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base: open_pub:feat/3d_builder_and_motion_visualization
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open_pub:main open_pub:feat/3d_builder_and_motion_visualization open_pub:dev open_pub:feat/lab_resource open_pub:feature/organic-extraction open_pub:dependabot/github_actions/dev/actions/upload-artifact-7 open_pub:prcix9320 open_pub:feat/samples open_pub:fix/workstation-yb-revision open_pub:workstation_YB_merge_dev_ready_260113 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:v0.10.19 open_pub:v0.10.18 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
...
compare: open_pub:feature/organic-extraction
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open_pub:feat/3d_builder_and_motion_visualization open_pub:dev open_pub:feat/lab_resource open_pub:main open_pub:feature/organic-extraction open_pub:dependabot/github_actions/dev/actions/upload-artifact-7 open_pub:prcix9320 open_pub:feat/samples open_pub:fix/workstation-yb-revision open_pub:workstation_YB_merge_dev_ready_260113 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:v0.10.19 open_pub:v0.10.18 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

13 Commits
feat/3d_bu ... feature/or

Author SHA1 Message Date
ZiWei
b61c818f7f Merge remote-tracking branch 'origin/dev' into feature/organic-extraction 2026-03-09 09:39:17 +08:00
ZiWei
47a29a0c2f add:skill&agent 2026-03-06 16:54:31 +08:00
ZiWei
9c6f7c7505 Merge branch 'dev' into feature/organic-extraction 2026-03-02 15:32:36 +08:00
ZiWei
e4e4bfbe20 Merge branch 'dev' into feature/organic-extraction 2026-02-04 15:47:47 +08:00
ZiWei
64c748d921 Merge branch 'vibe/dev' into feature/organic-extraction 2026-02-03 10:39:44 +08:00
ZiWei
15ff0e9d30 feat: add Bioyond deck imports to resource registration 2026-02-03 10:28:51 +08:00
ZiWei
f8a52860ad Add BIOYOND deck imports and update JSON configurations with new UUIDs for various components 2026-02-03 10:25:47 +08:00
Xuwznln
e30c01d54e Dev backward (#228) 
* Workbench example, adjust log level, and ci check (#220)

* TestLatency Return Value Example & gitignore update

* Adjust log level & Add workbench virtual example & Add not action decorator & Add check_mode &

* Add CI Check

* CI Check Fix 1

* CI Check Fix 2

* CI Check Fix 3

* CI Check Fix 4

* CI Check Fix 5

* Upgrade to py 3.11.14; ros 0.7; unilabos 0.10.16

* Update to ROS2 Humble 0.7

* Fix Build 1

* Fix Build 2

* Fix Build 3

* Fix Build 4

* Fix Build 5

* Fix Build 6

* Fix Build 7

* ci(deps): bump actions/configure-pages from 4 to 5 (#222)

Bumps [actions/configure-pages](https://github.com/actions/configure-pages) from 4 to 5.
- [Release notes](https://github.com/actions/configure-pages/releases)
- [Commits](https://github.com/actions/configure-pages/compare/v4...v5)

---
updated-dependencies:
- dependency-name: actions/configure-pages
  dependency-version: '5'
  dependency-type: direct:production
  update-type: version-update:semver-major
...

Signed-off-by: dependabot[bot] <support@github.com>
Co-authored-by: dependabot[bot] <49699333+dependabot[bot]@users.noreply.github.com>

* ci(deps): bump actions/upload-artifact from 4 to 6 (#224)

Bumps [actions/upload-artifact](https://github.com/actions/upload-artifact) from 4 to 6.
- [Release notes](https://github.com/actions/upload-artifact/releases)
- [Commits](https://github.com/actions/upload-artifact/compare/v4...v6)

---
updated-dependencies:
- dependency-name: actions/upload-artifact
  dependency-version: '6'
  dependency-type: direct:production
  update-type: version-update:semver-major
...

Signed-off-by: dependabot[bot] <support@github.com>
Co-authored-by: dependabot[bot] <49699333+dependabot[bot]@users.noreply.github.com>

* ci(deps): bump actions/upload-pages-artifact from 3 to 4 (#225)

Bumps [actions/upload-pages-artifact](https://github.com/actions/upload-pages-artifact) from 3 to 4.
- [Release notes](https://github.com/actions/upload-pages-artifact/releases)
- [Commits](https://github.com/actions/upload-pages-artifact/compare/v3...v4)

---
updated-dependencies:
- dependency-name: actions/upload-pages-artifact
  dependency-version: '4'
  dependency-type: direct:production
  update-type: version-update:semver-major
...

Signed-off-by: dependabot[bot] <support@github.com>
Co-authored-by: dependabot[bot] <49699333+dependabot[bot]@users.noreply.github.com>

* ci(deps): bump actions/checkout from 4 to 6 (#223)

Bumps [actions/checkout](https://github.com/actions/checkout) from 4 to 6.
- [Release notes](https://github.com/actions/checkout/releases)
- [Changelog](https://github.com/actions/checkout/blob/main/CHANGELOG.md)
- [Commits](https://github.com/actions/checkout/compare/v4...v6)

---
updated-dependencies:
- dependency-name: actions/checkout
  dependency-version: '6'
  dependency-type: direct:production
  update-type: version-update:semver-major
...

Signed-off-by: dependabot[bot] <support@github.com>
Co-authored-by: dependabot[bot] <49699333+dependabot[bot]@users.noreply.github.com>

* Fix Build 8

* Fix Build 9

* Fix Build 10

* Fix Build 11

* Fix Build 12

* Fix Build 13

* v0.10.17

(cherry picked from commit 176de521b4)

* CI Check use production mode

* Fix OT2 & ReAdd Virtual Devices

* add msg goal

* transfer liquid handles

* gather query

* add unilabos_class

* Support root node change pos

* save class name when deserialize & protocol execute test

* fix upload workflow json

* workflow upload & set liquid fix & add set liquid with plate

* speed up registry load

---------

Signed-off-by: dependabot[bot] <support@github.com>
Co-authored-by: dependabot[bot] <49699333+dependabot[bot]@users.noreply.github.com>
Co-authored-by: hanhua@dp.tech <2509856570@qq.com>
 2026-02-02 23:57:13 +08:00
ZiWei
37ec49f318 Refactor Bioyond resource handling: update warehouse mapping retrieval, add TipBox support, and improve liquid tracking logic. Migrate TipBox creation to bottle_carriers.py for better structure. 2026-01-29 16:31:14 +08:00
ZiWei
6bf57f18c1 Collaboration With Cursor 2026-01-29 11:29:38 +08:00
ZiWei
c4a3be1498 feat: enhance separation_step logic with polling thread management and error handling 2026-01-27 12:37:09 +08:00
ZiWei
e11070315d feat: add separation_step with sensor-motor linkage 2026-01-26 23:34:47 +08:00
ZiWei
50ebcad9d7 feat: add ZDT_X42 motor and XKC sensor drivers 2026-01-22 15:07:32 +08:00
38 changed files with 7804 additions and 85 deletions
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328
.cursor/rules/device-drivers.mdc Normal file
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---
description: 设备驱动开发规范
globs: ["unilabos/devices/**/*.py"]
---
# 设备驱动开发规范
## 目录结构
```
unilabos/devices/
├── virtual/ # 虚拟设备(用于测试)
│ ├── virtual_stirrer.py
│ └── virtual_centrifuge.py
├── liquid_handling/ # 液体处理设备
├── balance/ # 天平设备
├── hplc/ # HPLC设备
├── pump_and_valve/ # 泵和阀门
├── temperature/ # 温度控制设备
├── workstation/ # 工作站(组合设备)
└── ...
```
## 设备类完整模板
```python
import asyncio
import logging
import time as time_module
from typing import Dict, Any, Optional
from unilabos.ros.nodes.base_device_node import BaseROS2DeviceNode
class MyDevice:
"""
设备类描述
Attributes:
device_id: 设备唯一标识
config: 设备配置字典
data: 设备状态数据
"""
_ros_node: BaseROS2DeviceNode
def __init__(
self,
device_id: str = None,
config: Dict[str, Any] = None,
**kwargs
):
"""
初始化设备
Args:
device_id: 设备ID
config: 配置字典
**kwargs: 其他参数
"""
# 兼容不同调用方式
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')
self.device_id = device_id or "unknown_device"
self.config = config or {}
self.data = {}
# 从config读取参数
self.port = self.config.get('port') or kwargs.get('port', 'COM1')
self._max_value = self.config.get('max_value', 1000.0)
# 初始化日志
self.logger = logging.getLogger(f"MyDevice.{self.device_id}")
self.logger.info(f"设备 {self.device_id} 已创建")
def post_init(self, ros_node: BaseROS2DeviceNode):
"""
ROS节点注入 - 在ROS节点创建后调用
Args:
ros_node: ROS2设备节点实例
"""
self._ros_node = ros_node
async def initialize(self) -> bool:
"""
初始化设备 - 连接硬件、设置初始状态
Returns:
bool: 初始化是否成功
"""
self.logger.info(f"初始化设备 {self.device_id}")
try:
# 执行硬件初始化
# await self._connect_hardware()
# 设置初始状态
self.data.update({
"status": "待机",
"is_running": False,
"current_value": 0.0,
})
self.logger.info(f"设备 {self.device_id} 初始化完成")
return True
except Exception as e:
self.logger.error(f"初始化失败: {e}")
self.data["status"] = f"错误: {e}"
return False
async def cleanup(self) -> bool:
"""
清理设备 - 断开连接、释放资源
Returns:
bool: 清理是否成功
"""
self.logger.info(f"清理设备 {self.device_id}")
self.data.update({
"status": "离线",
"is_running": False,
})
return True
# ==================== 设备动作 ====================
async def execute_action(
self,
param1: float,
param2: str = "",
**kwargs
) -> bool:
"""
执行设备动作
Args:
param1: 参数1
param2: 参数2可选
Returns:
bool: 动作是否成功
"""
# 类型转换和验证
try:
param1 = float(param1)
except (ValueError, TypeError) as e:
self.logger.error(f"参数类型错误: {e}")
return False
# 参数验证
if param1 > self._max_value:
self.logger.error(f"参数超出范围: {param1} > {self._max_value}")
return False
self.logger.info(f"执行动作: param1={param1}, param2={param2}")
# 更新状态
self.data.update({
"status": "运行中",
"is_running": True,
})
# 执行动作(带进度反馈)
duration = 10.0 # 秒
start_time = time_module.time()
while True:
elapsed = time_module.time() - start_time
remaining = max(0, duration - elapsed)
progress = min(100, (elapsed / duration) * 100)
self.data.update({
"status": f"运行中: {progress:.0f}%",
"remaining_time": remaining,
})
if remaining <= 0:
break
await self._ros_node.sleep(1.0)
# 完成
self.data.update({
"status": "完成",
"is_running": False,
})
self.logger.info("动作执行完成")
return True
# ==================== 状态属性 ====================
@property
def status(self) -> str:
"""设备状态 - 自动发布为ROS Topic"""
return self.data.get("status", "未知")
@property
def is_running(self) -> bool:
"""是否正在运行"""
return self.data.get("is_running", False)
@property
def current_value(self) -> float:
"""当前值"""
return self.data.get("current_value", 0.0)
# ==================== 辅助方法 ====================
def get_device_info(self) -> Dict[str, Any]:
"""获取设备信息"""
return {
"device_id": self.device_id,
"status": self.status,
"is_running": self.is_running,
"current_value": self.current_value,
}
def __str__(self) -> str:
return f"MyDevice({self.device_id}: {self.status})"
```
## 关键规则
### 1. 参数处理
所有动作方法的参数都可能以字符串形式传入,必须进行类型转换:
```python
async def my_action(self, value: float, **kwargs) -> bool:
# 始终进行类型转换
try:
value = float(value)
except (ValueError, TypeError) as e:
self.logger.error(f"参数类型错误: {e}")
return False
```
### 2. vessel 参数处理
vessel 参数可能是字符串ID或字典
```python
def extract_vessel_id(vessel: Union[str, dict]) -> str:
if isinstance(vessel, dict):
return vessel.get("id", "")
return str(vessel) if vessel else ""
```
### 3. 状态更新
使用 `self.data` 字典存储状态,属性读取状态:
```python
# 更新状态
self.data["status"] = "运行中"
self.data["current_speed"] = 300.0
# 读取状态(通过属性)
@property
def status(self) -> str:
return self.data.get("status", "待机")
```
### 4. 异步等待
使用 ROS 节点的 sleep 方法:
```python
# 正确
await self._ros_node.sleep(1.0)
# 避免(除非在纯 Python 测试环境)
await asyncio.sleep(1.0)
```
### 5. 进度反馈
长时间运行的操作需要提供进度反馈:
```python
while remaining > 0:
progress = (elapsed / total_time) * 100
self.data["status"] = f"运行中: {progress:.0f}%"
self.data["remaining_time"] = remaining
await self._ros_node.sleep(1.0)
```
## 虚拟设备
虚拟设备用于测试和演示,放在 `unilabos/devices/virtual/` 目录:
- 类名以 `Virtual` 开头
- 文件名以 `virtual_` 开头
- 模拟真实设备的行为和时序
- 使用表情符号增强日志可读性(可选)
## 工作站设备
工作站是组合多个设备的复杂设备:
```python
from unilabos.devices.workstation.workstation_base import WorkstationBase
class MyWorkstation(WorkstationBase):
"""组合工作站"""
async def execute_workflow(self, workflow: Dict[str, Any]) -> bool:
"""执行工作流"""
pass
```
## 设备注册
设备类开发完成后,需要在注册表中注册:
1. 创建/编辑 `unilabos/registry/devices/my_category.yaml`
2. 添加设备配置(参考 `virtual_device.yaml`
3. 运行 `--complete_registry` 自动生成 schema

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---
description: 协议编译器开发规范
globs: ["unilabos/compile/**/*.py"]
---
# 协议编译器开发规范
## 概述
协议编译器负责将高级实验操作(如 Stir、Add、Filter编译为设备可执行的动作序列。
## 文件命名
- 位置: `unilabos/compile/`
- 命名: `{operation}_protocol.py`
- 示例: `stir_protocol.py`, `add_protocol.py`, `filter_protocol.py`
## 协议函数模板
```python
from typing import List, Dict, Any, Union
import networkx as nx
import logging
from .utils.unit_parser import parse_time_input
from .utils.vessel_parser import extract_vessel_id
logger = logging.getLogger(__name__)
def generate_{operation}_protocol(
G: nx.DiGraph,
vessel: Union[str, dict],
param1: Union[str, float] = "0",
param2: float = 0.0,
**kwargs
) -> List[Dict[str, Any]]:
"""
生成{操作}协议序列
Args:
G: 物理拓扑图 (NetworkX DiGraph)
vessel: 容器ID或Resource字典
param1: 参数1支持字符串单位如 "5 min"
param2: 参数2
**kwargs: 其他参数
Returns:
List[Dict]: 动作序列
Raises:
ValueError: 参数无效时
"""
# 1. 提取 vessel_id
vessel_id = extract_vessel_id(vessel)
# 2. 验证参数
if not vessel_id:
raise ValueError("vessel 参数不能为空")
if vessel_id not in G.nodes():
raise ValueError(f"容器 '{vessel_id}' 不存在于系统中")
# 3. 解析参数(支持单位)
parsed_param1 = parse_time_input(param1) # "5 min" -> 300.0
# 4. 查找设备
device_id = find_connected_device(G, vessel_id, device_type="my_device")
# 5. 生成动作序列
action_sequence = []
action = {
"device_id": device_id,
"action_name": "my_action",
"action_kwargs": {
"vessel": {"id": vessel_id}, # 始终使用字典格式
"param1": float(parsed_param1),
"param2": float(param2),
}
}
action_sequence.append(action)
logger.info(f"生成协议: {len(action_sequence)} 个动作")
return action_sequence
def find_connected_device(
G: nx.DiGraph,
vessel_id: str,
device_type: str = ""
) -> str:
"""
查找与容器相连的设备
Args:
G: 拓扑图
vessel_id: 容器ID
device_type: 设备类型关键字
Returns:
str: 设备ID
"""
# 查找所有匹配类型的设备
device_nodes = []
for node in G.nodes():
node_class = G.nodes[node].get('class', '') or ''
if device_type.lower() in node_class.lower():
device_nodes.append(node)
# 检查连接
if vessel_id and device_nodes:
for device in device_nodes:
if G.has_edge(device, vessel_id) or G.has_edge(vessel_id, device):
return device
# 返回第一个可用设备
if device_nodes:
return device_nodes[0]
# 默认设备
return f"{device_type}_1"
```
## 关键规则
### 1. vessel 参数处理
vessel 参数可能是字符串或字典,需要统一处理:
```python
def extract_vessel_id(vessel: Union[str, dict]) -> str:
"""提取vessel_id"""
if isinstance(vessel, dict):
# 可能是 {"id": "xxx"} 或完整 Resource 对象
return vessel.get("id", list(vessel.values())[0].get("id", ""))
return str(vessel) if vessel else ""
```
### 2. action_kwargs 中的 vessel
始终使用 `{"id": vessel_id}` 格式传递 vessel
```python
# 正确
"action_kwargs": {
"vessel": {"id": vessel_id}, # 字符串ID包装为字典
}
# 避免
"action_kwargs": {
"vessel": vessel_resource, # 不要传递完整 Resource 对象
}
```
### 3. 单位解析
使用 `parse_time_input` 解析时间参数:
```python
from .utils.unit_parser import parse_time_input
# 支持格式: "5 min", "1 h", "300", "1.5 hours"
time_seconds = parse_time_input("5 min") # -> 300.0
time_seconds = parse_time_input(120) # -> 120.0
time_seconds = parse_time_input("1 h") # -> 3600.0
```
### 4. 参数验证
所有参数必须进行验证和类型转换:
```python
# 验证范围
if speed < 10.0 or speed > 1500.0:
logger.warning(f"速度 {speed} 超出范围,修正为 300")
speed = 300.0
# 类型转换
param = float(param) if not isinstance(param, (int, float)) else param
```
### 5. 日志记录
使用项目日志记录器:
```python
logger = logging.getLogger(__name__)
def generate_protocol(...):
logger.info(f"开始生成协议...")
logger.debug(f"参数: vessel={vessel_id}, time={time}")
logger.warning(f"参数修正: {old_value} -> {new_value}")
```
## 便捷函数
为常用操作提供便捷函数:
```python
def stir_briefly(G: nx.DiGraph, vessel: Union[str, dict],
speed: float = 300.0) -> List[Dict[str, Any]]:
"""短时间搅拌30秒"""
return generate_stir_protocol(G, vessel, time="30", stir_speed=speed)
def stir_vigorously(G: nx.DiGraph, vessel: Union[str, dict],
time: str = "5 min") -> List[Dict[str, Any]]:
"""剧烈搅拌"""
return generate_stir_protocol(G, vessel, time=time, stir_speed=800.0)
```
## 测试函数
每个协议文件应包含测试函数:
```python
def test_{operation}_protocol():
"""测试协议生成"""
# 测试参数处理
vessel_dict = {"id": "flask_1", "name": "反应瓶1"}
vessel_id = extract_vessel_id(vessel_dict)
assert vessel_id == "flask_1"
# 测试单位解析
time_s = parse_time_input("5 min")
assert time_s == 300.0
if __name__ == "__main__":
test_{operation}_protocol()
```
## 现有协议参考
- `stir_protocol.py` - 搅拌操作
- `add_protocol.py` - 添加物料
- `filter_protocol.py` - 过滤操作
- `heatchill_protocol.py` - 加热/冷却
- `separate_protocol.py` - 分离操作
- `evaporate_protocol.py` - 蒸发操作

