle",
f"{solvent}",
f"vessel_{solvent}",
]
debug_print(f"📋 候选容器名称: {possible_names[:3]}... (共{len(possible_names)}个) 📝")
# 第一步:通过容器名称匹配
debug_print(" 🎯 步骤2: 精确名称匹配...")
for vessel_name in possible_names:
if vessel_name in G.nodes():
debug_print(f" 🎉 通过名称匹配找到容器: {vessel_name}")
return vessel_name
# 第二步通过模糊匹配节点ID和名称
debug_print(" 🔍 步骤3: 模糊名称匹配...")
for node_id in G.nodes():
if G.nodes[node_id].get('type') == 'container':
node_name = G.nodes[node_id].get('name', '').lower()
if solvent.lower() in node_id.lower() or solvent.lower() in node_name:
debug_print(f" 🎉 通过模糊匹配找到容器: {node_id} (名称: {node_name}) ✨")
return node_id
# 第三步:通过配置中的试剂信息匹配
debug_print(" 🧪 步骤4: 配置试剂信息匹配...")
for node_id in G.nodes():
if G.nodes[node_id].get('type') == 'container':
# 检查 config 中的 reagent 字段
node_config = G.nodes[node_id].get('config', {})
config_reagent = node_config.get('reagent', '').lower()
if config_reagent and solvent.lower() == config_reagent:
debug_print(f" 🎉 通过config.reagent匹配找到容器: {node_id} (试剂: {config_reagent}) ✨")
return node_id
# 第五步:部分匹配(如果前面都没找到)
debug_print(" 🔍 步骤5: 部分匹配...")
for node_id in G.nodes():
if G.nodes[node_id].get('type') == 'container':
node_config = G.nodes[node_id].get('config', {})
node_data = G.nodes[node_id].get('data', {})
node_name = G.nodes[node_id].get('name', '').lower()
config_reagent = node_config.get('reagent', '').lower()
data_reagent = node_data.get('reagent_name', '').lower()
# 检查是否包含溶剂名称
if (solvent.lower() in config_reagent or
solvent.lower() in data_reagent or
solvent.lower() in node_name or
solvent.lower() in node_id.lower()):
debug_print(f" 🎉 通过部分匹配找到容器: {node_id}")
debug_print(f" - 节点名称: {node_name}")
debug_print(f" - 配置试剂: {config_reagent}")
debug_print(f" - 数据试剂: {data_reagent}")
return node_id
# 调试信息:列出所有容器
debug_print(" 🔎 调试信息:列出所有容器...")
container_list = []
for node_id in G.nodes():
if G.nodes[node_id].get('type') == 'container':
node_config = G.nodes[node_id].get('config', {})
node_data = G.nodes[node_id].get('data', {})
node_name = G.nodes[node_id].get('name', '')
container_info = {
'id': node_id,
'name': node_name,
'config_reagent': node_config.get('reagent', ''),
'data_reagent': node_data.get('reagent_name', '')
}
container_list.append(container_info)
debug_print(
f" - 容器: {node_id}, 名称: {node_name}, config试剂: {node_config.get('reagent', '')}, data试剂: {node_data.get('reagent_name', '')}")
debug_print(f"❌ 找不到溶剂 '{solvent}' 对应的容器 😭")
debug_print(f"🔍 查找的溶剂: '{solvent}' (小写: '{solvent.lower()}')")
debug_print(f"📊 总共发现 {len(container_list)} 个容器")
raise ValueError(f"找不到溶剂 '{solvent}' 对应的容器")
def find_connected_stirrer(G: nx.DiGraph, vessel: str) -> str:
"""查找连接到指定容器的搅拌器"""
debug_print(f"🔍 查找连接到容器 '{vessel}' 的搅拌器...")
stirrer_nodes = []
for node in G.nodes():
node_class = G.nodes[node].get('class', '').lower()
if 'stirrer' in node_class:
stirrer_nodes.append(node)
debug_print(f"📋 发现搅拌器: {node}")
debug_print(f"📊 共找到 {len(stirrer_nodes)} 个搅拌器")
# 查找连接到容器的搅拌器
for stirrer in stirrer_nodes:
if G.has_edge(stirrer, vessel) or G.has_edge(vessel, stirrer):
debug_print(f"✅ 找到连接的搅拌器: {stirrer} 🔗")
return stirrer
# 返回第一个搅拌器
if stirrer_nodes:
debug_print(f"⚠️ 未找到直接连接的搅拌器,使用第一个: {stirrer_nodes[0]} 🔄")
return stirrer_nodes[0]
debug_print(f"❌ 未找到任何搅拌器")
return ""
def find_solid_dispenser(G: nx.DiGraph) -> str:
"""查找固体加样器"""
debug_print(f"🔍 查找固体加样器...")
for node in G.nodes():
node_class = G.nodes[node].get('class', '').lower()
if 'solid_dispenser' in node_class or 'dispenser' in node_class:
debug_print(f"✅ 找到固体加样器: {node} 🥄")
return node
debug_print(f"❌ 未找到固体加样器")
return ""

108
unilabos/compile/wash_solid_protocol.py
View File

@@ -3,118 +3,14 @@ import networkx as nx
import logging
import re
from .utils.unit_parser import parse_time_input, parse_volume_input
logger = logging.getLogger(__name__)
def debug_print(message):
"""调试输出"""
print(f"🧼 [WASH_SOLID] {message}", flush=True)
logger.info(f"[WASH_SOLID] {message}")
def parse_time_input(time_input: Union[str, float, int]) -> float:
"""统一时间解析函数(精简版)"""
if not time_input:
return 0.0
# 🔢 处理数值输入
if isinstance(time_input, (int, float)):
result = float(time_input)
debug_print(f"⏰ 数值时间: {time_input}{result}s")
return result
# 📝 处理字符串输入
time_str = str(time_input).lower().strip()
# ❓ 特殊值快速处理
special_times = {
'?': 60.0, 'unknown': 60.0, 'briefly': 30.0,
'quickly': 45.0, 'slowly': 120.0
}
if time_str in special_times:
result = special_times[time_str]
debug_print(f"🎯 特殊时间: '{time_str}'{result}s")
return result
# 🔢 数字提取(简化正则)
try:
# 提取数字
numbers = re.findall(r'\d+\.?\d*', time_str)
if numbers:
value = float(numbers[0])
# 简化单位判断
if any(unit in time_str for unit in ['min', 'm']):
result = value * 60.0
elif any(unit in time_str for unit in ['h', 'hour']):
result = value * 3600.0
else:
result = value # 默认秒
debug_print(f"✅ 时间解析: '{time_str}'{result}s")
return result
except:
pass
debug_print(f"⚠️ 时间解析失败: '{time_str}'使用默认60s")
return 60.0
def parse_volume_input(volume: Union[float, str], volume_spec: str = "", mass: str = "") -> float:
"""统一体积解析函数(精简版)"""
debug_print(f"💧 解析体积: volume={volume}, spec='{volume_spec}', mass='{mass}'")
# 🎯 优先级1volume_spec快速映射
if volume_spec:
spec_map = {
'small': 20.0, 'medium': 50.0, 'large': 100.0,
'minimal': 10.0, 'normal': 50.0, 'generous': 150.0
}
for key, val in spec_map.items():
if key in volume_spec.lower():
debug_print(f"🎯 规格匹配: '{volume_spec}'{val}mL")
return val
# 🧮 优先级2mass转体积简化1g=1mL
if mass:
try:
numbers = re.findall(r'\d+\.?\d*', mass)
if numbers:
value = float(numbers[0])
if 'mg' in mass.lower():
result = value / 1000.0
elif 'kg' in mass.lower():
result = value * 1000.0
else:
result = value # 默认g
debug_print(f"⚖️ 质量转换: {mass}{result}mL")
return result
except:
pass
# 📦 优先级3volume
if volume:
if isinstance(volume, (int, float)):
result = float(volume)
debug_print(f"💧 数值体积: {volume}{result}mL")
return result
elif isinstance(volume, str):
try:
# 提取数字
numbers = re.findall(r'\d+\.?\d*', volume)
if numbers:
value = float(numbers[0])
# 简化单位判断
if 'l' in volume.lower() and 'ml' not in volume.lower():
result = value * 1000.0 # L转mL
else:
result = value # 默认mL
debug_print(f"💧 字符串体积: '{volume}'{result}mL")
return result
except:
pass
# 默认值
debug_print(f"⚠️ 体积解析失败使用默认50mL")
return 50.0
def find_solvent_source(G: nx.DiGraph, solvent: str) -> str:
"""查找溶剂源(精简版)"""

65
unilabos/config/config.py
View File

@@ -1,14 +1,18 @@
#!/usr/bin/env python
# coding=utf-8
# 定义配置变量和加载函数
import base64
import traceback
import os
import importlib.util
from typing import Optional
from unilabos.utils import logger
class BasicConfig:
ENV = "pro" # 'test'
ak = ""
sk = ""
working_dir = ""
config_path = ""
is_host_mode = True
@@ -17,6 +21,17 @@ class BasicConfig:
machine_name = "undefined"
vis_2d_enable = False
enable_resource_load = True
# 通信协议配置
communication_protocol = "mqtt" # 支持: "mqtt", "websocket"
@classmethod
def auth_secret(cls):
# base64编码
if not cls.ak or not cls.sk:
return ""
target = f"{cls.ak}:{cls.sk}"
base64_target = base64.b64encode(target.encode("utf-8")).decode("utf-8")
return base64_target
# MQTT配置
@@ -38,6 +53,13 @@ class MQConfig:
key_file = "" # 相对config.py所在目录的路径
# WebSocket配置
class WSConfig:
reconnect_interval = 5 # 重连间隔(秒)
max_reconnect_attempts = 999 # 最大重连次数
ping_interval = 30 # ping间隔
# OSS上传配置
class OSSUploadConfig:
api_host = ""
@@ -65,7 +87,7 @@ class ROSConfig:
]
def _update_config_from_module(module, override_labid: str):
def _update_config_from_module(module):
for name, obj in globals().items():
if isinstance(obj, type) and name.endswith("Config"):
if hasattr(module, name) and isinstance(getattr(module, name), type):
@@ -74,39 +96,7 @@ def _update_config_from_module(module, override_labid: str):
setattr(obj, attr, getattr(getattr(module, name), attr))
# 更新OSS认证
if len(OSSUploadConfig.authorization) == 0:
OSSUploadConfig.authorization = f"lab {MQConfig.lab_id}"
# 对 ca_file cert_file key_file 进行初始化
if override_labid:
MQConfig.lab_id = override_labid
logger.warning(f"[ENV] 当前实验室启动的ID被设置为{override_labid}")
if len(MQConfig.ca_content) == 0:
# 需要先判断是否为相对路径
if MQConfig.ca_file.startswith("."):
MQConfig.ca_file = os.path.join(BasicConfig.config_path, MQConfig.ca_file)
if len(MQConfig.ca_file) != 0:
with open(MQConfig.ca_file, "r", encoding="utf-8") as f:
MQConfig.ca_content = f.read()
else:
logger.warning("Skipping CA file loading, ca_file is empty")
if len(MQConfig.cert_content) == 0:
# 需要先判断是否为相对路径
if MQConfig.cert_file.startswith("."):
MQConfig.cert_file = os.path.join(BasicConfig.config_path, MQConfig.cert_file)
if len(MQConfig.ca_file) != 0:
with open(MQConfig.cert_file, "r", encoding="utf-8") as f:
MQConfig.cert_content = f.read()
else:
logger.warning("Skipping cert file loading, cert_file is empty")
if len(MQConfig.key_content) == 0:
# 需要先判断是否为相对路径
if MQConfig.key_file.startswith("."):
MQConfig.key_file = os.path.join(BasicConfig.config_path, MQConfig.key_file)
if len(MQConfig.ca_file) != 0:
with open(MQConfig.key_file, "r", encoding="utf-8") as f:
MQConfig.key_content = f.read()
else:
logger.warning("Skipping key file loading, key_file is empty")
OSSUploadConfig.authorization = f"Lab {MQConfig.lab_id}"
def _update_config_from_env():
prefix = "UNILABOS_"
@@ -159,8 +149,7 @@ def _update_config_from_env():
logger.warning(f"[ENV] 解析环境变量 {env_key} 失败: {e}")
def load_config(config_path=None, override_labid=None):
def load_config(config_path=None):
# 如果提供了配置文件路径,从该文件导入配置
if config_path:
env_config_path = os.environ.get("UNILABOS_BASICCONFIG_CONFIG_PATH")
@@ -177,7 +166,7 @@ def load_config(config_path=None, override_labid=None):
return
module = importlib.util.module_from_spec(spec)
spec.loader.exec_module(module) # type: ignore
_update_config_from_module(module, override_labid)
_update_config_from_module(module)
logger.info(f"[ENV] 配置文件 {config_path} 加载成功")
_update_config_from_env()
except Exception as e:
@@ -186,4 +175,4 @@ def load_config(config_path=None, override_labid=None):
exit(1)
else:
config_path = os.path.join(os.path.dirname(__file__), "local_config.py")
load_config(config_path, override_labid)
load_config(config_path)

18
unilabos/config/example_config.py
View File

@@ -1,17 +1 @@
# MQTT配置
class MQConfig:
lab_id = ""
instance_id = ""
access_key = ""
secret_key = ""
group_id = ""
broker_url = ""
port = 1883
ca_file = "./CA.crt"
cert_file = "./lab.crt"
key_file = "./lab.key"
# HTTP配置
class HTTPConfig:
remote_addr = "https://uni-lab.bohrium.com/api/v1"
# 暂无配置

63
unilabos/devices/liquid_handling/liquid_handler_abstract.py
View File

@@ -1,11 +1,11 @@
from __future__ import annotations
import traceback
from typing import List, Sequence, Optional, Literal, Union, Iterator, Dict, Any, Callable, Set
from typing import List, Sequence, Optional, Literal, Union, Iterator, Dict, Any, Callable, Set, cast
from collections import Counter
import asyncio
import time
import pprint as pp
from pylabrobot.liquid_handling import LiquidHandler, LiquidHandlerBackend, LiquidHandlerChatterboxBackend, Strictness
from pylabrobot.liquid_handling.liquid_handler import TipPresenceProbingMethod
from pylabrobot.liquid_handling.standard import GripDirection
@@ -29,6 +29,7 @@ from pylabrobot.resources import (
class LiquidHandlerMiddleware(LiquidHandler):
def __init__(self, backend: LiquidHandlerBackend, deck: Deck, simulator: bool = False, channel_num: int = 8):
self._simulator = simulator
self.channel_num = channel_num
if simulator:
self._simulate_backend = LiquidHandlerChatterboxBackend(channel_num)
self._simulate_handler = LiquidHandlerAbstract(self._simulate_backend, deck, False)
@@ -104,8 +105,7 @@ class LiquidHandlerMiddleware(LiquidHandler):
offsets: Optional[List[Coordinate]] = None,
**backend_kwargs,
):
print('222'*200)
print(tip_spots)
if self._simulator:
return await self._simulate_handler.pick_up_tips(tip_spots, use_channels, offsets, **backend_kwargs)
return await super().pick_up_tips(tip_spots, use_channels, offsets, **backend_kwargs)
@@ -138,6 +138,8 @@ class LiquidHandlerMiddleware(LiquidHandler):
offsets: Optional[List[Coordinate]] = None,
**backend_kwargs,
):
if not offsets or (isinstance(offsets, list) and len(offsets) != len(use_channels)):
offsets = [Coordinate.zero()] * len(use_channels)
if self._simulator:
return await self._simulate_handler.discard_tips(use_channels, allow_nonzero_volume, offsets, **backend_kwargs)
return await super().discard_tips(use_channels, allow_nonzero_volume, offsets, **backend_kwargs)
@@ -543,6 +545,7 @@ class LiquidHandlerAbstract(LiquidHandlerMiddleware):
deck: Deck to use.
"""
self._simulator = simulator
self.group_info = dict()
super().__init__(backend, deck, simulator, channel_num)
@classmethod
@@ -554,6 +557,51 @@ class LiquidHandlerAbstract(LiquidHandlerMiddleware):
# REMOVE LIQUID --------------------------------------------------
# ---------------------------------------------------------------
def set_group(self, group_name: str, wells: List[Well], volumes: List[float]):
if len(wells) != 8:
raise RuntimeError(f"Expected 8 wells, got {len(wells)}")
self.group_info[group_name] = wells
self.set_liquid(wells, [group_name] * len(wells), volumes)
async def transfer_group(self, source_group_name: str, target_group_name: str, unit_volume: float):
source_wells = self.group_info.get(source_group_name, [])
target_wells = self.group_info.get(target_group_name, [])
rack_info = dict()
for child in self.deck.children:
if issubclass(child.__class__, TipRack):
rack: TipRack = cast(TipRack, child)
if "plate" not in rack.name.lower():
for tip in rack.get_all_tips():
if unit_volume > tip.maximal_volume:
break
else:
rack_info[rack.name] = (rack, tip.maximal_volume - unit_volume)
if len(rack_info) == 0:
raise ValueError(f"No tip rack can support volume {unit_volume}.")
rack_info = sorted(rack_info.items(), key=lambda x: x[1][1])
for child in self.deck.children:
if child.name == rack_info[0][0]:
target_rack = child
target_rack = cast(TipRack, target_rack)
available_tips = {}
for (idx, name), tipSpot in zip(target_rack._ordering.items(), target_rack.get_all_items()):
if tipSpot.has_tip():
available_tips[idx] = tipSpot
continue
colnum_list = [int(holename[1:]) for holename in available_tips.keys()]
available_cols = [colnum for colnum, count in dict(Counter(colnum_list)).items() if count == 8]
available_cols.sort() # 这样就确定了列号
tips_to_use = [available_tips[f"{chr(65 + i)}{available_cols[0]}"] for i in range(8)]
await self.pick_up_tips(tips_to_use, use_channels=list(range(0, 8)))
await self.aspirate(source_wells, [10] * 8, use_channels=list(range(0, 8)))
await self.dispense(target_wells, [10] * 8, use_channels=list(range(0, 8)))
await self.discard_tips(use_channels=list(range(0, 8)))
async def create_protocol(
self,
protocol_name: str,
@@ -567,6 +615,7 @@ class LiquidHandlerAbstract(LiquidHandlerMiddleware):
"""Create a new protocol with the given metadata."""
pass
async def remove_liquid(
self,
vols: List[float],
@@ -985,8 +1034,8 @@ class LiquidHandlerAbstract(LiquidHandlerMiddleware):
if delays is not None:
await self.custom_delay(seconds=delays[1])
await self.touch_tip(current_targets)
await self.discard_tips()
await self.discard_tips([0,1,2,3,4,5,6,7])
# except Exception as e:
# traceback.print_exc()
# raise RuntimeError(f"Liquid addition failed: {e}") from e

0
unilabos/devices/mock/__init__.py → unilabos/devices/liquid_handling/prcxi/__init__.py
View File