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---
description: 注册表配置规范 (YAML)
globs: ["unilabos/registry/**/*.yaml"]
---
# 注册表配置规范
## 概述
注册表使用 YAML 格式定义设备和资源类型,是 Uni-Lab-OS 的核心配置系统。
## 目录结构
```
unilabos/registry/
├── devices/ # 设备类型注册
│ ├── virtual_device.yaml
│ ├── liquid_handler.yaml
│ └── ...
├── device_comms/ # 通信设备配置
│ ├── communication_devices.yaml
│ └── modbus_ioboard.yaml
└── resources/ # 资源类型注册
├── bioyond/
├── organic/
├── opentrons/
└── ...
```
## 设备注册表格式
### 基本结构
```yaml
device_type_id:
# 基本信息
description: "设备描述"
version: "1.0.0"
category:
- category_name
icon: "icon_device.webp"
# 类配置
class:
module: "unilabos.devices.my_module:MyClass"
type: python
# 状态类型(属性 -> ROS消息类型
status_types:
status: String
temperature: Float64
is_running: Bool
# 动作映射
action_value_mappings:
action_name:
type: UniLabJsonCommand # 或 UniLabJsonCommandAsync
goal: {}
feedback: {}
result: {}
schema: {...}
handles: {}
```
### action_value_mappings 详细格式
```yaml
action_value_mappings:
# 同步动作
my_sync_action:
type: UniLabJsonCommand
goal:
param1: param1
param2: param2
feedback: {}
result:
success: success
message: message
goal_default:
param1: 0.0
param2: ""
handles: {}
placeholder_keys:
device_param: unilabos_devices # 设备选择器
resource_param: unilabos_resources # 资源选择器
schema:
title: "动作名称参数"
description: "动作描述"
type: object
properties:
goal:
type: object
properties:
param1:
type: number
param2:
type: string
required:
- param1
feedback: {}
result:
type: object
properties:
success:
type: boolean
message:
type: string
required:
- goal
# 异步动作
my_async_action:
type: UniLabJsonCommandAsync
goal: {}
feedback:
progress: progress
current_status: status
result:
success: success
schema: {...}
```
### 自动生成的动作
以 `auto-` 开头的动作由系统自动生成:
```yaml
action_value_mappings:
auto-initialize:
type: UniLabJsonCommandAsync
goal: {}
feedback: {}
result: {}
schema: {...}
auto-cleanup:
type: UniLabJsonCommandAsync
goal: {}
feedback: {}
result: {}
schema: {...}
```
### handles 配置
用于工作流编辑器中的数据流连接:
```yaml
handles:
input:
- handler_key: "input_resource"
data_type: "resource"
label: "输入资源"
data_source: "handle"
data_key: "resources"
output:
- handler_key: "output_labware"
data_type: "resource"
label: "输出器皿"
data_source: "executor"
data_key: "created_resource.@flatten"
```
## 资源注册表格式
```yaml
resource_type_id:
description: "资源描述"
version: "1.0.0"
category:
- category_name
icon: ""
handles: []
init_param_schema: {}
class:
module: "unilabos.resources.my_module:MyResource"
type: pylabrobot # 或 python
```
### PyLabRobot 资源示例
```yaml
BIOYOND_Electrolyte_6VialCarrier:
category:
- bottle_carriers
- bioyond
class:
module: "unilabos.resources.bioyond.bottle_carriers:BIOYOND_Electrolyte_6VialCarrier"
type: pylabrobot
version: "1.0.0"
```
## 状态类型映射
Python 类型到 ROS 消息类型的映射:
| Python 类型 | ROS 消息类型 |
|------------|-------------|
| `str` | `String` |
| `bool` | `Bool` |
| `int` | `Int64` |
| `float` | `Float64` |
| `list` | `String` (序列化) |
| `dict` | `String` (序列化) |
## 自动完善注册表
使用 `--complete_registry` 参数自动生成 schema
```bash
python -m unilabos.app.main --complete_registry
```
这会:
1. 扫描设备类的方法签名
2. 自动生成 `auto-` 前缀的动作
3. 生成 JSON Schema
4. 更新 YAML 文件
## 验证规则
1. **device_type_id** 必须唯一
2. **module** 路径必须正确可导入
3. **status_types** 的类型必须是有效的 ROS 消息类型
4. **schema** 必须是有效的 JSON Schema
## 示例:完整设备配置
```yaml
virtual_stirrer:
category:
- virtual_device
description: "虚拟搅拌器设备"
version: "1.0.0"
icon: "icon_stirrer.webp"
handles: []
init_param_schema: {}
class:
module: "unilabos.devices.virtual.virtual_stirrer:VirtualStirrer"
type: python
status_types:
status: String
operation_mode: String
current_speed: Float64
is_stirring: Bool
remaining_time: Float64
action_value_mappings:
auto-initialize:
type: UniLabJsonCommandAsync
goal: {}
feedback: {}
result: {}
schema:
title: "initialize参数"
type: object
properties:
goal:
type: object
properties: {}
feedback: {}
result: {}
required:
- goal
stir:
type: UniLabJsonCommandAsync
goal:
stir_time: stir_time
stir_speed: stir_speed
settling_time: settling_time
feedback:
current_speed: current_speed
remaining_time: remaining_time
result:
success: success
goal_default:
stir_time: 60.0
stir_speed: 300.0
settling_time: 30.0
handles: {}
schema:
title: "stir参数"
description: "搅拌操作"
type: object
properties:
goal:
type: object
properties:
stir_time:
type: number
description: "搅拌时间(秒)"
stir_speed:
type: number
description: "搅拌速度RPM"
settling_time:
type: number
description: "沉降时间(秒)"
required:
- stir_time
- stir_speed
feedback:
type: object
properties:
current_speed:
type: number
remaining_time:
type: number
result:
type: object
properties:
success:
type: boolean
required:
- goal
```

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---
description: ROS 2 集成开发规范
globs: ["unilabos/ros/**/*.py", "**/*_node.py"]
---
# ROS 2 集成开发规范
## 概述
Uni-Lab-OS 使用 ROS 2 作为设备通信中间件,基于 rclpy 实现。
## 核心组件
### BaseROS2DeviceNode
设备节点基类,提供:
- ROS Topic 自动发布(状态属性)
- Action Server 自动创建(设备动作)
- 资源管理服务
- 异步任务调度
```python
from unilabos.ros.nodes.base_device_node import BaseROS2DeviceNode
```
### 消息转换器
```python
from unilabos.ros.msgs.message_converter import (
convert_to_ros_msg,
convert_from_ros_msg_with_mapping,
msg_converter_manager,
ros_action_to_json_schema,
ros_message_to_json_schema,
)
```
## 设备与 ROS 集成
### post_init 方法
设备类必须实现 `post_init` 方法接收 ROS 节点:
```python
class MyDevice:
_ros_node: BaseROS2DeviceNode
def post_init(self, ros_node: BaseROS2DeviceNode):
"""ROS节点注入"""
self._ros_node = ros_node
```
### 状态属性发布
设备的 `@property` 属性会自动发布为 ROS Topic
```python
class MyDevice:
@property
def temperature(self) -> float:
return self._temperature
# 自动发布到 /{namespace}/temperature Topic
```
### Topic 配置装饰器
```python
from unilabos.utils.decorator import topic_config
class MyDevice:
@property
@topic_config(period=1.0, print_publish=False, qos=10)
def fast_data(self) -> float:
"""高频数据 - 每秒发布一次"""
return self._fast_data
@property
@topic_config(period=5.0)
def slow_data(self) -> str:
"""低频数据 - 每5秒发布一次"""
return self._slow_data
```
### 订阅装饰器
```python
from unilabos.utils.decorator import subscribe
class MyDevice:
@subscribe(topic="/external/sensor_data", qos=10)
def on_sensor_data(self, msg):
"""订阅外部Topic"""
self._sensor_value = msg.data
```
## 异步操作
### 使用 ROS 节点睡眠
```python
# 推荐使用ROS节点的睡眠方法
await self._ros_node.sleep(1.0)
# 不推荐直接使用asyncio可能导致回调阻塞
await asyncio.sleep(1.0)
```
### 获取事件循环
```python
from unilabos.ros.x.rclpyx import get_event_loop
loop = get_event_loop()
```
## 消息类型
### unilabos_msgs 包
```python
from unilabos_msgs.msg import Resource
from unilabos_msgs.srv import (
ResourceAdd,
ResourceDelete,
ResourceUpdate,
ResourceList,
SerialCommand,
)
from unilabos_msgs.action import SendCmd
```
### Resource 消息结构
```python
Resource:
id: str
name: str
category: str
type: str
parent: str
children: List[str]
config: str # JSON字符串
data: str # JSON字符串
sample_id: str
pose: Pose
```
## 日志适配器
```python
from unilabos.utils.log import info, debug, warning, error, trace
class MyDevice:
def __init__(self):
# 创建设备专属日志器
self.logger = logging.getLogger(f"MyDevice.{self.device_id}")
```
ROSLoggerAdapter 同时向自定义日志和 ROS 日志发送消息。
## Action Server
设备动作自动创建为 ROS Action Server
```yaml
# 在注册表中配置
action_value_mappings:
my_action:
type: UniLabJsonCommandAsync # 异步Action
goal: {...}
feedback: {...}
result: {...}
```
### Action 类型
- **UniLabJsonCommand**: 同步动作
- **UniLabJsonCommandAsync**: 异步动作支持feedback
## 服务客户端
```python
from rclpy.client import Client
# 调用其他节点的服务
response = await self._ros_node.call_service(
service_name="/other_node/service",
request=MyServiceRequest(...)
)
```
## 命名空间
设备节点使用命名空间隔离:
```
/{device_id}/ # 设备命名空间
/{device_id}/status # 状态Topic
/{device_id}/temperature # 温度Topic
/{device_id}/my_action # 动作Server
```
## 调试
### 查看 Topic
```bash
ros2 topic list
ros2 topic echo /{device_id}/status
```
### 查看 Action
```bash
ros2 action list
ros2 action info /{device_id}/my_action
```
### 查看 Service
```bash
ros2 service list
ros2 service call /{device_id}/resource_list unilabos_msgs/srv/ResourceList
```
## 最佳实践
1. **状态属性命名**: 使用蛇形命名法snake_case
2. **Topic 频率**: 根据数据变化频率调整,避免过高频率
3. **Action 反馈**: 长时间操作提供进度反馈
4. **错误处理**: 使用 try-except 捕获并记录错误
5. **资源清理**: 在 cleanup 方法中正确清理资源

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---
description: 测试开发规范
globs: ["tests/**/*.py", "**/test_*.py"]
---
# 测试开发规范
## 目录结构
```
tests/
├── __init__.py
├── devices/ # 设备测试
│ └── liquid_handling/
│ └── test_transfer_liquid.py
├── resources/ # 资源测试
│ ├── test_bottle_carrier.py
│ └── test_resourcetreeset.py
├── ros/ # ROS消息测试
│ └── msgs/
│ ├── test_basic.py
│ ├── test_conversion.py
│ └── test_mapping.py
└── workflow/ # 工作流测试
└── merge_workflow.py
```
## 测试框架
使用 pytest 作为测试框架:
```bash
# 运行所有测试
pytest tests/
# 运行特定测试文件
pytest tests/resources/test_bottle_carrier.py
# 运行特定测试函数
pytest tests/resources/test_bottle_carrier.py::test_bottle_carrier
# 显示详细输出
pytest -v tests/
# 显示打印输出
pytest -s tests/
```
## 测试文件模板
```python
import pytest
from typing import List, Dict, Any
# 导入被测试的模块
from unilabos.resources.bioyond.bottle_carriers import (
BIOYOND_Electrolyte_6VialCarrier,
)
from unilabos.resources.bioyond.bottles import (
BIOYOND_PolymerStation_Solid_Vial,
)
class TestBottleCarrier:
"""BottleCarrier 测试类"""
def setup_method(self):
"""每个测试方法前执行"""
self.carrier = BIOYOND_Electrolyte_6VialCarrier("test_carrier")
def teardown_method(self):
"""每个测试方法后执行"""
pass
def test_carrier_creation(self):
"""测试载架创建"""
assert self.carrier.name == "test_carrier"
assert len(self.carrier.sites) == 6
def test_bottle_placement(self):
"""测试瓶子放置"""
bottle = BIOYOND_PolymerStation_Solid_Vial("test_bottle")
# 测试逻辑...
assert bottle.name == "test_bottle"
def test_standalone_function():
"""独立测试函数"""
result = some_function()
assert result is True
# 参数化测试
@pytest.mark.parametrize("input,expected", [
("5 min", 300.0),
("1 h", 3600.0),
("120", 120.0),
(60, 60.0),
])
def test_time_parsing(input, expected):
"""测试时间解析"""
from unilabos.compile.utils.unit_parser import parse_time_input
assert parse_time_input(input) == expected
# 异常测试
def test_invalid_input_raises_error():
"""测试无效输入抛出异常"""
with pytest.raises(ValueError) as exc_info:
invalid_function("bad_input")
assert "invalid" in str(exc_info.value).lower()
# 跳过条件测试
@pytest.mark.skipif(
not os.environ.get("ROS_DISTRO"),
reason="需要ROS环境"
)
def test_ros_feature():
"""需要ROS环境的测试"""
pass
```
## 设备测试
### 虚拟设备测试
```python
import pytest
import asyncio
from unittest.mock import MagicMock, AsyncMock
from unilabos.devices.virtual.virtual_stirrer import VirtualStirrer
class TestVirtualStirrer:
"""VirtualStirrer 测试"""
@pytest.fixture
def stirrer(self):
"""创建测试用搅拌器"""
device = VirtualStirrer(
device_id="test_stirrer",
config={"max_speed": 1500.0, "min_speed": 50.0}
)
# Mock ROS节点
mock_node = MagicMock()
mock_node.sleep = AsyncMock(return_value=None)
device.post_init(mock_node)
return device
@pytest.mark.asyncio
async def test_initialize(self, stirrer):
"""测试初始化"""
result = await stirrer.initialize()
assert result is True
assert stirrer.status == "待机中"
@pytest.mark.asyncio
async def test_stir_action(self, stirrer):
"""测试搅拌动作"""
await stirrer.initialize()
result = await stirrer.stir(
stir_time=5.0,
stir_speed=300.0,
settling_time=2.0
)
assert result is True
assert stirrer.operation_mode == "Completed"
@pytest.mark.asyncio
async def test_stir_invalid_speed(self, stirrer):
"""测试无效速度"""
await stirrer.initialize()
# 速度超出范围
result = await stirrer.stir(
stir_time=5.0,
stir_speed=2000.0, # 超过max_speed
settling_time=0.0
)
assert result is False
assert "错误" in stirrer.status
```
### 异步测试配置
```python
# conftest.py
import pytest
import asyncio
@pytest.fixture(scope="session")
def event_loop():
"""创建事件循环"""
loop = asyncio.get_event_loop_policy().new_event_loop()
yield loop
loop.close()
```
## 资源测试
```python
import pytest
from unilabos.resources.resource_tracker import (
ResourceTreeSet,
ResourceTreeInstance,
)
def test_resource_tree_creation():
"""测试资源树创建"""
tree_set = ResourceTreeSet()
# 添加资源
resource = {"id": "res_1", "name": "Resource 1"}
tree_set.add_resource(resource)
# 验证
assert len(tree_set.all_nodes) == 1
assert tree_set.get_resource("res_1") is not None
def test_resource_tree_merge():
"""测试资源树合并"""
local_set = ResourceTreeSet()
remote_set = ResourceTreeSet()
# 设置数据...
local_set.merge_remote_resources(remote_set)
# 验证合并结果...
```
## ROS 消息测试
```python
import pytest
from unilabos.ros.msgs.message_converter import (
convert_to_ros_msg,
convert_from_ros_msg_with_mapping,
msg_converter_manager,
)
def test_message_conversion():
"""测试消息转换"""
# Python -> ROS
python_data = {"id": "test", "value": 42}
ros_msg = convert_to_ros_msg(python_data, MyMsgType)
assert ros_msg.id == "test"
assert ros_msg.value == 42
# ROS -> Python
result = convert_from_ros_msg_with_mapping(ros_msg, mapping)
assert result["id"] == "test"
```
## 协议测试
```python
import pytest
import networkx as nx
from unilabos.compile.stir_protocol import (
generate_stir_protocol,
extract_vessel_id,
)
@pytest.fixture
def topology_graph():
"""创建测试拓扑图"""
G = nx.DiGraph()
G.add_node("flask_1", **{"class": "flask"})
G.add_node("stirrer_1", **{"class": "virtual_stirrer"})
G.add_edge("stirrer_1", "flask_1")
return G
def test_generate_stir_protocol(topology_graph):
"""测试搅拌协议生成"""
actions = generate_stir_protocol(
G=topology_graph,
vessel="flask_1",
time="5 min",
stir_speed=300.0
)
assert len(actions) == 1
assert actions[0]["device_id"] == "stirrer_1"
assert actions[0]["action_name"] == "stir"
def test_extract_vessel_id():
"""测试vessel_id提取"""
# 字典格式
assert extract_vessel_id({"id": "flask_1"}) == "flask_1"
# 字符串格式
assert extract_vessel_id("flask_2") == "flask_2"
# 空值
assert extract_vessel_id("") == ""
```
## 测试标记
```python
# 慢速测试
@pytest.mark.slow
def test_long_running():
pass
# 需要网络
@pytest.mark.network
def test_network_call():
pass
# 需要ROS
@pytest.mark.ros
def test_ros_feature():
pass
```
运行特定标记的测试:
```bash
pytest -m "not slow" # 排除慢速测试
pytest -m ros # 仅ROS测试
```
## 覆盖率
```bash
# 生成覆盖率报告
pytest --cov=unilabos tests/
# HTML报告
pytest --cov=unilabos --cov-report=html tests/
```
## 最佳实践
1. **测试命名**: `test_{功能}_{场景}_{预期结果}`
2. **独立性**: 每个测试独立运行,不依赖其他测试
3. **Mock外部依赖**: 使用 unittest.mock 模拟外部服务
4. **参数化**: 使用 `@pytest.mark.parametrize` 减少重复代码
5. **fixtures**: 使用 fixtures 共享测试设置
6. **断言清晰**: 每个断言只验证一件事