753
unilabos/devices/liquid_handling/prcxi/prcxi.py
View File

@@ -67,7 +67,7 @@ class PRCXI9300Deck(Deck):
class PRCXI9300Container(Plate, TipRack):
"""PRCXI 9300 的专用 Deck 类,继承自 Deck。
"""PRCXI 9300 的专用 Container 类,继承自 Plate和TipRack。
该类定义了 PRCXI 9300 的工作台布局和槽位信息。
"""
@@ -134,6 +134,12 @@ class PRCXI9300Handler(LiquidHandlerAbstract):
def set_liquid(self, wells: list[Well], liquid_names: list[str], volumes: list[float]):
return super().set_liquid(wells, liquid_names, volumes)
def set_group(self, group_name: str, wells: List[Well], volumes: List[float]):
return super().set_group(group_name, wells, volumes)
async def transfer_group(self, source_group_name: str, target_group_name: str, unit_volume: float):
return await super().transfer_group(source_group_name, target_group_name, unit_volume)
async def create_protocol(
self,
@@ -431,14 +437,14 @@ class PRCXI9300Backend(LiquidHandlerBackend):
async def pick_up_tips(self, ops: List[Pickup], use_channels: List[int] = None):
"""Pick up tips from the specified resource."""
print('where?'*200)
plate_indexes = []
for op in ops:
plate = op.resource.parent
deck = plate.parent
plate_index = deck.children.index(plate)
print(f"Plate index: {plate_index}, Plate name: {plate.name}")
print(f"Number of children in deck: {len(deck.children)}")
# print(f"Plate index: {plate_index}, Plate name: {plate.name}")
# print(f"Number of children in deck: {len(deck.children)}")
plate_indexes.append(plate_index)
@@ -452,8 +458,6 @@ class PRCXI9300Backend(LiquidHandlerBackend):
tip_columns.append(tipspot_index // 8)
if len(set(tip_columns)) != 1:
raise ValueError("All pickups must be from the same tip column. Found different columns: " + str(tip_columns))
# print('111'*99)
# print(plate_indexes[0])
PlateNo = plate_indexes[0] + 1
hole_col = tip_columns[0] + 1
hole_row = 1
@@ -977,153 +981,162 @@ if __name__ == "__main__":
# 4.
# deck = PRCXI9300Deck(name="PRCXI_Deck_9300", size_x=100, size_y=100, size_z=100)
deck = PRCXI9300Deck(name="PRCXI_Deck_9300", size_x=100, size_y=100, size_z=100)
# from pylabrobot.resources.opentrons.tip_racks import opentrons_96_tiprack_300ul,opentrons_96_tiprack_10ul
# from pylabrobot.resources.opentrons.plates import corning_96_wellplate_360ul_flat, nest_96_wellplate_2ml_deep
from pylabrobot.resources.opentrons.tip_racks import opentrons_96_tiprack_300ul,opentrons_96_tiprack_10ul
from pylabrobot.resources.opentrons.plates import corning_96_wellplate_360ul_flat, nest_96_wellplate_2ml_deep
# def get_well_container(name: str) -> PRCXI9300Container:
# well_containers = corning_96_wellplate_360ul_flat(name).serialize()
# plate = PRCXI9300Container(name=name, size_x=50, size_y=50, size_z=10, category="plate",
# ordering=collections.OrderedDict())
# plate_serialized = plate.serialize()
# plate_serialized["parent_name"] = deck.name
# well_containers.update({k: v for k, v in plate_serialized.items() if k not in ["children"]})
# new_plate: PRCXI9300Container = PRCXI9300Container.deserialize(well_containers)
# return new_plate
def get_well_container(name: str) -> PRCXI9300Container:
well_containers = corning_96_wellplate_360ul_flat(name).serialize()
plate = PRCXI9300Container(name=name, size_x=50, size_y=50, size_z=10, category="plate",
ordering=well_containers["ordering"])
plate_serialized = plate.serialize()
plate_serialized["parent_name"] = deck.name
well_containers.update({k: v for k, v in plate_serialized.items() if k not in ["children"]})
new_plate: PRCXI9300Container = PRCXI9300Container.deserialize(well_containers)
return new_plate
# def get_tip_rack(name: str) -> PRCXI9300Container:
# tip_racks = opentrons_96_tiprack_300ul("name").serialize()
# tip_rack = PRCXI9300Container(name=name, size_x=50, size_y=50, size_z=10, category="tip_rack",
# ordering=collections.OrderedDict())
# tip_rack_serialized = tip_rack.serialize()
# tip_rack_serialized["parent_name"] = deck.name
# tip_racks.update({k: v for k, v in tip_rack_serialized.items() if k not in ["children"]})
# new_tip_rack: PRCXI9300Container = PRCXI9300Container.deserialize(tip_racks)
# return new_tip_rack
def get_tip_rack(name: str) -> PRCXI9300Container:
tip_racks = opentrons_96_tiprack_300ul("name").serialize()
tip_rack = PRCXI9300Container(name=name, size_x=50, size_y=50, size_z=10, category="tip_rack",
ordering=tip_racks["ordering"])
tip_rack_serialized = tip_rack.serialize()
tip_rack_serialized["parent_name"] = deck.name
tip_racks.update({k: v for k, v in tip_rack_serialized.items() if k not in ["children"]})
new_tip_rack: PRCXI9300Container = PRCXI9300Container.deserialize(tip_racks)
return new_tip_rack
# plate1 = get_tip_rack("RackT1")
# plate1.load_state({
# "Material": {
# "uuid": "076250742950465b9d6ea29a225dfb00",
# "Code": "ZX-001-300",
# "Name": "300μL Tip头"
# }
# })
plate1 = get_tip_rack("RackT1")
plate1.load_state({
"Material": {
"uuid": "076250742950465b9d6ea29a225dfb00",
"Code": "ZX-001-300",
"Name": "300μL Tip头"
}
})
# plate2 = get_well_container("PlateT2")
# plate2.load_state({
# "Material": {
# "uuid": "57b1e4711e9e4a32b529f3132fc5931f",
# "Code": "ZX-019-2.2",
# "Name": "96深孔板"
# }
# })
plate2 = get_well_container("PlateT2")
plate2.load_state({
"Material": {
"uuid": "57b1e4711e9e4a32b529f3132fc5931f",
"Code": "ZX-019-2.2",
"Name": "96深孔板"
}
})
# plate3 = PRCXI9300Trash("trash", size_x=50, size_y=100, size_z=10, category="trash")
# plate3.load_state({
# "Material": {
# "uuid": "730067cf07ae43849ddf4034299030e9"
# }
# })
plate3 = PRCXI9300Trash("trash", size_x=50, size_y=100, size_z=10, category="trash")
plate3.load_state({
"Material": {
"uuid": "730067cf07ae43849ddf4034299030e9"
}
})
# plate4 = get_well_container("PlateT4")
# plate4.load_state({
# "Material": {
# "uuid": "57b1e4711e9e4a32b529f3132fc5931f",
# "Code": "ZX-019-2.2",
# "Name": "96深孔板"
# }
# })
plate4 = get_well_container("PlateT4")
plate4.load_state({
"Material": {
"uuid": "57b1e4711e9e4a32b529f3132fc5931f",
"Code": "ZX-019-2.2",
"Name": "96深孔板"
}
})
# plate5 = get_well_container("PlateT5")
# plate5.load_state({
# "Material": {
# "uuid": "57b1e4711e9e4a32b529f3132fc5931f",
# "Code": "ZX-019-2.2",
# "Name": "96深孔板"
# }
# })
# plate6 = get_well_container("PlateT6")
plate5 = get_well_container("PlateT5")
plate5.load_state({
"Material": {
"uuid": "57b1e4711e9e4a32b529f3132fc5931f",
"Code": "ZX-019-2.2",
"Name": "96深孔板"
}
})
plate6 = get_well_container("PlateT6")
# plate6.load_state({
# "Material": {
# "uuid": "57b1e4711e9e4a32b529f3132fc5931f",
# "Code": "ZX-019-2.2",
# "Name": "96深孔板"
# }
# })
plate6.load_state({
"Material": {
"uuid": "57b1e4711e9e4a32b529f3132fc5931f",
"Code": "ZX-019-2.2",
"Name": "96深孔板"
}
})
# deck.assign_child_resource(plate1, location=Coordinate(0, 0, 0))
# deck.assign_child_resource(plate2, location=Coordinate(0, 0, 0))
# deck.assign_child_resource(plate3, location=Coordinate(0, 0, 0))
# deck.assign_child_resource(plate4, location=Coordinate(0, 0, 0))
# deck.assign_child_resource(plate5, location=Coordinate(0, 0, 0))
# deck.assign_child_resource(plate6, location=Coordinate(0, 0, 0))
deck.assign_child_resource(plate1, location=Coordinate(0, 0, 0))
deck.assign_child_resource(plate2, location=Coordinate(0, 0, 0))
deck.assign_child_resource(plate3, location=Coordinate(0, 0, 0))
deck.assign_child_resource(plate4, location=Coordinate(0, 0, 0))
deck.assign_child_resource(plate5, location=Coordinate(0, 0, 0))
deck.assign_child_resource(plate6, location=Coordinate(0, 0, 0))
# # print(plate2)
# plate_2_liquids = [[('water', 500)]]*96
# plate2.set_well_liquids(plate_2_liquids)
# handler = PRCXI9300Handler(deck=deck, host="10.181.214.132", port=9999,
# timeout=10.0, setup=False, debug=False,
# matrix_id="71593",
# channel_num=8, axis="Left") # Initialize the handler with the deck and host settings
# handler.set_tiprack([plate1])
handler = PRCXI9300Handler(deck=deck, host="10.181.214.132", port=9999,
timeout=10.0, setup=False, debug=False,
simulator=True,
matrix_id="71593",
channel_num=8, axis="Left") # Initialize the handler with the deck and host settings
# asyncio.run(handler.setup()) # Initialize the handler and setup the connection
# from pylabrobot.resources import set_volume_tracking
# # from pylabrobot.resources import set_tip_tracking
# set_volume_tracking(enabled=True)
plate_2_liquids = handler.set_group("water", plate2.children[:8], [200]*8)
plate5_liquids = handler.set_group("master_mix", plate5.children[:8], [100]*8)
handler.set_tiprack([plate1])
asyncio.run(handler.setup()) # Initialize the handler and setup the connection
from pylabrobot.resources import set_volume_tracking
# from pylabrobot.resources import set_tip_tracking
set_volume_tracking(enabled=True)
# from unilabos.resources.graphio import *
# A = tree_to_list([resource_plr_to_ulab(deck)])
# with open("deck_9300_new.json", "w", encoding="utf-8") as f:
# json.dump(A, f, indent=4, ensure_ascii=False)
# asyncio.run(handler.create_protocol(protocol_name="Test Protocol")) # Initialize the backend and setup the connection
# # A = tree_to_list([resource_plr_to_ulab(deck)])
# # with open("deck_9300_new.json", "w", encoding="utf-8") as f:
# # json.dump(A, f, indent=4, ensure_ascii=False)
asyncio.run(handler.create_protocol(protocol_name="Test Protocol")) # Initialize the backend and setup the connection
asyncio.run(handler.transfer_group("water", "master_mix", 100)) # Reset tip tracking
# # asyncio.run(handler.pick_up_tips(plate1.children[:8],[0,1,2,3,4,5,6,7]))
# # print(plate1.children[:8])
# # asyncio.run(handler.aspirate(plate2.children[:8],[50]*8, [0,1,2,3,4,5,6,7]))
# # print(plate2.children[:8])
# # asyncio.run(handler.dispense(plate5.children[:8],[50]*8,[0,1,2,3,4,5,6,7]))
# # print(plate5.children[:8])
# asyncio.run(handler.pick_up_tips(plate1.children[:8],[0,1,2,3,4,5,6,7]))
# print(plate1.children[:8])
# asyncio.run(handler.aspirate(plate2.children[:8],[50]*8, [0,1,2,3,4,5,6,7]))
# print(plate2.children[:8])
# asyncio.run(handler.dispense(plate5.children[:8],[50]*8,[0,1,2,3,4,5,6,7]))
# print(plate5.children[:8])
# # # # # asyncio.run(handler.drop_tips(tip_rack.children[8:16],[0,1,2,3,4,5,6,7]))
# # asyncio.run(handler.discard_tips())
# #asyncio.run(handler.drop_tips(tip_rack.children[8:16],[0,1,2,3,4,5,6,7]))
# asyncio.run(handler.discard_tips([0,1,2,3,4,5,6,7]))
# # asyncio.run(handler.mix(well_containers.children[:8
# # ], mix_time=3, mix_vol=50, height_to_bottom=0.5, offsets=Coordinate(0, 0, 0), mix_rate=100))
# # #print(json.dumps(handler._unilabos_backend.steps_todo_list, indent=2)) # Print matrix info
# # asyncio.run(handler.add_liquid(
# # asp_vols=[100]*16,
# # dis_vols=[100]*16,
# # reagent_sources=plate2.children[:16],
# # targets=plate5.children[:16],
# # use_channels=[0, 1, 2, 3, 4, 5, 6, 7],
# # flow_rates=[None] * 32,
# # offsets=[Coordinate(0, 0, 0)] * 32,
# # liquid_height=[None] * 16,
# # blow_out_air_volume=[None] * 16,
# # delays=None,
# # mix_time=3,
# # mix_vol=50,
# # spread="wide",
# # ))
# # asyncio.run(handler.run_protocol()) # Run the protocol
# # asyncio.run(handler.remove_liquid(
# # vols=[100]*16,
# # sources=plate2.children[-16:],
# # waste_liquid=plate5.children[:16], # 这个有些奇怪,但是好像也只能这么写
# # use_channels=[0, 1, 2, 3, 4, 5, 6, 7],
# # flow_rates=[None] * 32,
# # offsets=[Coordinate(0, 0, 0)] * 32,
# # liquid_height=[None] * 32,
# # blow_out_air_volume=[None] * 32,
# # spread="wide",
# # ))
# asyncio.run(handler.mix(well_containers.children[:8
# ], mix_time=3, mix_vol=50, height_to_bottom=0.5, offsets=Coordinate(0, 0, 0), mix_rate=100))
# #print(json.dumps(handler._unilabos_backend.steps_todo_list, indent=2)) # Print matrix info
# asyncio.run(handler.add_liquid(
# asp_vols=[100]*16,
# dis_vols=[100]*16,
# reagent_sources=plate2.children[:16],
# targets=plate5.children[:16],
# use_channels=[0, 1, 2, 3, 4, 5, 6, 7],
# flow_rates=[None] * 32,
# offsets=[Coordinate(0, 0, 0)] * 32,
# liquid_height=[None] * 16,
# blow_out_air_volume=[None] * 16,
# delays=None,
# mix_time=3,
# mix_vol=50,
# spread="wide",
# ))
# asyncio.run(handler.run_protocol()) # Run the protocol
# asyncio.run(handler.remove_liquid(
# vols=[100]*16,
# sources=plate2.children[-16:],
# waste_liquid=plate5.children[:16], # 这个有些奇怪,但是好像也只能这么写
# use_channels=[0, 1, 2, 3, 4, 5, 6, 7],
# flow_rates=[None] * 32,
# offsets=[Coordinate(0, 0, 0)] * 32,
# liquid_height=[None] * 32,
# blow_out_air_volume=[None] * 32,
# spread="wide",
# ))
# acid = [20]*8+[40]*8+[60]*8+[80]*8+[100]*8+[120]*8+[140]*8+[160]*8+[180]*8+[200]*8+[220]*8+[240]*8
# alkaline = acid[::-1] # Reverse the acid list for alkaline
@@ -1144,258 +1157,264 @@ if __name__ == "__main__":
# spread="wide",
# ))
# asyncio.run(handler.run_protocol()) # Run the protocol
# # # input("Running protocol...")
# # # input("Press Enter to continue...") # Wait for user input before proceeding
# # # print("PRCXI9300Handler initialized with deck and host settings.")
# # Example usage
# # 1. 用导出的json给每个T1 T2板子设定相应的物料如果是孔板和枪头盒要对应区分
# # 2. 设计一个单点动作流程,可以跑
# # 3.
# # input("Running protocol...")
# # input("Press Enter to continue...") # Wait for user input before proceeding
# # print("PRCXI9300Handler initialized with deck and host settings.")
deck = PRCXI9300Deck(name="PRCXI_Deck", size_x=100, size_y=100, size_z=100)
from pylabrobot.resources.opentrons.tip_racks import tipone_96_tiprack_200ul,opentrons_96_tiprack_10ul
from pylabrobot.resources.opentrons.plates import corning_96_wellplate_360ul_flat, nest_96_wellplate_2ml_deep
### 9320 ###
def get_well_container(name: str) -> PRCXI9300Container:
well_containers = corning_96_wellplate_360ul_flat(name).serialize()
plate = PRCXI9300Container(name=name, size_x=50, size_y=50, size_z=10, category="plate",
ordering=collections.OrderedDict())
plate_serialized = plate.serialize()
plate_serialized["parent_name"] = deck.name
well_containers.update({k: v for k, v in plate_serialized.items() if k not in ["children"]})
new_plate: PRCXI9300Container = PRCXI9300Container.deserialize(well_containers)
return new_plate
def get_tip_rack(name: str) -> PRCXI9300Container:
tip_racks = opentrons_96_tiprack_10ul("name").serialize()
tip_rack = PRCXI9300Container(name=name, size_x=50, size_y=50, size_z=10, category="tip_rack",
ordering=collections.OrderedDict())
tip_rack_serialized = tip_rack.serialize()
tip_rack_serialized["parent_name"] = deck.name
tip_racks.update({k: v for k, v in tip_rack_serialized.items() if k not in ["children"]})
new_tip_rack: PRCXI9300Container = PRCXI9300Container.deserialize(tip_racks)
return new_tip_rack
# deck = PRCXI9300Deck(name="PRCXI_Deck", size_x=100, size_y=100, size_z=100)
# from pylabrobot.resources.opentrons.tip_racks import tipone_96_tiprack_200ul,opentrons_96_tiprack_10ul
# from pylabrobot.resources.opentrons.plates import corning_96_wellplate_360ul_flat, nest_96_wellplate_2ml_deep
# def get_well_container(name: str) -> PRCXI9300Container:
# well_containers = corning_96_wellplate_360ul_flat(name).serialize()
# plate = PRCXI9300Container(name=name, size_x=50, size_y=50, size_z=10, category="plate",
# ordering=collections.OrderedDict())
# plate_serialized = plate.serialize()
# plate_serialized["parent_name"] = deck.name
# well_containers.update({k: v for k, v in plate_serialized.items() if k not in ["children"]})
# new_plate: PRCXI9300Container = PRCXI9300Container.deserialize(well_containers)
# return new_plate
# def get_tip_rack(name: str) -> PRCXI9300Container:
# tip_racks = opentrons_96_tiprack_10ul("name").serialize()
# tip_rack = PRCXI9300Container(name=name, size_x=50, size_y=50, size_z=10, category="tip_rack",
# ordering=collections.OrderedDict())
# tip_rack_serialized = tip_rack.serialize()
# tip_rack_serialized["parent_name"] = deck.name
# tip_racks.update({k: v for k, v in tip_rack_serialized.items() if k not in ["children"]})
# new_tip_rack: PRCXI9300Container = PRCXI9300Container.deserialize(tip_racks)
# return new_tip_rack
plate1 = get_well_container("HPLCPlateT1")
plate1.load_state({
"Material": {
"uuid": "548bbc3df0d4447586f2c19d2c0c0c55",
"Code": "HPLC01",
"Name": "HPLC料盘"
}
})
plate2 = get_well_container("PlateT2")
plate2.load_state({
"Material": {
"uuid": "04211a2dc93547fe9bf6121eac533650",
}
})
plate3 = get_well_container("PlateT3")
plate3.load_state({
"Material": {
"uuid": "04211a2dc93547fe9bf6121eac533650",
}
})
trash = PRCXI9300Trash(name="trash", size_x=50, size_y=50, size_z=10, category="trash")
trash.load_state({
"Material": {
"uuid": "730067cf07ae43849ddf4034299030e9"
}
})
plate5 = get_well_container("PlateT5")
plate5.load_state({
"Material": {
"uuid": "04211a2dc93547fe9bf6121eac533650",
}
})
plate6 = get_well_container("PlateT6")
plate6.load_state({
"Material": {
"uuid": "04211a2dc93547fe9bf6121eac533650"
}
})
plate7 = PRCXI9300Container(name="plateT7", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict())
plate7.load_state({
"Material": {
"uuid": "04211a2dc93547fe9bf6121eac533650"
}
})
plate8 = get_tip_rack("RackT8")
plate8.load_state({
"Material": {
"uuid": "068b3815e36b4a72a59bae017011b29f",
"Code": "ZX-001-10+",
"Name": "10μL加长 Tip头"
}
})
plate9 = get_well_container("PlateT9")
plate9.load_state({
"Material": {
"uuid": "04211a2dc93547fe9bf6121eac533650"
}
})
plate10 = get_well_container("PlateT10")
plate10.load_state({
"Material": {
"uuid": "04211a2dc93547fe9bf6121eac533650"
}
})
plate11 = get_well_container("PlateT11")
plate11.load_state({
"Material": {
"uuid": "57b1e4711e9e4a32b529f3132fc5931f",
}
})
plate12 = get_well_container("PlateT12")
plate12.load_state({
"Material": {
"uuid": "04211a2dc93547fe9bf6121eac533650"
}
})
plate13 = get_well_container("PlateT13")
plate13.load_state({
"Material": {
"uuid": "04211a2dc93547fe9bf6121eac533650"
}
})
# plate1 = get_well_container("HPLCPlateT1")
# plate1.load_state({
# "Material": {
# "uuid": "548bbc3df0d4447586f2c19d2c0c0c55",
# "Code": "HPLC01",
# "Name": "HPLC料盘"
# }
# })
# plate2 = get_well_container("PlateT2")
# plate2.load_state({
# "Material": {
# "uuid": "04211a2dc93547fe9bf6121eac533650",
# }
# })
# plate3 = get_well_container("PlateT3")
# plate3.load_state({
# "Material": {
# "uuid": "04211a2dc93547fe9bf6121eac533650",
# }
# })
# trash = PRCXI9300Trash(name="trash", size_x=50, size_y=50, size_z=10, category="trash")
# trash.load_state({
# "Material": {
# "uuid": "730067cf07ae43849ddf4034299030e9"
# }
# })
# plate5 = get_well_container("PlateT5")
# plate5.load_state({
# "Material": {
# "uuid": "04211a2dc93547fe9bf6121eac533650",
# }
# })
# plate6 = get_well_container("PlateT6")
# plate6.load_state({
# "Material": {
# "uuid": "04211a2dc93547fe9bf6121eac533650"
# }
# })
# plate7 = PRCXI9300Container(name="plateT7", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict())
# plate7.load_state({
# "Material": {
# "uuid": "04211a2dc93547fe9bf6121eac533650"
# }
# })
# plate8 = get_tip_rack("RackT8")
# plate8.load_state({
# "Material": {
# "uuid": "068b3815e36b4a72a59bae017011b29f",
# "Code": "ZX-001-10+",
# "Name": "10μL加长 Tip头"
# }
# })
# plate9 = get_well_container("PlateT9")
# plate9.load_state({
# "Material": {
# "uuid": "04211a2dc93547fe9bf6121eac533650"
# }
# })
# plate10 = get_well_container("PlateT10")
# plate10.load_state({
# "Material": {
# "uuid": "04211a2dc93547fe9bf6121eac533650"
# }
# })
# plate11 = get_well_container("PlateT11")
# plate11.load_state({
# "Material": {
# "uuid": "57b1e4711e9e4a32b529f3132fc5931f",
# }
# })
# plate12 = get_well_container("PlateT12")
# plate12.load_state({
# "Material": {
# "uuid": "04211a2dc93547fe9bf6121eac533650"
# }
# })
# plate13 = get_well_container("PlateT13")
# plate13.load_state({
# "Material": {
# "uuid": "04211a2dc93547fe9bf6121eac533650"
# }
# })
# container_for_nothing = PRCXI9300Container(name="container_for_nothing", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict())
# # container_for_nothing = PRCXI9300Container(name="container_for_nothing", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict())
deck.assign_child_resource(plate1, location=Coordinate(0, 0, 0))
deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing1", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing2", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
deck.assign_child_resource(trash, location=Coordinate(0, 0, 0))
deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing3", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing4", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
deck.assign_child_resource(plate8, location=Coordinate(0, 0, 0))
deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing5", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing6", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
deck.assign_child_resource(plate11, location=Coordinate(0, 0, 0))
deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing7", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing8", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
# deck.assign_child_resource(plate1, location=Coordinate(0, 0, 0))
# deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing1", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
# deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing2", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
# deck.assign_child_resource(trash, location=Coordinate(0, 0, 0))
# deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing3", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
# deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
# deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing4", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
# deck.assign_child_resource(plate8, location=Coordinate(0, 0, 0))
# deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing5", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
# deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing6", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
# deck.assign_child_resource(plate11, location=Coordinate(0, 0, 0))
# deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing7", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
# deck.assign_child_resource(PRCXI9300Container(name="container_for_nothing8", size_x=50, size_y=50, size_z=10, category="plate", ordering=collections.OrderedDict()), location=Coordinate(0, 0, 0))
handler = PRCXI9300Handler(deck=deck, host="10.181.102.13", port=9999,
timeout=10.0, setup=False, debug=False,
matrix_id="fd383e6d-2d0e-40b5-9c01-1b2870b1f1b1",
channel_num=1, axis="Right") # Initialize the handler with the deck and host settings
# handler = PRCXI9300Handler(deck=deck, host="10.181.102.13", port=9999,
# timeout=10.0, setup=False, debug=False,
# matrix_id="fd383e6d-2d0e-40b5-9c01-1b2870b1f1b1",
# channel_num=8, axis="Right") # Initialize the handler with the deck and host settings
handler.set_tiprack([plate8]) # Set the tip rack for the handler
asyncio.run(handler.setup()) # Initialize the handler and setup the connection
from pylabrobot.resources import set_volume_tracking
# from pylabrobot.resources import set_tip_tracking
set_volume_tracking(enabled=True)
# handler.set_tiprack([plate8]) # Set the tip rack for the handler
# asyncio.run(handler.setup()) # Initialize the handler and setup the connection
# from pylabrobot.resources import set_volume_tracking
# # from pylabrobot.resources import set_tip_tracking
# set_volume_tracking(enabled=True)
plate11.set_well_liquids([("Water", 100) if (i % 8 == 0 and i // 8 < 6) else (None, 100) for i in range(96)]) # Set liquids for every 8 wells in plate8
# plate11.set_well_liquids([("Water", 100) if (i % 8 == 0 and i // 8 < 6) else (None, 100) for i in range(96)]) # Set liquids for every 8 wells in plate8
from unilabos.resources.graphio import *
# from unilabos.resources.graphio import *
A = tree_to_list([resource_plr_to_ulab(deck)])
# with open("deck.json", "w", encoding="utf-8") as f:
# json.dump(A, f, indent=4, ensure_ascii=False)
# A = tree_to_list([resource_plr_to_ulab(deck)])
# # with open("deck.json", "w", encoding="utf-8") as f:
# # json.dump(A, f, indent=4, ensure_ascii=False)
print(plate11.get_well(0).tracker.get_used_volume())
asyncio.run(handler.create_protocol(protocol_name="Test Protocol")) # Initialize the backend and setup the connection
# asyncio.run(handler.pick_up_tips([plate8.children[8]],[0]))
# print(plate8.children[8])
# # asyncio.run(handler.run_protocol())
# asyncio.run(handler.aspirate([plate11.children[0]],[10], [0]))
# print(plate11.children[0])
# # asyncio.run(handler.run_protocol())
# asyncio.run(handler.dispense([plate1.children[0]],[10],[0]))
# print(plate1.children[0])
# # asyncio.run(handler.run_protocol())
# asyncio.run(handler.mix([plate1.children[0]], mix_time=3, mix_vol=5, height_to_bottom=0.5, offsets=Coordinate(0, 0, 0), mix_rate=100))
# print(plate1.children[0])
# asyncio.run(handler.discard_tips())
asyncio.run(handler.add_liquid(
asp_vols=[10]*7,
dis_vols=[10]*7,
reagent_sources=plate11.children[:7],
targets=plate1.children[2:9],
use_channels=[0],
flow_rates=[None] * 7,
offsets=[Coordinate(0, 0, 0)] * 7,
liquid_height=[None] * 7,
blow_out_air_volume=[None] * 2,
delays=None,
mix_time=3,
mix_vol=5,
spread="custom",
))
asyncio.run(handler.run_protocol()) # Run the protocol
# # asyncio.run(handler.transfer_liquid(
# # asp_vols=[10]*2,
# # dis_vols=[10]*2,
# # sources=plate11.children[:2],
# # targets=plate11.children[-2:],
# # use_channels=[0],
# # offsets=[Coordinate(0, 0, 0)] * 4,
# # liquid_height=[None] * 2,
# # blow_out_air_volume=[None] * 2,
# # delays=None,
# # mix_times=3,
# # mix_vol=5,
# # spread="wide",
# # tip_racks=[plate8]
# # ))
# # asyncio.run(handler.remove_liquid(
# # vols=[10]*2,
# # sources=plate11.children[:2],
# # waste_liquid=plate11.children[43],
# # use_channels=[0],
# # offsets=[Coordinate(0, 0, 0)] * 4,
# # liquid_height=[None] * 2,
# # blow_out_air_volume=[None] * 2,
# # delays=None,
# # spread="wide"
# # ))
# asyncio.run(handler.run_protocol())
# print(plate11.get_well(0).tracker.get_used_volume())
# asyncio.run(handler.create_protocol(protocol_name="Test Protocol")) # Initialize the backend and setup the connection
# # asyncio.run(handler.pick_up_tips([plate8.children[8]],[0]))
# # print(plate8.children[8])
# # # asyncio.run(handler.run_protocol())
# # asyncio.run(handler.aspirate([plate11.children[0]],[10], [0]))
# # print(plate11.children[0])
# # # asyncio.run(handler.run_protocol())
# # asyncio.run(handler.dispense([plate1.children[0]],[10],[0]))
# # print(plate1.children[0])
# # # asyncio.run(handler.run_protocol())
# # asyncio.run(handler.mix([plate1.children[0]], mix_time=3, mix_vol=5, height_to_bottom=0.5, offsets=Coordinate(0, 0, 0), mix_rate=100))
# # print(plate1.children[0])
# # asyncio.run(handler.discard_tips())
# # asyncio.run(handler.mix(well_containers.children[:8
# # ], mix_time=3, mix_vol=50, height_to_bottom=0.5, offsets=Coordinate(0, 0, 0), mix_rate=100))
# #print(json.dumps(handler._unilabos_backend.steps_todo_list, indent=2)) # Print matrix info
# asyncio.run(handler.add_liquid(
# asp_vols=[10]*7,
# dis_vols=[10]*7,
# reagent_sources=plate11.children[:7],
# targets=plate1.children[2:9],
# use_channels=[0],
# flow_rates=[None] * 7,
# offsets=[Coordinate(0, 0, 0)] * 7,
# liquid_height=[None] * 7,
# blow_out_air_volume=[None] * 2,
# delays=None,
# mix_time=3,
# mix_vol=5,
# spread="custom",
# ))
# asyncio.run(handler.run_protocol()) # Run the protocol
# # asyncio.run(handler.remove_liquid(
# # vols=[100]*16,
# # sources=well_containers.children[-16:],
# # waste_liquid=well_containers.children[:16], # 这个有些奇怪,但是好像也只能这么写
# # use_channels=[0, 1, 2, 3, 4, 5, 6, 7],
# # flow_rates=[None] * 32,
# # offsets=[Coordinate(0, 0, 0)] * 32,
# # liquid_height=[None] * 32,
# # blow_out_air_volume=[None] * 32,
# # spread="wide",
# # ))
# # asyncio.run(handler.transfer_liquid(
# # asp_vols=[100]*16,
# # dis_vols=[100]*16,
# # tip_racks=[tip_rack],
# # sources=well_containers.children[-16:],
# # targets=well_containers.children[:16],
# # use_channels=[0, 1, 2, 3, 4, 5, 6, 7],
# # offsets=[Coordinate(0, 0, 0)] * 32,
# # asp_flow_rates=[None] * 16,
# # dis_flow_rates=[None] * 16,
# # liquid_height=[None] * 32,
# # blow_out_air_volume=[None] * 32,
# # mix_times=3,
# # mix_vol=50,
# # spread="wide",
# # ))
print(json.dumps(handler._unilabos_backend.steps_todo_list, indent=2)) # Print matrix info
# # input("pick_up_tips add step")
# #asyncio.run(handler.run_protocol()) # Run the protocol
# # input("Running protocol...")
# # input("Press Enter to continue...") # Wait for user input before proceeding
# # print("PRCXI9300Handler initialized with deck and host settings.")
# # # asyncio.run(handler.transfer_liquid(
# # # asp_vols=[10]*2,
# # # dis_vols=[10]*2,
# # # sources=plate11.children[:2],
# # # targets=plate11.children[-2:],
# # # use_channels=[0],
# # # offsets=[Coordinate(0, 0, 0)] * 4,
# # # liquid_height=[None] * 2,
# # # blow_out_air_volume=[None] * 2,
# # # delays=None,
# # # mix_times=3,
# # # mix_vol=5,
# # # spread="wide",
# # # tip_racks=[plate8]
# # # ))
# # # asyncio.run(handler.remove_liquid(
# # # vols=[10]*2,
# # # sources=plate11.children[:2],
# # # waste_liquid=plate11.children[43],
# # # use_channels=[0],
# # # offsets=[Coordinate(0, 0, 0)] * 4,
# # # liquid_height=[None] * 2,
# # # blow_out_air_volume=[None] * 2,
# # # delays=None,
# # # spread="wide"
# # # ))
# # asyncio.run(handler.run_protocol())
# # # asyncio.run(handler.discard_tips())
# # # asyncio.run(handler.mix(well_containers.children[:8
# # # ], mix_time=3, mix_vol=50, height_to_bottom=0.5, offsets=Coordinate(0, 0, 0), mix_rate=100))
# # #print(json.dumps(handler._unilabos_backend.steps_todo_list, indent=2)) # Print matrix info
# # # asyncio.run(handler.remove_liquid(
# # # vols=[100]*16,
# # # sources=well_containers.children[-16:],
# # # waste_liquid=well_containers.children[:16], # 这个有些奇怪,但是好像也只能这么写
# # # use_channels=[0, 1, 2, 3, 4, 5, 6, 7],
# # # flow_rates=[None] * 32,
# # # offsets=[Coordinate(0, 0, 0)] * 32,
# # # liquid_height=[None] * 32,
# # # blow_out_air_volume=[None] * 32,
# # # spread="wide",
# # # ))
# # # asyncio.run(handler.transfer_liquid(
# # # asp_vols=[100]*16,
# # # dis_vols=[100]*16,
# # # tip_racks=[tip_rack],
# # # sources=well_containers.children[-16:],
# # # targets=well_containers.children[:16],
# # # use_channels=[0, 1, 2, 3, 4, 5, 6, 7],
# # # offsets=[Coordinate(0, 0, 0)] * 32,
# # # asp_flow_rates=[None] * 16,
# # # dis_flow_rates=[None] * 16,
# # # liquid_height=[None] * 32,
# # # blow_out_air_volume=[None] * 32,
# # # mix_times=3,
# # # mix_vol=50,
# # # spread="wide",
# # # ))
# # print(json.dumps(handler._unilabos_backend.steps_todo_list, indent=2)) # Print matrix info
# # # input("pick_up_tips add step")
# # #asyncio.run(handler.run_protocol()) # Run the protocol
# # # input("Running protocol...")
# # # input("Press Enter to continue...") # Wait for user input before proceeding
# # # print("PRCXI9300Handler initialized with deck and host settings.")

44
unilabos/devices/liquid_handling/prcxi/prcxi_res.py Normal file
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import collections
from pylabrobot.resources import opentrons_96_tiprack_10ul
from pylabrobot.resources.opentrons.plates import corning_96_wellplate_360ul_flat, nest_96_wellplate_2ml_deep
from unilabos.devices.liquid_handling.prcxi.prcxi import PRCXI9300Container, PRCXI9300Trash
def get_well_container(name: str) -> PRCXI9300Container:
well_containers = corning_96_wellplate_360ul_flat(name).serialize()
plate = PRCXI9300Container(name=name, size_x=50, size_y=50, size_z=10, category="plate",
ordering=collections.OrderedDict())
plate_serialized = plate.serialize()
well_containers.update({k: v for k, v in plate_serialized.items() if k not in ["children"]})
new_plate: PRCXI9300Container = PRCXI9300Container.deserialize(well_containers)
return new_plate
def get_tip_rack(name: str) -> PRCXI9300Container:
tip_racks = opentrons_96_tiprack_10ul("name").serialize()
tip_rack = PRCXI9300Container(name=name, size_x=50, size_y=50, size_z=10, category="tip_rack",
ordering=collections.OrderedDict())
tip_rack_serialized = tip_rack.serialize()
tip_racks.update({k: v for k, v in tip_rack_serialized.items() if k not in ["children"]})
new_tip_rack: PRCXI9300Container = PRCXI9300Container.deserialize(tip_racks)
return new_tip_rack
def prcxi_96_wellplate_360ul_flat(name: str):
return get_well_container(name)
def prcxi_opentrons_96_tiprack_10ul(name: str):
return get_tip_rack(name)
def prcxi_trash(name: str = None):
return PRCXI9300Trash(name="trash", size_x=50, size_y=50, size_z=10, category="trash")
if __name__ == "__main__":
# Example usage
test_plate = prcxi_96_wellplate_360ul_flat("test_plate")
test_rack = prcxi_opentrons_96_tiprack_10ul("test_rack")
tash = prcxi_trash("trash")
print(test_plate)
print(test_rack)
print(tash)
# Output will be a dictionary representation of the PRCXI9300Container with well details

177
unilabos/devices/mock/mock_chiller.py
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@@ -1,177 +0,0 @@
import time
import threading
class MockChiller:
def __init__(self, port: str = "MOCK"):
self.port = port
self._current_temperature: float = 25.0 # 室温开始
self._target_temperature: float = 25.0
self._status: str = "Idle"
self._is_cooling: bool = False
self._is_heating: bool = False
self._vessel = "Unknown"
self._purpose = "Unknown"
# 模拟温度变化的线程
self._temperature_thread = None
self._running = True
self._temperature_thread = threading.Thread(target=self._temperature_control_loop)
self._temperature_thread.daemon = True
self._temperature_thread.start()
@property
def current_temperature(self) -> float:
"""当前温度 - 会被自动识别的设备属性"""
return self._current_temperature
@property
def target_temperature(self) -> float:
"""目标温度"""
return self._target_temperature
@property
def status(self) -> str:
"""设备状态 - 会被自动识别的设备属性"""
return self._status
@property
def is_cooling(self) -> bool:
"""是否正在冷却"""
return self._is_cooling
@property
def is_heating(self) -> bool:
"""是否正在加热"""
return self._is_heating
@property
def vessel(self) -> str:
"""当前操作的容器名称"""
return self._vessel
@property
def purpose(self) -> str:
"""当前操作目的"""
return self._purpose
def heat_chill_start(self, vessel: str, temp: float, purpose: str):
"""设置目标温度并记录容器和目的"""
self._vessel = str(vessel)
self._purpose = str(purpose)
self._target_temperature = float(temp)
diff = self._target_temperature - self._current_temperature
if abs(diff) < 0.1:
self._status = "At Target Temperature"
self._is_cooling = False
self._is_heating = False
elif diff < 0:
self._status = "Cooling"
self._is_cooling = True
self._is_heating = False
else:
self._status = "Heating"
self._is_heating = True
self._is_cooling = False
self._start_temperature_control()
return True
def heat_chill_stop(self, vessel: str):
"""停止加热/制冷"""
if vessel != self._vessel:
return {"success": False, "status": f"Wrong vessel: expected {self._vessel}, got {vessel}"}
# 停止温度控制线程,锁定当前温度
self._stop_temperature_control()
# 更新状态
self._status = "Stopped"
self._is_cooling = False
self._is_heating = False
# 重新启动线程但保持温度
self._running = True
self._temperature_thread = threading.Thread(target=self._temperature_control_loop)
self._temperature_thread.daemon = True
self._temperature_thread.start()
return {"success": True, "status": self._status}
def _start_temperature_control(self):
"""启动温度控制线程"""
self._running = True
if self._temperature_thread is None or not self._temperature_thread.is_alive():
self._temperature_thread = threading.Thread(target=self._temperature_control_loop)
self._temperature_thread.daemon = True
self._temperature_thread.start()
def _stop_temperature_control(self):
"""停止温度控制"""
self._running = False
if self._temperature_thread:
self._temperature_thread.join(timeout=1.0)
def _temperature_control_loop(self):
"""温度控制循环 - 模拟真实冷却器的温度变化"""
while self._running:
# 如果状态是 Stopped不改变温度
if self._status == "Stopped":
time.sleep(1.0)
continue
temp_diff = self._target_temperature - self._current_temperature
if abs(temp_diff) < 0.1:
self._status = "At Target Temperature"
self._is_cooling = False
self._is_heating = False
elif temp_diff < 0:
self._status = "Cooling"
self._is_cooling = True
self._is_heating = False
self._current_temperature -= 0.5
else:
self._status = "Heating"
self._is_heating = True
self._is_cooling = False
self._current_temperature += 0.3
time.sleep(1.0)
def emergency_stop(self):
"""紧急停止"""
self._status = "Emergency Stop"
self._stop_temperature_control()
self._is_cooling = False
self._is_heating = False
def get_status_info(self) -> dict:
"""获取完整状态信息"""
return {
"current_temperature": self._current_temperature,
"target_temperature": self._target_temperature,
"status": self._status,
"is_cooling": self._is_cooling,
"is_heating": self._is_heating,
"vessel": self._vessel,
"purpose": self._purpose,
}
# 用于测试的主函数
if __name__ == "__main__":
chiller = MockChiller()
# 测试基本功能
print("启动冷却器测试...")
print(f"初始状态: {chiller.get_status_info()}")
# 模拟运行10秒
for i in range(10):
time.sleep(1)
print(f"{i+1}秒: 当前温度={chiller.current_temperature:.1f}°C, 状态={chiller.status}")
chiller.emergency_stop()
print("测试完成")