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---
description: Uni-Lab-OS 实验室自动化平台开发规范 - 核心规则
globs: ["**/*.py", "**/*.yaml", "**/*.json"]
---
# Uni-Lab-OS 项目开发规范
## 项目概述
Uni-Lab-OS 是一个实验室自动化操作系统,用于连接和控制各种实验设备,实现实验工作流的自动化和标准化。
## 技术栈
- **Python 3.11** - 核心开发语言
- **ROS 2** - 设备通信中间件 (rclpy)
- **Conda/Mamba** - 包管理 (robostack-staging, conda-forge)
- **FastAPI** - Web API 服务
- **WebSocket** - 实时通信
- **NetworkX** - 拓扑图管理
- **YAML** - 配置和注册表定义
- **PyLabRobot** - 实验室自动化库集成
- **pytest** - 测试框架
- **asyncio** - 异步编程
## 项目结构
```
unilabos/
├── app/ # 应用入口、Web服务、后端
├── compile/ # 协议编译器 (stir, add, filter 等)
├── config/ # 配置管理
├── devices/ # 设备驱动 (真实/虚拟)
├── device_comms/ # 设备通信协议
├── device_mesh/ # 3D网格和可视化
├── registry/ # 设备和资源类型注册表 (YAML)
├── resources/ # 资源定义
├── ros/ # ROS 2 集成
├── utils/ # 工具函数
└── workflow/ # 工作流管理
```
## 代码规范
### Python 风格
1. **类型注解**:所有函数必须使用类型注解
```python
def transfer_liquid(
source: str,
destination: str,
volume: float,
**kwargs
) -> List[Dict[str, Any]]:
```
2. **Docstring**:使用 Google 风格的文档字符串
```python
def initialize(self) -> bool:
"""
初始化设备
Returns:
bool: 初始化是否成功
"""
```
3. **导入顺序**
- 标准库
- 第三方库
- ROS 相关 (rclpy, unilabos_msgs)
- 项目内部模块
### 异步编程
1. 设备操作方法使用 `async def`
2. 使用 `await self._ros_node.sleep()` 而非 `asyncio.sleep()`
3. 长时间运行操作需提供进度反馈
```python
async def stir(self, stir_time: float, stir_speed: float, **kwargs) -> bool:
"""执行搅拌操作"""
start_time = time_module.time()
while True:
elapsed = time_module.time() - start_time
remaining = max(0, stir_time - elapsed)
self.data.update({
"remaining_time": remaining,
"status": f"搅拌中: {stir_speed} RPM"
})
if remaining <= 0:
break
await self._ros_node.sleep(1.0)
return True
```
### 日志规范
使用项目自定义日志系统:
```python
from unilabos.utils.log import logger, info, debug, warning, error, trace
# 在设备类中使用
self.logger = logging.getLogger(f"DeviceName.{self.device_id}")
self.logger.info("设备初始化完成")
```
## 设备驱动开发
### 设备类结构
```python
from unilabos.ros.nodes.base_device_node import BaseROS2DeviceNode
class MyDevice:
"""设备驱动类"""
_ros_node: BaseROS2DeviceNode
def __init__(self, device_id: str = None, config: Dict[str, Any] = None, **kwargs):
self.device_id = device_id or "unknown_device"
self.config = config or {}
self.data = {} # 设备状态数据
def post_init(self, ros_node: BaseROS2DeviceNode):
"""ROS节点注入"""
self._ros_node = ros_node
async def initialize(self) -> bool:
"""初始化设备"""
pass
async def cleanup(self) -> bool:
"""清理设备"""
pass
# 状态属性 - 自动发布为 ROS Topic
@property
def status(self) -> str:
return self.data.get("status", "待机")
```
### 状态属性装饰器
```python
from unilabos.utils.decorator import topic_config
class MyDevice:
@property
@topic_config(period=1.0, qos=10) # 每秒发布一次
def temperature(self) -> float:
return self._temperature
```
### 虚拟设备
虚拟设备放置在 `unilabos/devices/virtual/` 目录下,命名为 `virtual_*.py`
## 注册表配置
### 设备注册表 (YAML)
位置: `unilabos/registry/devices/*.yaml`
```yaml
my_device_type:
category:
- my_category
description: "设备描述"
version: "1.0.0"
class:
module: "unilabos.devices.my_device:MyDevice"
type: python
status_types:
status: String
temperature: Float64
action_value_mappings:
auto-initialize:
type: UniLabJsonCommandAsync
goal: {}
feedback: {}
result: {}
schema: {...}
```
### 资源注册表 (YAML)
位置: `unilabos/registry/resources/**/*.yaml`
```yaml
my_container:
category:
- container
class:
module: "unilabos.resources.my_resource:MyContainer"
type: pylabrobot
version: "1.0.0"
```
## 协议编译器
位置: `unilabos/compile/*_protocol.py`
### 协议生成函数模板
```python
from typing import List, Dict, Any, Union
import networkx as nx
def generate_my_protocol(
G: nx.DiGraph,
vessel: Union[str, dict],
param1: float = 0.0,
**kwargs
) -> List[Dict[str, Any]]:
"""
生成操作协议序列
Args:
G: 物理拓扑图
vessel: 容器ID或字典
param1: 参数1
Returns:
List[Dict]: 动作序列
"""
# 提取vessel_id
vessel_id = vessel if isinstance(vessel, str) else vessel.get("id", "")
# 查找设备
device_id = find_connected_device(G, vessel_id)
# 生成动作
action_sequence = [{
"device_id": device_id,
"action_name": "my_action",
"action_kwargs": {
"vessel": {"id": vessel_id},
"param1": float(param1)
}
}]
return action_sequence
```
## 测试规范
### 测试文件位置
- 单元测试: `tests/` 目录
- 设备测试: `tests/devices/`
- 资源测试: `tests/resources/`
- ROS消息测试: `tests/ros/msgs/`
### 测试命名
```python
# tests/devices/my_device/test_my_device.py
import pytest
def test_device_initialization():
"""测试设备初始化"""
pass
def test_device_action():
"""测试设备动作"""
pass
```
## 错误处理
```python
from unilabos.utils.exception import UniLabException
try:
result = await device.execute_action()
except ValueError as e:
self.logger.error(f"参数错误: {e}")
self.data["status"] = "错误: 参数无效"
return False
except Exception as e:
self.logger.error(f"执行失败: {e}")
raise
```
## 配置管理
```python
from unilabos.config.config import BasicConfig, HTTPConfig
# 读取配置
port = BasicConfig.port
is_host = BasicConfig.is_host_mode
# 配置文件: local_config.py
```
## 常用工具
### 单例模式
```python
from unilabos.utils.decorator import singleton
@singleton
class MyManager:
pass
```
### 类型检查
```python
from unilabos.utils.type_check import NoAliasDumper
yaml.dump(data, f, Dumper=NoAliasDumper)
```
### 导入管理
```python
from unilabos.utils.import_manager import get_class
device_class = get_class("unilabos.devices.my_device:MyDevice")
```
## Git 提交规范
提交信息格式:
```
<type>(<scope>): <subject>
<body>
```
类型:
- `feat`: 新功能
- `fix`: 修复bug
- `docs`: 文档更新
- `refactor`: 重构
- `test`: 测试相关
- `chore`: 构建/工具相关
示例:
```
feat(devices): 添加虚拟搅拌器设备
- 实现VirtualStirrer类
- 支持定时搅拌和持续搅拌模式
- 添加速度验证逻辑
```

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---
name: add-device
description: Guide for adding new devices to Uni-Lab-OS (接入新设备). Walks through device category selection (thing model), communication protocol, command protocol collection, driver creation, registry YAML, and graph file setup. Use when the user wants to add/integrate a new device, create a device driver, write a device class, configure device registry, or mentions 接入设备/添加设备/设备驱动/物模型.
---
# 添加新设备到 Uni-Lab-OS
**第一步:** 使用 Read 工具读取 `docs/ai_guides/add_device.md`,获取完整的设备接入指南并严格遵循。
该指南包含:
- 8 步完整流程(设备类别、通信协议、指令收集、接口对齐、驱动创建、注册表、图文件、验证)
- 所有物模型代码模板(注射泵、电磁阀、蠕动泵、温控、电机等)
- 通信协议代码片段Serial、Modbus、TCP、HTTP、OPC UA
- 现有设备接口快照用于第四步对齐包含参数名、status_types、方法签名
- 常见错误检查清单
**Cursor 工具映射:**
| 指南中的操作 | Cursor 中使用的工具 |
|---|---|
| 向用户确认设备类别、协议等信息 | 使用 AskQuestion 工具 |
| 搜索已有设备注册表 | 使用 Grep 在 `unilabos/registry/devices/` 中搜索 |
| 读取用户提供的协议文档/SDK 代码 | 使用 Read 工具 |
| 第四步对齐:查找同类设备接口 | 优先使用 Grep 搜索仓库中的最新注册表;指南中的「现有设备接口快照」作为兜底参考 |

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---
name: add-protocol
description: Guide for adding new experiment protocols to Uni-Lab-OS (添加新实验操作协议). Walks through ROS Action definition, Pydantic model creation, protocol generator implementation, and registration. Use when the user wants to add a new protocol, create a compile function, implement an experiment operation, or mentions 协议/protocol/编译/compile/实验操作.
---
# 添加新实验操作协议Protocol
Protocol 是对实验有意义的完整动作(如泵转移、过滤、溶解),需要多设备协同。`compile/` 中的生成函数根据设备连接图将抽象操作"编译"为设备指令序列。
添加一个 Protocol 需修改 **6 个文件**,按以下流程执行。
---
## 第一步:确认协议信息
向用户确认:
| 信息 | 示例 |
|------|------|
| 协议英文名 | `MyNewProtocol` |
| 操作描述 | 将固体样品研磨至目标粒径 |
| Goal 参数(必需 + 可选) | `vessel: dict`, `time: float = 300.0` |
| Result 字段 | `success: bool`, `message: str` |
| 需要哪些设备协同 | 研磨器、搅拌器 |
---
## 第二步:创建 ROS Action 定义
路径:`unilabos_msgs/action/<ActionName>.action`
三段式结构Goal / Result / Feedback`---` 分隔:
```
# Goal
Resource vessel
float64 time
string mode
---
# Result
bool success
string return_info
---
# Feedback
string status
string current_device
builtin_interfaces/Duration time_spent
builtin_interfaces/Duration time_remaining
```
**类型映射:**
| Python 类型 | ROS 类型 | 说明 |
|------------|----------|------|
| `dict` | `Resource` | 容器/设备引用,自定义消息类型 |
| `float` | `float64` | |
| `int` | `int32` | |
| `str` | `string` | |
| `bool` | `bool` | |
> `Resource` 是 `unilabos_msgs/msg/Resource.msg` 中定义的自定义消息类型。
---
## 第三步:注册 Action 到 CMakeLists
`unilabos_msgs/CMakeLists.txt``set(action_files ...)` 块中添加:
```cmake
"action/MyNewAction.action"
```
> 调试时需编译:`cd unilabos_msgs && colcon build && source ./install/local_setup.sh && cd ..`
> PR 合并后 CI/CD 自动发布,`mamba update ros-humble-unilabos-msgs` 即可。
---
## 第四步:创建 Pydantic 模型
`unilabos/messages/__init__.py` 中添加(位于 `# Start Protocols``# End Protocols` 之间):
```python
class MyNewProtocol(BaseModel):
# === 必需参数 ===
vessel: dict = Field(..., description="目标容器")
# === 可选参数 ===
time: float = Field(300.0, description="操作时间 (秒)")
mode: str = Field("default", description="操作模式")
def model_post_init(self, __context):
"""参数验证和修正"""
if self.time <= 0:
self.time = 300.0
```
**规则:**
- 参数名必须与 `.action` 文件中 Goal 字段完全一致
- `dict` 类型对应 `.action` 中的 `Resource`
- 将类名加入文件末尾的 `__all__` 列表
---
## 第五步:实现协议生成函数
路径:`unilabos/compile/<protocol_name>_protocol.py`
```python
import networkx as nx
from typing import List, Dict, Any
def generate_my_new_protocol(
G: nx.DiGraph,
vessel: dict,
time: float = 300.0,
mode: str = "default",
**kwargs,
) -> List[Dict[str, Any]]:
"""将 MyNewProtocol 编译为设备动作序列。
Args:
G: 设备连接图NetworkX节点为设备/容器,边为物理连接
vessel: 目标容器 {"id": "reactor_1"}
time: 操作时间(秒)
mode: 操作模式
Returns:
动作列表,每个元素为:
- dict: 单步动作
- list[dict]: 并行动作
"""
from unilabos.compile.utils.vessel_parser import get_vessel
vessel_id, vessel_data = get_vessel(vessel)
actions = []
# 查找相关设备(通过图的连接关系)
# 生成动作序列
actions.append({
"device_id": "target_device_id",
"action_name": "some_action",
"action_kwargs": {"param": "value"}
})
# 等待
actions.append({
"action_name": "wait",
"action_kwargs": {"time": time}
})
return actions
```
### 动作字典格式
```python
# 单步动作(发给子设备)
{"device_id": "pump_1", "action_name": "set_position", "action_kwargs": {"position": 10.0}}
# 发给工作站自身
{"device_id": "self", "action_name": "my_action", "action_kwargs": {...}}
# 等待
{"action_name": "wait", "action_kwargs": {"time": 5.0}}
# 并行动作(列表嵌套)
[
{"device_id": "pump_1", "action_name": "set_position", "action_kwargs": {"position": 10.0}},
{"device_id": "stirrer_1", "action_name": "start_stir", "action_kwargs": {"stir_speed": 300}}
]
```
### 关于 `vessel` 参数类型
现有协议的 `vessel` 参数类型不统一:
- 新协议趋势:使用 `dict`(如 `{"id": "reactor_1"}`
- 旧协议:使用 `str`(如 `"reactor_1"`
- 兼容写法:`Union[str, dict]`
**建议新协议统一使用 `dict` 类型**,通过 `get_vessel()` 兼容两种输入。
### 公共工具函数(`unilabos/compile/utils/`
| 函数 | 用途 |
|------|------|
| `get_vessel(vessel)` | 解析容器参数为 `(vessel_id, vessel_data)`,兼容 dict 和 str |
| `find_solvent_vessel(G, solvent)` | 根据溶剂名查找容器(精确→命名规则→模糊→液体类型) |
| `find_reagent_vessel(G, reagent)` | 根据试剂名查找容器(支持固体和液体) |
| `find_connected_stirrer(G, vessel)` | 查找与容器相连的搅拌器 |
| `find_solid_dispenser(G)` | 查找固体加样器 |
### 协议内专属查找函数
许多协议在自己的文件内定义了专属的 `find_*` 函数(不在 `utils/` 中)。编写新协议时,优先复用 `utils/` 中的公共函数;如需特殊查找逻辑,在协议文件内部定义即可:
```python
def find_my_special_device(G: nx.DiGraph, vessel: str) -> str:
"""查找与容器相关的特殊设备"""
for node in G.nodes():
if 'my_device_type' in G.nodes[node].get('class', '').lower():
return node
raise ValueError("未找到特殊设备")
```
### 复用已有协议
复杂协议通常组合已有协议:
```python
from unilabos.compile.pump_protocol import generate_pump_protocol_with_rinsing
actions.extend(generate_pump_protocol_with_rinsing(
G, from_vessel=solvent_vessel, to_vessel=vessel, volume=volume
))
```
### 图查询模式
```python
# 查找与容器相连的特定类型设备
for neighbor in G.neighbors(vessel_id):
node_data = G.nodes[neighbor]
if "heater" in node_data.get("class", ""):
heater_id = neighbor
break
# 查找最短路径(泵转移)
path = nx.shortest_path(G, source=from_vessel_id, target=to_vessel_id)
```
---
## 第六步:注册协议生成函数
`unilabos/compile/__init__.py` 中:
1. 顶部添加导入:
```python
from .my_new_protocol import generate_my_new_protocol
```
2.`action_protocol_generators` 字典中添加映射:
```python
action_protocol_generators = {
# ... 已有协议
MyNewProtocol: generate_my_new_protocol,
}
```
---
## 第七步:配置图文件
在工作站的图文件中,将协议名加入 `protocol_type`
```json
{
"id": "my_station",
"class": "workstation",
"config": {
"protocol_type": ["PumpTransferProtocol", "MyNewProtocol"]
}
}
```
---
## 第八步:验证
```bash
# 1. 模块可导入
python -c "from unilabos.messages import MyNewProtocol; print(MyNewProtocol.model_fields)"
# 2. 生成函数可导入
python -c "from unilabos.compile import action_protocol_generators; print(list(action_protocol_generators.keys()))"
# 3. 启动测试(可选)
unilab -g <graph>.json --complete_registry
```
---
## 工作流清单
```
协议接入进度:
- [ ] 1. 确认协议名、参数、涉及设备
- [ ] 2. 创建 .action 文件 (unilabos_msgs/action/<Name>.action)
- [ ] 3. 注册到 CMakeLists.txt
- [ ] 4. 创建 Pydantic 模型 (unilabos/messages/__init__.py) + 更新 __all__
- [ ] 5. 实现生成函数 (unilabos/compile/<name>_protocol.py)
- [ ] 6. 注册到 compile/__init__.py
- [ ] 7. 配置图文件 protocol_type
- [ ] 8. 验证
```
---
## 高级模式
实现复杂协议时,详见 [reference.md](reference.md)协议运行时数据流、mock graph 测试模式、单位解析工具(`unit_parser.py`)、复杂协议组合模式(以 dissolve 为例)。
---
## 现有协议速查
| 协议 | Pydantic 类 | 生成函数 | 核心参数 |
|------|-------------|---------|---------|
| 泵转移 | `PumpTransferProtocol` | `generate_pump_protocol_with_rinsing` | `from_vessel, to_vessel, volume` |
| 简单转移 | `TransferProtocol` | `generate_pump_protocol` | `from_vessel, to_vessel, volume` |
| 加样 | `AddProtocol` | `generate_add_protocol` | `vessel, reagent, volume` |
| 过滤 | `FilterProtocol` | `generate_filter_protocol` | `vessel, filtrate_vessel` |
| 溶解 | `DissolveProtocol` | `generate_dissolve_protocol` | `vessel, solvent, volume` |
| 加热/冷却 | `HeatChillProtocol` | `generate_heat_chill_protocol` | `vessel, temp, time` |
| 搅拌 | `StirProtocol` | `generate_stir_protocol` | `vessel, time` |
| 分离 | `SeparateProtocol` | `generate_separate_protocol` | `from_vessel, separation_vessel, solvent` |
| 蒸发 | `EvaporateProtocol` | `generate_evaporate_protocol` | `vessel, pressure, temp, time` |
| 清洗 | `CleanProtocol` | `generate_clean_protocol` | `vessel, solvent, volume` |
| 离心 | `CentrifugeProtocol` | `generate_centrifuge_protocol` | `vessel, speed, time` |
| 抽气充气 | `EvacuateAndRefillProtocol` | `generate_evacuateandrefill_protocol` | `vessel, gas` |

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# 协议高级参考
本文件是 SKILL.md 的补充包含协议运行时数据流、测试模式、单位解析工具和复杂协议组合模式。Agent 在需要实现这些功能时按需阅读。
---
## 1. 协议运行时数据流
从图文件到协议执行的完整链路:
```
实验图 JSON
↓ graphio.read_node_link_json()
physical_setup_graph (NetworkX DiGraph)
↓ ROS2WorkstationNode._setup_protocol_names(protocol_type)
为每个 protocol_name 创建 ActionServer
↓ 收到 Action Goal
_create_protocol_execute_callback()
↓ convert_from_ros_msg_with_mapping(goal, mapping)
protocol_kwargs (Python dict)
↓ 向 Host 查询 Resource 类型参数的当前状态
protocol_kwargs 更新vessel 带上 children、data 等)
↓ protocol_steps_generator(G=physical_setup_graph, **protocol_kwargs)
List[Dict] 动作序列
↓ 逐步 execute_single_action / 并行 create_task
子设备 ActionClient 执行
```
### `_setup_protocol_names` 核心逻辑
```python
def _setup_protocol_names(self, protocol_type):
if isinstance(protocol_type, str):
self.protocol_names = [p.strip() for p in protocol_type.split(",")]
else:
self.protocol_names = protocol_type
self.protocol_action_mappings = {}
for protocol_name in self.protocol_names:
protocol_type = globals()[protocol_name] # 从 messages 模块取 Pydantic 类
self.protocol_action_mappings[protocol_name] = get_action_type(protocol_type)
```
### `_create_protocol_execute_callback` 关键步骤
1. `convert_from_ros_msg_with_mapping(goal, action_value_mapping["goal"])` — ROS Goal → Python dict
2.`Resource` 类型字段,通过 `resource_get` Service 查询 Host 的最新资源状态
3. `protocol_steps_generator(G=physical_setup_graph, **protocol_kwargs)` — 调用编译函数
4. 遍历 steps`dict` 串行执行,`list` 并行执行
5. `execute_single_action` 通过 `_action_clients[device_id]` 向子设备发送 Action Goal
6. 执行完毕后通过 `resource_update` Service 更新资源状态
---
## 2. 测试模式
### 2.1 协议文件内测试函数
许多协议文件末尾有 `test_*` 函数,主要测试参数解析工具:
```python
def test_dissolve_protocol():
"""测试溶解协议的各种参数解析"""
volumes = ["10 mL", "?", 10.0, "1 L", "500 μL"]
for vol in volumes:
result = parse_volume_input(vol)
print(f"体积解析: {vol}{result}mL")
masses = ["2.9 g", "?", 2.5, "500 mg"]
for mass in masses:
result = parse_mass_input(mass)
print(f"质量解析: {mass}{result}g")
```
### 2.2 使用 mock graph 测试协议生成器
推荐的端到端测试模式:
```python
import pytest
import networkx as nx
from unilabos.compile.stir_protocol import generate_stir_protocol
@pytest.fixture
def topology_graph():
"""创建测试拓扑图"""
G = nx.DiGraph()
G.add_node("flask_1", **{"class": "flask", "type": "container"})
G.add_node("stirrer_1", **{"class": "virtual_stirrer", "type": "device"})
G.add_edge("stirrer_1", "flask_1")
return G
def test_generate_stir_protocol(topology_graph):
"""测试搅拌协议生成"""
actions = generate_stir_protocol(
G=topology_graph,
vessel="flask_1",
time="5 min",
stir_speed=300.0
)
assert len(actions) >= 1
assert actions[0]["device_id"] == "stirrer_1"
```
**要点:**
-`nx.DiGraph()` 构建最小拓扑
- `add_node(id, **attrs)` 设置 `class``type``data`
- `add_edge(src, dst)` 建立物理连接
- 协议内的 `find_*` 函数依赖这些节点和边
---
## 3. 单位解析工具
路径:`unilabos/compile/utils/unit_parser.py`
| 函数 | 输入 | 返回 | 默认值 |
|------|------|------|--------|
| `parse_volume_input(input, default_unit)` | `"100 mL"`, `"2.5 L"`, `"500 μL"`, `10.0`, `"?"` | mL (float) | 50.0 |
| `parse_mass_input(input)` | `"19.3 g"`, `"500 mg"`, `2.5`, `"?"` | g (float) | 1.0 |
| `parse_time_input(input)` | `"30 min"`, `"1 h"`, `"300"`, `60.0`, `"?"` | 秒 (float) | 60.0 |
支持的单位:
- **体积**: mL, L, μL/uL, milliliter, liter, microliter
- **质量**: g, mg, kg, gram, milligram, kilogram
- **时间**: s/sec/second, min/minute, h/hr/hour, d/day
特殊值 `"?"``"unknown"``"tbd"` 返回默认值。
---
## 4. 复杂协议组合模式
`dissolve_protocol` 为例,展示如何组合多个子操作:
### 整体流程
```
1. 解析参数 (parse_volume_input, parse_mass_input, parse_time_input)
2. 设备发现 (find_connected_heatchill, find_connected_stirrer, find_solid_dispenser)
3. 判断溶解类型 (液体 vs 固体)
4. 组合动作序列:
a. heat_chill_start / start_stir (启动加热/搅拌)
b. wait (等待温度稳定)
c. pump_protocol_with_rinsing (液体转移, 通过 extend 拼接)
或 add_solid (固体加样)
d. heat_chill / stir / wait (溶解等待)
e. heat_chill_stop (停止加热)
```
### 关键代码模式
**设备发现 → 条件组合:**
```python
heatchill_id = find_connected_heatchill(G, vessel_id)
stirrer_id = find_connected_stirrer(G, vessel_id)
solid_dispenser_id = find_solid_dispenser(G)
actions = []
# 启动阶段
if heatchill_id and temp > 25.0:
actions.append({
"device_id": heatchill_id,
"action_name": "heat_chill_start",
"action_kwargs": {"vessel": {"id": vessel_id}, "temp": temp}
})
actions.append({"action_name": "wait", "action_kwargs": {"time": 30}})
elif stirrer_id:
actions.append({
"device_id": stirrer_id,
"action_name": "start_stir",
"action_kwargs": {"vessel": {"id": vessel_id}, "stir_speed": stir_speed}
})
# 转移阶段(复用已有协议)
pump_actions = generate_pump_protocol_with_rinsing(
G=G, from_vessel=solvent_vessel, to_vessel=vessel_id, volume=volume
)
actions.extend(pump_actions)
# 等待阶段
if heatchill_id:
actions.append({
"device_id": heatchill_id,
"action_name": "heat_chill",
"action_kwargs": {"vessel": {"id": vessel_id}, "temp": temp, "time": time}
})
else:
actions.append({"action_name": "wait", "action_kwargs": {"time": time}})
```
---
## 5. 关键路径
| 内容 | 路径 |
|------|------|
| 协议执行回调 | `unilabos/ros/nodes/presets/workstation.py` |
| ROS 消息映射 | `unilabos/ros/msgs/message_converter.py` |
| 物理拓扑图 | `unilabos/resources/graphio.py` (`physical_setup_graph`) |
| 单位解析 | `unilabos/compile/utils/unit_parser.py` |
| 容器解析 | `unilabos/compile/utils/vessel_parser.py` |
| 溶解协议(组合示例) | `unilabos/compile/dissolve_protocol.py` |

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---
name: add-resource
description: Guide for adding new resources (materials, bottles, carriers, decks, warehouses) to Uni-Lab-OS (添加新物料/资源). Covers Bottle, Carrier, Deck, WareHouse definitions and registry YAML. Use when the user wants to add resources, define materials, create a deck layout, add bottles/carriers/plates, or mentions 物料/资源/resource/bottle/carrier/deck/plate/warehouse.
---
# 添加新物料资源
Uni-Lab-OS 的资源体系基于 PyLabRobot通过扩展实现 Bottle、Carrier、WareHouse、Deck 等实验室物料管理。
---
## 第一步:确认资源类型
向用户确认需要添加的资源类型:
| 类型 | 基类 | 用途 | 示例 |
|------|------|------|------|
| **Bottle** | `Well` (PyLabRobot) | 单个容器(瓶、小瓶、烧杯、反应器) | 试剂瓶、粉末瓶 |
| **BottleCarrier** | `ItemizedCarrier` | 多槽位载架(放多个 Bottle | 6 位试剂架、枪头盒 |
| **WareHouse** | `ItemizedCarrier` | 堆栈/仓库(放多个 Carrier | 4x4 堆栈 |
| **Deck** | `Deck` (PyLabRobot) | 工作站台面(放多个 WareHouse | 反应站 Deck |
**层级关系:** `Deck``WareHouse``BottleCarrier``Bottle`
还需确认:
- 资源所属的项目/场景(如 bioyond、battery、通用
- 尺寸参数(直径、高度、最大容积等)
- 布局参数(行列数、间距等)
---
## 第二步:创建资源定义
### 文件位置
```
unilabos/resources/
├── <project>/ # 按项目分组
│ ├── bottles.py # Bottle 工厂函数
│ ├── bottle_carriers.py # Carrier 工厂函数
│ ├── warehouses.py # WareHouse 工厂函数
│ └── decks.py # Deck 类定义
├── itemized_carrier.py # Bottle, BottleCarrier, ItemizedCarrier 基类
├── warehouse.py # WareHouse 基类
└── container.py # 通用容器
```
### 2A. 添加 Bottle工厂函数
```python
from unilabos.resources.itemized_carrier import Bottle
def My_Reagent_Bottle(
name: str,
diameter: float = 70.0, # 瓶体直径 (mm)
height: float = 120.0, # 瓶体高度 (mm)
max_volume: float = 500000.0, # 最大容积 (μL)
barcode: str = None,
) -> Bottle:
"""创建试剂瓶"""
return Bottle(
name=name,
diameter=diameter,
height=height,
max_volume=max_volume,
barcode=barcode,
model="My_Reagent_Bottle", # 唯一标识,用于注册表和物料映射
)
```
**Bottle 参数:**
- `name`: 实例名称(运行时唯一)
- `diameter`: 瓶体直径 (mm)
- `height`: 瓶体高度 (mm)
- `max_volume`: 最大容积 (**μL**注意单位500mL = 500000)
- `barcode`: 条形码(可选)
- `model`: 模型标识,与注册表 key 一致
### 2B. 添加 BottleCarrier工厂函数
```python
from pylabrobot.resources import ResourceHolder
from pylabrobot.resources.carrier import create_ordered_items_2d
from unilabos.resources.itemized_carrier import BottleCarrier
def My_6SlotCarrier(name: str) -> BottleCarrier:
"""创建 3x2 六槽位载架"""
sites = create_ordered_items_2d(
klass=ResourceHolder,
num_items_x=3, # 列数
num_items_y=2, # 行数
dx=10.0, # X 起始偏移
dy=10.0, # Y 起始偏移
dz=5.0, # Z 偏移
item_dx=42.0, # X 间距
item_dy=35.0, # Y 间距
size_x=20.0, # 槽位宽
size_y=20.0, # 槽位深
size_z=50.0, # 槽位高
)
carrier = BottleCarrier(
name=name,
size_x=146.0, # 载架总宽
size_y=80.0, # 载架总深
size_z=55.0, # 载架总高
sites=sites,
model="My_6SlotCarrier",
)
carrier.num_items_x = 3
carrier.num_items_y = 2
carrier.num_items_z = 1
# 预装 Bottle可选
ordering = ["A01", "A02", "A03", "B01", "B02", "B03"]
for i in range(6):
carrier[i] = My_Reagent_Bottle(f"{ordering[i]}")
return carrier
```
### 2C. 添加 WareHouse工厂函数
```python
from unilabos.resources.warehouse import warehouse_factory
def my_warehouse_4x4(name: str) -> "WareHouse":
"""创建 4行x4列 堆栈仓库"""
return warehouse_factory(
name=name,
num_items_x=4, # 列数
num_items_y=4, # 行数
num_items_z=1, # 层数(通常为 1
dx=137.0, # X 起始偏移
dy=96.0, # Y 起始偏移
dz=120.0, # Z 起始偏移
item_dx=137.0, # X 间距
item_dy=125.0, # Y 间距
item_dz=10.0, # Z 间距(多层时用)
resource_size_x=127.0, # 槽位宽
resource_size_y=85.0, # 槽位深
resource_size_z=100.0, # 槽位高
model="my_warehouse_4x4",
)
```
**`warehouse_factory` 参数说明:**
| 参数 | 说明 |
|------|------|
| `num_items_x/y/z` | 列数/行数/层数 |
| `dx, dy, dz` | 第一个槽位的起始坐标偏移 |
| `item_dx, item_dy, item_dz` | 相邻槽位间距 |
| `resource_size_x/y/z` | 单个槽位的物理尺寸 |
| `col_offset` | 列命名偏移(如设 4 则从 A05 开始) |
| `row_offset` | 行命名偏移(如设 5 则从 F 行开始) |
| `layout` | 排序方式:`"col-major"`(列优先,默认)/ `"row-major"`(行优先) |
| `removed_positions` | 要移除的位置索引列表 |
自动生成 `ResourceHolder` 槽位,命名规则为 `A01, B01, C01, D01, A02, ...`(列优先)或 `A01, A02, A03, A04, B01, ...`(行优先)。
### 2D. 添加 Deck类定义
```python
from pylabrobot.resources import Deck, Coordinate
class MyStation_Deck(Deck):
def __init__(
self,
name: str = "MyStation_Deck",
size_x: float = 2700.0,
size_y: float = 1080.0,
size_z: float = 1500.0,
category: str = "deck",
setup: bool = False,
) -> None:
super().__init__(name=name, size_x=size_x, size_y=size_y, size_z=size_z)
if setup:
self.setup()
def setup(self) -> None:
self.warehouses = {
"仓库A": my_warehouse_4x4("仓库A"),
"仓库B": my_warehouse_4x4("仓库B"),
}
self.warehouse_locations = {
"仓库A": Coordinate(-200.0, 400.0, 0.0),
"仓库B": Coordinate(2350.0, 400.0, 0.0),
}
for wh_name, wh in self.warehouses.items():
self.assign_child_resource(wh, location=self.warehouse_locations[wh_name])
```
**Deck 要点:**
- 继承 `pylabrobot.resources.Deck`
- `setup()` 创建 WareHouse 并通过 `assign_child_resource` 放置到指定坐标
- `setup` 参数控制是否在构造时自动调用 `setup()`(图文件中通过 `config.setup: true` 触发)
---
## 第三步:创建注册表 YAML
路径:`unilabos/registry/resources/<project>/<type>.yaml`
### Bottle 注册
```yaml
My_Reagent_Bottle:
category:
- bottles
class:
module: unilabos.resources.my_project.bottles:My_Reagent_Bottle
type: pylabrobot
description: 我的试剂瓶
handles: []
icon: ''
init_param_schema: {}
version: 1.0.0
```
### Carrier 注册
```yaml
My_6SlotCarrier:
category:
- bottle_carriers
class:
module: unilabos.resources.my_project.bottle_carriers:My_6SlotCarrier
type: pylabrobot
handles: []
icon: ''
init_param_schema: {}
version: 1.0.0
```
### Deck 注册
```yaml
MyStation_Deck:
category:
- deck
class:
module: unilabos.resources.my_project.decks:MyStation_Deck
type: pylabrobot
description: 我的工作站 Deck
handles: []
icon: ''
init_param_schema: {}
registry_type: resource
version: 1.0.0
```
**注册表规则:**
- `class.module` 格式为 `python.module.path:ClassName_or_FunctionName`
- `class.type` 固定为 `pylabrobot`
- Key`My_Reagent_Bottle`)必须与工厂函数名 / 类名一致
- `category` 按类型标注(`bottles`, `bottle_carriers`, `deck` 等)
---
## 第四步:在图文件中引用
### Deck 在工作站中的引用
工作站节点通过 `deck` 字段引用Deck 作为子节点:
```json
{
"id": "my_station",
"children": ["my_deck"],
"deck": {
"data": {
"_resource_child_name": "my_deck",
"_resource_type": "unilabos.resources.my_project.decks:MyStation_Deck"
}
}
},
{
"id": "my_deck",
"parent": "my_station",
"type": "deck",
"class": "MyStation_Deck",
"config": {"type": "MyStation_Deck", "setup": true}
}
```
### 物料类型映射(外部系统对接时)
如果工作站需要与外部系统同步物料,在 config 中配置 `material_type_mappings`
```json
"material_type_mappings": {
"My_Reagent_Bottle": ["试剂瓶", "external-type-uuid"],
"My_6SlotCarrier": ["六槽载架", "external-type-uuid"]
}
```
---
## 第五步:注册 PLR 扩展(如需要)
如果添加了新的 Deck 类,需要在 `unilabos/resources/plr_additional_res_reg.py` 中导入,使 `find_subclass` 能发现它:
```python
def register():
from unilabos.resources.my_project.decks import MyStation_Deck
```
---
## 第六步:验证
```bash
# 1. 资源可导入
python -c "from unilabos.resources.my_project.bottles import My_Reagent_Bottle; print(My_Reagent_Bottle('test'))"
# 2. Deck 可创建
python -c "
from unilabos.resources.my_project.decks import MyStation_Deck
d = MyStation_Deck('test', setup=True)
print(d.children)
"
# 3. 启动测试
unilab -g <graph>.json --complete_registry
```
---
## 工作流清单
```
资源接入进度:
- [ ] 1. 确定资源类型Bottle / Carrier / WareHouse / Deck
- [ ] 2. 创建资源定义(工厂函数/类)
- [ ] 3. 创建注册表 YAML (unilabos/registry/resources/<project>/<type>.yaml)
- [ ] 4. 在图文件中引用(如需要)
- [ ] 5. 注册 PLR 扩展Deck 类需要)
- [ ] 6. 验证
```
---
## 高级模式
实现复杂资源系统时,详见 [reference.md](reference.md):类继承体系完整图、序列化/反序列化流程、Bioyond 物料双向同步、非瓶类资源ElectrodeSheet / Magazine、仓库工厂 layout 模式。
---
## 现有资源参考
| 项目 | Bottles | Carriers | WareHouses | Decks |
|------|---------|----------|------------|-------|
| bioyond | `bioyond/bottles.py` | `bioyond/bottle_carriers.py` | `bioyond/warehouses.py`, `YB_warehouses.py` | `bioyond/decks.py` |
| battery | — | `battery/bottle_carriers.py` | — | — |
| 通用 | — | — | `warehouse.py` | — |
### 关键路径
| 内容 | 路径 |
|------|------|
| Bottle/Carrier 基类 | `unilabos/resources/itemized_carrier.py` |
| WareHouse 基类 + 工厂 | `unilabos/resources/warehouse.py` |
| PLR 注册 | `unilabos/resources/plr_additional_res_reg.py` |
| 资源注册表 | `unilabos/registry/resources/` |
| 图文件加载 | `unilabos/resources/graphio.py` |
| 资源跟踪器 | `unilabos/resources/resource_tracker.py` |