235
unilabos/devices/mock/mock_filter.py
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@@ -1,235 +0,0 @@
import time
import threading
class MockFilter:
def __init__(self, port: str = "MOCK"):
# 基本参数初始化
self.port = port
self._status: str = "Idle"
self._is_filtering: bool = False
# 过滤性能参数
self._flow_rate: float = 1.0 # 流速(L/min)
self._pressure_drop: float = 0.0 # 压降(Pa)
self._filter_life: float = 100.0 # 滤芯寿命(%)
# 过滤操作参数
self._vessel: str = "" # 源容器
self._filtrate_vessel: str = "" # 目标容器
self._stir: bool = False # 是否搅拌
self._stir_speed: float = 0.0 # 搅拌速度
self._temperature: float = 25.0 # 温度(℃)
self._continue_heatchill: bool = False # 是否继续加热/制冷
self._target_volume: float = 0.0 # 目标过滤体积(L)
self._filtered_volume: float = 0.0 # 已过滤体积(L)
self._progress: float = 0.0 # 过滤进度(%)
# 线程控制
self._filter_thread = None
self._running = False
@property
def status(self) -> str:
return self._status
@property
def is_filtering(self) -> bool:
return self._is_filtering
@property
def flow_rate(self) -> float:
return self._flow_rate
@property
def pressure_drop(self) -> float:
return self._pressure_drop
@property
def filter_life(self) -> float:
return self._filter_life
# 新增 property
@property
def vessel(self) -> str:
return self._vessel
@property
def filtrate_vessel(self) -> str:
return self._filtrate_vessel
@property
def filtered_volume(self) -> float:
return self._filtered_volume
@property
def progress(self) -> float:
return self._progress
@property
def stir(self) -> bool:
return self._stir
@property
def stir_speed(self) -> float:
return self._stir_speed
@property
def temperature(self) -> float:
return self._temperature
@property
def continue_heatchill(self) -> bool:
return self._continue_heatchill
@property
def target_volume(self) -> float:
return self._target_volume
def filter(self, vessel: str, filtrate_vessel: str, stir: bool = False, stir_speed: float = 0.0, temp: float = 25.0, continue_heatchill: bool = False, volume: float = 0.0) -> dict:
"""新的过滤操作"""
# 停止任何正在进行的过滤
if self._is_filtering:
self.stop_filtering()
# 验证参数
if volume <= 0:
return {"success": False, "message": "Target volume must be greater than 0"}
# 设置新的过滤参数
self._vessel = vessel
self._filtrate_vessel = filtrate_vessel
self._stir = stir
self._stir_speed = stir_speed
self._temperature = temp
self._continue_heatchill = continue_heatchill
self._target_volume = volume
# 重置过滤状态
self._filtered_volume = 0.0
self._progress = 0.0
self._status = "Starting Filter"
# 启动过滤过程
self._flow_rate = 1.0 # 设置默认流速
self._start_filter_process()
return {"success": True, "message": "Filter started"}
def stop_filtering(self):
"""停止过滤"""
self._status = "Stopping Filter"
self._stop_filter_process()
self._flow_rate = 0.0
self._is_filtering = False
self._status = "Stopped"
return True
def replace_filter(self):
"""更换滤芯"""
self._filter_life = 100.0
self._status = "Filter Replaced"
return True
def _start_filter_process(self):
"""启动过滤过程线程"""
if not self._running:
self._running = True
self._is_filtering = True
self._filter_thread = threading.Thread(target=self._filter_loop)
self._filter_thread.daemon = True
self._filter_thread.start()
def _stop_filter_process(self):
"""停止过滤过程"""
self._running = False
if self._filter_thread:
self._filter_thread.join(timeout=1.0)
def _filter_loop(self):
"""过滤进程主循环"""
update_interval = 1.0 # 更新间隔(秒)
while self._running and self._is_filtering:
try:
self._status = "Filtering"
# 计算这一秒过滤的体积 (L/min -> L/s)
volume_increment = (self._flow_rate / 60.0) * update_interval
# 更新已过滤体积
self._filtered_volume += volume_increment
# 更新进度 (避免除零错误)
if self._target_volume > 0:
self._progress = min(100.0, (self._filtered_volume / self._target_volume) * 100.0)
# 更新滤芯寿命 (每过滤1L减少0.5%寿命)
self._filter_life = max(0.0, self._filter_life - (volume_increment * 0.5))
# 更新压降 (根据滤芯寿命和流速动态计算)
life_factor = self._filter_life / 100.0 # 将寿命转换为0-1的因子
flow_factor = self._flow_rate / 2.0 # 将流速标准化(假设2L/min是标准流速)
base_pressure = 100.0 # 基础压降
# 压降随滤芯寿命降低而增加,随流速增加而增加
self._pressure_drop = base_pressure * (2 - life_factor) * flow_factor
# 检查是否完成目标体积
if self._target_volume > 0 and self._filtered_volume >= self._target_volume:
self._status = "Completed"
self._progress = 100.0
self.stop_filtering()
break
# 检查滤芯寿命
if self._filter_life <= 10.0:
self._status = "Filter Needs Replacement"
time.sleep(update_interval)
except Exception as e:
print(f"Error in filter loop: {e}")
self.emergency_stop()
break
def emergency_stop(self):
"""紧急停止"""
self._status = "Emergency Stop"
self._stop_filter_process()
self._is_filtering = False
self._flow_rate = 0.0
def get_status_info(self) -> dict:
"""扩展的状态信息"""
return {
"status": self._status,
"is_filtering": self._is_filtering,
"flow_rate": self._flow_rate,
"pressure_drop": self._pressure_drop,
"filter_life": self._filter_life,
"vessel": self._vessel,
"filtrate_vessel": self._filtrate_vessel,
"filtered_volume": self._filtered_volume,
"target_volume": self._target_volume,
"progress": self._progress,
"temperature": self._temperature,
"stir": self._stir,
"stir_speed": self._stir_speed
}
# 用于测试的主函数
if __name__ == "__main__":
filter_device = MockFilter()
# 测试基本功能
print("启动过滤器测试...")
print(f"初始状态: {filter_device.get_status_info()}")
# 模拟运行10秒
for i in range(10):
time.sleep(1)
print(
f"{i+1}秒: "
f"寿命={filter_device.filter_life:.1f}%, 状态={filter_device.status}"
)
filter_device.emergency_stop()
print("测试完成")

247
unilabos/devices/mock/mock_heater.py
View File

@@ -1,247 +0,0 @@
import time
import threading
class MockHeater:
def __init__(self, port: str = "MOCK"):
self.port = port
self._current_temperature: float = 25.0 # 室温开始
self._target_temperature: float = 25.0
self._status: str = "Idle"
self._is_heating: bool = False
self._heating_power: float = 0.0 # 加热功率百分比 0-100
self._max_temperature: float = 300.0 # 最大加热温度
# 新增加的属性
self._vessel: str = "Unknown"
self._purpose: str = "Unknown"
self._stir: bool = False
self._stir_speed: float = 0.0
# 模拟加热过程的线程
self._heating_thread = None
self._running = True
self._heating_thread = threading.Thread(target=self._heating_control_loop)
self._heating_thread.daemon = True
self._heating_thread.start()
@property
def current_temperature(self) -> float:
"""当前温度 - 会被自动识别的设备属性"""
return self._current_temperature
@property
def target_temperature(self) -> float:
"""目标温度"""
return self._target_temperature
@property
def status(self) -> str:
"""设备状态 - 会被自动识别的设备属性"""
return self._status
@property
def is_heating(self) -> bool:
"""是否正在加热"""
return self._is_heating
@property
def heating_power(self) -> float:
"""加热功率百分比"""
return self._heating_power
@property
def max_temperature(self) -> float:
"""最大加热温度"""
return self._max_temperature
@property
def vessel(self) -> str:
"""当前操作的容器名称"""
return self._vessel
@property
def purpose(self) -> str:
"""操作目的"""
return self._purpose
@property
def stir(self) -> bool:
"""是否搅拌"""
return self._stir
@property
def stir_speed(self) -> float:
"""搅拌速度"""
return self._stir_speed
def heat_chill_start(self, vessel: str, temp: float, purpose: str) -> dict:
"""开始加热/制冷过程"""
self._vessel = str(vessel)
self._purpose = str(purpose)
self._target_temperature = float(temp)
diff = self._target_temperature - self._current_temperature
if abs(diff) < 0.1:
self._status = "At Target Temperature"
self._is_heating = False
elif diff > 0:
self._status = "Heating"
self._is_heating = True
else:
self._status = "Cooling Down"
self._is_heating = False
return {"success": True, "status": self._status}
def heat_chill_stop(self, vessel: str) -> dict:
"""停止加热/制冷"""
if vessel != self._vessel:
return {"success": False, "status": f"Wrong vessel: expected {self._vessel}, got {vessel}"}
self._status = "Stopped"
self._is_heating = False
self._heating_power = 0.0
return {"success": True, "status": self._status}
def heat_chill(self, vessel: str, temp: float, time: float,
stir: bool = False, stir_speed: float = 0.0,
purpose: str = "Unknown") -> dict:
"""完整的加热/制冷控制"""
self._vessel = str(vessel)
self._target_temperature = float(temp)
self._purpose = str(purpose)
self._stir = stir
self._stir_speed = stir_speed
diff = self._target_temperature - self._current_temperature
if abs(diff) < 0.1:
self._status = "At Target Temperature"
self._is_heating = False
elif diff > 0:
self._status = "Heating"
self._is_heating = True
else:
self._status = "Cooling Down"
self._is_heating = False
return {"success": True, "status": self._status}
def set_temperature(self, temperature: float):
"""设置目标温度 - 需要在注册表添加的设备动作"""
try:
temperature = float(temperature)
except ValueError:
self._status = "Error: Invalid temperature value"
return False
if temperature > self._max_temperature:
self._status = f"Error: Temperature exceeds maximum ({self._max_temperature}°C)"
return False
self._target_temperature = temperature
self._status = "Setting Temperature"
# 启动加热控制
self._start_heating_control()
return True
def set_heating_power(self, power: float):
"""设置加热功率"""
try:
power = float(power)
except ValueError:
self._status = "Error: Invalid power value"
return False
self._heating_power = max(0.0, min(100.0, power)) # 限制在0-100%
return True
def _start_heating_control(self):
"""启动加热控制线程"""
if not self._running:
self._running = True
self._heating_thread = threading.Thread(target=self._heating_control_loop)
self._heating_thread.daemon = True
self._heating_thread.start()
def _stop_heating_control(self):
"""停止加热控制"""
self._running = False
if self._heating_thread:
self._heating_thread.join(timeout=1.0)
def _heating_control_loop(self):
"""加热控制循环"""
while self._running:
# 如果状态是 Stopped不改变温度
if self._status == "Stopped":
time.sleep(1.0)
continue
temp_diff = self._target_temperature - self._current_temperature
if abs(temp_diff) < 0.1:
self._status = "At Target Temperature"
self._is_heating = False
self._heating_power = 10.0
elif temp_diff > 0:
self._status = "Heating"
self._is_heating = True
self._heating_power = min(100.0, abs(temp_diff) * 2)
self._current_temperature += 0.5
else:
self._status = "Cooling Down"
self._is_heating = False
self._heating_power = 0.0
self._current_temperature -= 0.2
time.sleep(1.0)
def emergency_stop(self):
"""紧急停止"""
self._status = "Emergency Stop"
self._stop_heating_control()
self._is_heating = False
self._heating_power = 0.0
def get_status_info(self) -> dict:
"""获取完整状态信息"""
return {
"current_temperature": self._current_temperature,
"target_temperature": self._target_temperature,
"status": self._status,
"is_heating": self._is_heating,
"heating_power": self._heating_power,
"max_temperature": self._max_temperature,
"vessel": self._vessel,
"purpose": self._purpose,
"stir": self._stir,
"stir_speed": self._stir_speed
}
# 用于测试的主函数
if __name__ == "__main__":
heater = MockHeater()
print("启动加热器测试...")
print(f"初始状态: {heater.get_status_info()}")
# 设置目标温度为80度
heater.set_temperature(80.0)
# 模拟运行15秒
try:
for i in range(15):
time.sleep(1)
status = heater.get_status_info()
print(
f"\r温度: {status['current_temperature']:.1f}°C / {status['target_temperature']:.1f}°C | "
f"功率: {status['heating_power']:.1f}% | 状态: {status['status']}",
end=""
)
except KeyboardInterrupt:
heater.emergency_stop()
print("\n测试被手动停止")
print("\n测试完成")

360
unilabos/devices/mock/mock_pump.py
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@@ -1,360 +0,0 @@
import time
import threading
from datetime import datetime, timedelta
class MockPump:
def __init__(self, port: str = "MOCK"):
self.port = port
# 设备基本状态属性
self._current_device = "MockPump1" # 设备标识符
self._status: str = "Idle" # 设备状态Idle, Running, Error, Stopped
self._pump_state: str = "Stopped" # 泵运行状态Running, Stopped, Paused
# 流量相关属性
self._flow_rate: float = 0.0 # 当前流速 (mL/min)
self._target_flow_rate: float = 0.0 # 目标流速 (mL/min)
self._max_flow_rate: float = 100.0 # 最大流速 (mL/min)
self._total_volume: float = 0.0 # 累计流量 (mL)
# 压力相关属性
self._pressure: float = 0.0 # 当前压力 (bar)
self._max_pressure: float = 10.0 # 最大压力 (bar)
# 运行控制线程
self._pump_thread = None
self._running = False
self._thread_lock = threading.Lock()
# 新增 PumpTransfer 相关属性
self._from_vessel: str = ""
self._to_vessel: str = ""
self._transfer_volume: float = 0.0
self._amount: str = ""
self._transfer_time: float = 0.0
self._is_viscous: bool = False
self._rinsing_solvent: str = ""
self._rinsing_volume: float = 0.0
self._rinsing_repeats: int = 0
self._is_solid: bool = False
# 时间追踪
self._start_time: datetime = None
self._time_spent: timedelta = timedelta()
self._time_remaining: timedelta = timedelta()
# ==================== 状态属性 ====================
# 这些属性会被Uni-Lab系统自动识别并定时对外广播
@property
def status(self) -> str:
return self._status
@property
def current_device(self) -> str:
"""当前设备标识符"""
return self._current_device
@property
def pump_state(self) -> str:
return self._pump_state
@property
def flow_rate(self) -> float:
return self._flow_rate
@property
def target_flow_rate(self) -> float:
return self._target_flow_rate
@property
def pressure(self) -> float:
return self._pressure
@property
def total_volume(self) -> float:
return self._total_volume
@property
def max_flow_rate(self) -> float:
return self._max_flow_rate
@property
def max_pressure(self) -> float:
return self._max_pressure
# 添加新的属性访问器
@property
def from_vessel(self) -> str:
return self._from_vessel
@property
def to_vessel(self) -> str:
return self._to_vessel
@property
def transfer_volume(self) -> float:
return self._transfer_volume
@property
def amount(self) -> str:
return self._amount
@property
def transfer_time(self) -> float:
return self._transfer_time
@property
def is_viscous(self) -> bool:
return self._is_viscous
@property
def rinsing_solvent(self) -> str:
return self._rinsing_solvent
@property
def rinsing_volume(self) -> float:
return self._rinsing_volume
@property
def rinsing_repeats(self) -> int:
return self._rinsing_repeats
@property
def is_solid(self) -> bool:
return self._is_solid
# 修改这两个属性装饰器
@property
def time_spent(self) -> float:
"""已用时间(秒)"""
if isinstance(self._time_spent, timedelta):
return self._time_spent.total_seconds()
return float(self._time_spent)
@property
def time_remaining(self) -> float:
"""剩余时间(秒)"""
if isinstance(self._time_remaining, timedelta):
return self._time_remaining.total_seconds()
return float(self._time_remaining)
# ==================== 设备控制方法 ====================
# 这些方法需要在注册表中添加会作为ActionServer接受控制指令
def pump_transfer(self, from_vessel: str, to_vessel: str, volume: float,
amount: str = "", time: float = 0.0, viscous: bool = False,
rinsing_solvent: str = "", rinsing_volume: float = 0.0,
rinsing_repeats: int = 0, solid: bool = False) -> dict:
"""Execute pump transfer operation"""
# Stop any existing operation first
self._stop_pump_operation()
# Set transfer parameters
self._from_vessel = from_vessel
self._to_vessel = to_vessel
self._transfer_volume = float(volume)
self._amount = amount
self._transfer_time = float(time)
self._is_viscous = viscous
self._rinsing_solvent = rinsing_solvent
self._rinsing_volume = float(rinsing_volume)
self._rinsing_repeats = int(rinsing_repeats)
self._is_solid = solid
# Calculate flow rate
if self._transfer_time > 0 and self._transfer_volume > 0:
self._target_flow_rate = (self._transfer_volume / self._transfer_time) * 60.0
else:
self._target_flow_rate = 10.0 if not self._is_viscous else 5.0
# Reset timers and counters
self._start_time = datetime.now()
self._time_spent = timedelta()
self._time_remaining = timedelta(seconds=self._transfer_time)
self._total_volume = 0.0
self._flow_rate = 0.0
# Start pump operation
self._pump_state = "Running"
self._status = "Starting Transfer"
self._running = True
# Start pump operation thread
self._pump_thread = threading.Thread(target=self._pump_operation_loop)
self._pump_thread.daemon = True
self._pump_thread.start()
# Wait briefly to ensure thread starts
time.sleep(0.1)
return {
"success": True,
"status": self._status,
"current_device": self._current_device,
"time_spent": 0.0,
"time_remaining": float(self._transfer_time)
}
def pause_pump(self) -> str:
if self._pump_state != "Running":
self._status = "Error: Pump not running"
return "Error"
self._pump_state = "Paused"
self._status = "Pump Paused"
self._stop_pump_operation()
return "Success"
def resume_pump(self) -> str:
if self._pump_state != "Paused":
self._status = "Error: Pump not paused"
return "Error"
self._pump_state = "Running"
self._status = "Resuming Pump"
self._start_pump_operation()
return "Success"
def reset_volume_counter(self) -> str:
self._total_volume = 0.0
self._status = "Volume counter reset"
return "Success"
def emergency_stop(self) -> str:
self._status = "Emergency Stop"
self._pump_state = "Stopped"
self._stop_pump_operation()
self._flow_rate = 0.0
self._pressure = 0.0
self._target_flow_rate = 0.0
return "Success"
# ==================== 内部控制方法 ====================
def _start_pump_operation(self):
with self._thread_lock:
if not self._running:
self._running = True
self._pump_thread = threading.Thread(target=self._pump_operation_loop)
self._pump_thread.daemon = True
self._pump_thread.start()
def _stop_pump_operation(self):
with self._thread_lock:
self._running = False
if self._pump_thread and self._pump_thread.is_alive():
self._pump_thread.join(timeout=2.0)
def _pump_operation_loop(self):
"""泵运行主循环"""
print("Pump operation loop started") # Debug print
while self._running and self._pump_state == "Running":
try:
# Calculate flow rate adjustment
flow_diff = self._target_flow_rate - self._flow_rate
# Adjust flow rate more aggressively (50% of difference)
adjustment = flow_diff * 0.5
self._flow_rate += adjustment
# Ensure flow rate is within bounds
self._flow_rate = max(0.1, min(self._max_flow_rate, self._flow_rate))
# Update status based on flow rate
if abs(flow_diff) < 0.1:
self._status = "Running at Target Flow Rate"
else:
self._status = "Adjusting Flow Rate"
# Calculate volume increment
volume_increment = (self._flow_rate / 60.0) # mL/s
self._total_volume += volume_increment
# Update time tracking
self._time_spent = datetime.now() - self._start_time
if self._transfer_time > 0:
remaining = self._transfer_time - self._time_spent.total_seconds()
self._time_remaining = timedelta(seconds=max(0, remaining))
# Check completion
if self._total_volume >= self._transfer_volume:
self._status = "Transfer Completed"
self._pump_state = "Stopped"
self._running = False
break
# Update pressure
self._pressure = (self._flow_rate / self._max_flow_rate) * self._max_pressure
print(f"Debug - Flow: {self._flow_rate:.1f}, Volume: {self._total_volume:.1f}") # Debug print
time.sleep(1.0)
except Exception as e:
print(f"Error in pump operation: {str(e)}")
self._status = "Error in pump operation"
self._pump_state = "Stopped"
self._running = False
break
def get_status_info(self) -> dict:
"""
获取完整的设备状态信息
Returns:
dict: 包含所有设备状态的字典
"""
return {
"status": self._status,
"pump_state": self._pump_state,
"flow_rate": self._flow_rate,
"target_flow_rate": self._target_flow_rate,
"pressure": self._pressure,
"total_volume": self._total_volume,
"max_flow_rate": self._max_flow_rate,
"max_pressure": self._max_pressure,
"current_device": self._current_device,
"from_vessel": self._from_vessel,
"to_vessel": self._to_vessel,
"transfer_volume": self._transfer_volume,
"amount": self._amount,
"transfer_time": self._transfer_time,
"is_viscous": self._is_viscous,
"rinsing_solvent": self._rinsing_solvent,
"rinsing_volume": self._rinsing_volume,
"rinsing_repeats": self._rinsing_repeats,
"is_solid": self._is_solid,
"time_spent": self._time_spent.total_seconds(),
"time_remaining": self._time_remaining.total_seconds()
}
# 用于测试的主函数
if __name__ == "__main__":
pump = MockPump()
# 测试基本功能
print("启动泵设备测试...")
print(f"初始状态: {pump.get_status_info()}")
# 设置流速并启动
pump.set_flow_rate(50.0)
pump.start_pump()
# 模拟运行10秒
for i in range(10):
time.sleep(1)
print(f"{i+1}秒: 流速={pump.flow_rate:.1f}mL/min, 压力={pump.pressure:.2f}bar, 状态={pump.status}")
# 测试方向切换
print("切换泵方向...")
pump.emergency_stop()
print("测试完成")

390
unilabos/devices/mock/mock_rotavap.py
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@@ -1,390 +0,0 @@
import time
import threading
import json
class MockRotavap:
"""
模拟旋转蒸发器设备类
这个类模拟了一个实验室旋转蒸发器的行为,包括旋转控制、
真空泵控制、温度控制等功能。参考了现有的 RotavapOne 实现。
"""
def __init__(self, port: str = "MOCK"):
"""
初始化MockRotavap实例
Args:
port (str): 设备端口,默认为"MOCK"表示模拟设备
"""
self.port = port
# 设备基本状态属性
self._status: str = "Idle" # 设备状态Idle, Running, Error, Stopped
# 旋转相关属性
self._rotate_state: str = "Stopped" # 旋转状态Running, Stopped
self._rotate_time: float = 0.0 # 旋转剩余时间 (秒)
self._rotate_speed: float = 0.0 # 旋转速度 (rpm)
self._max_rotate_speed: float = 300.0 # 最大旋转速度 (rpm)
# 真空泵相关属性
self._pump_state: str = "Stopped" # 泵状态Running, Stopped
self._pump_time: float = 0.0 # 泵剩余时间 (秒)
self._vacuum_level: float = 0.0 # 真空度 (mbar)
self._target_vacuum: float = 50.0 # 目标真空度 (mbar)
# 温度相关属性
self._temperature: float = 25.0 # 水浴温度 (°C)
self._target_temperature: float = 25.0 # 目标温度 (°C)
self._max_temperature: float = 180.0 # 最大温度 (°C)
# 运行控制线程
self._operation_thread = None
self._running = False
self._thread_lock = threading.Lock()
# 操作成功标志
self.success: str = "True" # 使用字符串而不是布尔值
# ==================== 状态属性 ====================
# 这些属性会被Uni-Lab系统自动识别并定时对外广播
@property
def status(self) -> str:
return self._status
@property
def rotate_state(self) -> str:
return self._rotate_state
@property
def rotate_time(self) -> float:
return self._rotate_time
@property
def rotate_speed(self) -> float:
return self._rotate_speed
@property
def pump_state(self) -> str:
return self._pump_state
@property
def pump_time(self) -> float:
return self._pump_time
@property
def vacuum_level(self) -> float:
return self._vacuum_level
@property
def temperature(self) -> float:
return self._temperature
@property
def target_temperature(self) -> float:
return self._target_temperature
# ==================== 设备控制方法 ====================
# 这些方法需要在注册表中添加会作为ActionServer接受控制指令
def set_timer(self, command: str) -> str:
"""
设置定时器 - 兼容现有RotavapOne接口
Args:
command (str): JSON格式的命令字符串包含rotate_time和pump_time
Returns:
str: 操作结果状态 ("Success", "Error")
"""
try:
timer = json.loads(command)
rotate_time = timer.get("rotate_time", 0)
pump_time = timer.get("pump_time", 0)
self.success = "False"
self._rotate_time = float(rotate_time)
self._pump_time = float(pump_time)
self.success = "True"
self._status = "Timer Set"
return "Success"
except (json.JSONDecodeError, ValueError, KeyError) as e:
self._status = f"Error: Invalid command format - {str(e)}"
self.success = "False"
return "Error"
def set_rotate_time(self, time_seconds: float) -> str:
"""
设置旋转时间
Args:
time_seconds (float): 旋转时间 (秒)
Returns:
str: 操作结果状态 ("Success", "Error")
"""
self.success = "False"
self._rotate_time = max(0.0, float(time_seconds))
self.success = "True"
self._status = "Rotate time set"
return "Success"
def set_pump_time(self, time_seconds: float) -> str:
"""
设置泵时间
Args:
time_seconds (float): 泵时间 (秒)
Returns:
str: 操作结果状态 ("Success", "Error")
"""
self.success = "False"
self._pump_time = max(0.0, float(time_seconds))
self.success = "True"
self._status = "Pump time set"
return "Success"
def set_rotate_speed(self, speed: float) -> str:
"""
设置旋转速度
Args:
speed (float): 旋转速度 (rpm)
Returns:
str: 操作结果状态 ("Success", "Error")
"""
if speed < 0 or speed > self._max_rotate_speed:
self._status = f"Error: Speed out of range (0-{self._max_rotate_speed})"
return "Error"
self._rotate_speed = speed
self._status = "Rotate speed set"
return "Success"
def set_temperature(self, temperature: float) -> str:
"""
设置水浴温度
Args:
temperature (float): 目标温度 (°C)
Returns:
str: 操作结果状态 ("Success", "Error")
"""
if temperature < 0 or temperature > self._max_temperature:
self._status = f"Error: Temperature out of range (0-{self._max_temperature})"
return "Error"
self._target_temperature = temperature
self._status = "Temperature set"
# 启动操作线程以开始温度控制
self._start_operation()
return "Success"
def start_rotation(self) -> str:
"""
启动旋转
Returns:
str: 操作结果状态 ("Success", "Error")
"""
if self._rotate_time <= 0:
self._status = "Error: No rotate time set"
return "Error"
self._rotate_state = "Running"
self._status = "Rotation started"
return "Success"
def start_pump(self) -> str:
"""
启动真空泵
Returns:
str: 操作结果状态 ("Success", "Error")
"""
if self._pump_time <= 0:
self._status = "Error: No pump time set"
return "Error"
self._pump_state = "Running"
self._status = "Pump started"
return "Success"
def stop_all_operations(self) -> str:
"""
停止所有操作
Returns:
str: 操作结果状态 ("Success", "Error")
"""
self._rotate_state = "Stopped"
self._pump_state = "Stopped"
self._stop_operation()
self._rotate_time = 0.0
self._pump_time = 0.0
self._vacuum_level = 0.0
self._status = "All operations stopped"
return "Success"
def emergency_stop(self) -> str:
"""
紧急停止
Returns:
str: 操作结果状态 ("Success", "Error")
"""
self._status = "Emergency Stop"
self.stop_all_operations()
return "Success"
# ==================== 内部控制方法 ====================
def _start_operation(self):
"""
启动操作线程
这个方法启动一个后台线程来模拟旋蒸的实际运行过程。
"""
with self._thread_lock:
if not self._running:
self._running = True
self._operation_thread = threading.Thread(target=self._operation_loop)
self._operation_thread.daemon = True
self._operation_thread.start()
def _stop_operation(self):
"""
停止操作线程
安全地停止后台运行线程并等待其完成。
"""
with self._thread_lock:
self._running = False
if self._operation_thread and self._operation_thread.is_alive():
self._operation_thread.join(timeout=2.0)
def _operation_loop(self):
"""
操作主循环
这个方法在后台线程中运行,模拟真实旋蒸的工作过程:
1. 时间倒计时
2. 温度控制
3. 真空度控制
4. 状态更新
"""
while self._running:
try:
# 处理旋转时间倒计时
if self._rotate_time > 0:
self._rotate_state = "Running"
self._rotate_time = max(0.0, self._rotate_time - 1.0)
else:
self._rotate_state = "Stopped"
# 处理泵时间倒计时
if self._pump_time > 0:
self._pump_state = "Running"
self._pump_time = max(0.0, self._pump_time - 1.0)
# 模拟真空度变化
if self._vacuum_level > self._target_vacuum:
self._vacuum_level = max(self._target_vacuum, self._vacuum_level - 5.0)
else:
self._pump_state = "Stopped"
# 真空度逐渐回升
self._vacuum_level = min(1013.25, self._vacuum_level + 2.0)
# 模拟温度控制
temp_diff = self._target_temperature - self._temperature
if abs(temp_diff) > 0.5:
if temp_diff > 0:
self._temperature += min(1.0, temp_diff * 0.1)
else:
self._temperature += max(-1.0, temp_diff * 0.1)
# 更新整体状态
if self._rotate_state == "Running" or self._pump_state == "Running":
self._status = "Operating"
elif self._rotate_time > 0 or self._pump_time > 0:
self._status = "Ready"
else:
self._status = "Idle"
# 等待1秒后继续下一次循环
time.sleep(1.0)
except Exception as e:
self._status = f"Error in operation: {str(e)}"
break
# 循环结束时的清理工作
self._status = "Idle"
def get_status_info(self) -> dict:
"""
获取完整的设备状态信息
Returns:
dict: 包含所有设备状态的字典
"""
return {
"status": self._status,
"rotate_state": self._rotate_state,
"rotate_time": self._rotate_time,
"rotate_speed": self._rotate_speed,
"pump_state": self._pump_state,
"pump_time": self._pump_time,
"vacuum_level": self._vacuum_level,
"temperature": self._temperature,
"target_temperature": self._target_temperature,
"success": self.success,
}
# 用于测试的主函数
if __name__ == "__main__":
rotavap = MockRotavap()
# 测试基本功能
print("启动旋转蒸发器测试...")
print(f"初始状态: {rotavap.get_status_info()}")
# 设置定时器
timer_command = '{"rotate_time": 300, "pump_time": 600}'
rotavap.set_timer(timer_command)
# 设置温度和转速
rotavap.set_temperature(60.0)
rotavap.set_rotate_speed(120.0)
# 启动操作
rotavap.start_rotation()
rotavap.start_pump()
# 模拟运行10秒
for i in range(10):
time.sleep(1)
print(
f"{i+1}秒: 旋转={rotavap.rotate_time:.0f}s, 泵={rotavap.pump_time:.0f}s, "
f"温度={rotavap.temperature:.1f}°C, 真空={rotavap.vacuum_level:.1f}mbar"
)
rotavap.emergency_stop()
print("测试完成")

399
unilabos/devices/mock/mock_separator.py
View File

@@ -1,399 +0,0 @@
import time
import threading
from datetime import datetime, timedelta
class MockSeparator:
def __init__(self, port: str = "MOCK"):
self.port = port
# 基本状态属性
self._status: str = "Idle" # 当前总体状态
self._valve_state: str = "Closed" # 阀门状态Open 或 Closed
self._settling_time: float = 0.0 # 静置时间(秒)
# 搅拌相关属性
self._shake_time: float = 0.0 # 剩余摇摆时间(秒)
self._shake_status: str = "Not Shaking" # 摇摆状态
# 用于后台模拟 shake 动作
self._operation_thread = None
self._thread_lock = threading.Lock()
self._running = False
# Separate action 相关属性
self._current_device: str = "MockSeparator1"
self._purpose: str = "" # wash or extract
self._product_phase: str = "" # top or bottom
self._from_vessel: str = ""
self._separation_vessel: str = ""
self._to_vessel: str = ""
self._waste_phase_to_vessel: str = ""
self._solvent: str = ""
self._solvent_volume: float = 0.0
self._through: str = ""
self._repeats: int = 1
self._stir_time: float = 0.0
self._stir_speed: float = 0.0
self._time_spent = timedelta()
self._time_remaining = timedelta()
self._start_time = datetime.now() # 添加这一行
@property
def current_device(self) -> str:
return self._current_device
@property
def purpose(self) -> str:
return self._purpose
@property
def valve_state(self) -> str:
return self._valve_state
@property
def settling_time(self) -> float:
return self._settling_time
@property
def status(self) -> str:
return self._status
@property
def shake_time(self) -> float:
with self._thread_lock:
return self._shake_time
@property
def shake_status(self) -> str:
with self._thread_lock:
return self._shake_status
@property
def product_phase(self) -> str:
return self._product_phase
@property
def from_vessel(self) -> str:
return self._from_vessel
@property
def separation_vessel(self) -> str:
return self._separation_vessel
@property
def to_vessel(self) -> str:
return self._to_vessel
@property
def waste_phase_to_vessel(self) -> str:
return self._waste_phase_to_vessel
@property
def solvent(self) -> str:
return self._solvent
@property
def solvent_volume(self) -> float:
return self._solvent_volume
@property
def through(self) -> str:
return self._through
@property
def repeats(self) -> int:
return self._repeats
@property
def stir_time(self) -> float:
return self._stir_time
@property
def stir_speed(self) -> float:
return self._stir_speed
@property
def time_spent(self) -> float:
if self._running:
self._time_spent = datetime.now() - self._start_time
return self._time_spent.total_seconds()
@property
def time_remaining(self) -> float:
if self._running:
elapsed = (datetime.now() - self._start_time).total_seconds()
total_time = (self._stir_time + self._settling_time + 10) * self._repeats
remain = max(0, total_time - elapsed)
self._time_remaining = timedelta(seconds=remain)
return self._time_remaining.total_seconds()
def separate(self, purpose: str, product_phase: str, from_vessel: str,
separation_vessel: str, to_vessel: str, waste_phase_to_vessel: str = "",
solvent: str = "", solvent_volume: float = 0.0, through: str = "",
repeats: int = 1, stir_time: float = 0.0, stir_speed: float = 0.0,
settling_time: float = 60.0) -> dict:
"""
执行分离操作
"""
with self._thread_lock:
# 检查是否已经在运行
if self._running:
return {
"success": False,
"status": "Error: Operation already in progress"
}
# 必填参数验证
if not all([from_vessel, separation_vessel, to_vessel]):
self._status = "Error: Missing required vessel parameters"
return {"success": False}
# 验证参数
if purpose not in ["wash", "extract"]:
self._status = "Error: Invalid purpose"
return {"success": False}
if product_phase not in ["top", "bottom"]:
self._status = "Error: Invalid product phase"
return {"success": False}
# 数值参数验证
try:
solvent_volume = float(solvent_volume)
repeats = int(repeats)
stir_time = float(stir_time)
stir_speed = float(stir_speed)
settling_time = float(settling_time)
except ValueError:
self._status = "Error: Invalid numeric parameters"
return {"success": False}
# 设置参数
self._purpose = purpose
self._product_phase = product_phase
self._from_vessel = from_vessel
self._separation_vessel = separation_vessel
self._to_vessel = to_vessel
self._waste_phase_to_vessel = waste_phase_to_vessel
self._solvent = solvent
self._solvent_volume = float(solvent_volume)
self._through = through
self._repeats = int(repeats)
self._stir_time = float(stir_time)
self._stir_speed = float(stir_speed)
self._settling_time = float(settling_time)
# 重置计时器
self._start_time = datetime.now()
self._time_spent = timedelta()
total_time = (self._stir_time + self._settling_time + 10) * self._repeats
self._time_remaining = timedelta(seconds=total_time)
# 启动分离操作
self._status = "Starting Separation"
self._running = True
# 在锁内创建和启动线程
self._operation_thread = threading.Thread(target=self._operation_loop)
self._operation_thread.daemon = True
self._operation_thread.start()
# 等待确认操作已经开始
time.sleep(0.1) # 短暂等待确保操作线程已启动
return {
"success": True,
"status": self._status,
"current_device": self._current_device,
"time_spent": self._time_spent.total_seconds(),
"time_remaining": self._time_remaining.total_seconds()
}
def shake(self, shake_time: float) -> str:
"""
模拟 shake搅拌操作
- 进入 "Shaking" 状态,倒计时 shake_time 秒
- shake 结束后,进入 "Settling" 状态,静置时间固定为 5 秒
- 最后恢复为 Idle
"""
try:
shake_time = float(shake_time)
except ValueError:
self._status = "Error: Invalid shake time"
return "Error"
with self._thread_lock:
self._status = "Shaking"
self._settling_time = 0.0
self._shake_time = shake_time
self._shake_status = "Shaking"
def _run_shake():
remaining = shake_time
while remaining > 0:
time.sleep(1)
remaining -= 1
with self._thread_lock:
self._shake_time = remaining
with self._thread_lock:
self._status = "Settling"
self._settling_time = 60.0 # 固定静置时间为60秒
self._shake_status = "Settling"
while True:
with self._thread_lock:
if self._settling_time <= 0:
self._status = "Idle"
self._shake_status = "Idle"
break
time.sleep(1)
with self._thread_lock:
self._settling_time = max(0.0, self._settling_time - 1)
self._operation_thread = threading.Thread(target=_run_shake)
self._operation_thread.daemon = True
self._operation_thread.start()
return "Success"
def set_valve(self, command: str) -> str:
"""
阀门控制命令:传入 "open""close"
"""
command = command.lower()
if command == "open":
self._valve_state = "Open"
self._status = "Valve Opened"
elif command == "close":
self._valve_state = "Closed"
self._status = "Valve Closed"
else:
self._status = "Error: Invalid valve command"
return "Error"
return "Success"
def _operation_loop(self):
"""分离操作主循环"""
try:
current_repeat = 1
# 立即更新状态确保不会停留在Starting Separation
with self._thread_lock:
self._status = f"Separation Cycle {current_repeat}/{self._repeats}"
while self._running and current_repeat <= self._repeats:
# 第一步:搅拌
if self._stir_time > 0:
with self._thread_lock:
self._status = f"Stirring (Repeat {current_repeat}/{self._repeats})"
remaining_stir = self._stir_time
while remaining_stir > 0 and self._running:
time.sleep(1)
remaining_stir -= 1
# 第二步:静置
if self._settling_time > 0:
with self._thread_lock:
self._status = f"Settling (Repeat {current_repeat}/{self._repeats})"
remaining_settle = self._settling_time
while remaining_settle > 0 and self._running:
time.sleep(1)
remaining_settle -= 1
# 第三步:打开阀门排出
with self._thread_lock:
self._valve_state = "Open"
self._status = f"Draining (Repeat {current_repeat}/{self._repeats})"
# 模拟排出时间5秒
time.sleep(10)
# 关闭阀门
with self._thread_lock:
self._valve_state = "Closed"
# 检查是否继续下一次重复
if current_repeat < self._repeats:
current_repeat += 1
else:
with self._thread_lock:
self._status = "Separation Complete"
break
except Exception as e:
with self._thread_lock:
self._status = f"Error in separation: {str(e)}"
finally:
with self._thread_lock:
self._running = False
self._valve_state = "Closed"
if self._status == "Starting Separation":
self._status = "Error: Operation failed to start"
elif self._status != "Separation Complete":
self._status = "Stopped"
def stop_operations(self) -> str:
"""停止任何正在执行的操作"""
with self._thread_lock:
self._running = False
if self._operation_thread and self._operation_thread.is_alive():
self._operation_thread.join(timeout=1.0)
self._operation_thread = None
self._settling_time = 0.0
self._status = "Idle"
self._shake_status = "Idle"
self._shake_time = 0.0
self._time_remaining = timedelta()
return "Success"
def get_status_info(self) -> dict:
"""获取当前设备状态信息"""
with self._thread_lock:
current_time = datetime.now()
if self._start_time:
self._time_spent = current_time - self._start_time
return {
"status": self._status,
"valve_state": self._valve_state,
"settling_time": self._settling_time,
"shake_time": self._shake_time,
"shake_status": self._shake_status,
"current_device": self._current_device,
"purpose": self._purpose,
"product_phase": self._product_phase,
"from_vessel": self._from_vessel,
"separation_vessel": self._separation_vessel,
"to_vessel": self._to_vessel,
"waste_phase_to_vessel": self._waste_phase_to_vessel,
"solvent": self._solvent,
"solvent_volume": self._solvent_volume,
"through": self._through,
"repeats": self._repeats,
"stir_time": self._stir_time,
"stir_speed": self._stir_speed,
"time_spent": self._time_spent.total_seconds(),
"time_remaining": self._time_remaining.total_seconds()
}
# 主函数用于测试
if __name__ == "__main__":
separator = MockSeparator()
print("启动简单版分离器测试...")
print("初始状态:", separator.get_status_info())
# 触发 shake 操作,模拟 10 秒的搅拌
print("执行 shake 操作...")
print(separator.shake(10.0))
# 循环显示状态变化
for i in range(20):
time.sleep(1)
info = separator.get_status_info()
print(
f"{i+1}秒: 状态={info['status']}, 静置时间={info['settling_time']:.1f}秒, "
f"阀门状态={info['valve_state']}, shake_time={info['shake_time']:.1f}, "
f"shake_status={info['shake_status']}"
)
# 模拟打开阀门
print("打开阀门...", separator.set_valve("open"))
print("最终状态:", separator.get_status_info())

89
unilabos/devices/mock/mock_solenoid_valve.py
View File

@@ -1,89 +0,0 @@
import time
class MockSolenoidValve:
"""
模拟电磁阀设备类 - 简化版本
这个类提供了电磁阀的基本功能:开启、关闭和状态查询
"""
def __init__(self, port: str = "MOCK"):
"""
初始化MockSolenoidValve实例
Args:
port (str): 设备端口,默认为"MOCK"表示模拟设备
"""
self.port = port
self._status: str = "Idle"
self._valve_status: str = "Closed" # 阀门位置Open, Closed
@property
def status(self) -> str:
"""设备状态 - 会被自动识别的设备属性"""
return self._status
@property
def valve_status(self) -> str:
"""阀门状态"""
return self._valve_status
def set_valve_status(self, status: str) -> str:
"""
设置阀门位置
Args:
position (str): 阀门位置,可选值:"Open", "Closed"
Returns:
str: 操作结果状态 ("Success", "Error")
"""
if status not in ["Open", "Closed"]:
self._status = "Error: Invalid position"
return "Error"
self._status = "Moving"
time.sleep(1) # 模拟阀门动作时间
self._valve_status = status
self._status = "Idle"
return "Success"
def open_valve(self) -> str:
"""打开阀门"""
return self.set_valve_status("Open")
def close_valve(self) -> str:
"""关闭阀门"""
return self.set_valve_status("Closed")
def get_valve_status(self) -> str:
"""获取阀门位置"""
return self._valve_status
def is_open(self) -> bool:
"""检查阀门是否打开"""
return self._valve_status == "Open"
def is_closed(self) -> bool:
"""检查阀门是否关闭"""
return self._valve_status == "Closed"
# 用于测试的主函数
if __name__ == "__main__":
valve = MockSolenoidValve()
print("启动电磁阀测试...")
print(f"初始状态: 位置={valve.valve_status}, 状态={valve.status}")
# 测试开启阀门
valve.open_valve()
print(f"开启后: 位置={valve.valve_status}, 状态={valve.status}")
# 测试关闭阀门
valve.close_valve()
print(f"关闭后: 位置={valve.valve_status}, 状态={valve.status}")
print("测试完成")

307
unilabos/devices/mock/mock_stirrer.py
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@@ -1,307 +0,0 @@
import time
import threading
class MockStirrer:
def __init__(self, port: str = "MOCK"):
self.port = port
# 设备基本状态属性
self._status: str = "Idle" # 设备状态Idle, Running, Error, Stopped
# 搅拌相关属性
self._stir_speed: float = 0.0 # 当前搅拌速度 (rpm)
self._target_stir_speed: float = 0.0 # 目标搅拌速度 (rpm)
self._max_stir_speed: float = 2000.0 # 最大搅拌速度 (rpm)
self._stir_state: str = "Stopped" # 搅拌状态Running, Stopped
# 温度相关属性
self._temperature: float = 25.0 # 当前温度 (°C)
self._target_temperature: float = 25.0 # 目标温度 (°C)
self._max_temperature: float = 300.0 # 最大温度 (°C)
self._heating_state: str = "Off" # 加热状态On, Off
self._heating_power: float = 0.0 # 加热功率百分比 0-100
# 运行控制线程
self._operation_thread = None
self._running = False
self._thread_lock = threading.Lock()
# ==================== 状态属性 ====================
# 这些属性会被Uni-Lab系统自动识别并定时对外广播
@property
def status(self) -> str:
return self._status
@property
def stir_speed(self) -> float:
return self._stir_speed
@property
def target_stir_speed(self) -> float:
return self._target_stir_speed
@property
def stir_state(self) -> str:
return self._stir_state
@property
def temperature(self) -> float:
"""
当前温度
Returns:
float: 当前温度 (°C)
"""
return self._temperature
@property
def target_temperature(self) -> float:
"""
目标温度
Returns:
float: 目标温度 (°C)
"""
return self._target_temperature
@property
def heating_state(self) -> str:
return self._heating_state
@property
def heating_power(self) -> float:
return self._heating_power
@property
def max_stir_speed(self) -> float:
return self._max_stir_speed
@property
def max_temperature(self) -> float:
return self._max_temperature
# ==================== 设备控制方法 ====================
# 这些方法需要在注册表中添加会作为ActionServer接受控制指令
def set_stir_speed(self, speed: float) -> str:
speed = float(speed) # 确保传入的速度是浮点数
if speed < 0 or speed > self._max_stir_speed:
self._status = f"Error: Speed out of range (0-{self._max_stir_speed})"
return "Error"
self._target_stir_speed = speed
self._status = "Setting Stir Speed"
# 如果设置了非零速度,启动搅拌
if speed > 0:
self._stir_state = "Running"
else:
self._stir_state = "Stopped"
return "Success"
def set_temperature(self, temperature: float) -> str:
temperature = float(temperature) # 确保传入的温度是浮点数
if temperature < 0 or temperature > self._max_temperature:
self._status = f"Error: Temperature out of range (0-{self._max_temperature})"
return "Error"
self._target_temperature = temperature
self._status = "Setting Temperature"
return "Success"
def start_stirring(self) -> str:
if self._target_stir_speed <= 0:
self._status = "Error: No target speed set"
return "Error"
self._stir_state = "Running"
self._status = "Stirring Started"
return "Success"
def stop_stirring(self) -> str:
self._stir_state = "Stopped"
self._target_stir_speed = 0.0
self._status = "Stirring Stopped"
return "Success"
def heating_control(self, heating_state: str = "On") -> str:
if heating_state not in ["On", "Off"]:
self._status = "Error: Invalid heating state"
return "Error"
self._heating_state = heating_state
if heating_state == "On":
self._status = "Heating On"
else:
self._status = "Heating Off"
self._heating_power = 0.0
return "Success"
def stop_all_operations(self) -> str:
self._stir_state = "Stopped"
self._heating_state = "Off"
self._stop_operation()
self._stir_speed = 0.0
self._target_stir_speed = 0.0
self._heating_power = 0.0
self._status = "All operations stopped"
return "Success"
def emergency_stop(self) -> str:
"""
紧急停止
Returns:
str: 操作结果状态 ("Success", "Error")
"""
self._status = "Emergency Stop"
self.stop_all_operations()
return "Success"
# ==================== 内部控制方法 ====================
def _start_operation(self):
with self._thread_lock:
if not self._running:
self._running = True
self._operation_thread = threading.Thread(target=self._operation_loop)
self._operation_thread.daemon = True
self._operation_thread.start()
def _stop_operation(self):
"""
停止操作线程
安全地停止后台运行线程并等待其完成。
"""
with self._thread_lock:
self._running = False
if self._operation_thread and self._operation_thread.is_alive():
self._operation_thread.join(timeout=2.0)
def _operation_loop(self):
while self._running:
try:
# 处理搅拌速度控制
if self._stir_state == "Running":
speed_diff = self._target_stir_speed - self._stir_speed
if abs(speed_diff) < 1.0: # 速度接近目标值
self._stir_speed = self._target_stir_speed
if self._stir_speed > 0:
self._status = "Stirring at Target Speed"
else:
# 模拟速度调节每秒调整10%的差值
adjustment = speed_diff * 0.1
self._stir_speed += adjustment
self._status = "Adjusting Stir Speed"
# 确保速度在合理范围内
self._stir_speed = max(0.0, min(self._max_stir_speed, self._stir_speed))
else:
# 搅拌停止时速度逐渐降为0
if self._stir_speed > 0:
self._stir_speed = max(0.0, self._stir_speed - 50.0) # 每秒减少50rpm
# 处理温度控制
if self._heating_state == "On":
temp_diff = self._target_temperature - self._temperature
if abs(temp_diff) < 0.5: # 温度接近目标值
self._heating_power = 20.0 # 维持温度的最小功率
elif temp_diff > 0: # 需要加热
# 根据温差调整加热功率
if temp_diff > 50:
self._heating_power = 100.0
elif temp_diff > 20:
self._heating_power = 80.0
elif temp_diff > 10:
self._heating_power = 60.0
else:
self._heating_power = 40.0
# 模拟加热过程
heating_rate = self._heating_power / 100.0 * 1.5 # 最大每秒升温1.5度
self._temperature += heating_rate
else: # 目标温度低于当前温度
self._heating_power = 0.0
# 自然冷却
self._temperature -= 0.1
else:
self._heating_power = 0.0
# 自然冷却到室温
if self._temperature > 25.0:
self._temperature -= 0.2
# 限制温度范围
self._temperature = max(20.0, min(self._max_temperature, self._temperature))
# 更新整体状态
if self._stir_state == "Running" and self._heating_state == "On":
self._status = "Stirring and Heating"
elif self._stir_state == "Running":
self._status = "Stirring Only"
elif self._heating_state == "On":
self._status = "Heating Only"
else:
self._status = "Idle"
# 等待1秒后继续下一次循环
time.sleep(1.0)
except Exception as e:
self._status = f"Error in operation: {str(e)}"
break
# 循环结束时的清理工作
self._status = "Idle"
def get_status_info(self) -> dict:
return {
"status": self._status,
"stir_speed": self._stir_speed,
"target_stir_speed": self._target_stir_speed,
"stir_state": self._stir_state,
"temperature": self._temperature,
"target_temperature": self._target_temperature,
"heating_state": self._heating_state,
"heating_power": self._heating_power,
"max_stir_speed": self._max_stir_speed,
"max_temperature": self._max_temperature,
}
# 用于测试的主函数
if __name__ == "__main__":
stirrer = MockStirrer()
# 测试基本功能
print("启动搅拌器测试...")
print(f"初始状态: {stirrer.get_status_info()}")
# 设置搅拌速度和温度
stirrer.set_stir_speed(800.0)
stirrer.set_temperature(60.0)
stirrer.heating_control("On")
# 模拟运行15秒
for i in range(15):
time.sleep(1)
print(
f"{i+1}秒: 速度={stirrer.stir_speed:.0f}rpm, 温度={stirrer.temperature:.1f}°C, "
f"功率={stirrer.heating_power:.1f}%, 状态={stirrer.status}"
)
stirrer.emergency_stop()
print("测试完成")

229
unilabos/devices/mock/mock_stirrer_new.py
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@@ -1,229 +0,0 @@
import time
import threading
from datetime import datetime, timedelta
class MockStirrer_new:
def __init__(self, port: str = "MOCK"):
self.port = port
# 基本状态属性
self._status: str = "Idle"
self._vessel: str = ""
self._purpose: str = ""
# 搅拌相关属性
self._stir_speed: float = 0.0
self._target_stir_speed: float = 0.0
self._max_stir_speed: float = 2000.0
self._stir_state: str = "Stopped"
# 计时相关
self._stir_time: float = 0.0
self._settling_time: float = 0.0
self._start_time = datetime.now()
self._time_remaining = timedelta()
# 运行控制
self._operation_thread = None
self._running = False
self._thread_lock = threading.Lock()
# 创建操作线程
self._operation_thread = threading.Thread(target=self._operation_loop)
self._operation_thread.daemon = True
self._operation_thread.start()
# ==================== 状态属性 ====================
@property
def status(self) -> str:
return self._status
@property
def stir_speed(self) -> float:
return self._stir_speed
@property
def target_stir_speed(self) -> float:
return self._target_stir_speed
@property
def stir_state(self) -> str:
return self._stir_state
@property
def vessel(self) -> str:
return self._vessel
@property
def purpose(self) -> str:
return self._purpose
@property
def stir_time(self) -> float:
return self._stir_time
@property
def settling_time(self) -> float:
return self._settling_time
@property
def max_stir_speed(self) -> float:
return self._max_stir_speed
@property
def progress(self) -> float:
"""返回当前操作的进度0-100"""
if not self._running:
return 0.0
elapsed = (datetime.now() - self._start_time).total_seconds()
total_time = self._stir_time + self._settling_time
if total_time <= 0:
return 100.0
return min(100.0, (elapsed / total_time) * 100)
# ==================== Action Server 方法 ====================
def start_stir(self, vessel: str, stir_speed: float = 0.0, purpose: str = "") -> dict:
"""
StartStir.action 对应的方法
"""
with self._thread_lock:
if self._running:
return {
"success": False,
"message": "Operation already in progress"
}
try:
# 重置所有参数
self._vessel = vessel
self._purpose = purpose
self._stir_time = 0.0 # 连续搅拌模式下不设置搅拌时间
self._settling_time = 0.0
self._start_time = datetime.now() # 重置开始时间
if stir_speed > 0:
self._target_stir_speed = min(stir_speed, self._max_stir_speed)
self._stir_state = "Running"
self._status = "Stirring Started"
self._running = True
return {
"success": True,
"message": "Stirring started successfully"
}
except Exception as e:
return {
"success": False,
"message": f"Error: {str(e)}"
}
def stir(self, stir_time: float, stir_speed: float, settling_time: float) -> dict:
"""
Stir.action 对应的方法
"""
with self._thread_lock:
try:
# 如果已经在运行,先停止当前操作
if self._running:
self._running = False
self._stir_state = "Stopped"
self._target_stir_speed = 0.0
time.sleep(0.1) # 给一个短暂的停止时间
# 重置所有参数
self._stir_time = float(stir_time)
self._settling_time = float(settling_time)
self._target_stir_speed = min(float(stir_speed), self._max_stir_speed)
self._start_time = datetime.now() # 重置开始时间
self._stir_state = "Running"
self._status = "Stirring"
self._running = True
return {"success": True}
except ValueError:
self._status = "Error: Invalid parameters"
return {"success": False}
def stop_stir(self, vessel: str) -> dict:
"""
StopStir.action 对应的方法
"""
with self._thread_lock:
if vessel != self._vessel:
return {
"success": False,
"message": "Vessel mismatch"
}
self._running = False
self._stir_state = "Stopped"
self._target_stir_speed = 0.0
self._status = "Stirring Stopped"
return {
"success": True,
"message": "Stirring stopped successfully"
}
# ==================== 内部控制方法 ====================
def _operation_loop(self):
"""操作主循环"""
while True:
try:
current_time = datetime.now()
with self._thread_lock: # 添加锁保护
if self._stir_state == "Running":
# 实际搅拌逻辑
speed_diff = self._target_stir_speed - self._stir_speed
if abs(speed_diff) > 0.1:
adjustment = speed_diff * 0.1
self._stir_speed += adjustment
else:
self._stir_speed = self._target_stir_speed
# 更新进度
if self._running:
if self._stir_time > 0: # 定时搅拌模式
elapsed = (current_time - self._start_time).total_seconds()
if elapsed >= self._stir_time + self._settling_time:
self._running = False
self._stir_state = "Stopped"
self._target_stir_speed = 0.0
self._stir_speed = 0.0
self._status = "Stirring Complete"
elif elapsed >= self._stir_time:
self._status = "Settling"
else: # 连续搅拌模式
self._status = "Stirring"
else:
# 停止状态下慢慢降低速度
if self._stir_speed > 0:
self._stir_speed = max(0, self._stir_speed - 20.0)
time.sleep(0.1)
except Exception as e:
print(f"Error in operation loop: {str(e)}") # 添加错误输出
self._status = f"Error: {str(e)}"
time.sleep(1.0) # 错误发生时等待较长时间
def get_status_info(self) -> dict:
"""获取设备状态信息"""
return {
"status": self._status,
"vessel": self._vessel,
"purpose": self._purpose,
"stir_speed": self._stir_speed,
"target_stir_speed": self._target_stir_speed,
"stir_state": self._stir_state,
"stir_time": self._stir_time, # 添加
"settling_time": self._settling_time, # 添加
"progress": self.progress,
"max_stir_speed": self._max_stir_speed
}

410
unilabos/devices/mock/mock_vacuum.py
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@@ -1,410 +0,0 @@
import time
import threading
class MockVacuum:
"""
模拟真空泵设备类
这个类模拟了一个实验室真空泵的行为,包括真空度控制、
压力监测、运行状态管理等功能。参考了现有的 VacuumPumpMock 实现。
"""
def __init__(self, port: str = "MOCK"):
"""
初始化MockVacuum实例
Args:
port (str): 设备端口,默认为"MOCK"表示模拟设备
"""
self.port = port
# 设备基本状态属性
self._status: str = "Idle" # 设备状态Idle, Running, Error, Stopped
self._power_state: str = "Off" # 电源状态On, Off
self._pump_state: str = "Stopped" # 泵运行状态Running, Stopped, Paused
# 真空相关属性
self._vacuum_level: float = 1013.25 # 当前真空度 (mbar) - 大气压开始
self._target_vacuum: float = 50.0 # 目标真空度 (mbar)
self._min_vacuum: float = 1.0 # 最小真空度 (mbar)
self._max_vacuum: float = 1013.25 # 最大真空度 (mbar) - 大气压
# 泵性能相关属性
self._pump_speed: float = 0.0 # 泵速 (L/s)
self._max_pump_speed: float = 100.0 # 最大泵速 (L/s)
self._pump_efficiency: float = 95.0 # 泵效率百分比
# 运行控制线程
self._vacuum_thread = None
self._running = False
self._thread_lock = threading.Lock()
# ==================== 状态属性 ====================
# 这些属性会被Uni-Lab系统自动识别并定时对外广播
@property
def status(self) -> str:
"""
设备状态 - 会被自动识别的设备属性
Returns:
str: 当前设备状态 (Idle, Running, Error, Stopped)
"""
return self._status
@property
def power_state(self) -> str:
"""
电源状态
Returns:
str: 电源状态 (On, Off)
"""
return self._power_state
@property
def pump_state(self) -> str:
"""
泵运行状态
Returns:
str: 泵状态 (Running, Stopped, Paused)
"""
return self._pump_state
@property
def vacuum_level(self) -> float:
"""
当前真空度
Returns:
float: 当前真空度 (mbar)
"""
return self._vacuum_level
@property
def target_vacuum(self) -> float:
"""
目标真空度
Returns:
float: 目标真空度 (mbar)
"""
return self._target_vacuum
@property
def pump_speed(self) -> float:
"""
泵速
Returns:
float: 泵速 (L/s)
"""
return self._pump_speed
@property
def pump_efficiency(self) -> float:
"""
泵效率
Returns:
float: 泵效率百分比
"""
return self._pump_efficiency
@property
def max_pump_speed(self) -> float:
"""
最大泵速
Returns:
float: 最大泵速 (L/s)
"""
return self._max_pump_speed
# ==================== 设备控制方法 ====================
# 这些方法需要在注册表中添加会作为ActionServer接受控制指令
def power_control(self, power_state: str = "On") -> str:
"""
电源控制方法
Args:
power_state (str): 电源状态,可选值:"On", "Off"
Returns:
str: 操作结果状态 ("Success", "Error")
"""
if power_state not in ["On", "Off"]:
self._status = "Error: Invalid power state"
return "Error"
self._power_state = power_state
if power_state == "On":
self._status = "Power On"
self._start_vacuum_operation()
else:
self._status = "Power Off"
self.stop_vacuum()
return "Success"
def set_vacuum_level(self, vacuum_level: float) -> str:
"""
设置目标真空度
Args:
vacuum_level (float): 目标真空度 (mbar)
Returns:
str: 操作结果状态 ("Success", "Error")
"""
try:
vacuum_level = float(vacuum_level)
except ValueError:
self._status = "Error: Invalid vacuum level"
return "Error"
if self._power_state != "On":
self._status = "Error: Power Off"
return "Error"
if vacuum_level < self._min_vacuum or vacuum_level > self._max_vacuum:
self._status = f"Error: Vacuum level out of range ({self._min_vacuum}-{self._max_vacuum})"
return "Error"
self._target_vacuum = vacuum_level
self._status = "Setting Vacuum Level"
return "Success"
def start_vacuum(self) -> str:
"""
启动真空泵
Returns:
str: 操作结果状态 ("Success", "Error")
"""
if self._power_state != "On":
self._status = "Error: Power Off"
return "Error"
self._pump_state = "Running"
self._status = "Starting Vacuum Pump"
self._start_vacuum_operation()
return "Success"
def stop_vacuum(self) -> str:
"""
停止真空泵
Returns:
str: 操作结果状态 ("Success", "Error")
"""
self._pump_state = "Stopped"
self._status = "Stopping Vacuum Pump"
self._stop_vacuum_operation()
self._pump_speed = 0.0
return "Success"
def pause_vacuum(self) -> str:
"""
暂停真空泵
Returns:
str: 操作结果状态 ("Success", "Error")
"""
if self._pump_state != "Running":
self._status = "Error: Pump not running"
return "Error"
self._pump_state = "Paused"
self._status = "Vacuum Pump Paused"
self._stop_vacuum_operation()
return "Success"
def resume_vacuum(self) -> str:
"""
恢复真空泵运行
Returns:
str: 操作结果状态 ("Success", "Error")
"""
if self._pump_state != "Paused":
self._status = "Error: Pump not paused"
return "Error"
if self._power_state != "On":
self._status = "Error: Power Off"
return "Error"
self._pump_state = "Running"
self._status = "Resuming Vacuum Pump"
self._start_vacuum_operation()
return "Success"
def vent_to_atmosphere(self) -> str:
"""
通大气 - 将真空度恢复到大气压
Returns:
str: 操作结果状态 ("Success", "Error")
"""
self._target_vacuum = self._max_vacuum # 设置为大气压
self._status = "Venting to Atmosphere"
return "Success"
def emergency_stop(self) -> str:
"""
紧急停止
Returns:
str: 操作结果状态 ("Success", "Error")
"""
self._status = "Emergency Stop"
self._pump_state = "Stopped"
self._stop_vacuum_operation()
self._pump_speed = 0.0
return "Success"
# ==================== 内部控制方法 ====================
def _start_vacuum_operation(self):
"""
启动真空操作线程
这个方法启动一个后台线程来模拟真空泵的实际运行过程。
"""
with self._thread_lock:
if not self._running and self._power_state == "On":
self._running = True
self._vacuum_thread = threading.Thread(target=self._vacuum_operation_loop)
self._vacuum_thread.daemon = True
self._vacuum_thread.start()
def _stop_vacuum_operation(self):
"""
停止真空操作线程
安全地停止后台运行线程并等待其完成。
"""
with self._thread_lock:
self._running = False
if self._vacuum_thread and self._vacuum_thread.is_alive():
self._vacuum_thread.join(timeout=2.0)
def _vacuum_operation_loop(self):
"""
真空操作主循环
这个方法在后台线程中运行,模拟真空泵的工作过程:
1. 检查电源状态和运行状态
2. 如果泵状态为 "Running",根据目标真空调整泵速和真空度
3. 否则等待
"""
while self._running and self._power_state == "On":
try:
with self._thread_lock:
# 只有泵状态为 Running 时才进行更新
if self._pump_state == "Running":
vacuum_diff = self._vacuum_level - self._target_vacuum
if abs(vacuum_diff) < 1.0: # 真空度接近目标值
self._status = "At Target Vacuum"
self._pump_speed = self._max_pump_speed * 0.2 # 维持真空的最小泵速
elif vacuum_diff > 0: # 需要抽真空(降低压力)
self._status = "Pumping Down"
if vacuum_diff > 500:
self._pump_speed = self._max_pump_speed
elif vacuum_diff > 100:
self._pump_speed = self._max_pump_speed * 0.8
elif vacuum_diff > 50:
self._pump_speed = self._max_pump_speed * 0.6
else:
self._pump_speed = self._max_pump_speed * 0.4
# 根据泵速和效率计算真空降幅
pump_rate = (self._pump_speed / self._max_pump_speed) * self._pump_efficiency / 100.0
vacuum_reduction = pump_rate * 10.0 # 每秒最大降低10 mbar
self._vacuum_level = max(self._target_vacuum, self._vacuum_level - vacuum_reduction)
else: # 目标真空度高于当前值,需要通气
self._status = "Venting"
self._pump_speed = 0.0
self._vacuum_level = min(self._target_vacuum, self._vacuum_level + 5.0)
# 限制真空度范围
self._vacuum_level = max(self._min_vacuum, min(self._max_vacuum, self._vacuum_level))
else:
# 当泵状态不是 Running 时,可保持原状态
self._status = "Vacuum Pump Not Running"
# 释放锁后等待1秒钟
time.sleep(1.0)
except Exception as e:
with self._thread_lock:
self._status = f"Error in vacuum operation: {str(e)}"
break
# 循环结束后的清理工作
if self._pump_state == "Running":
self._status = "Idle"
# 停止泵后,真空度逐渐回升到大气压
while self._vacuum_level < self._max_vacuum * 0.9:
with self._thread_lock:
self._vacuum_level += 2.0
time.sleep(0.1)
def get_status_info(self) -> dict:
"""
获取完整的设备状态信息
Returns:
dict: 包含所有设备状态的字典
"""
return {
"status": self._status,
"power_state": self._power_state,
"pump_state": self._pump_state,
"vacuum_level": self._vacuum_level,
"target_vacuum": self._target_vacuum,
"pump_speed": self._pump_speed,
"pump_efficiency": self._pump_efficiency,
"max_pump_speed": self._max_pump_speed,
}
# 用于测试的主函数
if __name__ == "__main__":
vacuum = MockVacuum()
# 测试基本功能
print("启动真空泵测试...")
vacuum.power_control("On")
print(f"初始状态: {vacuum.get_status_info()}")
# 设置目标真空度并启动
vacuum.set_vacuum_level(10.0) # 设置为10mbar
vacuum.start_vacuum()
# 模拟运行15秒
for i in range(15):
time.sleep(1)
print(
f"{i+1}秒: 真空度={vacuum.vacuum_level:.1f}mbar, 泵速={vacuum.pump_speed:.1f}L/s, 状态={vacuum.status}"
)
# 测试通大气
print("测试通大气...")
vacuum.vent_to_atmosphere()
# 继续运行5秒观察通大气过程
for i in range(5):
time.sleep(1)
print(f"通大气第{i+1}秒: 真空度={vacuum.vacuum_level:.1f}mbar, 状态={vacuum.status}")
vacuum.emergency_stop()
print("测试完成")