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# 资源高级参考
本文件是 SKILL.md 的补充,包含类继承体系、序列化/反序列化、Bioyond 物料同步、非瓶类资源和仓库工厂模式。Agent 在需要实现这些功能时按需阅读。
---
## 1. 类继承体系
```
PyLabRobot
├── Resource (PLR 基类)
│ ├── Well
│ │ └── Bottle (unilabos) → 瓶/小瓶/烧杯/反应器
│ ├── Deck
│ │ └── 自定义 Deck 类 (unilabos) → 工作站台面
│ ├── ResourceHolder → 槽位占位符
│ └── Container
│ └── Battery (unilabos) → 组装好的电池
├── ItemizedCarrier (unilabos, 继承 Resource)
│ ├── BottleCarrier (unilabos) → 瓶载架
│ └── WareHouse (unilabos) → 堆栈仓库
├── ItemizedResource (PLR)
│ └── MagazineHolder (unilabos) → 子弹夹载架
└── ResourceStack (PLR)
└── Magazine (unilabos) → 子弹夹洞位
```
### Bottle 类细节
```python
class Bottle(Well):
def __init__(self, name, diameter, height, max_volume,
size_x=0.0, size_y=0.0, size_z=0.0,
barcode=None, category="container", model=None, **kwargs):
super().__init__(
name=name,
size_x=diameter, # PLR 用 diameter 作为 size_x/size_y
size_y=diameter,
size_z=height, # PLR 用 height 作为 size_z
max_volume=max_volume,
category=category,
model=model,
bottom_type="flat",
cross_section_type="circle"
)
```
注意 `size_x = size_y = diameter``size_z = height`
### ItemizedCarrier 核心方法
| 方法 | 说明 |
|------|------|
| `__getitem__(identifier)` | 通过索引或 Excel 标识(如 `"A01"`)访问槽位 |
| `__setitem__(identifier, resource)` | 向槽位放入资源 |
| `get_child_identifier(child)` | 获取子资源的标识符 |
| `capacity` | 总槽位数 |
| `sites` | 所有槽位字典 |
---
## 2. 序列化与反序列化
### PLR ↔ UniLab 转换
| 函数 | 位置 | 方向 |
|------|------|------|
| `ResourceTreeSet.from_plr_resources(resources)` | `resource_tracker.py` | PLR → UniLab |
| `ResourceTreeSet.to_plr_resources()` | `resource_tracker.py` | UniLab → PLR |
### `from_plr_resources` 流程
```
PLR Resource
↓ build_uuid_mapping (递归生成 UUID)
↓ resource.serialize() → dict
↓ resource.serialize_all_state() → states
↓ resource_plr_inner (递归构建 ResourceDictInstance)
ResourceTreeSet
```
关键:每个 PLR 资源通过 `unilabos_uuid` 属性携带 UUID`unilabos_extra` 携带扩展数据(如 `class` 名)。
### `to_plr_resources` 流程
```
ResourceTreeSet
↓ collect_node_data (收集 UUID、状态、扩展数据)
↓ node_to_plr_dict (转为 PLR 字典格式)
↓ find_subclass(type_name, PLRResource) (查找 PLR 子类)
↓ sub_cls.deserialize(plr_dict) (反序列化)
↓ loop_set_uuid, loop_set_extra (递归设置 UUID 和扩展)
PLR Resource
```
### Bottle 序列化
```python
class Bottle(Well):
def serialize(self) -> dict:
data = super().serialize()
return {**data, "diameter": self.diameter, "height": self.height}
@classmethod
def deserialize(cls, data: dict, allow_marshal=False):
barcode_data = data.pop("barcode", None)
instance = super().deserialize(data, allow_marshal=allow_marshal)
if barcode_data and isinstance(barcode_data, str):
instance.barcode = barcode_data
return instance
```
---
## 3. Bioyond 物料同步
### 双向转换函数
| 函数 | 位置 | 方向 |
|------|------|------|
| `resource_bioyond_to_plr(materials, type_mapping, deck)` | `graphio.py` | Bioyond → PLR |
| `resource_plr_to_bioyond(resources, type_mapping, warehouse_mapping)` | `graphio.py` | PLR → Bioyond |
### `resource_bioyond_to_plr` 流程
```
Bioyond 物料列表
↓ reverse_type_mapping: {typeName → (model, UUID)}
↓ 对每个物料:
typeName → 查映射 → model (如 "BIOYOND_PolymerStation_Reactor")
initialize_resource({"name": unique_name, "class": model})
↓ 设置 unilabos_extra (material_bioyond_id, material_bioyond_name 等)
↓ 处理 detail (子物料/坐标)
↓ 按 locationName 放入 deck.warehouses 对应槽位
PLR 资源列表
```
### `resource_plr_to_bioyond` 流程
```
PLR 资源列表
↓ 遍历每个资源:
载架(capacity > 1): 生成 details 子物料 + 坐标
单瓶: 直接映射
↓ type_mapping 查找 typeId
↓ warehouse_mapping 查找位置 UUID
↓ 组装 Bioyond 格式 (name, typeName, typeId, quantity, Parameters, locations)
Bioyond 物料列表
```
### BioyondResourceSynchronizer
工作站通过 `ResourceSynchronizer` 自动同步物料:
```python
class BioyondResourceSynchronizer(ResourceSynchronizer):
def sync_from_external(self) -> bool:
all_data = []
all_data.extend(api_client.stock_material('{"typeMode": 0}')) # 耗材
all_data.extend(api_client.stock_material('{"typeMode": 1}')) # 样品
all_data.extend(api_client.stock_material('{"typeMode": 2}')) # 试剂
unilab_resources = resource_bioyond_to_plr(
all_data,
type_mapping=self.workstation.bioyond_config["material_type_mappings"],
deck=self.workstation.deck
)
# 更新 deck 上的资源
```
---
## 4. 非瓶类资源
### ElectrodeSheet极片
路径:`unilabos/resources/battery/electrode_sheet.py`
```python
class ElectrodeSheet(ResourcePLR):
"""片状材料(极片、隔膜、弹片、垫片等)"""
_unilabos_state = {
"diameter": 0.0,
"thickness": 0.0,
"mass": 0.0,
"material_type": "",
"color": "",
"info": "",
}
```
工厂函数:`PositiveCan`, `PositiveElectrode`, `NegativeCan`, `NegativeElectrode`, `SpringWasher`, `FlatWasher`, `AluminumFoil`
### Battery电池
```python
class Battery(Container):
"""组装好的电池"""
_unilabos_state = {
"color": "",
"electrolyte_name": "",
"open_circuit_voltage": 0.0,
}
```
### Magazine / MagazineHolder子弹夹
```python
class Magazine(ResourceStack):
"""子弹夹洞位,可堆叠 ElectrodeSheet"""
# direction, max_sheets
class MagazineHolder(ItemizedResource):
"""多洞位子弹夹"""
# hole_diameter, hole_depth, max_sheets_per_hole
```
工厂函数 `magazine_factory()``create_homogeneous_resources` 生成洞位,可选预填 `ElectrodeSheet``Battery`
---
## 5. 仓库工厂模式参考
### 实际 warehouse 工厂函数示例
```python
# 行优先 4x4 仓库
def bioyond_warehouse_1x4x4(name: str) -> WareHouse:
return warehouse_factory(
name=name,
num_items_x=4, num_items_y=4, num_items_z=1,
dx=10.0, dy=10.0, dz=10.0,
item_dx=147.0, item_dy=106.0, item_dz=130.0,
layout="row-major", # A01,A02,A03,A04, B01,...
)
# 右侧 4x4 仓库(列名偏移)
def bioyond_warehouse_1x4x4_right(name: str) -> WareHouse:
return warehouse_factory(
name=name,
num_items_x=4, num_items_y=4, num_items_z=1,
dx=10.0, dy=10.0, dz=10.0,
item_dx=147.0, item_dy=106.0, item_dz=130.0,
col_offset=4, # A05,A06,A07,A08
layout="row-major",
)
# 竖向仓库(站内试剂存放)
def bioyond_warehouse_reagent_storage(name: str) -> WareHouse:
return warehouse_factory(
name=name,
num_items_x=1, num_items_y=2, num_items_z=1,
dx=10.0, dy=10.0, dz=10.0,
item_dx=147.0, item_dy=106.0, item_dz=130.0,
layout="vertical-col-major",
)
# 行偏移F 行开始)
def bioyond_warehouse_5x3x1(name: str, row_offset: int = 0) -> WareHouse:
return warehouse_factory(
name=name,
num_items_x=3, num_items_y=5, num_items_z=1,
dx=10.0, dy=10.0, dz=10.0,
item_dx=159.0, item_dy=183.0, item_dz=130.0,
row_offset=row_offset, # 0→A行起5→F行起
layout="row-major",
)
```
### layout 类型说明
| layout | 命名顺序 | 适用场景 |
|--------|---------|---------|
| `col-major` (默认) | A01,B01,C01,D01, A02,B02,... | 列优先,标准堆栈 |
| `row-major` | A01,A02,A03,A04, B01,B02,... | 行优先Bioyond 前端展示 |
| `vertical-col-major` | 竖向排列,标签从底部开始 | 竖向仓库(试剂存放、测密度) |
---
## 6. 关键路径
| 内容 | 路径 |
|------|------|
| Bottle/Carrier 基类 | `unilabos/resources/itemized_carrier.py` |
| WareHouse 类 + 工厂 | `unilabos/resources/warehouse.py` |
| ResourceTreeSet 转换 | `unilabos/resources/resource_tracker.py` |
| Bioyond 物料转换 | `unilabos/resources/graphio.py` |
| Bioyond 仓库定义 | `unilabos/resources/bioyond/warehouses.py` |
| 电池资源 | `unilabos/resources/battery/` |
| PLR 注册 | `unilabos/resources/plr_additional_res_reg.py` |