0
unilabos/devices/laiyu_add_solid/laiyu.py → unilabos/devices/powder_dispense/laiyu.py
View File

6
unilabos/devices/pump_and_valve/runze_backbone.py
View File

@@ -3,6 +3,7 @@ from threading import Lock, Event
from enum import Enum
from dataclasses import dataclass
import time
import traceback
from typing import Any, Union, Optional, overload
import serial.tools.list_ports
@@ -386,3 +387,8 @@ class RunzeSyringePump:
def list():
for item in serial.tools.list_ports.comports():
yield RunzeSyringePumpInfo(port=item.device)
if __name__ == "__main__":
r = RunzeSyringePump("/dev/tty.usbserial-D30JUGG5", "1", 25.0)
r.initialize()

282
unilabos/devices/separator/chinwe.py Normal file
View File

@@ -0,0 +1,282 @@
import sys
import threading
import serial
import serial.tools.list_ports
import re
import time
from typing import Optional, List, Dict, Tuple
class ChinweDevice:
"""
ChinWe设备控制类
提供串口通信、电机控制、传感器数据读取等功能
"""
def __init__(self, port: str, baudrate: int = 115200, debug: bool = False):
"""
初始化ChinWe设备
Args:
port: 串口名称如果为None则自动检测
baudrate: 波特率默认115200
"""
self.debug = debug
self.port = port
self.baudrate = baudrate
self.serial_port: Optional[serial.Serial] = None
self._voltage: float = 0.0
self._ec_value: float = 0.0
self._ec_adc_value: int = 0
self._is_connected = False
self.connect()
@property
def is_connected(self) -> bool:
"""获取连接状态"""
return self._is_connected and self.serial_port and self.serial_port.is_open
@property
def voltage(self) -> float:
"""获取电源电压值"""
return self._voltage
@property
def ec_value(self) -> float:
"""获取电导率值 (ms/cm)"""
return self._ec_value
@property
def ec_adc_value(self) -> int:
"""获取EC ADC原始值"""
return self._ec_adc_value
@property
def device_status(self) -> Dict[str, any]:
"""
获取设备状态信息
Returns:
包含设备状态的字典
"""
return {
"connected": self.is_connected,
"port": self.port,
"baudrate": self.baudrate,
"voltage": self.voltage,
"ec_value": self.ec_value,
"ec_adc_value": self.ec_adc_value
}
def connect(self, port: Optional[str] = None, baudrate: Optional[int] = None) -> bool:
"""
连接到串口设备
Args:
port: 串口名称如果为None则使用初始化时的port或自动检测
baudrate: 波特率如果为None则使用初始化时的baudrate
Returns:
连接是否成功
"""
if self.is_connected:
return True
target_port = port or self.port
target_baudrate = baudrate or self.baudrate
try:
self.serial_port = serial.Serial(target_port, target_baudrate, timeout=0.5)
self._is_connected = True
self.port = target_port
self.baudrate = target_baudrate
connect_allow_times = 5
while not self.serial_port.is_open and connect_allow_times > 0:
time.sleep(0.5)
connect_allow_times -= 1
print(f"尝试连接到 {target_port} @ {target_baudrate},剩余尝试次数: {connect_allow_times}", self.debug)
raise ValueError("串口未打开,请检查设备连接")
print(f"已连接到 {target_port} @ {target_baudrate}", self.debug)
threading.Thread(target=self._read_data, daemon=True).start()
return True
except Exception as e:
print(f"ChinweDevice连接失败: {e}")
self._is_connected = False
return False
def disconnect(self) -> bool:
"""
断开串口连接
Returns:
断开是否成功
"""
if self.serial_port and self.serial_port.is_open:
try:
self.serial_port.close()
self._is_connected = False
print("已断开串口连接")
return True
except Exception as e:
print(f"断开连接失败: {e}")
return False
return True
def _send_motor_command(self, command: str) -> bool:
"""
发送电机控制命令
Args:
command: 电机命令字符串,例如 "M 1 CW 1.5"
Returns:
发送是否成功
"""
if not self.is_connected:
print("设备未连接")
return False
try:
self.serial_port.write((command + "\n").encode('utf-8'))
print(f"发送命令: {command}")
return True
except Exception as e:
print(f"发送命令失败: {e}")
return False
def rotate_motor(self, motor_id: int, turns: float, clockwise: bool = True) -> bool:
"""
使电机转动指定圈数
Args:
motor_id: 电机ID1, 2, 3...
turns: 转动圈数,支持小数
clockwise: True为顺时针False为逆时针
Returns:
命令发送是否成功
"""
if clockwise:
command = f"M {motor_id} CW {turns}"
else:
command = f"M {motor_id} CCW {turns}"
return self._send_motor_command(command)
def set_motor_speed(self, motor_id: int, speed: float) -> bool:
"""
设置电机转速(如果设备支持)
Args:
motor_id: 电机ID1, 2, 3...
speed: 转速值
Returns:
命令发送是否成功
"""
command = f"M {motor_id} SPEED {speed}"
return self._send_motor_command(command)
def _read_data(self) -> List[str]:
"""
读取串口数据并解析
Returns:
读取到的数据行列表
"""
print("开始读取串口数据...")
if not self.is_connected:
return []
data_lines = []
try:
while self.serial_port.in_waiting:
time.sleep(0.1) # 等待数据稳定
try:
line = self.serial_port.readline().decode('utf-8', errors='ignore').strip()
if line:
data_lines.append(line)
self._parse_sensor_data(line)
except Exception as ex:
print(f"解码数据错误: {ex}")
except Exception as e:
print(f"读取串口数据错误: {e}")
return data_lines
def _parse_sensor_data(self, line: str) -> None:
"""
解析传感器数据
Args:
line: 接收到的数据行
"""
# 解析电源电压
if "电源电压" in line:
try:
val = float(line.split("")[1].replace("V", "").strip())
self._voltage = val
if self.debug:
print(f"电源电压更新: {val}V")
except Exception:
pass
# 解析电导率和ADC原始值支持两种格式
if "电导率" in line and "ADC原始值" in line:
try:
# 支持格式如电导率2.50ms/cm, ADC原始值2052
ec_match = re.search(r"电导率[:]\s*([\d\.]+)", line)
adc_match = re.search(r"ADC原始值[:]\s*(\d+)", line)
if ec_match:
ec_val = float(ec_match.group(1))
self._ec_value = ec_val
if self.debug:
print(f"电导率更新: {ec_val:.2f} ms/cm")
if adc_match:
adc_val = int(adc_match.group(1))
self._ec_adc_value = adc_val
if self.debug:
print(f"EC ADC原始值更新: {adc_val}")
except Exception:
pass
# 仅电导率无ADC原始值
elif "电导率" in line:
try:
val = float(line.split("")[1].replace("ms/cm", "").strip())
self._ec_value = val
if self.debug:
print(f"电导率更新: {val:.2f} ms/cm")
except Exception:
pass
# 仅ADC原始值如有分开回传场景
elif "ADC原始值" in line:
try:
adc_val = int(line.split("")[1].strip())
self._ec_adc_value = adc_val
if self.debug:
print(f"EC ADC原始值更新: {adc_val}")
except Exception:
pass
def spin_when_ec_ge_0():
pass
def main():
"""测试函数"""
print("=== ChinWe设备测试 ===")
# 创建设备实例
device = ChinweDevice("/dev/tty.usbserial-A5069RR4", debug=True)
try:
# 测试5: 发送电机命令
print("\n5. 发送电机命令测试:")
print(" 5.3 使用通用函数控制电机20顺时针转2圈:")
device.rotate_motor(2, 20.0, clockwise=True)
time.sleep(0.5)
finally:
time.sleep(10)
# 测试7: 断开连接
print("\n7. 断开连接:")
device.disconnect()
if __name__ == "__main__":
main()

52
unilabos/devices/virtual/virtual_filter.py
View File

@@ -3,6 +3,8 @@ import logging
import time as time_module
from typing import Dict, Any, Optional
from unilabos.compile.utils.vessel_parser import get_vessel
class VirtualFilter:
"""Virtual filter device - 完全按照 Filter.action 规范 🌊"""
@@ -40,7 +42,6 @@ class VirtualFilter:
"progress": 0.0, # Filter.action feedback
"current_temp": 25.0, # Filter.action feedback
"filtered_volume": 0.0, # Filter.action feedback
"current_status": "Ready for filtration", # Filter.action feedback
"message": "Ready for filtration"
})
@@ -52,9 +53,7 @@ class VirtualFilter:
self.logger.info(f"🧹 清理虚拟过滤器 {self.device_id} 🔚")
self.data.update({
"status": "Offline",
"current_status": "System offline",
"message": "System offline"
"status": "Offline"
})
self.logger.info(f"✅ 过滤器 {self.device_id} 清理完成 💤")
@@ -62,8 +61,8 @@ class VirtualFilter:
async def filter(
self,
vessel: str,
filtrate_vessel: str = "",
vessel: dict,
filtrate_vessel: dict = {},
stir: bool = False,
stir_speed: float = 300.0,
temp: float = 25.0,
@@ -71,7 +70,9 @@ class VirtualFilter:
volume: float = 0.0
) -> bool:
"""Execute filter action - 完全按照 Filter.action 参数 🌊"""
vessel_id, _ = get_vessel(vessel)
filtrate_vessel_id, _ = get_vessel(filtrate_vessel) if filtrate_vessel else (f"{vessel_id}_filtrate", {})
# 🔧 新增:温度自动调整
original_temp = temp
if temp == 0.0:
@@ -81,7 +82,7 @@ class VirtualFilter:
temp = 4.0 # 小于4度自动设置为4度
self.logger.info(f"🌡️ 温度自动调整: {original_temp}°C → {temp}°C (最低温度) ❄️")
self.logger.info(f"🌊 开始过滤操作: {vessel}{filtrate_vessel} 🚰")
self.logger.info(f"🌊 开始过滤操作: {vessel_id}{filtrate_vessel_id} 🚰")
self.logger.info(f" 🌪️ 搅拌: {stir} ({stir_speed} RPM)")
self.logger.info(f" 🌡️ 温度: {temp}°C")
self.logger.info(f" 💧 体积: {volume}mL")
@@ -93,7 +94,6 @@ class VirtualFilter:
self.logger.error(f"{error_msg}")
self.data.update({
"status": f"Error: 温度超出范围 ⚠️",
"current_status": f"Error: 温度超出范围 ⚠️",
"message": error_msg
})
return False
@@ -103,7 +103,6 @@ class VirtualFilter:
self.logger.error(f"{error_msg}")
self.data.update({
"status": f"Error: 搅拌速度超出范围 ⚠️",
"current_status": f"Error: 搅拌速度超出范围 ⚠️",
"message": error_msg
})
return False
@@ -112,8 +111,7 @@ class VirtualFilter:
error_msg = f"💧 过滤体积 {volume} mL 超出范围 (0-{self._max_volume} mL) ⚠️"
self.logger.error(f"{error_msg}")
self.data.update({
"status": f"Error: 体积超出范围 ⚠️",
"current_status": f"Error: 体积超出范围 ⚠️",
"status": f"Error",
"message": error_msg
})
return False
@@ -123,12 +121,11 @@ class VirtualFilter:
self.logger.info(f"🚀 开始过滤 {filter_volume}mL 液体 💧")
self.data.update({
"status": f"🌊 过滤中: {vessel}",
"status": f"Running",
"current_temp": temp,
"filtered_volume": 0.0,
"progress": 0.0,
"current_status": f"🌊 Filtering {vessel}{filtrate_vessel}",
"message": f"🚀 Starting filtration: {vessel}{filtrate_vessel}"
"message": f"🚀 Starting filtration: {vessel_id}{filtrate_vessel_id}"
})
try:
@@ -164,8 +161,7 @@ class VirtualFilter:
"progress": progress, # Filter.action feedback
"current_temp": temp, # Filter.action feedback
"filtered_volume": current_filtered, # Filter.action feedback
"current_status": f"🌊 Filtering: {progress:.1f}% complete", # Filter.action feedback
"status": status_msg,
"status": "Running",
"message": f"🌊 Filtering: {progress:.1f}% complete, {current_filtered:.1f}mL filtered"
})
@@ -190,11 +186,10 @@ class VirtualFilter:
"progress": 100.0, # Filter.action feedback
"current_temp": final_temp, # Filter.action feedback
"filtered_volume": filter_volume, # Filter.action feedback
"current_status": f"✅ Filtration completed: {filter_volume}mL", # Filter.action feedback
"message": f"✅ Filtration completed: {filter_volume}mL filtered from {vessel}"
"message": f"✅ Filtration completed: {filter_volume}mL filtered from {vessel_id}"
})
self.logger.info(f"🎉 过滤完成! 💧 {filter_volume}mL 从 {vessel} 过滤到 {filtrate_vessel}")
self.logger.info(f"🎉 过滤完成! 💧 {filter_volume}mL 从 {vessel_id} 过滤到 {filtrate_vessel_id}")
self.logger.info(f"📊 最终状态: 温度 {final_temp}°C | 进度 100% | 体积 {filter_volume}mL 🏁")
return True
@@ -202,8 +197,7 @@ class VirtualFilter:
error_msg = f"过滤过程中发生错误: {str(e)} 💥"
self.logger.error(f"{error_msg}")
self.data.update({
"status": f"❌ 过滤错误: {str(e)}",
"current_status": f"❌ Filtration failed: {str(e)}",
"status": f"Error",
"message": f"❌ Filtration failed: {str(e)}"
})
return False
@@ -222,17 +216,17 @@ class VirtualFilter:
def current_temp(self) -> float:
"""Filter.action feedback 字段 🌡️"""
return self.data.get("current_temp", 25.0)
@property
def filtered_volume(self) -> float:
"""Filter.action feedback 字段 💧"""
return self.data.get("filtered_volume", 0.0)
@property
def current_status(self) -> str:
"""Filter.action feedback 字段 📋"""
return self.data.get("current_status", "")
@property
def filtered_volume(self) -> float:
"""Filter.action feedback 字段 💧"""
return self.data.get("filtered_volume", 0.0)
@property
def message(self) -> str:
return self.data.get("message", "")

39
unilabos/devices/virtual/virtual_heatchill.py
View File

@@ -67,8 +67,8 @@ class VirtualHeatChill:
self.logger.info(f"✅ 温控设备 {self.device_id} 清理完成 💤")
return True
async def heat_chill(self, vessel: str, temp: float, time, stir: bool,
stir_speed: float, purpose: str) -> bool:
async def heat_chill(self, temp: float, time, stir: bool,
stir_speed: float, purpose: str, vessel: dict = {}) -> bool:
"""Execute heat chill action - 🔧 修复:确保参数类型正确"""
# 🔧 关键修复:确保所有参数类型正确
@@ -77,7 +77,6 @@ class VirtualHeatChill:
time_value = float(time) # 强制转换为浮点数
stir_speed = float(stir_speed)
stir = bool(stir)
vessel = str(vessel)
purpose = str(purpose)
except (ValueError, TypeError) as e:
error_msg = f"参数类型转换错误: temp={temp}({type(temp)}), time={time}({type(time)}), error={str(e)}"
@@ -102,8 +101,7 @@ class VirtualHeatChill:
operation_mode = "Maintaining"
status_action = "保温"
self.logger.info(f"🌡️ 开始温控操作: {vessel}{temp}°C {temp_emoji}")
self.logger.info(f" 🥽 容器: {vessel}")
self.logger.info(f"🌡️ 开始温控操作: {temp}°C {temp_emoji}")
self.logger.info(f" 🎯 目标温度: {temp}°C {temp_emoji}")
self.logger.info(f" ⏰ 持续时间: {time_value}s")
self.logger.info(f" 🌪️ 搅拌: {stir} ({stir_speed} RPM)")
@@ -147,7 +145,7 @@ class VirtualHeatChill:
stir_info = f" | 🌪️ 搅拌: {stir_speed} RPM" if stir else ""
self.data.update({
"status": f"{temp_emoji} 运行中: {status_action} {vessel}{temp}°C | ⏰ 剩余: {total_time:.0f}s{stir_info}",
"status": f"{temp_emoji} 运行中: {status_action}{temp}°C | ⏰ 剩余: {total_time:.0f}s{stir_info}",
"operation_mode": operation_mode,
"is_stirring": stir,
"stir_speed": stir_speed if stir else 0.0,
@@ -165,7 +163,7 @@ class VirtualHeatChill:
# 更新剩余时间和状态
self.data.update({
"remaining_time": remaining,
"status": f"{temp_emoji} 运行中: {status_action} {vessel}{temp}°C | ⏰ 剩余: {remaining:.0f}s{stir_info}",
"status": f"{temp_emoji} 运行中: {status_action}{temp}°C | ⏰ 剩余: {remaining:.0f}s{stir_info}",
"progress": progress
})
@@ -185,7 +183,7 @@ class VirtualHeatChill:
final_stir_info = f" | 🌪️ 搅拌: {stir_speed} RPM" if stir else ""
self.data.update({
"status": f"✅ 完成: {vessel} 已达到 {temp}°C {temp_emoji} | ⏱️ 用时: {total_time:.0f}s{final_stir_info}",
"status": f"✅ 完成: 已达到 {temp}°C {temp_emoji} | ⏱️ 用时: {total_time:.0f}s{final_stir_info}",
"operation_mode": "Completed",
"remaining_time": 0.0,
"is_stirring": False,
@@ -195,7 +193,6 @@ class VirtualHeatChill:
self.logger.info(f"🎉 温控操作完成! ✨")
self.logger.info(f"📊 操作结果:")
self.logger.info(f" 🥽 容器: {vessel}")
self.logger.info(f" 🌡️ 达到温度: {temp}°C {temp_emoji}")
self.logger.info(f" ⏱️ 总用时: {total_time:.0f}s")
if stir:
@@ -204,13 +201,12 @@ class VirtualHeatChill:
return True
async def heat_chill_start(self, vessel: str, temp: float, purpose: str) -> bool:
async def heat_chill_start(self, temp: float, purpose: str, vessel: dict = {}) -> bool:
"""Start continuous heat chill 🔄"""
# 🔧 添加类型转换
try:
temp = float(temp)
vessel = str(vessel)
purpose = str(purpose)
except (ValueError, TypeError) as e:
error_msg = f"参数类型转换错误: {str(e)}"
@@ -235,8 +231,7 @@ class VirtualHeatChill:
operation_mode = "Maintaining"
status_action = "恒温保持"
self.logger.info(f"🔄 启动持续温控: {vessel}{temp}°C {temp_emoji}")
self.logger.info(f" 🥽 容器: {vessel}")
self.logger.info(f"🔄 启动持续温控: {temp}°C {temp_emoji}")
self.logger.info(f" 🎯 目标温度: {temp}°C {temp_emoji}")
self.logger.info(f" 🔄 模式: {status_action}")
self.logger.info(f" 📝 目的: {purpose}")
@@ -252,7 +247,7 @@ class VirtualHeatChill:
return False
self.data.update({
"status": f"🔄 启动: {status_action} {vessel}{temp}°C {temp_emoji} | ♾️ 持续运行",
"status": f"🔄 启动: {status_action}{temp}°C {temp_emoji} | ♾️ 持续运行",
"operation_mode": operation_mode,
"is_stirring": False,
"stir_speed": 0.0,
@@ -262,28 +257,20 @@ class VirtualHeatChill:
self.logger.info(f"✅ 持续温控已启动! {temp_emoji} {status_action}模式 🚀")
return True
async def heat_chill_stop(self, vessel: str) -> bool:
async def heat_chill_stop(self, vessel: dict = {}) -> bool:
"""Stop heat chill 🛑"""
# 🔧 添加类型转换
try:
vessel = str(vessel)
except (ValueError, TypeError) as e:
error_msg = f"参数类型转换错误: {str(e)}"
self.logger.error(f"{error_msg}")
return False
self.logger.info(f"🛑 停止温控: {vessel}")
self.logger.info(f"🛑 停止温控:")
self.data.update({
"status": f"🛑 已停止: {vessel} 温控停止",
"status": f"🛑 {self.device_id} 温控停止",
"operation_mode": "Stopped",
"is_stirring": False,
"stir_speed": 0.0,
"remaining_time": 0.0,
})
self.logger.info(f"✅ 温控设备已停止 {vessel} 温度控制 🏁")
self.logger.info(f"✅ 温控设备已停止 {self.device_id} 温度控制 🏁")
return True
# 状态属性

75
unilabos/devices/virtual/virtual_multiway_valve.py
View File

@@ -21,19 +21,6 @@ class VirtualMultiwayValve:
self._current_position = 0 # 默认在0号位transfer pump位置
self._target_position = 0
# 位置映射说明
self.position_map = {
0: "transfer_pump", # 0号位连接转移泵
1: "port_1", # 1号位
2: "port_2", # 2号位
3: "port_3", # 3号位
4: "port_4", # 4号位
5: "port_5", # 5号位
6: "port_6", # 6号位
7: "port_7", # 7号位
8: "port_8" # 8号位
}
print(f"🔄 === 虚拟多通阀门已创建 === ✨")
print(f"🎯 端口: {port} | 📊 位置范围: 0-{self.max_positions} | 🏠 初始位置: 0 (transfer_pump)")
self.logger.info(f"🔧 多通阀门初始化: 端口={port}, 最大位置={self.max_positions}")
@@ -60,7 +47,7 @@ class VirtualMultiwayValve:
def get_current_port(self) -> str:
"""获取当前连接的端口名称 🔌"""
return self.position_map.get(self._current_position, "unknown")
return self._current_position
def set_position(self, command: Union[int, str]):
"""
@@ -115,7 +102,7 @@ class VirtualMultiwayValve:
old_position = self._current_position
old_port = self.get_current_port()
self.logger.info(f"🔄 阀门切换: {old_position}({old_port}) → {pos}({self.position_map.get(pos, 'unknown')}) {pos_emoji}")
self.logger.info(f"🔄 阀门切换: {old_position}({old_port}) → {pos} {pos_emoji}")
self._status = "Busy"
self._valve_state = "Moving"
@@ -190,6 +177,17 @@ class VirtualMultiwayValve:
"""获取阀门位置 - 兼容性方法 📍"""
return self._current_position
def set_valve_position(self, command: Union[int, str]):
"""
设置阀门位置 - 兼容pump_protocol调用 🎯
这是set_position的别名方法用于兼容pump_protocol.py
Args:
command: 目标位置 (0-8) 或位置字符串
"""
# 删除debug日志self.logger.debug(f"🎯 兼容性调用: set_valve_position({command})")
return self.set_position(command)
def is_at_position(self, position: int) -> bool:
"""检查是否在指定位置 🎯"""
result = self._current_position == position
@@ -210,17 +208,6 @@ class VirtualMultiwayValve:
# 删除debug日志self.logger.debug(f"🔌 端口{port_number}检查: {port_status} (当前位置: {self._current_position})")
return result
def get_available_positions(self) -> list:
"""获取可用位置列表 📋"""
positions = list(range(0, self.max_positions + 1))
# 删除debug日志self.logger.debug(f"📋 可用位置: {positions}")
return positions
def get_available_ports(self) -> Dict[int, str]:
"""获取可用端口映射 🗺️"""
# 删除debug日志self.logger.debug(f"🗺️ 端口映射: {self.position_map}")
return self.position_map.copy()
def reset(self):
"""重置阀门到transfer pump位置0号位🔄"""
self.logger.info(f"🔄 重置阀门到泵位置...")
@@ -253,41 +240,12 @@ class VirtualMultiwayValve:
# 删除debug日志self.logger.debug(f"🌊 当前流路: {flow_path}")
return flow_path
def get_info(self) -> dict:
"""获取阀门详细信息 📊"""
info = {
"port": self.port,
"max_positions": self.max_positions,
"total_positions": self.total_positions,
"current_position": self._current_position,
"current_port": self.get_current_port(),
"target_position": self._target_position,
"status": self._status,
"valve_state": self._valve_state,
"flow_path": self.get_flow_path(),
"position_map": self.position_map
}
# 删除debug日志self.logger.debug(f"📊 阀门信息: 位置={self._current_position}, 状态={self._status}, 端口={self.get_current_port()}")
return info
def __str__(self):
current_port = self.get_current_port()
status_emoji = "" if self._status == "Idle" else "🔄" if self._status == "Busy" else ""
return f"🔄 VirtualMultiwayValve({status_emoji} 位置: {self._current_position}/{self.max_positions}, 端口: {current_port}, 状态: {self._status})"
def set_valve_position(self, command: Union[int, str]):
"""
设置阀门位置 - 兼容pump_protocol调用 🎯
这是set_position的别名方法用于兼容pump_protocol.py
Args:
command: 目标位置 (0-8) 或位置字符串
"""
# 删除debug日志self.logger.debug(f"🎯 兼容性调用: set_valve_position({command})")
return self.set_position(command)
# 使用示例
if __name__ == "__main__":
@@ -309,13 +267,6 @@ if __name__ == "__main__":
print(f"\n🔌 切换到2号位: {valve.set_to_port(2)}")
print(f"📍 当前状态: {valve}")
# 显示所有可用位置
print(f"\n📋 可用位置: {valve.get_available_positions()}")
print(f"🗺️ 端口映射: {valve.get_available_ports()}")
# 获取详细信息
print(f"\n📊 详细信息: {valve.get_info()}")
# 测试切换功能
print(f"\n🔄 智能切换测试:")
print(f"当前位置: {valve._current_position}")

197
unilabos/devices/virtual/virtual_pump.py
View File

@@ -1,197 +0,0 @@
import asyncio
import logging
from typing import Dict, Any, Optional
class VirtualPump:
"""Virtual pump device for transfer and cleaning operations"""
def __init__(self, device_id: str = None, config: Dict[str, Any] = None, **kwargs):
# 处理可能的不同调用方式
if device_id is None and 'id' in kwargs:
device_id = kwargs.pop('id')
if config is None and 'config' in kwargs:
config = kwargs.pop('config')
# 设置默认值
self.device_id = device_id or "unknown_pump"
self.config = config or {}
self.logger = logging.getLogger(f"VirtualPump.{self.device_id}")
self.data = {}
# 从config或kwargs中获取配置参数
self.port = self.config.get('port') or kwargs.get('port', 'VIRTUAL')
self._max_volume = self.config.get('max_volume') or kwargs.get('max_volume', 50.0)
self._transfer_rate = self.config.get('transfer_rate') or kwargs.get('transfer_rate', 10.0)
print(f"=== VirtualPump {self.device_id} created with max_volume={self._max_volume}, transfer_rate={self._transfer_rate} ===")
async def initialize(self) -> bool:
"""Initialize virtual pump"""
self.logger.info(f"Initializing virtual pump {self.device_id}")
self.data.update({
"status": "Idle",
"valve_position": 0,
"current_volume": 0.0,
"max_volume": self._max_volume,
"transfer_rate": self._transfer_rate,
"from_vessel": "",
"to_vessel": "",
"progress": 0.0,
"transferred_volume": 0.0,
"current_status": "Ready"
})
return True
async def cleanup(self) -> bool:
"""Cleanup virtual pump"""
self.logger.info(f"Cleaning up virtual pump {self.device_id}")
return True
async def transfer(self, from_vessel: str, to_vessel: str, volume: float,
amount: str = "", time: float = 0.0, viscous: bool = False,
rinsing_solvent: str = "", rinsing_volume: float = 0.0,
rinsing_repeats: int = 0, solid: bool = False) -> bool:
"""Execute transfer operation"""
self.logger.info(f"Transferring {volume}mL from {from_vessel} to {to_vessel}")
# 计算转移时间
transfer_time = volume / self._transfer_rate if time == 0 else time
self.data.update({
"status": "Running",
"from_vessel": from_vessel,
"to_vessel": to_vessel,
"current_status": "Transferring",
"progress": 0.0,
"transferred_volume": 0.0
})
# 模拟转移过程
steps = 10
step_time = transfer_time / steps
step_volume = volume / steps
for i in range(steps):
await asyncio.sleep(step_time)
progress = (i + 1) / steps * 100
current_volume = step_volume * (i + 1)
self.data.update({
"progress": progress,
"transferred_volume": current_volume,
"current_status": f"Transferring: {progress:.1f}%"
})
self.logger.info(f"Transfer progress: {progress:.1f}%")
self.data.update({
"status": "Idle",
"current_status": "Transfer completed",
"progress": 100.0,
"transferred_volume": volume
})
return True
async def clean_vessel(self, vessel: str, solvent: str, volume: float,
temp: float, repeats: int = 1) -> bool:
"""Execute vessel cleaning operation - matches CleanVessel action"""
self.logger.info(f"Starting vessel cleaning: {vessel} with {solvent} ({volume}mL at {temp}°C, {repeats} repeats)")
# 更新设备状态
self.data.update({
"status": "Running",
"from_vessel": f"flask_{solvent}",
"to_vessel": vessel,
"current_status": "Cleaning in progress",
"progress": 0.0,
"transferred_volume": 0.0
})
# 计算清洗时间(基于体积和重复次数)
# 假设清洗速度为 transfer_rate 的一半(因为需要加载和排放)
cleaning_rate = self._transfer_rate / 2
cleaning_time_per_cycle = volume / cleaning_rate
total_cleaning_time = cleaning_time_per_cycle * repeats
# 模拟清洗过程
steps_per_repeat = 10 # 每次重复清洗分10个步骤
total_steps = steps_per_repeat * repeats
step_time = total_cleaning_time / total_steps
for repeat in range(repeats):
self.logger.info(f"Starting cleaning cycle {repeat + 1}/{repeats}")
for step in range(steps_per_repeat):
await asyncio.sleep(step_time)
# 计算当前进度
current_step = repeat * steps_per_repeat + step + 1
progress = (current_step / total_steps) * 100
# 计算已处理的体积
volume_processed = (current_step / total_steps) * volume * repeats
# 更新状态
self.data.update({
"progress": progress,
"transferred_volume": volume_processed,
"current_status": f"Cleaning cycle {repeat + 1}/{repeats} - Step {step + 1}/{steps_per_repeat} ({progress:.1f}%)"
})
self.logger.info(f"Cleaning progress: {progress:.1f}% (Cycle {repeat + 1}/{repeats})")
# 清洗完成
self.data.update({
"status": "Idle",
"current_status": "Cleaning completed successfully",
"progress": 100.0,
"transferred_volume": volume * repeats,
"from_vessel": "",
"to_vessel": ""
})
self.logger.info(f"Vessel cleaning completed: {vessel}")
return True
# 状态属性
@property
def status(self) -> str:
return self.data.get("status", "Unknown")
@property
def valve_position(self) -> int:
return self.data.get("valve_position", 0)
@property
def current_volume(self) -> float:
return self.data.get("current_volume", 0.0)
@property
def max_volume(self) -> float:
return self.data.get("max_volume", 0.0)
@property
def transfer_rate(self) -> float:
return self.data.get("transfer_rate", 0.0)
@property
def from_vessel(self) -> str:
return self.data.get("from_vessel", "")
@property
def to_vessel(self) -> str:
return self.data.get("to_vessel", "")
@property
def progress(self) -> float:
return self.data.get("progress", 0.0)
@property
def transferred_volume(self) -> float:
return self.data.get("transferred_volume", 0.0)
@property
def current_status(self) -> str:
return self.data.get("current_status", "Ready")

4
unilabos/devices/virtual/virtual_rotavap.py
View File

@@ -99,8 +99,8 @@ class VirtualRotavap:
self.logger.error(f"❌ 时间参数类型无效: {type(time)}使用默认值180.0秒")
time = 180.0
# 确保time是float类型
time = float(time)
# 确保time是float类型; 并加速
time = float(time) / 10.0
# 🔧 简化处理如果vessel就是设备自己直接操作
if vessel == self.device_id:

14
unilabos/devices/virtual/virtual_solenoid_valve.py
View File

@@ -48,20 +48,6 @@ class VirtualSolenoidValve:
"""获取阀门位置状态"""
return "OPEN" if self._is_open else "CLOSED"
@property
def state(self) -> dict:
"""获取阀门完整状态"""
return {
"device_id": self.device_id,
"port": self.port,
"voltage": self.voltage,
"response_time": self.response_time,
"is_open": self._is_open,
"valve_state": self._valve_state,
"status": self._status,
"position": self.valve_position
}
async def set_valve_position(self, command: str = None, **kwargs):
"""
设置阀门位置 - ROS动作接口

17
unilabos/devices/virtual/virtual_solid_dispenser.py
View File

@@ -319,21 +319,6 @@ class VirtualSolidDispenser:
def total_operations(self) -> int:
return self._total_operations
def get_device_info(self) -> Dict[str, Any]:
"""获取设备状态信息 📊"""
info = {
"device_id": self.device_id,
"status": self._status,
"current_reagent": self._current_reagent,
"last_dispensed_amount": self._dispensed_amount,
"total_operations": self._total_operations,
"max_capacity": self.max_capacity,
"precision": self.precision
}
self.logger.debug(f"📊 设备信息: 状态={self._status}, 试剂={self._current_reagent}, 加样量={self._dispensed_amount:.6f}g")
return info
def __str__(self):
status_emoji = "" if self._status == "Ready" else "🔄" if self._status == "Dispensing" else "" if self._status == "Error" else "🏠"
return f"⚗️ VirtualSolidDispenser({status_emoji} {self.device_id}: {self._status}, 最后加样 {self._dispensed_amount:.3f}g)"
@@ -380,8 +365,6 @@ async def test_solid_dispenser():
mass="150 g" # 超过100g限制
)
print(f"📊 测试4结果: {result4}")
print(f"\n📊 最终设备信息: {dispenser.get_device_info()}")
print(f"✅ === 测试完成 === 🎉")

2
unilabos/devices/virtual/virtual_stirrer.py
View File

@@ -321,7 +321,7 @@ class VirtualStirrer:
"min_speed": self._min_speed
}
self.logger.debug(f"📊 设备信息: 模式={self.operation_mode}, 速度={self.current_speed} RPM, 搅拌={self.is_stirring}")
# self.logger.debug(f"📊 设备信息: 模式={self.operation_mode}, 速度={self.current_speed} RPM, 搅拌={self.is_stirring}")
return info
def __str__(self):

18
unilabos/devices/virtual/virtual_transferpump.py
View File

@@ -380,22 +380,6 @@ class VirtualTransferPump:
"""检查是否已满"""
return self._current_volume >= (self.max_volume - 0.01) # 允许小量误差
# 调试和状态信息
def get_pump_info(self) -> dict:
"""获取泵的详细信息"""
return {
"device_id": self.device_id,
"status": self._status,
"position": self._position,
"current_volume": self._current_volume,
"max_volume": self.max_volume,
"max_velocity": self._max_velocity,
"mode": self.mode.name,
"is_empty": self.is_empty(),
"is_full": self.is_full(),
"remaining_capacity": self.get_remaining_capacity()
}
def __str__(self):
return f"VirtualTransferPump({self.device_id}: {self._current_volume:.2f}/{self.max_volume} ml, {self._status})"
@@ -425,8 +409,6 @@ async def demo():
result = await pump.set_position(0.0)
print(f"Empty result: {result}")
print(f"After emptying: {pump}")
print("\nPump info:", pump.get_pump_info())
if __name__ == "__main__":

8
unilabos/registry/device_comms/serial.yaml → unilabos/registry/device_comms/communication_devices.yaml
View File

@@ -1,6 +1,6 @@
serial:
category:
- serial
- communication_devices
class:
action_value_mappings:
auto-handle_serial_request:
@@ -9,7 +9,7 @@ serial:
goal_default:
request: null
response: null
handles: []
handles: {}
result: {}
schema:
description: handle_serial_request的参数schema
@@ -35,7 +35,7 @@ serial:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: read_data的参数schema
@@ -56,7 +56,7 @@ serial:
goal: {}
goal_default:
command: null
handles: []
handles: {}
result: {}
schema:
description: send_command的参数schema

6
unilabos/registry/devices/camera.yaml
View File

@@ -1,4 +1,4 @@
camera:
camera.USB:
category:
- camera
class:
@@ -7,7 +7,7 @@ camera:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: 用于安全地关闭摄像头设备释放摄像头资源停止视频采集和发布服务。调用此函数将清理OpenCV摄像头连接并销毁ROS2节点。
@@ -27,7 +27,7 @@ camera:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: 定时器回调函数的参数schema。此函数负责定期采集摄像头视频帧将OpenCV格式的图像转换为ROS Image消息格式并发布到指定的视频话题。默认以10Hz频率执行确保视频流的连续性和实时性。

404
unilabos/registry/devices/characterization_chromatic.yaml Normal file
View File

@@ -0,0 +1,404 @@
hplc.agilent:
category:
- characterization_chromatic
class:
action_value_mappings:
auto-check_status:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: 检查安捷伦HPLC设备状态的函数。用于监控设备的运行状态、连接状态、错误信息等关键指标。该函数定期查询设备状态确保系统稳定运行及时发现和报告设备异常。适用于自动化流程中的设备监控、故障诊断、系统维护等场景。
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: check_status参数
type: object
type: UniLabJsonCommand
auto-extract_data_from_txt:
feedback: {}
goal: {}
goal_default:
file_path: null
handles: {}
result: {}
schema:
description: 从文本文件中提取分析数据的函数。用于解析安捷伦HPLC生成的结果文件提取峰面积、保留时间、浓度等关键分析数据。支持多种文件格式的自动识别和数据结构化处理为后续数据分析和报告生成提供标准化的数据格式。适用于批量数据处理、结果验证、质量控制等分析工作流程。
properties:
feedback: {}
goal:
properties:
file_path:
type: string
required:
- file_path
type: object
result: {}
required:
- goal
title: extract_data_from_txt参数
type: object
type: UniLabJsonCommand
auto-start_sequence:
feedback: {}
goal: {}
goal_default:
params: null
resource: null
wf_name: null
handles: {}
result: {}
schema:
description: 启动安捷伦HPLC分析序列的函数。用于执行预定义的分析方法序列包括样品进样、色谱分离、检测等完整的分析流程。支持参数配置、资源分配、工作流程管理等功能实现全自动的样品分析。适用于批量样品处理、标准化分析、质量检测等需要连续自动分析的应用场景。
properties:
feedback: {}
goal:
properties:
params:
type: string
resource:
type: object
wf_name:
type: string
required:
- wf_name
type: object
result: {}
required:
- goal
title: start_sequence参数
type: object
type: UniLabJsonCommand
auto-try_close_sub_device:
feedback: {}
goal: {}
goal_default:
device_name: null
handles: {}
result: {}
schema:
description: 尝试关闭HPLC子设备的函数。用于安全地关闭泵、检测器、进样器等各个子模块确保设备正常断开连接并保护硬件安全。该函数提供错误处理和状态确认机制避免强制关闭可能造成的设备损坏。适用于设备维护、系统重启、紧急停机等需要安全关闭设备的场景。
properties:
feedback: {}
goal:
properties:
device_name:
type: string
required: []
type: object
result: {}
required:
- goal
title: try_close_sub_device参数
type: object
type: UniLabJsonCommand
auto-try_open_sub_device:
feedback: {}
goal: {}
goal_default:
device_name: null
handles: {}
result: {}
schema:
description: 尝试打开HPLC子设备的函数。用于初始化和连接泵、检测器、进样器等各个子模块建立设备通信并进行自检。该函数提供连接验证和错误恢复机制确保子设备正常启动并准备就绪。适用于设备初始化、系统启动、设备重连等需要建立设备连接的场景。
properties:
feedback: {}
goal:
properties:
device_name:
type: string
required: []
type: object
result: {}
required:
- goal
title: try_open_sub_device参数
type: object
type: UniLabJsonCommand
execute_command_from_outer:
feedback: {}
goal:
command: command
goal_default:
command: ''
handles: {}
result:
success: success
schema:
description: ''
properties:
feedback:
properties:
status:
type: string
required:
- status
title: SendCmd_Feedback
type: object
goal:
properties:
command:
type: string
required:
- command
title: SendCmd_Goal
type: object
result:
properties:
return_info:
type: string
success:
type: boolean
required:
- return_info
- success
title: SendCmd_Result
type: object
required:
- goal
title: SendCmd
type: object
type: SendCmd
module: unilabos.devices.hplc.AgilentHPLC:HPLCDriver
status_types:
could_run: bool
data_file: list
device_status: str
driver_init_ok: bool
finish_status: str
is_running: bool
status_text: str
success: bool
type: python
config_info: []
description: 安捷伦高效液相色谱HPLC分析设备用于复杂化合物的分离、检测和定量分析。该设备通过UI自动化技术控制安捷伦ChemStation软件实现全自动的样品分析流程。具备序列启动、设备状态监控、数据文件提取、结果处理等功能。支持多样品批量处理和实时状态反馈适用于药物分析、环境检测、食品安全、化学研究等需要高精度色谱分析的实验室应用。
handles: []
icon: ''
init_param_schema:
config:
properties:
driver_debug:
default: false
type: string
required: []
type: object
data:
properties:
could_run:
type: boolean
data_file:
type: array
device_status:
type: string
driver_init_ok:
type: boolean
finish_status:
type: string
is_running:
type: boolean
status_text:
type: string
success:
type: boolean
required:
- status_text
- device_status
- could_run
- driver_init_ok
- is_running
- success
- finish_status
- data_file
type: object
version: 1.0.0
hplc.agilent-zhida:
category:
- characterization_chromatic
class:
action_value_mappings:
abort:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: ''
properties:
feedback:
properties: {}
required: []
title: EmptyIn_Feedback
type: object
goal:
properties: {}
required: []
title: EmptyIn_Goal
type: object
result:
properties:
return_info:
type: string
required:
- return_info
title: EmptyIn_Result
type: object
required:
- goal
title: EmptyIn
type: object
type: EmptyIn
auto-close:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: HPLC设备连接关闭函数。安全地断开与智达HPLC设备的TCP socket连接释放网络资源。该函数确保连接的正确关闭避免网络资源泄露。通常在设备使用完毕或系统关闭时调用。
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: close参数
type: object
type: UniLabJsonCommand
auto-connect:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: HPLC设备连接建立函数。与智达HPLC设备建立TCP socket通信连接配置通信超时参数。该函数是设备使用前的必要步骤建立成功后可进行状态查询、方法获取、任务启动等操作。连接失败时会抛出异常。
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: connect参数
type: object
type: UniLabJsonCommand
get_methods:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: ''
properties:
feedback:
properties: {}
required: []
title: EmptyIn_Feedback
type: object
goal:
properties: {}
required: []
title: EmptyIn_Goal
type: object
result:
properties:
return_info:
type: string
required:
- return_info
title: EmptyIn_Result
type: object
required:
- goal
title: EmptyIn
type: object
type: EmptyIn
start:
feedback: {}
goal:
string: string
goal_default:
string: ''
handles: {}
result: {}
schema:
description: ''
properties:
feedback:
properties: {}
required: []
title: StrSingleInput_Feedback
type: object
goal:
properties:
string:
type: string
required:
- string
title: StrSingleInput_Goal
type: object
result:
properties:
return_info:
type: string
success:
type: boolean
required:
- return_info
- success
title: StrSingleInput_Result
type: object
required:
- goal
title: StrSingleInput
type: object
type: StrSingleInput
module: unilabos.devices.zhida_hplc.zhida:ZhidaClient
status_types:
methods: dict
status: dict
type: python
config_info: []
description: 智达高效液相色谱HPLC分析设备用于实验室样品的分离、检测和定量分析。该设备通过TCP socket与HPLC控制系统通信支持远程控制和状态监控。具备自动进样、梯度洗脱、多检测器数据采集等功能可执行复杂的色谱分析方法。适用于化学分析、药物检测、环境监测、生物样品分析等需要高精度分离分析的实验室应用场景。
handles: []
icon: ''
init_param_schema:
config:
properties:
host:
default: 192.168.1.47
type: string
port:
default: 5792
type: string
timeout:
default: 10.0
type: string
required: []
type: object
data:
properties:
methods:
type: object
status:
type: object
required:
- status
- methods
type: object
version: 1.0.0

233
unilabos/registry/devices/characterization_optic.yaml
View File

@@ -1,225 +1,4 @@
hplc.agilent:
category:
- characterization_optic
class:
action_value_mappings:
auto-check_status:
feedback: {}
goal: {}
goal_default: {}
handles: []
result: {}
schema:
description: 检查安捷伦HPLC设备状态的函数。用于监控设备的运行状态、连接状态、错误信息等关键指标。该函数定期查询设备状态确保系统稳定运行及时发现和报告设备异常。适用于自动化流程中的设备监控、故障诊断、系统维护等场景。
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: check_status参数
type: object
type: UniLabJsonCommand
auto-extract_data_from_txt:
feedback: {}
goal: {}
goal_default:
file_path: null
handles: []
result: {}
schema:
description: 从文本文件中提取分析数据的函数。用于解析安捷伦HPLC生成的结果文件提取峰面积、保留时间、浓度等关键分析数据。支持多种文件格式的自动识别和数据结构化处理为后续数据分析和报告生成提供标准化的数据格式。适用于批量数据处理、结果验证、质量控制等分析工作流程。
properties:
feedback: {}
goal:
properties:
file_path:
type: string
required:
- file_path
type: object
result: {}
required:
- goal
title: extract_data_from_txt参数
type: object
type: UniLabJsonCommand
auto-start_sequence:
feedback: {}
goal: {}
goal_default:
params: null
resource: null
wf_name: null
handles: []
result: {}
schema:
description: 启动安捷伦HPLC分析序列的函数。用于执行预定义的分析方法序列包括样品进样、色谱分离、检测等完整的分析流程。支持参数配置、资源分配、工作流程管理等功能实现全自动的样品分析。适用于批量样品处理、标准化分析、质量检测等需要连续自动分析的应用场景。
properties:
feedback: {}
goal:
properties:
params:
type: string
resource:
type: object
wf_name:
type: string
required:
- wf_name
type: object
result: {}
required:
- goal
title: start_sequence参数
type: object
type: UniLabJsonCommand
auto-try_close_sub_device:
feedback: {}
goal: {}
goal_default:
device_name: null
handles: []
result: {}
schema:
description: 尝试关闭HPLC子设备的函数。用于安全地关闭泵、检测器、进样器等各个子模块确保设备正常断开连接并保护硬件安全。该函数提供错误处理和状态确认机制避免强制关闭可能造成的设备损坏。适用于设备维护、系统重启、紧急停机等需要安全关闭设备的场景。
properties:
feedback: {}
goal:
properties:
device_name:
type: string
required: []
type: object
result: {}
required:
- goal
title: try_close_sub_device参数
type: object
type: UniLabJsonCommand
auto-try_open_sub_device:
feedback: {}
goal: {}
goal_default:
device_name: null
handles: []
result: {}
schema:
description: 尝试打开HPLC子设备的函数。用于初始化和连接泵、检测器、进样器等各个子模块建立设备通信并进行自检。该函数提供连接验证和错误恢复机制确保子设备正常启动并准备就绪。适用于设备初始化、系统启动、设备重连等需要建立设备连接的场景。
properties:
feedback: {}
goal:
properties:
device_name:
type: string
required: []
type: object
result: {}
required:
- goal
title: try_open_sub_device参数
type: object
type: UniLabJsonCommand
execute_command_from_outer:
feedback: {}
goal:
command: command
goal_default:
command: ''
handles: []
result:
success: success
schema:
description: ''
properties:
feedback:
properties:
status:
type: string
required:
- status
title: SendCmd_Feedback
type: object
goal:
properties:
command:
type: string
required:
- command
title: SendCmd_Goal
type: object
result:
properties:
return_info:
type: string
success:
type: boolean
required:
- return_info
- success
title: SendCmd_Result
type: object
required:
- goal
title: SendCmd
type: object
type: SendCmd
module: unilabos.devices.hplc.AgilentHPLC:HPLCDriver
status_types:
could_run: bool
data_file: list
device_status: str
driver_init_ok: bool
finish_status: str
is_running: bool
status_text: str
success: bool
type: python
config_info: []
description: 安捷伦高效液相色谱HPLC分析设备用于复杂化合物的分离、检测和定量分析。该设备通过UI自动化技术控制安捷伦ChemStation软件实现全自动的样品分析流程。具备序列启动、设备状态监控、数据文件提取、结果处理等功能。支持多样品批量处理和实时状态反馈适用于药物分析、环境检测、食品安全、化学研究等需要高精度色谱分析的实验室应用。
handles: []
icon: ''
init_param_schema:
config:
properties:
driver_debug:
default: false
type: string
required: []
type: object
data:
properties:
could_run:
type: boolean
data_file:
type: array
device_status:
type: string
driver_init_ok:
type: boolean
finish_status:
type: string
is_running:
type: boolean
status_text:
type: string
success:
type: boolean
required:
- status_text
- device_status
- could_run
- driver_init_ok
- is_running
- success
- finish_status
- data_file
type: object
version: 1.0.0
raman_home_made:
raman.home_made:
category:
- characterization_optic
class:
@@ -229,7 +8,7 @@ raman_home_made:
goal: {}
goal_default:
int_time: null
handles: []
handles: {}
result: {}
schema:
description: 设置CCD检测器积分时间的函数。用于配置拉曼光谱仪的信号采集时间控制光谱数据的质量和信噪比。较长的积分时间可获得更高的信号强度和更好的光谱质量但会增加测量时间。该函数允许根据样品特性和测量要求动态调整检测参数优化测量效果。
@@ -253,7 +32,7 @@ raman_home_made:
goal: {}
goal_default:
output_voltage_laser: null
handles: []
handles: {}
result: {}
schema:
description: 设置激光器输出功率的函数。用于控制拉曼光谱仪激光器的功率输出,调节激光强度以适应不同样品的测量需求。适当的激光功率能够获得良好的拉曼信号同时避免样品损伤。该函数支持精确的功率控制,确保测量结果的稳定性和重现性。
@@ -278,7 +57,7 @@ raman_home_made:
goal_default:
int_time: null
laser_power: null
handles: []
handles: {}
result: {}
schema:
description: 执行无背景扣除的拉曼光谱测量函数。用于直接采集样品的拉曼光谱信号,不进行背景校正处理。该函数配置积分时间和激光功率参数,获取原始光谱数据用于后续的数据处理分析。适用于对光谱数据质量要求较高或需要自定义背景处理流程的测量场景。
@@ -308,7 +87,7 @@ raman_home_made:
int_time: null
laser_power: null
sample_name: null
handles: []
handles: {}
result: {}
schema:
description: 执行多次平均的无背景拉曼光谱测量函数。通过多次测量取平均值来提高光谱数据的信噪比和测量精度,减少随机噪声影响。该函数支持自定义平均次数、积分时间、激光功率等参数,并可为样品指定名称便于数据管理。适用于对测量精度要求较高的定量分析和研究应用。
@@ -342,7 +121,7 @@ raman_home_made:
command: command
goal_default:
command: ''
handles: []
handles: {}
result:
success: success
schema:

23
unilabos/registry/devices/vacuum_and_purge.yaml → unilabos/registry/devices/gas_handler.yaml
View File

@@ -1,13 +1,13 @@
gas_source.mock:
category:
- vacuum_and_purge
- gas_handler
class:
action_value_mappings:
auto-is_closed:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: is_closed的参数schema
@@ -27,7 +27,7 @@ gas_source.mock:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: is_open的参数schema
@@ -47,7 +47,7 @@ gas_source.mock:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -79,7 +79,7 @@ gas_source.mock:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -113,7 +113,7 @@ gas_source.mock:
string: string
goal_default:
string: ''
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -180,13 +180,14 @@ gas_source.mock:
vacuum_pump.mock:
category:
- vacuum_and_purge
- gas_handler
class:
action_value_mappings:
auto-is_closed:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: is_closed的参数schema
@@ -206,7 +207,7 @@ vacuum_pump.mock:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: is_open的参数schema
@@ -226,7 +227,7 @@ vacuum_pump.mock:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -258,7 +259,7 @@ vacuum_pump.mock:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -292,7 +293,7 @@ vacuum_pump.mock:
string: string
goal_default:
string: ''
handles: []
handles: {}
result: {}
schema:
description: ''

879
unilabos/registry/devices/liquid_handler.yaml
View File

File diff suppressed because it is too large Load Diff

4685
unilabos/registry/devices/mock_devices.yaml
View File

File diff suppressed because it is too large Load Diff

704
unilabos/registry/devices/moveit_config.yaml
View File

@@ -1,704 +0,0 @@
moveit.arm_slider:
category:
- moveit_config
class:
action_value_mappings:
auto-check_tf_update_actions:
feedback: {}
goal: {}
goal_default: {}
handles: []
result: {}
schema:
description: check_tf_update_actions的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: check_tf_update_actions参数
type: object
type: UniLabJsonCommand
auto-moveit_joint_task:
feedback: {}
goal: {}
goal_default:
joint_names: null
joint_positions: null
move_group: null
retry: 10
speed: 1
handles: []
result: {}
schema:
description: moveit_joint_task的参数schema
properties:
feedback: {}
goal:
properties:
joint_names:
type: string
joint_positions:
type: string
move_group:
type: string
retry:
default: 10
type: string
speed:
default: 1
type: string
required:
- move_group
- joint_positions
type: object
result: {}
required:
- goal
title: moveit_joint_task参数
type: object
type: UniLabJsonCommand
auto-moveit_task:
feedback: {}
goal: {}
goal_default:
cartesian: false
move_group: null
offsets:
- 0
- 0
- 0
position: null
quaternion: null
retry: 10
speed: 1
target_link: null
handles: []
result: {}
schema:
description: moveit_task的参数schema
properties:
feedback: {}
goal:
properties:
cartesian:
default: false
type: string
move_group:
type: string
offsets:
default:
- 0
- 0
- 0
type: string
position:
type: string
quaternion:
type: string
retry:
default: 10
type: string
speed:
default: 1
type: string
target_link:
type: string
required:
- move_group
- position
- quaternion
type: object
result: {}
required:
- goal
title: moveit_task参数
type: object
type: UniLabJsonCommand
auto-post_init:
feedback: {}
goal: {}
goal_default:
ros_node: null
handles: []
result: {}
schema:
description: post_init的参数schema
properties:
feedback: {}
goal:
properties:
ros_node:
type: string
required:
- ros_node
type: object
result: {}
required:
- goal
title: post_init参数
type: object
type: UniLabJsonCommand
auto-resource_manager:
feedback: {}
goal: {}
goal_default:
parent_link: null
resource: null
handles: []
result: {}
schema:
description: resource_manager的参数schema
properties:
feedback: {}
goal:
properties:
parent_link:
type: string
resource:
type: string
required:
- resource
- parent_link
type: object
result: {}
required:
- goal
title: resource_manager参数
type: object
type: UniLabJsonCommand
auto-wait_for_resource_action:
feedback: {}
goal: {}
goal_default: {}
handles: []
result: {}
schema:
description: wait_for_resource_action的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: wait_for_resource_action参数
type: object
type: UniLabJsonCommand
pick_and_place:
feedback: {}
goal:
command: command
goal_default:
command: ''
handles: []
result: {}
schema:
description: ''
properties:
feedback:
properties:
status:
type: string
required:
- status
title: SendCmd_Feedback
type: object
goal:
properties:
command:
type: string
required:
- command
title: SendCmd_Goal
type: object
result:
properties:
return_info:
type: string
success:
type: boolean
required:
- return_info
- success
title: SendCmd_Result
type: object
required:
- goal
title: SendCmd
type: object
type: SendCmd
set_position:
feedback: {}
goal:
command: command
goal_default:
command: ''
handles: []
result: {}
schema:
description: ''
properties:
feedback:
properties:
status:
type: string
required:
- status
title: SendCmd_Feedback
type: object
goal:
properties:
command:
type: string
required:
- command
title: SendCmd_Goal
type: object
result:
properties:
return_info:
type: string
success:
type: boolean
required:
- return_info
- success
title: SendCmd_Result
type: object
required:
- goal
title: SendCmd
type: object
type: SendCmd
set_status:
feedback: {}
goal:
command: command
goal_default:
command: ''
handles: []
result: {}
schema:
description: ''
properties:
feedback:
properties:
status:
type: string
required:
- status
title: SendCmd_Feedback
type: object
goal:
properties:
command:
type: string
required:
- command
title: SendCmd_Goal
type: object
result:
properties:
return_info:
type: string
success:
type: boolean
required:
- return_info
- success
title: SendCmd_Result
type: object
required:
- goal
title: SendCmd
type: object
type: SendCmd
module: unilabos.devices.ros_dev.moveit_interface:MoveitInterface
status_types: {}
type: python
config_info: []
description: 机械臂与滑块运动系统基于MoveIt2运动规划框架的多自由度机械臂控制设备。该系统集成机械臂和线性滑块通过ROS2和MoveIt2实现精确的轨迹规划和协调运动控制。支持笛卡尔空间和关节空间的运动规划、碰撞检测、逆运动学求解等功能。适用于复杂的pick-and-place操作、精密装配、多工位协作等需要高精度多轴协调运动的实验室自动化应用。
handles: []
icon: ''
init_param_schema:
config:
properties:
device_config:
type: string
joint_poses:
type: string
moveit_type:
type: string
rotation:
type: string
required:
- moveit_type
- joint_poses
type: object
data:
properties: {}
required: []
type: object
model:
mesh: arm_slider
type: device
version: 1.0.0
moveit.toyo_xyz:
category:
- moveit_config
class:
action_value_mappings:
auto-check_tf_update_actions:
feedback: {}
goal: {}
goal_default: {}
handles: []
result: {}
schema:
description: check_tf_update_actions的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: check_tf_update_actions参数
type: object
type: UniLabJsonCommand
auto-moveit_joint_task:
feedback: {}
goal: {}
goal_default:
joint_names: null
joint_positions: null
move_group: null
retry: 10
speed: 1
handles: []
result: {}
schema:
description: moveit_joint_task的参数schema
properties:
feedback: {}
goal:
properties:
joint_names:
type: string
joint_positions:
type: string
move_group:
type: string
retry:
default: 10
type: string
speed:
default: 1
type: string
required:
- move_group
- joint_positions
type: object
result: {}
required:
- goal
title: moveit_joint_task参数
type: object
type: UniLabJsonCommand
auto-moveit_task:
feedback: {}
goal: {}
goal_default:
cartesian: false
move_group: null
offsets:
- 0
- 0
- 0
position: null
quaternion: null
retry: 10
speed: 1
target_link: null
handles: []
result: {}
schema:
description: moveit_task的参数schema
properties:
feedback: {}
goal:
properties:
cartesian:
default: false
type: string
move_group:
type: string
offsets:
default:
- 0
- 0
- 0
type: string
position:
type: string
quaternion:
type: string
retry:
default: 10
type: string
speed:
default: 1
type: string
target_link:
type: string
required:
- move_group
- position
- quaternion
type: object
result: {}
required:
- goal
title: moveit_task参数
type: object
type: UniLabJsonCommand
auto-post_init:
feedback: {}
goal: {}
goal_default:
ros_node: null
handles: []
result: {}
schema:
description: post_init的参数schema
properties:
feedback: {}
goal:
properties:
ros_node:
type: string
required:
- ros_node
type: object
result: {}
required:
- goal
title: post_init参数
type: object
type: UniLabJsonCommand
auto-resource_manager:
feedback: {}
goal: {}
goal_default:
parent_link: null
resource: null
handles: []
result: {}
schema:
description: resource_manager的参数schema
properties:
feedback: {}
goal:
properties:
parent_link:
type: string
resource:
type: string
required:
- resource
- parent_link
type: object
result: {}
required:
- goal
title: resource_manager参数
type: object
type: UniLabJsonCommand
auto-wait_for_resource_action:
feedback: {}
goal: {}
goal_default: {}
handles: []
result: {}
schema:
description: wait_for_resource_action的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: wait_for_resource_action参数
type: object
type: UniLabJsonCommand
pick_and_place:
feedback: {}
goal:
command: command
goal_default:
command: ''
handles: []
result: {}
schema:
description: ''
properties:
feedback:
properties:
status:
type: string
required:
- status
title: SendCmd_Feedback
type: object
goal:
properties:
command:
type: string
required:
- command
title: SendCmd_Goal
type: object
result:
properties:
return_info:
type: string
success:
type: boolean
required:
- return_info
- success
title: SendCmd_Result
type: object
required:
- goal
title: SendCmd
type: object
type: SendCmd
set_position:
feedback: {}
goal:
command: command
goal_default:
command: ''
handles: []
result: {}
schema:
description: ''
properties:
feedback:
properties:
status:
type: string
required:
- status
title: SendCmd_Feedback
type: object
goal:
properties:
command:
type: string
required:
- command
title: SendCmd_Goal
type: object
result:
properties:
return_info:
type: string
success:
type: boolean
required:
- return_info
- success
title: SendCmd_Result
type: object
required:
- goal
title: SendCmd
type: object
type: SendCmd
set_status:
feedback: {}
goal:
command: command
goal_default:
command: ''
handles: []
result: {}
schema:
description: ''
properties:
feedback:
properties:
status:
type: string
required:
- status
title: SendCmd_Feedback
type: object
goal:
properties:
command:
type: string
required:
- command
title: SendCmd_Goal
type: object
result:
properties:
return_info:
type: string
success:
type: boolean
required:
- return_info
- success
title: SendCmd_Result
type: object
required:
- goal
title: SendCmd
type: object
type: SendCmd
module: unilabos.devices.ros_dev.moveit_interface:MoveitInterface
status_types: {}
type: python
config_info: []
description: 东洋XYZ三轴运动平台基于MoveIt2运动规划框架的精密定位设备。该设备通过ROS2和MoveIt2实现三维空间的精确运动控制支持复杂轨迹规划、多点定位、速度控制等功能。具备高精度定位、平稳运动、实时轨迹监控等特性。适用于精密加工、样品定位、检测扫描、自动化装配等需要高精度三维运动控制的实验室和工业应用场景。
handles: []
icon: ''
init_param_schema:
config:
properties:
device_config:
type: string
joint_poses:
type: string
moveit_type:
type: string
rotation:
type: string
required:
- moveit_type
- joint_poses
type: object
data:
properties: {}
required: []
type: object
model:
mesh: toyo_xyz
type: device
version: 1.0.0