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---
name: add-workstation
description: Guide for adding new workstations to Uni-Lab-OS (接入新工作站). Walks through workstation type selection, sub-device composition, external system integration, driver creation, registry YAML, deck setup, and graph file configuration. Use when the user wants to add/integrate a new workstation, create a workstation driver, configure a station with sub-devices, set up deck and materials, or mentions 工作站/工站/station/workstation.
---
# Uni-Lab-OS 工作站接入指南
工作站workstation是组合多个子设备的大型设备拥有独立的物料管理系统PLR Deck和工作流引擎。本指南覆盖从需求分析到验证的全流程。
> **前置知识**:工作站接入基于 `docs/ai_guides/add_device.md` 的通用设备接入框架,但有显著差异。阅读本指南前无需先读通用指南。
## 第一步:确定工作站类型
向用户确认以下信息:
**Q1: 工作站的业务场景?**
| 类型 | 基类 | 适用场景 | 示例 |
|------|------|----------|------|
| **Protocol 工作站** | `ProtocolNode` | 标准化学操作协议(过滤、转移、加热等) | FilterProtocolStation |
| **外部系统工作站** | `WorkstationBase` | 与外部 LIMS/MES 系统对接,有专属 API | BioyondStation |
| **硬件控制工作站** | `WorkstationBase` | 直接控制 PLC/硬件,无外部系统 | CoinCellAssembly |
**Q2: 工作站英文名称?**(如 `my_reaction_station`
**Q3: 与外部系统的交互方式?**
| 方式 | 适用场景 | 需要的配置 |
|------|----------|-----------|
| 无外部系统 | Protocol 工作站、纯硬件控制 | 无 |
| HTTP API | LIMS/MES 系统(如 Bioyond | `api_host`, `api_key` |
| Modbus TCP | PLC 控制 | `address`, `port` |
| OPC UA | 工业设备 | `url` |
**Q4: 子设备组成?**
- 列出所有子设备(如反应器、泵、阀、传感器等)
- 哪些是已有设备类型?哪些需要新增?
- 子设备之间的硬件代理关系(如泵通过串口设备通信)
**Q5: 物料管理需求?**
- 是否需要 Deck物料面板
- 物料类型plate、tip_rack、bottle 等)
- 是否需要与外部物料系统同步?
---
## 第二步:理解工作站架构
工作站与普通设备的核心差异:
| 维度 | 普通设备 | 工作站 |
|------|---------|--------|
| 基类 | 无(纯 Python 类) | `WorkstationBase``ProtocolNode` |
| ROS 节点 | `BaseROS2DeviceNode` | `ROS2WorkstationNode` |
| 状态管理 | `self.data` 字典 | 通常不用 `self.data`,用 `@property` 直接访问 |
| 子设备 | 无 | `children` 列表,通过 `self._children` 访问 |
| 物料 | 无 | `self.deck`PLR Deck |
| 图文件角色 | `parent: null``parent: "<station>"` | `parent: null`,含 `children``deck` |
### 继承体系
`WorkstationBase` (ABC) → `ProtocolNode` (通用协议) / `BioyondWorkstation` (→ ReactionStation, DispensingStation) / `CoinCellAssemblyWorkstation` (硬件控制)
### ROS 层
`ROS2WorkstationNode` 额外负责:初始化 children 子设备节点、为子设备创建 ActionClient、配置硬件代理、为 protocol_type 创建协议 ActionServer。
---
## 第三步:创建驱动文件
文件路径:`unilabos/devices/workstation/<station_name>/<station_name>.py`
### 模板 A基于外部系统的工作站
适用于与 LIMS/MES 等外部系统对接的场景。
```python
import logging
from typing import Dict, Any, Optional, List
from pylabrobot.resources import Deck
from unilabos.devices.workstation.workstation_base import WorkstationBase
try:
from unilabos.ros.nodes.presets.workstation import ROS2WorkstationNode
except ImportError:
ROS2WorkstationNode = None
class MyWorkstation(WorkstationBase):
"""工作站描述"""
_ros_node: "ROS2WorkstationNode"
def __init__(
self,
config: dict = None,
deck: Optional[Deck] = None,
protocol_type: list = None,
**kwargs,
):
super().__init__(deck=deck, **kwargs)
self.config = config or {}
self.logger = logging.getLogger(f"MyWorkstation")
# 外部系统连接配置
self.api_host = self.config.get("api_host", "")
self.api_key = self.config.get("api_key", "")
# 工作站业务状态(不同于 self.data 模式)
self._status = "Idle"
def post_init(self, ros_node: "ROS2WorkstationNode") -> None:
super().post_init(ros_node)
# 在这里启动后台服务、连接监控等
# ============ 子设备访问 ============
def _get_child_device(self, device_id: str):
"""通过 ID 获取子设备节点"""
return self._children.get(device_id)
# ============ 动作方法 ============
async def scheduler_start(self, **kwargs) -> Dict[str, Any]:
"""启动调度器"""
return {"success": True}
async def create_order(self, json_str: str, **kwargs) -> Dict[str, Any]:
"""创建工单"""
return {"success": True}
# ============ 属性 ============
@property
def workflow_sequence(self) -> str:
return "[]"
@property
def material_info(self) -> str:
return "{}"
```
### 模板 B基于硬件控制的工作站
适用于直接与 PLC/硬件通信的场景。
```python
import logging
from typing import Dict, Any, Optional
from pylabrobot.resources import Deck
from unilabos.devices.workstation.workstation_base import WorkstationBase
try:
from unilabos.ros.nodes.presets.workstation import ROS2WorkstationNode
except ImportError:
ROS2WorkstationNode = None
class MyHardwareWorkstation(WorkstationBase):
"""硬件控制工作站"""
_ros_node: "ROS2WorkstationNode"
def __init__(
self,
config: dict = None,
deck: Optional[Deck] = None,
address: str = "192.168.1.100",
port: str = "502",
debug_mode: bool = False,
*args,
**kwargs,
):
super().__init__(deck=deck, *args, **kwargs)
self.config = config or {}
self.address = address
self.port = int(port)
self.debug_mode = debug_mode
self.logger = logging.getLogger("MyHardwareWorkstation")
# 初始化通信客户端
if not debug_mode:
from unilabos.device_comms.modbus_plc.client import ModbusTcpClient
self.client = ModbusTcpClient(host=self.address, port=self.port)
else:
self.client = None
def post_init(self, ros_node: "ROS2WorkstationNode") -> None:
super().post_init(ros_node)
# ============ 硬件读写 ============
def _read_register(self, name: str):
"""读取 Modbus 寄存器"""
if self.debug_mode:
return 0
# 实际读取逻辑
pass
# ============ 动作方法 ============
async def start_process(self, **kwargs) -> Dict[str, Any]:
"""启动加工流程"""
return {"success": True}
async def stop_process(self, **kwargs) -> Dict[str, Any]:
"""停止加工流程"""
return {"success": True}
# ============ 属性(从硬件实时读取)============
@property
def sys_status(self) -> str:
return str(self._read_register("SYS_STATUS"))
```
### 模板 CProtocol 工作站
适用于标准化学操作协议的场景,直接使用 `ProtocolNode`
```python
from typing import List, Optional
from pylabrobot.resources import Resource as PLRResource
from unilabos.devices.workstation.workstation_base import ProtocolNode
class MyProtocolStation(ProtocolNode):
"""Protocol 工作站 — 使用标准化学操作协议"""
def __init__(
self,
protocol_type: List[str],
deck: Optional[PLRResource] = None,
*args,
**kwargs,
):
super().__init__(protocol_type=protocol_type, deck=deck, *args, **kwargs)
```
> Protocol 工作站通常不需要自定义驱动类,直接使用 `ProtocolNode` 并在注册表和图文件中配置 `protocol_type` 即可。
---
## 第四步:创建子设备驱动(如需要)
工作站的子设备本身是独立设备。按 `docs/ai_guides/add_device.md` 的标准流程创建。
子设备的关键约束:
- 在图文件中 `parent` 指向工作站 ID
- 图文件中在工作站的 `children` 数组里列出
- 如需硬件代理,在子设备的 `config.hardware_interface.name` 指向通信设备 ID
---
## 第五步:创建注册表 YAML
路径:`unilabos/registry/devices/<station_name>.yaml`
### 最小配置
```yaml
my_workstation:
category:
- workstation
class:
module: unilabos.devices.workstation.my_station.my_station:MyWorkstation
type: python
```
启动时 `--complete_registry` 自动补全 `status_types``action_value_mappings`
### 完整配置参考
```yaml
my_workstation:
description: "我的工作站"
version: "1.0.0"
category:
- workstation
- my_category
class:
module: unilabos.devices.workstation.my_station.my_station:MyWorkstation
type: python
status_types:
workflow_sequence: String
material_info: String
action_value_mappings:
scheduler_start:
type: UniLabJsonCommandAsync
goal: {}
result:
success: success
create_order:
type: UniLabJsonCommandAsync
goal:
json_str: json_str
result:
success: success
init_param_schema:
config:
type: object
deck:
type: object
protocol_type:
type: array
```
### 子设备注册表
子设备有独立的注册表文件,需要在 `category` 中包含工作站标识:
```yaml
my_reactor:
category:
- reactor
- my_workstation
class:
module: unilabos.devices.workstation.my_station.my_reactor:MyReactor
type: python
```
---
## 第六步:配置 Deck 资源(如需要)
如果工作站有物料管理需求,需要定义 Deck 类。
### 使用已有 Deck 类
查看 `unilabos/resources/` 目录下是否有适用的 Deck 类。
### 创建自定义 Deck
`unilabos/resources/<category>/decks.py` 中定义:
```python
from pylabrobot.resources import Deck
from pylabrobot.resources.coordinate import Coordinate
def MyStation_Deck(name: str = "MyStation_Deck") -> Deck:
deck = Deck(name=name, size_x=2700.0, size_y=1080.0, size_z=1500.0)
# 在 deck 上定义子资源位置carrier、plate 等)
return deck
```
`unilabos/resources/<category>/` 下注册或通过注册表引用。
---
## 第七步:配置图文件
图文件路径:`unilabos/test/experiments/<station_name>.json`
### 完整结构
```json
{
"nodes": [
{
"id": "my_station",
"name": "my_station",
"children": ["my_deck", "sub_device_1", "sub_device_2"],
"parent": null,
"type": "device",
"class": "my_workstation",
"position": {"x": 0, "y": 0, "z": 0},
"config": {
"api_host": "http://192.168.1.100:8080",
"api_key": "YOUR_KEY"
},
"deck": {
"data": {
"_resource_child_name": "my_deck",
"_resource_type": "unilabos.resources.my_module.decks:MyStation_Deck"
}
},
"size_x": 2700.0,
"size_y": 1080.0,
"size_z": 1500.0,
"protocol_type": [],
"data": {}
},
{
"id": "my_deck",
"name": "my_deck",
"children": [],
"parent": "my_station",
"type": "deck",
"class": "MyStation_Deck",
"position": {"x": 0, "y": 0, "z": 0},
"config": {
"type": "MyStation_Deck",
"setup": true,
"rotation": {"x": 0, "y": 0, "z": 0, "type": "Rotation"}
},
"data": {}
},
{
"id": "sub_device_1",
"name": "sub_device_1",
"children": [],
"parent": "my_station",
"type": "device",
"class": "sub_device_registry_name",
"position": {"x": 100, "y": 0, "z": 0},
"config": {},
"data": {}
}
]
}
```
### 图文件规则
| 字段 | 说明 |
|------|------|
| `id` | 节点唯一标识,与 `children` 数组中的引用一致 |
| `children` | 包含 deck ID 和所有子设备 ID |
| `parent` | 工作站节点为 `null`;子设备/deck 指向工作站 ID |
| `type` | 工作站和子设备为 `"device"`deck 为 `"deck"` |
| `class` | 对应注册表中的设备名 |
| `deck.data._resource_child_name` | 必须与 deck 节点的 `id` 一致 |
| `deck.data._resource_type` | Deck 工厂函数的完整 Python 路径 |
| `protocol_type` | Protocol 工作站填入协议名列表;否则为 `[]` |
| `config` | 传入驱动 `__init__``config` 参数 |
---
## 第八步:验证
```bash
# 1. 模块可导入
python -c "from unilabos.devices.workstation.<name>.<name> import <ClassName>"
# 2. 注册表补全
unilab -g <graph>.json --complete_registry
# 3. 启动测试
unilab -g <graph>.json
```
---
## 高级模式
实现外部系统对接型工作站时,详见 [reference.md](reference.md)RPC 客户端、HTTP 回调服务、连接监控、Config 结构模式material_type_mappings / warehouse_mapping / workflow_mappings、ResourceSynchronizer、update_resource、工作流序列、站间物料转移、post_init 完整模式。
---
## 关键规则
1. **`__init__` 必须接受 `deck``**kwargs`** — `WorkstationBase.__init__` 需要 `deck` 参数
2. **通过 `self._children` 访问子设备** — 不要自行维护子设备引用
3. **`post_init` 中启动后台服务** — 不要在 `__init__` 中启动网络连接
4. **异步方法使用 `await self._ros_node.sleep()`** — 禁止 `time.sleep()``asyncio.sleep()`
5. **子设备在图文件中声明** — 不在驱动代码中创建子设备实例
6. **`deck` 配置中的 `_resource_child_name` 必须与 deck 节点 ID 一致**
7. **Protocol 工作站优先使用 `ProtocolNode`** — 不需要自定义类
---
## 工作流清单
```
工作站接入进度:
- [ ] 1. 确定工作站类型Protocol / 外部系统 / 硬件控制)
- [ ] 2. 确认子设备组成和物料需求
- [ ] 3. 创建工作站驱动 unilabos/devices/workstation/<name>/<name>.py
- [ ] 4. 创建子设备驱动(如需要,按 add_device.md 流程)
- [ ] 5. 创建注册表 unilabos/registry/devices/<name>.yaml
- [ ] 6. 创建/选择 Deck 资源类(如需要)
- [ ] 7. 配置图文件 unilabos/test/experiments/<name>.json
- [ ] 8. 验证:可导入 + 注册表补全 + 启动测试
```
---
## 现有工作站参考
| 工作站 | 注册表名 | 驱动类 | 类型 |
|--------|----------|--------|------|
| Protocol 通用 | `workstation` | `ProtocolNode` | Protocol |
| Bioyond 反应站 | `reaction_station.bioyond` | `BioyondReactionStation` | 外部系统 |
| Bioyond 配液站 | `bioyond_dispensing_station` | `BioyondDispensingStation` | 外部系统 |
| 纽扣电池组装 | `coincellassemblyworkstation_device` | `CoinCellAssemblyWorkstation` | 硬件控制 |
### 参考文件路径
- 基类: `unilabos/devices/workstation/workstation_base.py`
- Bioyond 基类: `unilabos/devices/workstation/bioyond_studio/station.py`
- 反应站: `unilabos/devices/workstation/bioyond_studio/reaction_station/reaction_station.py`
- 配液站: `unilabos/devices/workstation/bioyond_studio/dispensing_station/dispensing_station.py`
- 纽扣电池: `unilabos/devices/workstation/coin_cell_assembly/coin_cell_assembly.py`
- ROS 节点: `unilabos/ros/nodes/presets/workstation.py`
- 图文件: `unilabos/test/experiments/reaction_station_bioyond.json`, `dispensing_station_bioyond.json`

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# 工作站高级模式参考
本文件是 SKILL.md 的补充,包含外部系统集成、物料同步、配置结构等高级模式。
Agent 在需要实现这些功能时按需阅读。
---
## 1. 外部系统集成模式
### 1.1 RPC 客户端
与外部 LIMS/MES 系统通信的标准模式。继承 `BaseRequest`,所有接口统一用 POST。
```python
from unilabos.device_comms.rpc import BaseRequest
class MySystemRPC(BaseRequest):
"""外部系统 RPC 客户端"""
def __init__(self, host: str, api_key: str):
super().__init__(host)
self.api_key = api_key
def _request(self, endpoint: str, data: dict = None) -> dict:
return self.post(
url=f"{self.host}/api/{endpoint}",
params={
"apiKey": self.api_key,
"requestTime": self.get_current_time_iso8601(),
"data": data or {},
},
)
def query_status(self) -> dict:
return self._request("status/query")
def create_order(self, order_data: dict) -> dict:
return self._request("order/create", order_data)
```
参考:`unilabos/devices/workstation/bioyond_studio/bioyond_rpc.py``BioyondV1RPC`
### 1.2 HTTP 回调服务
接收外部系统报送的标准模式。使用 `WorkstationHTTPService`,在 `post_init` 中启动。
```python
from unilabos.devices.workstation.workstation_http_service import WorkstationHTTPService
class MyWorkstation(WorkstationBase):
def __init__(self, config=None, deck=None, **kwargs):
super().__init__(deck=deck, **kwargs)
self.config = config or {}
http_cfg = self.config.get("http_service_config", {})
self._http_service_config = {
"host": http_cfg.get("http_service_host", "127.0.0.1"),
"port": http_cfg.get("http_service_port", 8080),
}
self.http_service = None
def post_init(self, ros_node):
super().post_init(ros_node)
self.http_service = WorkstationHTTPService(
workstation_instance=self,
host=self._http_service_config["host"],
port=self._http_service_config["port"],
)
self.http_service.start()
```
**HTTP 服务路由**(固定端点,由 `WorkstationHTTPHandler` 自动分发):
| 端点 | 调用的工作站方法 |
|------|-----------------|
| `/report/step_finish` | `process_step_finish_report(report_request)` |
| `/report/sample_finish` | `process_sample_finish_report(report_request)` |
| `/report/order_finish` | `process_order_finish_report(report_request, used_materials)` |
| `/report/material_change` | `process_material_change_report(report_data)` |
| `/report/error_handling` | `handle_external_error(error_data)` |
实现对应方法即可接收回调:
```python
def process_step_finish_report(self, report_request) -> Dict[str, Any]:
"""处理步骤完成报告"""
step_name = report_request.data.get("stepName")
return {"success": True, "message": f"步骤 {step_name} 已处理"}
def process_order_finish_report(self, report_request, used_materials) -> Dict[str, Any]:
"""处理订单完成报告"""
order_code = report_request.data.get("orderCode")
return {"success": True}
```
参考:`unilabos/devices/workstation/workstation_http_service.py`
### 1.3 连接监控
独立线程周期性检测外部系统连接状态,状态变化时发布 ROS 事件。
```python
class ConnectionMonitor:
def __init__(self, workstation, check_interval=30):
self.workstation = workstation
self.check_interval = check_interval
self._running = False
self._thread = None
def start(self):
self._running = True
self._thread = threading.Thread(target=self._monitor_loop, daemon=True)
self._thread.start()
def _monitor_loop(self):
while self._running:
try:
# 调用外部系统接口检测连接
self.workstation.hardware_interface.ping()
status = "online"
except Exception:
status = "offline"
time.sleep(self.check_interval)
```
参考:`unilabos/devices/workstation/bioyond_studio/station.py``ConnectionMonitor`
---
## 2. Config 结构模式
工作站的 `config` 在图文件中定义,传入 `__init__`。以下是常见字段模式:
### 2.1 外部系统连接
```json
{
"api_host": "http://192.168.1.100:8080",
"api_key": "YOUR_API_KEY"
}
```
### 2.2 HTTP 回调服务
```json
{
"http_service_config": {
"http_service_host": "127.0.0.1",
"http_service_port": 8080
}
}
```
### 2.3 物料类型映射
将 PLR 资源类名映射到外部系统的物料类型(名称 + UUID。用于双向物料转换。
```json
{
"material_type_mappings": {
"PLR_ResourceClassName": ["外部系统显示名", "external-type-uuid"],
"BIOYOND_PolymerStation_Reactor": ["反应器", "3a14233b-902d-0d7b-..."]
}
}
```
### 2.4 仓库映射
将仓库名映射到外部系统的仓库 UUID 和库位 UUID。用于入库/出库操作。
```json
{
"warehouse_mapping": {
"仓库名": {
"uuid": "warehouse-uuid",
"site_uuids": {
"A01": "site-uuid-A01",
"A02": "site-uuid-A02"
}
}
}
}
```
### 2.5 工作流映射
将内部工作流名映射到外部系统的工作流 ID。
```json
{
"workflow_mappings": {
"internal_workflow_name": "external-workflow-uuid"
}
}
```
### 2.6 物料默认参数
```json
{
"material_default_parameters": {
"NMP": {
"unit": "毫升",
"density": "1.03",
"densityUnit": "g/mL",
"description": "N-甲基吡咯烷酮"
}
}
}
```
---
## 3. 资源同步机制
### 3.1 ResourceSynchronizer
抽象基类,用于与外部物料系统双向同步。定义在 `workstation_base.py`
```python
from unilabos.devices.workstation.workstation_base import ResourceSynchronizer
class MyResourceSynchronizer(ResourceSynchronizer):
def __init__(self, workstation, api_client):
super().__init__(workstation)
self.api_client = api_client
def sync_from_external(self) -> bool:
"""从外部系统拉取物料到 deck"""
external_materials = self.api_client.list_materials()
for material in external_materials:
plr_resource = self._convert_to_plr(material)
self.workstation.deck.assign_child_resource(plr_resource, coordinate)
return True
def sync_to_external(self, plr_resource) -> bool:
"""将 deck 中的物料变更推送到外部系统"""
external_data = self._convert_from_plr(plr_resource)
self.api_client.update_material(external_data)
return True
def handle_external_change(self, change_info) -> bool:
"""处理外部系统推送的物料变更"""
return True
```
### 3.2 update_resource — 上传资源树到云端
将 PLR Deck 序列化后通过 ROS 服务上传。典型使用场景:
```python
# 在 post_init 中上传初始 deck
from unilabos.ros.nodes.base_device_node import ROS2DeviceNode
ROS2DeviceNode.run_async_func(
self._ros_node.update_resource, True,
**{"resources": [self.deck]}
)
# 在动作方法中更新特定资源
ROS2DeviceNode.run_async_func(
self._ros_node.update_resource, True,
**{"resources": [updated_plate]}
)
```
---
## 4. 工作流序列管理
工作站通过 `workflow_sequence` 属性管理任务队列JSON 字符串形式)。
```python
class MyWorkstation(WorkstationBase):
def __init__(self, **kwargs):
super().__init__(**kwargs)
self._workflow_sequence = []
@property
def workflow_sequence(self) -> str:
"""返回 JSON 字符串ROS 自动发布"""
import json
return json.dumps(self._workflow_sequence)
async def append_to_workflow_sequence(self, workflow_name: str) -> Dict[str, Any]:
"""添加工作流到队列"""
self._workflow_sequence.append({
"name": workflow_name,
"status": "pending",
"created_at": time.time(),
})
return {"success": True}
async def clear_workflows(self) -> Dict[str, Any]:
"""清空工作流队列"""
self._workflow_sequence = []
return {"success": True}
```
---
## 5. 站间物料转移
工作站之间转移物料的模式。通过 ROS ActionClient 调用目标站的动作。
```python
async def transfer_materials_to_another_station(
self,
target_device_id: str,
transfer_groups: list,
**kwargs,
) -> Dict[str, Any]:
"""将物料转移到另一个工作站"""
target_node = self._children.get(target_device_id)
if not target_node:
# 通过 ROS 节点查找非子设备的目标站
pass
for group in transfer_groups:
resource = self.find_resource_by_name(group["resource_name"])
# 从本站 deck 移除
resource.unassign()
# 调用目标站的接收方法
# ...
return {"success": True, "transferred": len(transfer_groups)}
```
参考:`BioyondDispensingStation.transfer_materials_to_reaction_station`
---
## 6. post_init 完整模式
`post_init` 是工作站初始化的关键阶段,此时 ROS 节点和子设备已就绪。
```python
def post_init(self, ros_node):
super().post_init(ros_node)
# 1. 初始化外部系统客户端(此时 config 已可用)
self.rpc_client = MySystemRPC(
host=self.config.get("api_host"),
api_key=self.config.get("api_key"),
)
self.hardware_interface = self.rpc_client
# 2. 启动连接监控
self.connection_monitor = ConnectionMonitor(self)
self.connection_monitor.start()
# 3. 启动 HTTP 回调服务
if hasattr(self, '_http_service_config'):
self.http_service = WorkstationHTTPService(
workstation_instance=self,
host=self._http_service_config["host"],
port=self._http_service_config["port"],
)
self.http_service.start()
# 4. 上传 deck 到云端
ROS2DeviceNode.run_async_func(
self._ros_node.update_resource, True,
**{"resources": [self.deck]}
)
# 5. 初始化资源同步器(可选)
self.resource_synchronizer = MyResourceSynchronizer(self, self.rpc_client)
```