28
unilabos/registry/devices/organic_miscellaneous.yaml
View File

@@ -8,7 +8,7 @@ rotavap.one:
goal: {}
goal_default:
cmd: null
handles: []
handles: {}
result: {}
schema:
description: cmd_write的参数schema
@@ -31,7 +31,7 @@ rotavap.one:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: main_loop的参数schema
@@ -52,7 +52,7 @@ rotavap.one:
goal: {}
goal_default:
time: null
handles: []
handles: {}
result: {}
schema:
description: set_pump_time的参数schema
@@ -76,7 +76,7 @@ rotavap.one:
goal: {}
goal_default:
time: null
handles: []
handles: {}
result: {}
schema:
description: set_rotate_time的参数schema
@@ -101,7 +101,7 @@ rotavap.one:
command: command
goal_default:
command: ''
handles: []
handles: {}
result:
success: success
schema:
@@ -171,7 +171,7 @@ separator.homemade:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: read_sensor_loop的参数schema
@@ -193,7 +193,7 @@ separator.homemade:
goal_default:
condition: null
value: null
handles: []
handles: {}
result: {}
schema:
description: valve_open的参数schema
@@ -220,7 +220,7 @@ separator.homemade:
goal: {}
goal_default:
data: null
handles: []
handles: {}
result: {}
schema:
description: write的参数schema
@@ -273,7 +273,7 @@ separator.homemade:
z: 0.0
sample_id: ''
type: ''
handles: []
handles: {}
result:
success: success
schema:
@@ -336,7 +336,7 @@ separator.homemade:
- y
- z
- w
title: Quaternion
title: orientation
type: object
position:
properties:
@@ -350,12 +350,12 @@ separator.homemade:
- x
- y
- z
title: Point
title: position
type: object
required:
- position
- orientation
title: Pose
title: pose
type: object
sample_id:
type: string
@@ -372,7 +372,7 @@ separator.homemade:
- pose
- config
- data
title: Resource
title: vessel
type: object
required:
- vessel
@@ -410,7 +410,7 @@ separator.homemade:
command: command
goal_default:
command: ''
handles: []
handles: {}
result:
success: success
schema:

638
unilabos/registry/devices/pump_and_valve.yaml
View File

@@ -7,7 +7,7 @@ solenoid_valve:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: close的参数schema
@@ -27,7 +27,7 @@ solenoid_valve:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: is_closed的参数schema
@@ -47,7 +47,7 @@ solenoid_valve:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: is_open的参数schema
@@ -67,7 +67,7 @@ solenoid_valve:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -87,7 +87,7 @@ solenoid_valve:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: read_data的参数schema
@@ -108,7 +108,7 @@ solenoid_valve:
goal: {}
goal_default:
command: null
handles: []
handles: {}
result: {}
schema:
description: send_command的参数schema
@@ -133,7 +133,7 @@ solenoid_valve:
string: position
goal_default:
string: ''
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -204,7 +204,7 @@ solenoid_valve.mock:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: is_closed的参数schema
@@ -224,7 +224,7 @@ solenoid_valve.mock:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: is_open的参数schema
@@ -245,7 +245,7 @@ solenoid_valve.mock:
goal: {}
goal_default:
position: null
handles: []
handles: {}
result: {}
schema:
description: set_valve_position的参数schema
@@ -268,7 +268,7 @@ solenoid_valve.mock:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -300,7 +300,7 @@ solenoid_valve.mock:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -366,7 +366,7 @@ solenoid_valve.mock:
- valve_position
type: object
version: 1.0.0
syringe_pump_with_valve.runze:
syringe_pump_with_valve.runze.SY03B-T06:
category:
- pump_and_valve
class:
@@ -375,7 +375,7 @@ syringe_pump_with_valve.runze:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: close的参数schema
@@ -395,7 +395,7 @@ syringe_pump_with_valve.runze:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: initialize的参数schema
@@ -416,7 +416,7 @@ syringe_pump_with_valve.runze:
goal: {}
goal_default:
volume: null
handles: []
handles: {}
result: {}
schema:
description: pull_plunger的参数schema
@@ -440,7 +440,7 @@ syringe_pump_with_valve.runze:
goal: {}
goal_default:
volume: null
handles: []
handles: {}
result: {}
schema:
description: push_plunger的参数schema
@@ -463,7 +463,7 @@ syringe_pump_with_valve.runze:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: query_aux_input_status_1的参数schema
@@ -483,7 +483,7 @@ syringe_pump_with_valve.runze:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: query_aux_input_status_2的参数schema
@@ -503,7 +503,7 @@ syringe_pump_with_valve.runze:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: query_backlash_position的参数schema
@@ -523,7 +523,7 @@ syringe_pump_with_valve.runze:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: query_command_buffer_status的参数schema
@@ -543,7 +543,7 @@ syringe_pump_with_valve.runze:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: query_software_version的参数schema
@@ -564,7 +564,7 @@ syringe_pump_with_valve.runze:
goal: {}
goal_default:
full_command: null
handles: []
handles: {}
result: {}
schema:
description: send_command的参数schema
@@ -588,7 +588,7 @@ syringe_pump_with_valve.runze:
goal: {}
goal_default:
baudrate: null
handles: []
handles: {}
result: {}
schema:
description: set_baudrate的参数schema
@@ -612,7 +612,7 @@ syringe_pump_with_valve.runze:
goal: {}
goal_default:
velocity: null
handles: []
handles: {}
result: {}
schema:
description: set_max_velocity的参数schema
@@ -637,7 +637,7 @@ syringe_pump_with_valve.runze:
goal_default:
max_velocity: null
position: null
handles: []
handles: {}
result: {}
schema:
description: set_position的参数schema
@@ -663,7 +663,7 @@ syringe_pump_with_valve.runze:
goal: {}
goal_default:
position: null
handles: []
handles: {}
result: {}
schema:
description: set_valve_position的参数schema
@@ -687,7 +687,7 @@ syringe_pump_with_valve.runze:
goal: {}
goal_default:
velocity: null
handles: []
handles: {}
result: {}
schema:
description: set_velocity_grade的参数schema
@@ -710,7 +710,7 @@ syringe_pump_with_valve.runze:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: stop_operation的参数schema
@@ -730,7 +730,7 @@ syringe_pump_with_valve.runze:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: wait_error的参数schema
@@ -764,7 +764,583 @@ syringe_pump_with_valve.runze:
type: python
config_info: []
description: 润泽精密注射泵设备,集成阀门控制的高精度流体输送系统。该设备通过串口通信控制,支持多种运行模式和精确的体积控制。具备可变速度控制、精密定位、阀门切换、实时状态监控等功能。适用于微量液体输送、精密进样、流速控制、化学反应进料等需要高精度流体操作的实验室自动化应用。
handles: []
handles:
- data_key: fluid_port_1
data_source: executor
data_type: fluid
description: 八通阀门端口1
handler_key: '1'
io_type: source
label: '1'
side: NORTH
- data_key: fluid_port_2
data_source: executor
data_type: fluid
description: 八通阀门端口2
handler_key: '2'
io_type: source
label: '2'
side: EAST
- data_key: fluid_port_3
data_source: executor
data_type: fluid
description: 八通阀门端口3
handler_key: '3'
io_type: source
label: '3'
side: SOUTH
- data_key: fluid_port_4
data_source: executor
data_type: fluid
description: 八通阀门端口4
handler_key: '4'
io_type: source
label: '4'
side: SOUTH
- data_key: fluid_port_5
data_source: executor
data_type: fluid
description: 八通阀门端口5
handler_key: '5'
io_type: source
label: '5'
side: EAST
- data_key: fluid_port_6
data_source: executor
data_type: fluid
description: 八通阀门端口6
handler_key: '6'
io_type: source
label: '6'
side: NORTH
- data_key: fluid_port_6
data_source: executor
data_type: fluid
description: 六通阀门端口6-特殊输入
handler_key: '6'
io_type: target
label: 6-in
side: WEST
icon: ''
init_param_schema:
config:
properties:
address:
default: '1'
type: string
max_volume:
default: 25.0
type: number
mode:
type: string
port:
type: string
required:
- port
type: object
data:
properties:
max_velocity:
type: number
mode:
type: integer
plunger_position:
type: string
position:
type: number
status:
type: string
valve_position:
type: string
velocity_end:
type: string
velocity_grade:
type: string
velocity_init:
type: string
required:
- status
- mode
- max_velocity
- velocity_grade
- velocity_init
- velocity_end
- valve_position
- position
- plunger_position
type: object
version: 1.0.0
syringe_pump_with_valve.runze.SY03B-T08:
category:
- pump_and_valve
class:
action_value_mappings:
auto-close:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: close的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: close参数
type: object
type: UniLabJsonCommand
auto-initialize:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: initialize的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: initialize参数
type: object
type: UniLabJsonCommand
auto-pull_plunger:
feedback: {}
goal: {}
goal_default:
volume: null
handles: {}
result: {}
schema:
description: pull_plunger的参数schema
properties:
feedback: {}
goal:
properties:
volume:
type: number
required:
- volume
type: object
result: {}
required:
- goal
title: pull_plunger参数
type: object
type: UniLabJsonCommand
auto-push_plunger:
feedback: {}
goal: {}
goal_default:
volume: null
handles: {}
result: {}
schema:
description: push_plunger的参数schema
properties:
feedback: {}
goal:
properties:
volume:
type: number
required:
- volume
type: object
result: {}
required:
- goal
title: push_plunger参数
type: object
type: UniLabJsonCommand
auto-query_aux_input_status_1:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: query_aux_input_status_1的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: query_aux_input_status_1参数
type: object
type: UniLabJsonCommand
auto-query_aux_input_status_2:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: query_aux_input_status_2的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: query_aux_input_status_2参数
type: object
type: UniLabJsonCommand
auto-query_backlash_position:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: query_backlash_position的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: query_backlash_position参数
type: object
type: UniLabJsonCommand
auto-query_command_buffer_status:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: query_command_buffer_status的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: query_command_buffer_status参数
type: object
type: UniLabJsonCommand
auto-query_software_version:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: query_software_version的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: query_software_version参数
type: object
type: UniLabJsonCommand
auto-send_command:
feedback: {}
goal: {}
goal_default:
full_command: null
handles: {}
result: {}
schema:
description: send_command的参数schema
properties:
feedback: {}
goal:
properties:
full_command:
type: string
required:
- full_command
type: object
result: {}
required:
- goal
title: send_command参数
type: object
type: UniLabJsonCommand
auto-set_baudrate:
feedback: {}
goal: {}
goal_default:
baudrate: null
handles: {}
result: {}
schema:
description: set_baudrate的参数schema
properties:
feedback: {}
goal:
properties:
baudrate:
type: string
required:
- baudrate
type: object
result: {}
required:
- goal
title: set_baudrate参数
type: object
type: UniLabJsonCommand
auto-set_max_velocity:
feedback: {}
goal: {}
goal_default:
velocity: null
handles: {}
result: {}
schema:
description: set_max_velocity的参数schema
properties:
feedback: {}
goal:
properties:
velocity:
type: number
required:
- velocity
type: object
result: {}
required:
- goal
title: set_max_velocity参数
type: object
type: UniLabJsonCommand
auto-set_position:
feedback: {}
goal: {}
goal_default:
max_velocity: null
position: null
handles: {}
result: {}
schema:
description: set_position的参数schema
properties:
feedback: {}
goal:
properties:
max_velocity:
type: number
position:
type: number
required:
- position
type: object
result: {}
required:
- goal
title: set_position参数
type: object
type: UniLabJsonCommand
auto-set_valve_position:
feedback: {}
goal: {}
goal_default:
position: null
handles: {}
result: {}
schema:
description: set_valve_position的参数schema
properties:
feedback: {}
goal:
properties:
position:
type: string
required:
- position
type: object
result: {}
required:
- goal
title: set_valve_position参数
type: object
type: UniLabJsonCommand
auto-set_velocity_grade:
feedback: {}
goal: {}
goal_default:
velocity: null
handles: {}
result: {}
schema:
description: set_velocity_grade的参数schema
properties:
feedback: {}
goal:
properties:
velocity:
type: string
required:
- velocity
type: object
result: {}
required:
- goal
title: set_velocity_grade参数
type: object
type: UniLabJsonCommand
auto-stop_operation:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: stop_operation的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: stop_operation参数
type: object
type: UniLabJsonCommand
auto-wait_error:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: wait_error的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: wait_error参数
type: object
type: UniLabJsonCommand
hardware_interface:
name: hardware_interface
read: send_command
write: send_command
module: unilabos.devices.pump_and_valve.runze_backbone:RunzeSyringePump
status_types:
max_velocity: float
mode: int
plunger_position: String
position: float
status: str
valve_position: str
velocity_end: String
velocity_grade: String
velocity_init: String
type: python
config_info: []
description: 润泽精密注射泵设备,集成阀门控制的高精度流体输送系统。该设备通过串口通信控制,支持多种运行模式和精确的体积控制。具备可变速度控制、精密定位、阀门切换、实时状态监控等功能。适用于微量液体输送、精密进样、流速控制、化学反应进料等需要高精度流体操作的实验室自动化应用。
handles:
- data_key: fluid_port_1
data_source: executor
data_type: fluid
description: 八通阀门端口1
handler_key: '1'
io_type: source
label: '1'
side: NORTH
- data_key: fluid_port_2
data_source: executor
data_type: fluid
description: 八通阀门端口2
handler_key: '2'
io_type: source
label: '2'
side: EAST
- data_key: fluid_port_3
data_source: executor
data_type: fluid
description: 八通阀门端口3
handler_key: '3'
io_type: source
label: '3'
side: EAST
- data_key: fluid_port_4
data_source: executor
data_type: fluid
description: 八通阀门端口4
handler_key: '4'
io_type: source
label: '4'
side: SOUTH
- data_key: fluid_port_5
data_source: executor
data_type: fluid
description: 八通阀门端口5
handler_key: '5'
io_type: source
label: '5'
side: SOUTH
- data_key: fluid_port_6
data_source: executor
data_type: fluid
description: 八通阀门端口6
handler_key: '6'
io_type: source
label: '6'
side: WEST
- data_key: fluid_port_7
data_source: executor
data_type: fluid
description: 八通阀门端口7
handler_key: '7'
io_type: source
label: '7'
side: WEST
- data_key: fluid_port_8
data_source: executor
data_type: fluid
description: 八通阀门端口8-特殊输入
handler_key: '8'
io_type: target
label: '8'
side: WEST
- data_key: fluid_port_8
data_source: executor
data_type: fluid
description: 八通阀门端口8
handler_key: '8'
io_type: source
label: '8'
side: NORTH
icon: ''
init_param_schema:
config:

4
unilabos/registry/devices/robot_agv.yaml
View File

@@ -10,7 +10,7 @@ agv.SEER:
cmd: null
ex_data: ''
obj: receive_socket
handles: []
handles: {}
result: {}
schema:
description: AGV底层通信命令发送函数。通过TCP socket连接向AGV发送底层控制命令支持pose位置、status状态、nav导航等命令类型。用于获取AGV当前位置坐标、运行状态或发送导航指令。该函数封装了AGV的通信协议将命令转换为十六进制数据包并处理响应解析。
@@ -41,7 +41,7 @@ agv.SEER:
command: command
goal_default:
command: ''
handles: []
handles: {}
result:
success: success
schema:

378
unilabos/registry/devices/robot_arm.yaml
View File

@@ -1,3 +1,355 @@
robotic_arm.SCARA_with_slider.virtual:
category:
- robot_arm
class:
action_value_mappings:
auto-check_tf_update_actions:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: check_tf_update_actions的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: check_tf_update_actions参数
type: object
type: UniLabJsonCommand
auto-moveit_joint_task:
feedback: {}
goal: {}
goal_default:
joint_names: null
joint_positions: null
move_group: null
retry: 10
speed: 1
handles: {}
result: {}
schema:
description: moveit_joint_task的参数schema
properties:
feedback: {}
goal:
properties:
joint_names:
type: string
joint_positions:
type: string
move_group:
type: string
retry:
default: 10
type: string
speed:
default: 1
type: string
required:
- move_group
- joint_positions
type: object
result: {}
required:
- goal
title: moveit_joint_task参数
type: object
type: UniLabJsonCommand
auto-moveit_task:
feedback: {}
goal: {}
goal_default:
cartesian: false
move_group: null
offsets:
- 0
- 0
- 0
position: null
quaternion: null
retry: 10
speed: 1
target_link: null
handles: {}
result: {}
schema:
description: moveit_task的参数schema
properties:
feedback: {}
goal:
properties:
cartesian:
default: false
type: string
move_group:
type: string
offsets:
default:
- 0
- 0
- 0
type: string
position:
type: string
quaternion:
type: string
retry:
default: 10
type: string
speed:
default: 1
type: string
target_link:
type: string
required:
- move_group
- position
- quaternion
type: object
result: {}
required:
- goal
title: moveit_task参数
type: object
type: UniLabJsonCommand
auto-post_init:
feedback: {}
goal: {}
goal_default:
ros_node: null
handles: {}
result: {}
schema:
description: post_init的参数schema
properties:
feedback: {}
goal:
properties:
ros_node:
type: string
required:
- ros_node
type: object
result: {}
required:
- goal
title: post_init参数
type: object
type: UniLabJsonCommand
auto-resource_manager:
feedback: {}
goal: {}
goal_default:
parent_link: null
resource: null
handles: {}
result: {}
schema:
description: resource_manager的参数schema
properties:
feedback: {}
goal:
properties:
parent_link:
type: string
resource:
type: string
required:
- resource
- parent_link
type: object
result: {}
required:
- goal
title: resource_manager参数
type: object
type: UniLabJsonCommand
auto-wait_for_resource_action:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: wait_for_resource_action的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: wait_for_resource_action参数
type: object
type: UniLabJsonCommand
pick_and_place:
feedback: {}
goal:
command: command
goal_default:
command: ''
handles: {}
result: {}
schema:
description: ''
properties:
feedback:
properties:
status:
type: string
required:
- status
title: SendCmd_Feedback
type: object
goal:
properties:
command:
type: string
required:
- command
title: SendCmd_Goal
type: object
result:
properties:
return_info:
type: string
success:
type: boolean
required:
- return_info
- success
title: SendCmd_Result
type: object
required:
- goal
title: SendCmd
type: object
type: SendCmd
set_position:
feedback: {}
goal:
command: command
goal_default:
command: ''
handles: {}
result: {}
schema:
description: ''
properties:
feedback:
properties:
status:
type: string
required:
- status
title: SendCmd_Feedback
type: object
goal:
properties:
command:
type: string
required:
- command
title: SendCmd_Goal
type: object
result:
properties:
return_info:
type: string
success:
type: boolean
required:
- return_info
- success
title: SendCmd_Result
type: object
required:
- goal
title: SendCmd
type: object
type: SendCmd
set_status:
feedback: {}
goal:
command: command
goal_default:
command: ''
handles: {}
result: {}
schema:
description: ''
properties:
feedback:
properties:
status:
type: string
required:
- status
title: SendCmd_Feedback
type: object
goal:
properties:
command:
type: string
required:
- command
title: SendCmd_Goal
type: object
result:
properties:
return_info:
type: string
success:
type: boolean
required:
- return_info
- success
title: SendCmd_Result
type: object
required:
- goal
title: SendCmd
type: object
type: SendCmd
module: unilabos.devices.ros_dev.moveit_interface:MoveitInterface
status_types: {}
type: python
config_info: []
description: 机械臂与滑块运动系统基于MoveIt2运动规划框架的多自由度机械臂控制设备。该系统集成机械臂和线性滑块通过ROS2和MoveIt2实现精确的轨迹规划和协调运动控制。支持笛卡尔空间和关节空间的运动规划、碰撞检测、逆运动学求解等功能。适用于复杂的pick-and-place操作、精密装配、多工位协作等需要高精度多轴协调运动的实验室自动化应用。
handles: []
icon: ''
init_param_schema:
config:
properties:
device_config:
type: string
joint_poses:
type: string
moveit_type:
type: string
rotation:
type: string
required:
- moveit_type
- joint_poses
type: object
data:
properties: {}
required: []
type: object
model:
mesh: arm_slider
type: device
version: 1.0.0
robotic_arm.UR:
category:
- robot_arm
@@ -7,7 +359,7 @@ robotic_arm.UR:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: 机械臂初始化函数。执行UR机械臂的完整初始化流程包括上电、释放制动器、解除保护停止状态等。该函数确保机械臂从安全停止状态恢复到可操作状态是机械臂使用前的必要步骤。初始化完成后机械臂将处于就绪状态可以接收后续的运动指令。
@@ -28,7 +380,7 @@ robotic_arm.UR:
goal: {}
goal_default:
data: null
handles: []
handles: {}
result: {}
schema:
description: 从JSON字符串加载位置数据函数。接收包含机械臂位置信息的JSON格式字符串解析并存储位置数据供后续运动任务使用。位置数据通常包含多个预定义的工作位置坐标用于实现精确的多点运动控制。适用于动态配置机械臂工作位置的场景。
@@ -52,7 +404,7 @@ robotic_arm.UR:
goal: {}
goal_default:
file: null
handles: []
handles: {}
result: {}
schema:
description: 从文件加载位置数据函数。读取指定的JSON文件并加载其中的机械臂位置信息。该函数支持从外部配置文件中获取预设的工作位置便于位置数据的管理和重用。适用于需要从固定配置文件中读取复杂位置序列的应用场景。
@@ -75,7 +427,7 @@ robotic_arm.UR:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: 重新加载位置数据函数。重新读取并解析之前设置的位置文件,更新内存中的位置数据。该函数用于在位置文件被修改后刷新机械臂的位置配置,无需重新初始化整个系统。适用于动态更新机械臂工作位置的场景。
@@ -97,7 +449,7 @@ robotic_arm.UR:
command: command
goal_default:
command: ''
handles: []
handles: {}
result:
success: success
schema:
@@ -183,7 +535,7 @@ robotic_arm.elite:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -203,7 +555,7 @@ robotic_arm.elite:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -226,7 +578,7 @@ robotic_arm.elite:
quantity: null
start_addr: null
unit_id: null
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -256,7 +608,7 @@ robotic_arm.elite:
goal: {}
goal_default:
job_id: null
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -282,7 +634,7 @@ robotic_arm.elite:
register_addr: null
unit_id: null
value: null
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -312,7 +664,7 @@ robotic_arm.elite:
goal: {}
goal_default:
response: null
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -336,7 +688,7 @@ robotic_arm.elite:
goal: {}
goal_default:
command: null
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -361,7 +713,7 @@ robotic_arm.elite:
command: command
goal_default:
command: ''
handles: []
handles: {}
result: {}
schema:
description: ''

36
unilabos/registry/devices/robot_gripper.yaml
View File

@@ -7,7 +7,7 @@ gripper.misumi_rz:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: data_loop的参数schema
@@ -27,7 +27,7 @@ gripper.misumi_rz:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: data_reader的参数schema
@@ -50,7 +50,7 @@ gripper.misumi_rz:
force: null
pos: null
speed: null
handles: []
handles: {}
result: {}
schema:
description: 夹爪抓取运动控制函数。控制夹爪的开合运动,支持位置、速度、力矩的精确设定。位置参数控制夹爪开合程度,速度参数控制运动快慢,力矩参数控制夹持强度。该函数提供安全的力控制,避免损坏被抓取物体,适用于各种形状和材质的物品抓取。
@@ -79,7 +79,7 @@ gripper.misumi_rz:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: 夹爪初始化函数。执行Misumi RZ夹爪的完整初始化流程包括Modbus通信建立、电机参数配置、传感器校准等。该函数确保夹爪系统从安全状态恢复到可操作状态是夹爪使用前的必要步骤。初始化完成后夹爪将处于就绪状态可接收抓取和旋转指令。
@@ -100,7 +100,7 @@ gripper.misumi_rz:
goal: {}
goal_default:
data: null
handles: []
handles: {}
result: {}
schema:
description: modbus_crc的参数schema
@@ -129,7 +129,7 @@ gripper.misumi_rz:
spin_F: null
spin_pos: null
spin_v: null
handles: []
handles: {}
result: {}
schema:
description: move_and_rotate的参数schema
@@ -168,7 +168,7 @@ gripper.misumi_rz:
goal: {}
goal_default:
cmd: null
handles: []
handles: {}
result: {}
schema:
description: 节点夹爪移动任务函数。接收逗号分隔的命令字符串,解析位置、速度、力矩参数并执行夹爪抓取动作。该函数等待运动完成并返回执行结果,提供同步的运动控制接口。适用于需要可靠完成确认的精密抓取操作。
@@ -192,7 +192,7 @@ gripper.misumi_rz:
goal: {}
goal_default:
cmd: null
handles: []
handles: {}
result: {}
schema:
description: 节点旋转移动任务函数。接收逗号分隔的命令字符串,解析角度、速度、力矩参数并执行夹爪旋转动作。该函数等待旋转完成并返回执行结果,提供同步的旋转控制接口。适用于需要精确角度定位和完成确认的旋转操作。
@@ -218,7 +218,7 @@ gripper.misumi_rz:
address: null
data_len: null
id: null
handles: []
handles: {}
result: {}
schema:
description: read_address的参数schema
@@ -250,7 +250,7 @@ gripper.misumi_rz:
force: null
pos: null
speed: null
handles: []
handles: {}
result: {}
schema:
description: 夹爪绝对位置旋转控制函数。控制夹爪主轴旋转到指定的绝对角度位置支持360度连续旋转。位置参数指定目标角度速度参数控制旋转速率力矩参数设定旋转阻力限制。该函数提供高精度的角度定位适用于需要精确方向控制的操作场景。
@@ -283,7 +283,7 @@ gripper.misumi_rz:
data: null
fun: null
id: null
handles: []
handles: {}
result: {}
schema:
description: send_cmd的参数schema
@@ -315,7 +315,7 @@ gripper.misumi_rz:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: wait_for_gripper的参数schema
@@ -335,7 +335,7 @@ gripper.misumi_rz:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: wait_for_gripper_init的参数schema
@@ -355,7 +355,7 @@ gripper.misumi_rz:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: wait_for_rotate的参数schema
@@ -377,7 +377,7 @@ gripper.misumi_rz:
command: command
goal_default:
command: ''
handles: []
handles: {}
result:
success: success
schema:
@@ -461,7 +461,7 @@ gripper.mock:
resource:
Gripper1: {}
wf_name: gripper_run
handles: []
handles: {}
result: {}
schema:
description: 模拟夹爪资源ID编辑函数。用于测试和演示资源管理功能模拟修改夹爪资源的标识信息。该函数接收工作流名称、参数和资源对象模拟真实的资源更新过程并返回修改后的资源信息。适用于系统测试和开发调试场景。
@@ -498,7 +498,7 @@ gripper.mock:
command:
max_effort: 0.0
position: 0.0
handles: []
handles: {}
result:
effort: torque
position: position
@@ -533,7 +533,7 @@ gripper.mock:
required:
- position
- max_effort
title: GripperCommand
title: command
type: object
required:
- command

408
unilabos/registry/devices/robot_linear_motion.yaml
View File

@@ -7,7 +7,7 @@ linear_motion.grbl:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: CNC设备初始化函数。执行Grbl CNC的完整初始化流程包括归零操作、轴校准和状态复位。该函数将所有轴移动到原点位置(0,0,0),确保设备处于已知的参考状态。初始化完成后设备进入空闲状态,可接收后续的运动指令。
@@ -28,7 +28,7 @@ linear_motion.grbl:
goal: {}
goal_default:
position: null
handles: []
handles: {}
result: {}
schema:
description: CNC绝对位置设定函数。控制CNC设备移动到指定的三维坐标位置(x,y,z)。该函数支持安全限位检查,防止超出设备工作范围。移动过程中会监控设备状态,确保安全到达目标位置。适用于精确定位和轨迹控制操作。
@@ -51,7 +51,7 @@ linear_motion.grbl:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: CNC操作停止函数。立即停止当前正在执行的所有CNC运动包括轴移动和主轴旋转。该函数用于紧急停止或任务中断确保设备和工件的安全。停止后设备将保持当前位置等待新的指令。
@@ -71,7 +71,7 @@ linear_motion.grbl:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: wait_error的参数schema
@@ -113,7 +113,7 @@ linear_motion.grbl:
x: 0.0
y: 0.0
z: 0.0
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -139,12 +139,12 @@ linear_motion.grbl:
required:
- sec
- nanosec
title: Time
title: stamp
type: object
required:
- stamp
- frame_id
title: Header
title: header
type: object
pose:
properties:
@@ -163,7 +163,7 @@ linear_motion.grbl:
- y
- z
- w
title: Quaternion
title: orientation
type: object
position:
properties:
@@ -177,17 +177,17 @@ linear_motion.grbl:
- x
- y
- z
title: Point
title: position
type: object
required:
- position
- orientation
title: Pose
title: pose
type: object
required:
- header
- pose
title: PoseStamped
title: current_pose
type: object
distance_remaining:
type: number
@@ -204,7 +204,7 @@ linear_motion.grbl:
required:
- sec
- nanosec
title: Duration
title: estimated_time_remaining
type: object
navigation_time:
properties:
@@ -219,7 +219,7 @@ linear_motion.grbl:
required:
- sec
- nanosec
title: Duration
title: navigation_time
type: object
number_of_poses_remaining:
maximum: 32767
@@ -262,12 +262,12 @@ linear_motion.grbl:
required:
- sec
- nanosec
title: Time
title: stamp
type: object
required:
- stamp
- frame_id
title: Header
title: header
type: object
pose:
properties:
@@ -286,7 +286,7 @@ linear_motion.grbl:
- y
- z
- w
title: Quaternion
title: orientation
type: object
position:
properties:
@@ -300,17 +300,17 @@ linear_motion.grbl:
- x
- y
- z
title: Point
title: position
type: object
required:
- position
- orientation
title: Pose
title: pose
type: object
required:
- header
- pose
title: PoseStamped
title: poses
type: object
type: array
required:
@@ -323,7 +323,7 @@ linear_motion.grbl:
result:
properties: {}
required: []
title: Empty
title: result
type: object
required:
- result
@@ -345,7 +345,7 @@ linear_motion.grbl:
nanosec: 0
sec: 0
position: 0.0
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -371,12 +371,12 @@ linear_motion.grbl:
required:
- sec
- nanosec
title: Time
title: stamp
type: object
required:
- stamp
- frame_id
title: Header
title: header
type: object
position:
type: number
@@ -406,7 +406,7 @@ linear_motion.grbl:
required:
- sec
- nanosec
title: Duration
title: min_duration
type: object
position:
type: number
@@ -470,6 +470,358 @@ linear_motion.grbl:
- spindle_speed
type: object
version: 1.0.0
linear_motion.toyo_xyz.sim:
category:
- robot_linear_motion
class:
action_value_mappings:
auto-check_tf_update_actions:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: check_tf_update_actions的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: check_tf_update_actions参数
type: object
type: UniLabJsonCommand
auto-moveit_joint_task:
feedback: {}
goal: {}
goal_default:
joint_names: null
joint_positions: null
move_group: null
retry: 10
speed: 1
handles: {}
result: {}
schema:
description: moveit_joint_task的参数schema
properties:
feedback: {}
goal:
properties:
joint_names:
type: string
joint_positions:
type: string
move_group:
type: string
retry:
default: 10
type: string
speed:
default: 1
type: string
required:
- move_group
- joint_positions
type: object
result: {}
required:
- goal
title: moveit_joint_task参数
type: object
type: UniLabJsonCommand
auto-moveit_task:
feedback: {}
goal: {}
goal_default:
cartesian: false
move_group: null
offsets:
- 0
- 0
- 0
position: null
quaternion: null
retry: 10
speed: 1
target_link: null
handles: {}
result: {}
schema:
description: moveit_task的参数schema
properties:
feedback: {}
goal:
properties:
cartesian:
default: false
type: string
move_group:
type: string
offsets:
default:
- 0
- 0
- 0
type: string
position:
type: string
quaternion:
type: string
retry:
default: 10
type: string
speed:
default: 1
type: string
target_link:
type: string
required:
- move_group
- position
- quaternion
type: object
result: {}
required:
- goal
title: moveit_task参数
type: object
type: UniLabJsonCommand
auto-post_init:
feedback: {}
goal: {}
goal_default:
ros_node: null
handles: {}
result: {}
schema:
description: post_init的参数schema
properties:
feedback: {}
goal:
properties:
ros_node:
type: string
required:
- ros_node
type: object
result: {}
required:
- goal
title: post_init参数
type: object
type: UniLabJsonCommand
auto-resource_manager:
feedback: {}
goal: {}
goal_default:
parent_link: null
resource: null
handles: {}
result: {}
schema:
description: resource_manager的参数schema
properties:
feedback: {}
goal:
properties:
parent_link:
type: string
resource:
type: string
required:
- resource
- parent_link
type: object
result: {}
required:
- goal
title: resource_manager参数
type: object
type: UniLabJsonCommand
auto-wait_for_resource_action:
feedback: {}
goal: {}
goal_default: {}
handles: {}
result: {}
schema:
description: wait_for_resource_action的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: wait_for_resource_action参数
type: object
type: UniLabJsonCommand
pick_and_place:
feedback: {}
goal:
command: command
goal_default:
command: ''
handles: {}
result: {}
schema:
description: ''
properties:
feedback:
properties:
status:
type: string
required:
- status
title: SendCmd_Feedback
type: object
goal:
properties:
command:
type: string
required:
- command
title: SendCmd_Goal
type: object
result:
properties:
return_info:
type: string
success:
type: boolean
required:
- return_info
- success
title: SendCmd_Result
type: object
required:
- goal
title: SendCmd
type: object
type: SendCmd
set_position:
feedback: {}
goal:
command: command
goal_default:
command: ''
handles: {}
result: {}
schema:
description: ''
properties:
feedback:
properties:
status:
type: string
required:
- status
title: SendCmd_Feedback
type: object
goal:
properties:
command:
type: string
required:
- command
title: SendCmd_Goal
type: object
result:
properties:
return_info:
type: string
success:
type: boolean
required:
- return_info
- success
title: SendCmd_Result
type: object
required:
- goal
title: SendCmd
type: object
type: SendCmd
set_status:
feedback: {}
goal:
command: command
goal_default:
command: ''
handles: {}
result: {}
schema:
description: ''
properties:
feedback:
properties:
status:
type: string
required:
- status
title: SendCmd_Feedback
type: object
goal:
properties:
command:
type: string
required:
- command
title: SendCmd_Goal
type: object
result:
properties:
return_info:
type: string
success:
type: boolean
required:
- return_info
- success
title: SendCmd_Result
type: object
required:
- goal
title: SendCmd
type: object
type: SendCmd
module: unilabos.devices.ros_dev.moveit_interface:MoveitInterface
status_types: {}
type: python
config_info: []
description: 东洋XYZ三轴运动平台基于MoveIt2运动规划框架的精密定位设备。该设备通过ROS2和MoveIt2实现三维空间的精确运动控制支持复杂轨迹规划、多点定位、速度控制等功能。具备高精度定位、平稳运动、实时轨迹监控等特性。适用于精密加工、样品定位、检测扫描、自动化装配等需要高精度三维运动控制的实验室和工业应用场景。
handles: []
icon: ''
init_param_schema:
config:
properties:
device_config:
type: string
joint_poses:
type: string
moveit_type:
type: string
rotation:
type: string
required:
- moveit_type
- joint_poses
type: object
data:
properties: {}
required: []
type: object
model:
mesh: toyo_xyz
type: device
version: 1.0.0
motor.iCL42:
category:
- robot_linear_motion
@@ -482,7 +834,7 @@ motor.iCL42:
mode: null
position: null
velocity: null
handles: []
handles: {}
result: {}
schema:
description: 步进电机执行运动函数。直接执行电机运动命令,包括位置设定、速度控制和路径规划。该函数处理底层的电机控制协议,消除警告信息,设置运动参数并启动电机运行。适用于需要直接控制电机运动的应用场景。
@@ -511,7 +863,7 @@ motor.iCL42:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: iCL42电机设备初始化函数。建立与iCL42步进电机驱动器的串口通信连接配置通信参数包括波特率、数据位、校验位等。该函数是电机使用前的必要步骤确保驱动器处于可控状态并准备接收运动指令。
@@ -534,7 +886,7 @@ motor.iCL42:
mode: null
position: null
velocity: null
handles: []
handles: {}
result: {}
schema:
description: 步进电机运动控制函数。根据指定的运动模式、目标位置和速度参数控制电机运动。支持多种运动模式和精确的位置控制,自动处理运动轨迹规划和执行。该函数提供异步执行和状态反馈,确保运动的准确性和可靠性。
@@ -565,7 +917,7 @@ motor.iCL42:
command: command
goal_default:
command: ''
handles: []
handles: {}
result:
success: success
schema:

315
unilabos/registry/devices/sim_nodes.yaml
View File

@@ -1,315 +0,0 @@
lh_joint_publisher:
category:
- sim_nodes
class:
action_value_mappings:
auto-check_tf_update_actions:
feedback: {}
goal: {}
goal_default: {}
handles: []
result: {}
schema:
description: check_tf_update_actions的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: check_tf_update_actions参数
type: object
type: UniLabJsonCommand
auto-find_resource_parent:
feedback: {}
goal: {}
goal_default:
resource_id: null
handles: []
result: {}
schema:
description: find_resource_parent的参数schema
properties:
feedback: {}
goal:
properties:
resource_id:
type: string
required:
- resource_id
type: object
result: {}
required:
- goal
title: find_resource_parent参数
type: object
type: UniLabJsonCommand
auto-inverse_kinematics:
feedback: {}
goal: {}
goal_default:
parent_id: null
x: null
x_joint: null
y: null
y_joint: null
z: null
z_joint: null
handles: []
result: {}
schema:
description: inverse_kinematics的参数schema
properties:
feedback: {}
goal:
properties:
parent_id:
type: string
x:
type: string
x_joint:
type: object
y:
type: string
y_joint:
type: object
z:
type: string
z_joint:
type: object
required:
- x
- y
- z
- parent_id
- x_joint
- y_joint
- z_joint
type: object
result: {}
required:
- goal
title: inverse_kinematics参数
type: object
type: UniLabJsonCommand
auto-lh_joint_action_callback:
feedback: {}
goal: {}
goal_default:
goal_handle: null
handles: []
result: {}
schema:
description: lh_joint_action_callback的参数schema
properties:
feedback: {}
goal:
properties:
goal_handle:
type: string
required:
- goal_handle
type: object
result: {}
required:
- goal
title: lh_joint_action_callback参数
type: object
type: UniLabJsonCommand
auto-lh_joint_pub_callback:
feedback: {}
goal: {}
goal_default: {}
handles: []
result: {}
schema:
description: lh_joint_pub_callback的参数schema
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: lh_joint_pub_callback参数
type: object
type: UniLabJsonCommand
auto-move_joints:
feedback: {}
goal: {}
goal_default:
option: null
resource_names: null
speed: 0.1
x: null
x_joint: null
y: null
y_joint: null
z: null
z_joint: null
handles: []
result: {}
schema:
description: move_joints的参数schema
properties:
feedback: {}
goal:
properties:
option:
type: string
resource_names:
type: string
speed:
default: 0.1
type: string
x:
type: string
x_joint:
type: string
y:
type: string
y_joint:
type: string
z:
type: string
z_joint:
type: string
required:
- resource_names
- x
- y
- z
- option
type: object
result: {}
required:
- goal
title: move_joints参数
type: object
type: UniLabJsonCommand
auto-move_to:
feedback: {}
goal: {}
goal_default:
joint_positions: null
parent_id: null
speed: null
handles: []
result: {}
schema:
description: move_to的参数schema
properties:
feedback: {}
goal:
properties:
joint_positions:
type: string
parent_id:
type: string
speed:
type: string
required:
- joint_positions
- speed
- parent_id
type: object
result: {}
required:
- goal
title: move_to参数
type: object
type: UniLabJsonCommand
auto-resource_move:
feedback: {}
goal: {}
goal_default:
channels: null
link_name: null
resource_id: null
handles: []
result: {}
schema:
description: resource_move的参数schema
properties:
feedback: {}
goal:
properties:
channels:
type: array
link_name:
type: string
resource_id:
type: string
required:
- resource_id
- link_name
- channels
type: object
result: {}
required:
- goal
title: resource_move参数
type: object
type: UniLabJsonCommand
auto-send_resource_action:
feedback: {}
goal: {}
goal_default:
link_name: null
resource_id_list: null
handles: []
result: {}
schema:
description: send_resource_action的参数schema
properties:
feedback: {}
goal:
properties:
link_name:
type: string
resource_id_list:
type: array
required:
- resource_id_list
- link_name
type: object
result: {}
required:
- goal
title: send_resource_action参数
type: object
type: UniLabJsonCommand
module: unilabos.devices.ros_dev.liquid_handler_joint_publisher:LiquidHandlerJointPublisher
status_types: {}
type: ros2
config_info: []
description: 液体处理器关节发布器用于ROS2仿真系统中的液体处理设备运动控制。该节点通过发布关节状态驱动仿真模型中的机械臂运动支持三维坐标到关节空间的逆运动学转换、多关节协调控制、资源跟踪和TF变换。具备精确的位置控制、速度调节、pick-and-place操作等功能。适用于液体处理系统的虚拟仿真、运动规划验证、系统集成测试等应用场景。
handles: []
icon: ''
init_param_schema:
config:
properties:
device_id:
default: lh_joint_publisher
type: string
rate:
default: 50
type: string
resource_tracker:
type: string
resources_config:
type: array
required:
- resources_config
- resource_tracker
type: object
data:
properties: {}
required: []
type: object
version: 1.0.0

24
unilabos/registry/devices/laiyu_add_solid.yaml → unilabos/registry/devices/solid_dispenser.yaml
View File

@@ -1,6 +1,6 @@
laiyu_add_solid:
solid_dispenser.laiyu:
category:
- laiyu_add_solid
- solid_dispenser
class:
action_value_mappings:
add_powder_tube:
@@ -13,7 +13,7 @@ laiyu_add_solid:
compound_mass: 0.0
powder_tube_number: 0
target_tube_position: ''
handles: []
handles: {}
result:
actual_mass_mg: actual_mass_mg
schema:
@@ -64,7 +64,7 @@ laiyu_add_solid:
goal: {}
goal_default:
data: null
handles: []
handles: {}
result: {}
schema:
description: Modbus CRC-16校验码计算函数。计算Modbus RTU通信协议所需的CRC-16校验码确保数据传输的完整性和可靠性。该函数实现标准的CRC-16算法用于构造完整的Modbus指令帧。
@@ -88,7 +88,7 @@ laiyu_add_solid:
goal: {}
goal_default:
command: null
handles: []
handles: {}
result: {}
schema:
description: Modbus指令发送函数。构造完整的Modbus RTU指令帧包含CRC校验发送给分装设备并等待响应。该函数处理底层通信协议确保指令的正确传输和响应接收支持最长3分钟的响应等待时间。
@@ -113,7 +113,7 @@ laiyu_add_solid:
float_input: float_input
goal_default:
float_in: 0.0
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -153,7 +153,7 @@ laiyu_add_solid:
string: string
goal_default:
string: ''
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -197,7 +197,7 @@ laiyu_add_solid:
x: 0.0
y: 0.0
z: 0.0
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -243,7 +243,7 @@ laiyu_add_solid:
int_input: int_input
goal_default:
int_input: 0
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -285,7 +285,7 @@ laiyu_add_solid:
int_input: int_input
goal_default:
int_input: 0
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -325,7 +325,7 @@ laiyu_add_solid:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: ''
@@ -353,7 +353,7 @@ laiyu_add_solid:
title: EmptyIn
type: object
type: EmptyIn
module: unilabos.devices.laiyu_add_solid.laiyu:Laiyu
module: unilabos.devices.powder_dispense.laiyu:Laiyu
status_types:
status: str
type: python

40
unilabos/registry/devices/temperature.yaml
View File

@@ -11,7 +11,7 @@ chiller:
function_code: null
register_address: null
value: null
handles: []
handles: {}
result: {}
schema:
description: build_modbus_frame的参数schema
@@ -45,7 +45,7 @@ chiller:
goal_default:
decimal_points: 1
temperature: null
handles: []
handles: {}
result: {}
schema:
description: convert_temperature_to_modbus_value的参数schema
@@ -72,7 +72,7 @@ chiller:
goal: {}
goal_default:
data: null
handles: []
handles: {}
result: {}
schema:
description: modbus_crc的参数schema
@@ -95,7 +95,7 @@ chiller:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: stop的参数schema
@@ -117,7 +117,7 @@ chiller:
command: command
goal_default:
command: ''
handles: []
handles: {}
result:
success: success
schema:
@@ -187,7 +187,7 @@ heaterstirrer.dalong:
feedback: {}
goal: {}
goal_default: {}
handles: []
handles: {}
result: {}
schema:
description: close的参数schema
@@ -208,7 +208,7 @@ heaterstirrer.dalong:
goal: {}
goal_default:
speed: null
handles: []
handles: {}
result: {}
schema:
description: set_stir_speed的参数schema
@@ -233,7 +233,7 @@ heaterstirrer.dalong:
goal_default:
temp: null
type: warning
handles: []
handles: {}
result: {}
schema:
description: set_temp_inner的参数schema
@@ -293,7 +293,7 @@ heaterstirrer.dalong:
z: 0.0
sample_id: ''
type: ''
handles: []
handles: {}
result:
success: success
schema:
@@ -362,7 +362,7 @@ heaterstirrer.dalong:
- y
- z
- w
title: Quaternion
title: orientation
type: object
position:
properties:
@@ -376,12 +376,12 @@ heaterstirrer.dalong:
- x
- y
- z
title: Point
title: position
type: object
required:
- position
- orientation
title: Pose
title: pose
type: object
sample_id:
type: string
@@ -398,7 +398,7 @@ heaterstirrer.dalong:
- pose
- config
- data
title: Resource
title: vessel
type: object
required:
- vessel
@@ -438,7 +438,7 @@ heaterstirrer.dalong:
command: temp
goal_default:
command: ''
handles: []
handles: {}
result:
success: success
schema:
@@ -482,7 +482,7 @@ heaterstirrer.dalong:
command: temp
goal_default:
command: ''
handles: []
handles: {}
result:
success: success
schema:
@@ -579,7 +579,7 @@ tempsensor:
function_code: null
register_address: null
register_count: null
handles: []
handles: {}
result: {}
schema:
description: build_modbus_request的参数schema
@@ -612,7 +612,7 @@ tempsensor:
goal: {}
goal_default:
data: null
handles: []
handles: {}
result: {}
schema:
description: calculate_crc的参数schema
@@ -636,7 +636,7 @@ tempsensor:
goal: {}
goal_default:
response: null
handles: []
handles: {}
result: {}
schema:
description: read_modbus_response的参数schema
@@ -660,7 +660,7 @@ tempsensor:
goal: {}
goal_default:
command: null
handles: []
handles: {}
result: {}
schema:
description: send_prototype_command的参数schema
@@ -685,7 +685,7 @@ tempsensor:
command: command
goal_default:
command: ''
handles: []
handles: {}
result:
success: success
schema:

886
unilabos/registry/devices/virtual_device.yaml
View File

File diff suppressed because it is too large Load Diff

488
unilabos/registry/devices/work_station.yaml
View File

File diff suppressed because it is too large Load Diff

183
unilabos/registry/devices/zhida_hplc.yaml
View File

@@ -1,183 +0,0 @@
zhida_hplc:
category:
- zhida_hplc
class:
action_value_mappings:
abort:
feedback: {}
goal: {}
goal_default: {}
handles: []
result: {}
schema:
description: ''
properties:
feedback:
properties: {}
required: []
title: EmptyIn_Feedback
type: object
goal:
properties: {}
required: []
title: EmptyIn_Goal
type: object
result:
properties:
return_info:
type: string
required:
- return_info
title: EmptyIn_Result
type: object
required:
- goal
title: EmptyIn
type: object
type: EmptyIn
auto-close:
feedback: {}
goal: {}
goal_default: {}
handles: []
result: {}
schema:
description: HPLC设备连接关闭函数。安全地断开与智达HPLC设备的TCP socket连接释放网络资源。该函数确保连接的正确关闭避免网络资源泄露。通常在设备使用完毕或系统关闭时调用。
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: close参数
type: object
type: UniLabJsonCommand
auto-connect:
feedback: {}
goal: {}
goal_default: {}
handles: []
result: {}
schema:
description: HPLC设备连接建立函数。与智达HPLC设备建立TCP socket通信连接配置通信超时参数。该函数是设备使用前的必要步骤建立成功后可进行状态查询、方法获取、任务启动等操作。连接失败时会抛出异常。
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: connect参数
type: object
type: UniLabJsonCommand
get_methods:
feedback: {}
goal: {}
goal_default: {}
handles: []
result: {}
schema:
description: ''
properties:
feedback:
properties: {}
required: []
title: EmptyIn_Feedback
type: object
goal:
properties: {}
required: []
title: EmptyIn_Goal
type: object
result:
properties:
return_info:
type: string
required:
- return_info
title: EmptyIn_Result
type: object
required:
- goal
title: EmptyIn
type: object
type: EmptyIn
start:
feedback: {}
goal:
string: string
goal_default:
string: ''
handles: []
result: {}
schema:
description: ''
properties:
feedback:
properties: {}
required: []
title: StrSingleInput_Feedback
type: object
goal:
properties:
string:
type: string
required:
- string
title: StrSingleInput_Goal
type: object
result:
properties:
return_info:
type: string
success:
type: boolean
required:
- return_info
- success
title: StrSingleInput_Result
type: object
required:
- goal
title: StrSingleInput
type: object
type: StrSingleInput
module: unilabos.devices.zhida_hplc.zhida:ZhidaClient
status_types:
methods: dict
status: dict
type: python
config_info: []
description: 智达高效液相色谱HPLC分析设备用于实验室样品的分离、检测和定量分析。该设备通过TCP socket与HPLC控制系统通信支持远程控制和状态监控。具备自动进样、梯度洗脱、多检测器数据采集等功能可执行复杂的色谱分析方法。适用于化学分析、药物检测、环境监测、生物样品分析等需要高精度分离分析的实验室应用场景。
handles: []
icon: ''
init_param_schema:
config:
properties:
host:
default: 192.168.1.47
type: string
port:
default: 5792
type: string
timeout:
default: 10.0
type: string
required: []
type: object
data:
properties:
methods:
type: object
status:
type: object
required:
- status
- methods
type: object
version: 1.0.0

41
unilabos/registry/registry.py
View File

@@ -24,12 +24,11 @@ DEFAULT_PATHS = [Path(__file__).absolute().parent]
class Registry:
def __init__(self, registry_paths=None):
import ctypes
try:
import unilabos_msgs
except ImportError:
logger.error(
"[UniLab Registry] unilabos_msgs模块未找到请确保已根据官方文档安装unilabos_msgs包。"
)
logger.error("[UniLab Registry] unilabos_msgs模块未找到请确保已根据官方文档安装unilabos_msgs包。")
sys.exit(1)
try:
ctypes.CDLL(str(Path(unilabos_msgs.__file__).parent / "unilabos_msgs_s__rosidl_typesupport_c.pyd"))
@@ -53,7 +52,7 @@ class Registry:
# 其他状态变量
# self.is_host_mode = False # 移至BasicConfig中
def setup(self, complete_registry=False):
def setup(self, complete_registry=False, upload_registry=False):
# 检查是否已调用过setup
if self._setup_called:
logger.critical("[UniLab Registry] setup方法已被调用过不允许多次调用")
@@ -152,22 +151,22 @@ class Registry:
}
}
)
logger.debug(f"[UniLab Registry] ----------Setup----------")
logger.trace(f"[UniLab Registry] ----------Setup----------")
self.registry_paths = [Path(path).absolute() for path in self.registry_paths]
for i, path in enumerate(self.registry_paths):
sys_path = path.parent
logger.debug(f"[UniLab Registry] Path {i+1}/{len(self.registry_paths)}: {sys_path}")
logger.trace(f"[UniLab Registry] Path {i+1}/{len(self.registry_paths)}: {sys_path}")
sys.path.append(str(sys_path))
self.load_device_types(path, complete_registry)
if BasicConfig.enable_resource_load:
self.load_resource_types(path, complete_registry)
self.load_resource_types(path, complete_registry, upload_registry)
else:
logger.warning("跳过了资源注册表加载!")
logger.info("[UniLab Registry] 注册表设置完成")
# 标记setup已被调用
self._setup_called = True
def load_resource_types(self, path: os.PathLike, complete_registry: bool):
def load_resource_types(self, path: os.PathLike, complete_registry: bool, upload_registry: bool):
abs_path = Path(path).absolute()
resource_path = abs_path / "resources"
files = list(resource_path.glob("*/*.yaml"))
@@ -194,7 +193,12 @@ class Registry:
resource_info["handles"] = []
if "init_param_schema" not in resource_info:
resource_info["init_param_schema"] = {}
if complete_registry:
if "config_info" in resource_info:
del resource_info["config_info"]
if "file_path" in resource_info:
del resource_info["file_path"]
complete_data[resource_id] = copy.deepcopy(dict(sorted(resource_info.items())))
if upload_registry:
class_info = resource_info.get("class", {})
if len(class_info) and "module" in class_info:
if class_info.get("type") == "pylabrobot":
@@ -205,7 +209,6 @@ class Registry:
res_instance = res_class(res_class.__name__)
res_ulr = tree_to_list([resource_plr_to_ulab(res_instance)])
resource_info["config_info"] = res_ulr
complete_data[resource_id] = copy.deepcopy(dict(sorted(resource_info.items()))) # 稍后dump到文件
resource_info["registry_type"] = "resource"
resource_info["file_path"] = str(file.absolute()).replace("\\", "/")
complete_data = dict(sorted(complete_data.items()))
@@ -215,7 +218,7 @@ class Registry:
yaml.dump(complete_data, f, allow_unicode=True, default_flow_style=False, Dumper=NoAliasDumper)
self.resource_type_registry.update(data)
logger.debug(
logger.trace( # type: ignore
f"[UniLab Registry] Resource-{current_resource_number} File-{i+1}/{len(files)} "
+ f"Add {list(data.keys())}"
)
@@ -402,7 +405,7 @@ class Registry:
devices_path = abs_path / "devices"
device_comms_path = abs_path / "device_comms"
files = list(devices_path.glob("*.yaml")) + list(device_comms_path.glob("*.yaml"))
logger.debug(
logger.trace( # type: ignore
f"[UniLab Registry] devices: {devices_path.exists()}, device_comms: {device_comms_path.exists()}, "
+ f"total: {len(files)}"
)
@@ -447,6 +450,8 @@ class Registry:
if complete_registry:
device_config["class"]["status_types"].clear()
enhanced_info = get_enhanced_class_info(device_config["class"]["module"], use_dynamic=True)
if not enhanced_info.get("dynamic_import_success", False):
continue
device_config["class"]["status_types"].update(
{k: v["return_type"] for k, v in enhanced_info["status_methods"].items()}
)
@@ -517,6 +522,12 @@ class Registry:
for action_name, action_config in device_config["class"]["action_value_mappings"].items():
if "handles" not in action_config:
action_config["handles"] = {}
elif isinstance(action_config["handles"], list):
if len(action_config["handles"]):
logger.error(f"设备{device_id} {action_name} 的handles配置错误应该是字典类型")
continue
else:
action_config["handles"] = {}
if "type" in action_config:
action_type_str: str = action_config["type"]
# 通过Json发放指令而不是通过特殊的ros action进行处理
@@ -565,7 +576,7 @@ class Registry:
}
device_config["file_path"] = str(file.absolute()).replace("\\", "/")
device_config["registry_type"] = "device"
logger.debug(
logger.trace( # type: ignore
f"[UniLab Registry] Device-{current_device_number} File-{i+1}/{len(files)} Add {device_id} "
+ f"[{data[device_id].get('name', '未命名设备')}]"
)
@@ -627,7 +638,7 @@ class Registry:
lab_registry = Registry()
def build_registry(registry_paths=None, complete_registry=False):
def build_registry(registry_paths=None, complete_registry=False, upload_registry=False):
"""
构建或获取Registry单例实例
@@ -651,6 +662,6 @@ def build_registry(registry_paths=None, complete_registry=False):
lab_registry.registry_paths.append(path)
# 初始化注册表
lab_registry.setup(complete_registry)
lab_registry.setup(complete_registry, upload_registry)
return lab_registry

6
unilabos/registry/resources/common/resource_container.yaml
View File

@@ -4,9 +4,7 @@ hplc_plate:
class:
module: unilabos.devices.resource_container.container:PlateContainer
type: python
config_info: []
description: HPLC板
file_path: C:/Users/10230/PycharmProjects/Uni-Lab-OS/unilabos/registry/resources/common/resource_container.yaml
handles: []
icon: ''
init_param_schema: {}
@@ -28,9 +26,7 @@ plate_96_high:
class:
module: unilabos.devices.resource_container.container:PlateContainer
type: python
config_info: []
description: 96孔板
file_path: C:/Users/10230/PycharmProjects/Uni-Lab-OS/unilabos/registry/resources/common/resource_container.yaml
handles: []
icon: ''
init_param_schema: {}
@@ -52,9 +48,7 @@ tiprack_96_high:
class:
module: unilabos.devices.resource_container.container:TipRackContainer
type: python
config_info: []
description: 96孔板
file_path: C:/Users/10230/PycharmProjects/Uni-Lab-OS/unilabos/registry/resources/common/resource_container.yaml
handles: []
icon: ''
init_param_schema: {}

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