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---
name: edit-experiment-graph
description: Guide for creating and editing experiment graph files in Uni-Lab-OS (创建/编辑实验组态图). Covers node types, link types, parent-child relationships, deck configuration, and common graph patterns. Use when the user wants to create a graph file, edit an experiment configuration, set up device topology, or mentions 图文件/graph/组态/拓扑/实验图/experiment JSON.
---
# 创建/编辑实验组态图
实验图Graph File定义设备拓扑、物理连接和物料配置。系统启动时加载图文件初始化所有设备和连接关系。
路径:`unilabos/test/experiments/<name>.json`
---
## 第一步:确认需求
向用户确认:
| 信息 | 说明 |
|------|------|
| 场景类型 | 单设备调试 / 多设备联调 / 工作站完整图 |
| 包含的设备 | 设备 ID、注册表 class 名、配置参数 |
| 连接关系 | 物理连接(管道)/ 通信连接(串口)/ 无连接 |
| 父子关系 | 是否有工作站包含子设备 |
| 物料需求 | 是否需要 Deck、容器、试剂瓶 |
---
## 第二步JSON 顶层结构
```json
{
"nodes": [],
"links": []
}
```
> `links` 也可写作 `edges`,加载时两者等效。
---
## 第三步:定义 Nodes
### 节点字段
| 字段 | 类型 | 必需 | 默认值 | 说明 |
|------|------|------|--------|------|
| `id` | string | **是** | — | 节点唯一标识links 和 children 中引用此值 |
| `class` | string | **是** | — | 对应注册表名(设备/资源 YAML 的 key容器可为 `null` |
| `name` | string | 否 | 同 `id` | 显示名称,缺省时自动用 `id` |
| `type` | string | 否 | `"device"` | 节点类型(见下表),缺省时自动设为 `"device"` |
| `children` | string[] | 否 | `[]` | 子节点 ID 列表 |
| `parent` | string\|null | 否 | `null` | 父节点 ID顶层设备为 `null` |
| `position` | object | 否 | `{x:0,y:0,z:0}` | 空间坐标 |
| `config` | object | 否 | `{}` | 传给驱动 `__init__` 的参数 |
| `data` | object | 否 | `{}` | 初始运行状态 |
| `size_x/y/z` | float | 否 | — | 节点物理尺寸(工作站节点常用) |
> 非标准字段(如 `api_host`)会自动移入 `config`。
### 节点类型
| `type` | 用途 | `class` 要求 |
|--------|------|-------------|
| `device` | 设备(默认) | 注册表中的设备名 |
| `deck` | 工作台面 | Deck 工厂函数/类名 |
| `container` | 容器(烧瓶、反应釜) | `null` 或具体容器类名 |
### 设备节点模板
```json
{
"id": "my_device",
"name": "我的设备",
"children": [],
"parent": null,
"type": "device",
"class": "registry_device_name",
"position": {"x": 0, "y": 0, "z": 0},
"config": {
"port": "/dev/ttyUSB0",
"baudrate": 115200
},
"data": {
"status": "Idle"
}
}
```
### 容器节点模板
容器用于协议系统中表示试剂瓶、反应釜等,`class` 通常为 `null`
```json
{
"id": "flask_DMF",
"name": "DMF试剂瓶",
"children": [],
"parent": "my_station",
"type": "container",
"class": null,
"position": {"x": 200, "y": 500, "z": 0},
"config": {"max_volume": 1000.0},
"data": {
"liquid": [{"liquid_type": "DMF", "liquid_volume": 800.0}]
}
}
```
### Deck 节点模板
```json
{
"id": "my_deck",
"name": "my_deck",
"children": [],
"parent": "my_station",
"type": "deck",
"class": "MyStation_Deck",
"position": {"x": 0, "y": 0, "z": 0},
"config": {
"type": "MyStation_Deck",
"setup": true,
"rotation": {"x": 0, "y": 0, "z": 0, "type": "Rotation"}
},
"data": {}
}
```
---
## 第四步:定义 Links
### Link 字段
| 字段 | 类型 | 说明 |
|------|------|------|
| `source` | string | 源节点 ID |
| `target` | string | 目标节点 ID |
| `type` | string | `"physical"` / `"fluid"` / `"communication"` |
| `port` | object | 端口映射 `{source_id: "port_name", target_id: "port_name"}` |
### 物理/流体连接
设备间的管道连接,协议系统用此查找路径:
```json
{
"source": "multiway_valve_1",
"target": "flask_DMF",
"type": "fluid",
"port": {
"multiway_valve_1": "2",
"flask_DMF": "outlet"
}
}
```
### 通信连接
设备间的串口/IO 通信代理,加载时自动将端口信息写入目标设备 config
```json
{
"source": "pump_1",
"target": "serial_device",
"type": "communication",
"port": {
"pump_1": "port",
"serial_device": "port"
}
}
```
---
## 第五步:父子关系与工作站配置
### 工作站 + 子设备
工作站节点的 `children` 列出所有子节点 ID子节点的 `parent` 指向工作站:
```json
{
"id": "my_station",
"children": ["my_deck", "pump_1", "valve_1", "reactor_1"],
"parent": null,
"type": "device",
"class": "workstation",
"config": {
"protocol_type": ["PumpTransferProtocol", "CleanProtocol"]
}
}
```
### 工作站 + Deck 引用
工作站节点中通过 `deck` 字段引用 Deck
```json
{
"id": "my_station",
"children": ["my_deck", "sub_device_1"],
"deck": {
"data": {
"_resource_child_name": "my_deck",
"_resource_type": "unilabos.resources.my_module.decks:MyDeck"
}
}
}
```
**关键约束:**
- `_resource_child_name` 必须与 Deck 节点的 `id` 一致
- `_resource_type` 为 Deck 类/工厂函数的完整 Python 路径
---
## 常见图模式
### 模式 A单设备调试
最简形式,一个设备节点,无连接:
```json
{
"nodes": [
{
"id": "my_device",
"name": "my_device",
"children": [],
"parent": null,
"type": "device",
"class": "motor.zdt_x42",
"position": {"x": 0, "y": 0, "z": 0},
"config": {"port": "/dev/ttyUSB0", "baudrate": 115200},
"data": {"status": "idle"}
}
],
"links": []
}
```
### 模式 BProtocol 工作站(泵+阀+容器)
工作站配合泵、阀、容器和物理连接,用于协议编译:
```json
{
"nodes": [
{
"id": "station", "name": "协议工作站",
"class": "workstation", "type": "device", "parent": null,
"children": ["pump", "valve", "flask_solvent", "reactor", "waste"],
"config": {"protocol_type": ["PumpTransferProtocol"]}
},
{"id": "pump", "name": "转移泵", "class": "virtual_transfer_pump",
"type": "device", "parent": "station",
"config": {"port": "VIRTUAL", "max_volume": 25.0},
"data": {"status": "Idle", "position": 0.0, "valve_position": "0"}},
{"id": "valve", "name": "多通阀", "class": "virtual_multiway_valve",
"type": "device", "parent": "station",
"config": {"port": "VIRTUAL", "positions": 8}},
{"id": "flask_solvent", "name": "溶剂瓶", "type": "container",
"class": null, "parent": "station",
"config": {"max_volume": 1000.0},
"data": {"liquid": [{"liquid_type": "DMF", "liquid_volume": 500}]}},
{"id": "reactor", "name": "反应器", "type": "container",
"class": null, "parent": "station"},
{"id": "waste", "name": "废液瓶", "type": "container",
"class": null, "parent": "station"}
],
"links": [
{"source": "pump", "target": "valve", "type": "fluid",
"port": {"pump": "transferpump", "valve": "transferpump"}},
{"source": "valve", "target": "flask_solvent", "type": "fluid",
"port": {"valve": "1", "flask_solvent": "outlet"}},
{"source": "valve", "target": "reactor", "type": "fluid",
"port": {"valve": "2", "reactor": "inlet"}},
{"source": "valve", "target": "waste", "type": "fluid",
"port": {"valve": "3", "waste": "inlet"}}
]
}
```
### 模式 C外部系统工作站 + Deck
```json
{
"nodes": [
{
"id": "bioyond_station", "class": "reaction_station.bioyond",
"parent": null, "children": ["bioyond_deck"],
"config": {
"api_host": "http://192.168.1.100:8080",
"api_key": "YOUR_KEY",
"material_type_mappings": {},
"warehouse_mapping": {}
},
"deck": {
"data": {
"_resource_child_name": "bioyond_deck",
"_resource_type": "unilabos.resources.bioyond.decks:BIOYOND_PolymerReactionStation_Deck"
}
}
},
{
"id": "bioyond_deck", "class": "BIOYOND_PolymerReactionStation_Deck",
"parent": "bioyond_station", "type": "deck",
"config": {"type": "BIOYOND_PolymerReactionStation_Deck", "setup": true}
}
],
"links": []
}
```
### 模式 D通信代理串口设备
泵通过串口设备通信,使用 `communication` 类型的 link。加载时系统会自动将串口端口信息写入泵的 `config`
```json
{
"nodes": [
{"id": "station", "name": "工作站", "type": "device",
"class": "workstation", "parent": null,
"children": ["serial_1", "pump_1"]},
{"id": "serial_1", "name": "串口", "type": "device",
"class": "serial", "parent": "station",
"config": {"port": "COM7", "baudrate": 9600}},
{"id": "pump_1", "name": "注射泵", "type": "device",
"class": "syringe_pump_with_valve.runze.SY03B-T08", "parent": "station"}
],
"links": [
{"source": "pump_1", "target": "serial_1", "type": "communication",
"port": {"pump_1": "port", "serial_1": "port"}}
]
}
```
---
## 验证
```bash
# 启动测试
unilab -g unilabos/test/experiments/<name>.json --complete_registry
# 仅检查注册表
python -m unilabos --check_mode --skip_env_check
```
---
## 高级模式
处理复杂图文件时,详见 [reference.md](reference.md)ResourceDict 完整字段 schema、Pose 标准化规则、Handle 验证机制、GraphML 格式支持、外部系统工作站完整 config 结构。
---
## 常见错误
| 错误 | 原因 | 修复 |
|------|------|------|
| `class` 找不到 | 注册表中无此设备名 | 在 `unilabos/registry/devices/``resources/` 中搜索正确名称 |
| children/parent 不一致 | 子节点 `parent` 与父节点 `children` 不匹配 | 确保双向一致 |
| `_resource_child_name` 不匹配 | Deck 引用名与 Deck 节点 `id` 不同 | 保持一致 |
| Link 端口错误 | `port` 中的 key 不是 source/target 的 `id` | key 必须是对应节点的 `id` |
| 重复 UUID | 多个节点有相同 `uuid` | 删除或修改 UUID |
---
## 参考路径
| 内容 | 路径 |
|------|------|
| 图文件目录 | `unilabos/test/experiments/` |
| 协议测试站 | `unilabos/test/experiments/Protocol_Test_Station/` |
| 图加载代码 | `unilabos/resources/graphio.py` |
| 节点模型 | `unilabos/resources/resource_tracker.py` |
| 设备注册表 | `unilabos/registry/devices/` |
| 资源注册表 | `unilabos/registry/resources/` |
| 用户文档 | `docs/user_guide/graph_files.md` |

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# 实验图高级参考
本文件是 SKILL.md 的补充,包含 ResourceDict 完整 schema、Handle 验证、GraphML 格式、Pose 标准化规则和复杂图文件结构。Agent 在需要处理这些场景时按需阅读。
---
## 1. ResourceDict 完整字段
`unilabos/resources/resource_tracker.py` 中定义的节点数据模型:
| 字段 | 类型 | 别名 | 说明 |
|------|------|------|------|
| `id` | `str` | — | 节点唯一标识 |
| `uuid` | `str` | — | 全局唯一标识 |
| `name` | `str` | — | 显示名称 |
| `description` | `str` | — | 描述(默认 `""` |
| `resource_schema` | `Dict[str, Any]` | `schema` | 资源 schema |
| `model` | `Dict[str, Any]` | — | 3D 模型信息 |
| `icon` | `str` | — | 图标(默认 `""` |
| `parent_uuid` | `Optional[str]` | — | 父节点 UUID |
| `parent` | `Optional[ResourceDict]` | — | 父节点引用(序列化时 exclude |
| `type` | `Union[Literal["device"], str]` | — | 节点类型 |
| `klass` | `str` | `class` | 注册表类名 |
| `pose` | `ResourceDictPosition` | — | 位姿信息 |
| `config` | `Dict[str, Any]` | — | 配置参数 |
| `data` | `Dict[str, Any]` | — | 运行时数据 |
| `extra` | `Dict[str, Any]` | — | 扩展数据 |
### Pose 完整结构ResourceDictPosition
| 字段 | 类型 | 默认值 | 说明 |
|------|------|--------|------|
| `size` | `{width, height, depth}` | `{0,0,0}` | 节点尺寸 |
| `scale` | `{x, y, z}` | `{1,1,1}` | 缩放比例 |
| `layout` | `"2d"/"x-y"/"z-y"/"x-z"` | `"x-y"` | 布局方向 |
| `position` | `{x, y, z}` | `{0,0,0}` | 2D 位置 |
| `position3d` | `{x, y, z}` | `{0,0,0}` | 3D 位置 |
| `rotation` | `{x, y, z}` | `{0,0,0}` | 旋转角度 |
| `cross_section_type` | `"rectangle"/"circle"/"rounded_rectangle"` | `"rectangle"` | 横截面形状 |
---
## 2. Position / Pose 标准化规则
图文件中的 `position` 有多种写法,加载时自动标准化。
### 输入格式兼容
```json
// 格式 A: 直接 {x, y, z}(最常用)
"position": {"x": 100, "y": 200, "z": 0}
// 格式 B: 嵌套 position
"position": {"position": {"x": 100, "y": 200, "z": 0}}
// 格式 C: 使用 pose 字段
"pose": {"position": {"x": 100, "y": 200, "z": 0}}
// 格式 D: 顶层 x, y, z无 position 字段)
"x": 100, "y": 200, "z": 0
```
### 标准化流程
1. **graphio.py `canonicalize_nodes_data`**:若 `position` 不是 dict从节点顶层提取 `x/y/z` 填入 `pose.position`
2. **resource_tracker.py `get_resource_instance_from_dict`**:若 `position.x` 存在(旧格式),转为 `{"position": {"x":..., "y":..., "z":...}}`
3. `pose.size``config.size_x/size_y/size_z` 自动填充
---
## 3. Handle 验证
启动时系统验证 link 中的 `sourceHandle` / `targetHandle` 是否在注册表的 `handles` 中定义。
```python
# unilabos/app/main.py (约 449-481 行)
source_handler_keys = [
h["handler_key"] for h in materials[source_node.klass]["handles"]
if h["io_type"] == "source"
]
target_handler_keys = [
h["handler_key"] for h in materials[target_node.klass]["handles"]
if h["io_type"] == "target"
]
if source_handle not in source_handler_keys:
print_status(f"节点 {source_node.id} 的source端点 {source_handle} 不存在", "error")
resource_edge_info.pop(...) # 移除非法 link
```
**Handle 定义在注册表 YAML 中:**
```yaml
my_device:
handles:
- handler_key: access
io_type: target
data_type: fluid
side: NORTH
label: access
```
> 大多数简单设备不定义 handles此验证仅对有 `sourceHandle`/`targetHandle` 的 link 生效。
---
## 4. GraphML 格式支持
除 JSON 外,系统也支持 GraphML 格式(`unilabos/resources/graphio.py::read_graphml`)。
### 与 JSON 的关键差异
| 特性 | JSON | GraphML |
|------|------|---------|
| 父子关系 | `parent`/`children` 字段 | `::` 分隔的节点 ID`station::pump_1` |
| 加载后 | 直接解析 | 先 `nx.read_graphml` 再转 JSON 格式 |
| 输出 | 不生成副本 | 自动生成等价的 `.json` 文件 |
### GraphML 转换流程
```
nx.read_graphml(file)
↓ 用 label 重映射节点名
↓ 从 "::" 推断 parent_relation
nx.relabel_nodes + nx.node_link_data
↓ canonicalize_nodes_data + canonicalize_links_ports
↓ 写出等价 JSON 文件
physical_setup_graph + handle_communications
```
---
## 5. 复杂图文件结构示例
### 外部系统工作站完整 config
`reaction_station_bioyond.json` 为例,工作站 `config` 中的关键字段:
```json
{
"config": {
"api_key": "DE9BDDA0",
"api_host": "http://172.21.103.36:45388",
"workflow_mappings": {
"scheduler_start": {"workflow": "start", "params": {}},
"create_order": {"workflow": "create_order", "params": {}}
},
"material_type_mappings": {
"BIOYOND_PolymerStation_Reactor": ["反应器", "type-uuid-here"],
"BIOYOND_PolymerStation_1BottleCarrier": ["试剂瓶", "type-uuid-here"]
},
"warehouse_mapping": {
"堆栈1左": {
"uuid": "warehouse-uuid-here",
"site_uuids": {
"A01": "site-uuid-1",
"A02": "site-uuid-2"
}
}
},
"http_service_config": {
"enabled": true,
"host": "0.0.0.0",
"port": 45399,
"routes": ["/callback/workflow", "/callback/material"]
},
"deck": {
"data": {
"_resource_child_name": "Bioyond_Deck",
"_resource_type": "unilabos.resources.bioyond.decks:BIOYOND_PolymerReactionStation_Deck"
}
},
"size_x": 2700.0,
"size_y": 1080.0,
"size_z": 2500.0,
"protocol_type": [],
"data": {}
}
}
```
### 子设备 Reactor 节点
```json
{
"id": "reactor_1",
"name": "reactor_1",
"parent": "reaction_station_bioyond",
"type": "device",
"class": "bioyond_reactor",
"position": {"x": 1150, "y": 300, "z": 0},
"config": {
"reactor_index": 0,
"bioyond_workflow_key": "reactor_1"
},
"data": {}
}
```
### Deck 节点
```json
{
"id": "Bioyond_Deck",
"name": "Bioyond_Deck",
"parent": "reaction_station_bioyond",
"type": "deck",
"class": "BIOYOND_PolymerReactionStation_Deck",
"position": {"x": 0, "y": 0, "z": 0},
"config": {
"type": "BIOYOND_PolymerReactionStation_Deck",
"setup": true,
"rotation": {"x": 0, "y": 0, "z": 0, "type": "Rotation"}
},
"data": {}
}
```
---
## 6. Link 端口标准化
`graphio.py::canonicalize_links_ports` 处理 `port` 字段的多种格式:
```python
# 输入: 字符串格式 "(A,B)"
"port": "(pump_1, valve_1)"
# 输出: 字典格式
"port": {"source_id": "pump_1", "target_id": "valve_1"}
# 输入: 已是字典
"port": {"pump_1": "port", "serial_1": "port"}
# 保持不变
# 输入: 无 port 字段
# 自动补充空 port
```
---
## 7. 关键路径
| 内容 | 路径 |
|------|------|
| ResourceDict 模型 | `unilabos/resources/resource_tracker.py` |
| 图加载 + 标准化 | `unilabos/resources/graphio.py` |
| Handle 验证 | `unilabos/app/main.py` (449-481 行) |
| 反应站图文件 | `unilabos/test/experiments/reaction_station_bioyond.json` |
| 配液站图文件 | `unilabos/test/experiments/dispensing_station_bioyond.json` |
| 用户文档 | `docs/user_guide/graph_files.md` |

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# ============================================================
# Uni-Lab-OS Cursor Ignore 配置,控制 Cursor AI 的文件索引范围
# ============================================================
# ==================== 敏感配置文件 ====================
# 本地配置(可能包含密钥)
**/local_config.py
test_config.py
local_test*.py
# 环境变量和密钥
.env
.env.*
**/.certs/
*.pem
*.key
credentials.json
secrets.yaml
# ==================== 二进制和 3D 模型文件 ====================
# 3D 模型文件(无需索引)
*.stl
*.dae
*.glb
*.gltf
*.obj
*.fbx
*.blend
# URDF/Xacro 机器人描述文件大型XML
*.xacro
# 图片文件
*.png
*.jpg
*.jpeg
*.gif
*.webp
*.ico
*.svg
*.bmp
# 压缩包
*.zip
*.tar
*.tar.gz
*.tgz
*.bz2
*.rar
*.7z
# ==================== Python 生成文件 ====================
__pycache__/
*.py[cod]
*$py.class
*.so
*.pyd
*.egg
*.egg-info/
.eggs/
dist/
build/
*.manifest
*.spec
# ==================== IDE 和编辑器 ====================
.idea/
.vscode/
*.swp
*.swo
*~
.#*
# ==================== 测试和覆盖率 ====================
.pytest_cache/
.coverage
.coverage.*
htmlcov/
.tox/
.nox/
coverage.xml
*.cover
# ==================== 虚拟环境 ====================
.venv/
venv/
env/
ENV/
# ==================== ROS 2 生成文件 ====================
# ROS 构建目录
build/
install/
log/
logs/
devel/
# ROS 消息生成
msg_gen/
srv_gen/
msg/*Action.msg
msg/*ActionFeedback.msg
msg/*ActionGoal.msg
msg/*ActionResult.msg
msg/*Feedback.msg
msg/*Goal.msg
msg/*Result.msg
msg/_*.py
srv/_*.py
build_isolated/
devel_isolated/
# ROS 动态配置
*.cfgc
/cfg/cpp/
/cfg/*.py
# ==================== 项目特定目录 ====================
# 工作数据目录
unilabos_data/
# 临时和输出目录
temp/
output/
cursor_docs/
configs/
# 文档构建
docs/_build/
/site
# ==================== 大型数据文件 ====================
# 点云数据
*.pcd
# GraphML 图形文件
*.graphml
# 日志文件
*.log
# 数据库
*.sqlite3
*.db
# Jupyter 检查点
.ipynb_checkpoints/
# ==================== 设备网格资源 ====================
# 3D 网格文件目录(包含大量 STL/DAE 文件)
unilabos/device_mesh/devices/**/*.stl
unilabos/device_mesh/devices/**/*.dae
unilabos/device_mesh/resources/**/*.stl
unilabos/device_mesh/resources/**/*.glb
unilabos/device_mesh/resources/**/*.xacro
# RViz 配置
*.rviz
# ==================== 系统文件 ====================
.DS_Store
Thumbs.db
desktop.ini
# ==================== 锁文件 ====================
poetry.lock
Pipfile.lock
pdm.lock
package-lock.json
yarn.lock
# ==================== 类型检查缓存 ====================
.mypy_cache/
.dmypy.json
.pytype/
.pyre/
pyrightconfig.json
# ==================== 其他 ====================
# Catkin
CATKIN_IGNORE
# Eclipse/Qt
.project
.cproject
CMakeLists.txt.user
*.user
qtcreator-*

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## 设备接入
当被要求添加设备驱动时,参考 `docs/ai_guides/add_device.md`
该指南包含完整的模板和已有设备接口参考。
## 关键规则
- 动作方法的参数名是接口契约,不可重命名
- `status` 字符串必须与同类已有设备一致
- `self.data` 必须在 `__init__` 中预填充所有属性字段
- 异步方法中使用 `await self._ros_node.sleep()`,禁止 `time.sleep()`

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# Uni-Lab-OS AI Agent 指南
## 设备接入
当用户要求添加/接入新设备时,读取 `docs/ai_guides/add_device.md` 并按其流程执行。
该指南完全自包含,包含物模型模板、现有设备接口快照、常见错误和验证清单。
## 关键规则
- 动作方法的参数名是接口契约,不可重命名(如 `volume` 不能改为 `volume_ml`
- `status` 字符串必须与同类已有设备一致(如 `"Idle"` 不能改为 `"就绪"`
- `self.data` 必须在 `__init__` 中预填充所有属性字段
- 异步方法中使用 `await self._ros_node.sleep()`,禁止 `time.sleep()``asyncio.sleep()`
## 项目结构
- 设备驱动:`unilabos/devices/<category>/<device_name>.py`
- 设备注册表:`unilabos/registry/devices/<device_name>.yaml`
- 实验图文件:`unilabos/test/experiments/*.json`
- 人类开发文档:`docs/developer_guide/`
- AI 专用指南:`docs/ai_guides/`

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# Uni-Lab-OS
## 设备接入
读取 `docs/ai_guides/add_device.md` 获取完整的自包含指南。
如果可以访问仓库,优先搜索 `unilabos/registry/devices/` 获取最新设备接口;
否则使用指南中内联的「现有设备接口快照」。
## 关键规则
- 动作方法的参数名是接口契约,不可重命名(如 `volume` 不能改为 `volume_ml`
- `status` 字符串必须与同类已有设备一致(如 `"Idle"` 不能改为 `"就绪"`
- `self.data` 必须在 `__init__` 中预填充所有属性字段
- 异步方法中使用 `await self._ros_node.sleep()`,禁止 `time.sleep()``asyncio.sleep()`

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# Uni-Lab-OS 设备接入 Agent — 提示词模板
> 本文件提供一套可直接复制使用的 Agent 系统提示词,以及各平台的配置说明。
> 提示词模板与 `add_device.md`(领域知识)配合使用,前者控制 Agent 行为,后者提供完整的技术细节。
---
## 系统提示词模板
以下内容可直接作为系统提示词 / Instructions / Custom Instructions 使用。`{{...}}` 标记的变量根据平台替换。
---
### 开始复制 ↓
```
你是 Uni-Lab-OS 设备接入专家。你的任务是帮助用户将新的实验室硬件设备接入 Uni-Lab-OS 系统。
你能做的事:
- 根据用户描述生成完整的设备驱动代码Python、注册表YAML和实验图文件JSON
- 解读用户提供的通信协议文档、SDK 代码、或口述的指令格式
- 诊断已有驱动代码的接口对齐问题
你不能做的事:
- 凭空猜测硬件私有通信指令(必须从用户提供的资料中获取)
- 替代真实硬件联调测试
## 知识来源
{{KNOWLEDGE_LOADING}}
## 工作流程
当用户要求接入新设备时,严格按以下流程执行。每个暂停点必须等待用户确认后再继续。
### 阶段 1设备画像交互
向用户收集以下三个信息,可以一次性提问:
1. **设备类别** — 属于以下哪一种?
- temperature温控、pump_and_valve泵阀、motor电机
- heaterstirrer加热搅拌、balance天平、sensor传感器
- liquid_handling液体处理、robot_arm机械臂、workstation工作站
- virtual虚拟设备、custom自定义
- 如果是 pump_and_valve进一步确认子类型注射泵 / 电磁阀 / 蠕动泵
2. **设备英文名称** — 用于文件名和类名(如 my_heater、runze_sy03b
3. **通信协议** — Serial(RS232/RS485) / Modbus RTU / Modbus TCP / TCP Socket / HTTP API / OPC UA / 无通信(虚拟)
⏸️ **暂停:等待用户回答后继续**
### 阶段 2指令协议收集交互
根据上一步确定的通信协议,引导用户提供指令信息:
- 如果用户有 **SDK/驱动代码**:请用户提供代码文件,你从中提取通信逻辑
- 如果用户有 **协议文档**请用户提供文档PDF/图片/文本),你从中解析指令格式
- 如果用户 **口头描述**:针对每个标准动作逐一确认硬件指令
- 如果是 **标准协议**Modbus 寄存器表、SCPI请用户提供寄存器/指令映射
- 如果是 **虚拟设备**:跳过此阶段
⏸️ **暂停:确认已获取足够的指令协议信息**
### 阶段 3确认摘要
在开始生成代码前,向用户展示你的理解摘要:
```
设备接入摘要:
- 设备名称:<name>
- 设备类别:<category><subtype>
- 通信协议:<protocol>
- 指令来源:<source>
- 将要实现的属性:<list>
- 将要实现的动作:<list>
- 同类已有设备:<existing>(将对齐其接口)
```
⏸️ **暂停:用户确认"没问题"后再生成代码**
### 阶段 4自动生成无需暂停
按以下顺序自动执行:
1. **对齐同类设备接口**(指南第四步)
- 查阅指南中的「现有设备接口快照」或搜索仓库注册表
- 确保所有已有设备的 status_types 和动作方法都被覆盖
- 参数名必须完全一致
2. **生成驱动代码** — `unilabos/devices/<category>/<name>.py`
3. **生成注册表** — `unilabos/registry/devices/<name>.yaml`(最小配置)
4. **生成图文件** — `unilabos/test/experiments/graph_example_<name>.json`
### 阶段 5验证输出
生成完成后,逐项检查对齐验证清单并展示结果:
```
对齐验证清单:
- [x] 所有动作方法的参数名与已有设备完全一致
- [x] status 属性返回的字符串值与已有设备一致
- [x] 已有设备的所有 status_types 字段都有对应 @property
- [x] 已有设备的所有非 auto- 前缀的 action 都有对应方法
- [x] self.data 在 __init__ 中已预填充所有属性字段的默认值
- [x] 串口/二进制协议的响应解析先定位帧起始标记
```
如果有未通过的项,主动修复后再展示。
## 硬约束(违反任何一条都会导致设备接入失败)
1. **禁止重命名参数** — 动作方法的参数名(如 volume、position、max_velocity是接口契约框架通过参数名分派调用。绝不能加后缀如 volume_ml、改名如 speed_ml_s。单位写在 docstring 中。
2. **status 字符串必须一致** — 如果同类已有设备用英文(如 "Idle" / "Busy"),新驱动必须用相同的字符串,不能改为中文(如 "就绪")。
3. **self.data 必须预填充** — 不能用空字典 {}。框架在 initialize() 之前就可能读取属性值。每个 @property 对应的键都必须在 __init__ 中有初始值。
4. **禁止跳过接口对齐** — 对齐同类设备接口是强制步骤。缺失的属性和动作会导致设备在工作流中不可互换。
5. **串口解析先找帧头** — RS-485 总线上响应前常有回声/噪声字节。必须先定位帧起始标记(如 /、0xFE禁止用硬编码索引直接解析。
6. **异步等待用 _ros_node.sleep** — 在 async 方法中使用 await self._ros_node.sleep(),禁止 time.sleep()(阻塞事件循环)和 asyncio.sleep()。
7. **物理单位对外暴露** — 对外参数使用用户友好的物理单位mL、°C、RPM驱动内部负责转换到硬件原始值步数、Hz、寄存器值
## 代码骨架参考
所有设备驱动遵循以下结构:
```python
import logging
import time as time_module
from typing import Dict, Any
try:
from unilabos.ros.nodes.base_device_node import BaseROS2DeviceNode
except ImportError:
BaseROS2DeviceNode = None
class MyDevice:
_ros_node: "BaseROS2DeviceNode"
def __init__(self, device_id: str = None, config: Dict[str, Any] = None, **kwargs):
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')
self.device_id = device_id or "unknown_device"
self.config = config or {}
self.logger = logging.getLogger(f"MyDevice.{self.device_id}")
self.data = {
"status": "Idle",
# 所有 @property 的键都必须在此预填充
}
def post_init(self, ros_node: "BaseROS2DeviceNode"):
self._ros_node = ros_node
async def initialize(self) -> bool:
self.data["status"] = "Idle"
return True
async def cleanup(self) -> bool:
self.data["status"] = "Offline"
return True
@property
def status(self) -> str:
return self.data.get("status", "Idle")
```
## 注册表最小配置
```yaml
my_device:
class:
module: unilabos.devices.<category>.<file>:MyDevice
type: python
```
启动时 --complete_registry 自动生成 status_types 和 action_value_mappings。
## 图文件模板
```json
{
"nodes": [
{
"id": "my_device_1",
"name": "设备名称",
"children": [],
"parent": null,
"type": "device",
"class": "my_device",
"position": {"x": 0, "y": 0, "z": 0},
"config": {},
"data": {}
}
]
}
```
## 现有设备接口快照(对齐用)
对齐时参考以下已有设备接口。如果能联网,优先从 GitHub 获取最新版本:
https://github.com/dptech-corp/Uni-Lab-OS/tree/main/unilabos/registry/devices/
### pump_and_valve — 注射泵
已有设备syringe_pump_with_valve.runze.SY03B-T06
属性status(str, "Idle"/"Busy"), valve_position(str), position(float, mL), max_velocity(float, mL/s), mode(int), plunger_position(String), velocity_grade(String), velocity_init(String), velocity_end(String)
方法签名(参数名不可改):
- initialize()
- set_valve_position(position)
- set_position(position: float, max_velocity: float = None)
- pull_plunger(volume: float)
- push_plunger(volume: float)
- set_max_velocity(velocity: float)
- set_velocity_grade(velocity)
- stop_operation()
### pump_and_valve — 电磁阀
属性status(str), valve_position(str)
方法open(), close(), set_valve_position(position), is_open(), is_closed()
### temperature
属性status(str), temp(float, °C), temp_target(float, °C), stir_speed(float, RPM), temp_warning(float, °C)
### motor
属性status(str), position(int)
### sensor
属性level(bool), rssi(int)
```
### 结束复制 ↑
---
## `{{KNOWLEDGE_LOADING}}` 变量替换
根据平台能力,将提示词中的 `{{KNOWLEDGE_LOADING}}` 替换为以下对应内容:
### 方案 A有知识库Custom GPT / Claude Project
```
你的知识库中包含 add_device.md 文件,这是完整的设备接入指南。
执行工作流时,参考该文件获取物模型模板、通信协议代码片段、指令协议模式和常见错误检查清单。
本提示词中的「现有设备接口快照」和「硬约束」是从指南中提炼的关键内容,以确保即使知识库检索不完整也能正确工作。
```
### 方案 B有联网能力
```
执行工作流前,从以下 URL 获取完整的设备接入指南:
https://raw.githubusercontent.com/dptech-corp/Uni-Lab-OS/main/docs/ai_guides/add_device.md
该指南包含物模型模板、通信协议代码片段、指令协议模式和常见错误检查清单。
如果无法访问 URL使用本提示词中内联的「现有设备接口快照」和「代码骨架参考」作为兜底。
```
### 方案 C无知识库、无联网
```
完整的设备接入指南需要用户在对话中提供。
如果用户未主动提供,请在阶段 1 开始前询问:
"请将 add_device.md 的内容粘贴到对话中,或上传该文件。如果没有该文件,我将使用内置的精简规则工作。"
本提示词已内联了最关键的内容(硬约束 + 代码骨架 + 接口快照),足以生成基本正确的驱动。
但完整指南包含更多物模型模板和通信协议代码片段,能显著提升生成质量。
```
---
## 各平台配置指南
### OpenAI Custom GPT
1. 进入 https://chat.openai.com/gpts/editor
2. **Name**Uni-Lab-OS 设备接入助手
3. **Description**:帮助用户将实验室硬件设备接入 Uni-Lab-OS 系统,自动生成驱动代码、注册表和图文件。
4. **Instructions**:粘贴上方系统提示词,`{{KNOWLEDGE_LOADING}}` 替换为方案 A
5. **Knowledge**:上传 `docs/ai_guides/add_device.md`
6. **Capabilities**:开启 Code Interpreter用于代码验证
7. **Conversation starters**
- "我要接入一个新的注射泵"
- "帮我把这个 SDK 包装成 UniLab 驱动"
- "检查我的设备驱动有没有接口问题"
### Claude Project
1. 创建新 Project
2. **Custom Instructions**:粘贴系统提示词,`{{KNOWLEDGE_LOADING}}` 替换为方案 A
3. **Project Knowledge**:上传 `docs/ai_guides/add_device.md`
### API AgentLangChain / AutoGen / 自建框架)
```python
system_prompt = """
<粘贴完整系统提示词,{{KNOWLEDGE_LOADING}} 替换为方案 B>
"""
# 如果框架支持工具调用,可注册以下工具:
tools = [
{
"name": "fetch_device_guide",
"description": "获取最新的 Uni-Lab-OS 设备接入指南",
"url": "https://raw.githubusercontent.com/dptech-corp/Uni-Lab-OS/main/docs/ai_guides/add_device.md"
},
{
"name": "fetch_registry",
"description": "获取最新的设备注册表",
"url": "https://raw.githubusercontent.com/dptech-corp/Uni-Lab-OS/main/unilabos/registry/devices/{category}.yaml"
},
]
```
### Cursor Agent Mode
无需使用本模板。Cursor 中使用已有的 `.cursor/skills/add-device/SKILL.md`,它会自动读取 `docs/ai_guides/add_device.md` 并利用 Cursor 的工具能力Grep 搜索注册表、AskQuestion 收集信息等)。
### 纯网页对话ChatGPT / Claude 无 Project
1. 第一条消息粘贴系统提示词(`{{KNOWLEDGE_LOADING}}` 替换为方案 C
2. 第二条消息上传或粘贴 `add_device.md`
3. 第三条消息开始描述设备
---
## 维护说明
- **硬约束更新**:如果 `add_device.md` 中新增了禁止事项或常见错误,需要同步更新本模板的「硬约束」部分
- **接口快照更新**:新增设备类别或已有设备接口变更时,需要同步更新本模板的「现有设备接口快照」部分
- **工作流调整**:如果接入流程发生变化(新增步骤、合并步骤),需要同步调整「工作流程」部分
- 本模板与 `add_device.md` 是**互补关系**:模板定义 Agent 行为,指南提供领域知识。两者独立维护

12
unilabos/devices/liquid_handling/liquid_handler_abstract.py
View File

@@ -57,6 +57,18 @@ class TransferLiquidReturn(TypedDict):
targets: List[List[ResourceDict]]
class SetLiquidReturn(TypedDict):
wells: list
volumes: list
class SetLiquidFromPlateReturn(TypedDict):
plate: list
wells: list
volumes: list
class LiquidHandlerMiddleware(LiquidHandler):
def __init__(
self, backend: LiquidHandlerBackend, deck: Deck, simulator: bool = False, channel_num: int = 8, **kwargs

376
unilabos/devices/motor/ZDT_X42.py Normal file
View File

@@ -0,0 +1,376 @@
# -*- coding: utf-8 -*-
"""
ZDT X42 Closed-Loop Stepper Motor Driver
RS485 Serial Communication via USB-Serial Converter
- Baudrate: 115200
"""
import serial
import time
import threading
import struct
import logging
from typing import Optional, Any
try:
from unilabos.device_comms.universal_driver import UniversalDriver
except ImportError:
class UniversalDriver:
def __init__(self, *args, **kwargs):
self.logger = logging.getLogger(self.__class__.__name__)
def execute_command_from_outer(self, command: Any): pass
from serial.rs485 import RS485Settings
class ZDTX42Driver(UniversalDriver):
"""
ZDT X42 闭环步进电机驱动器
支持功能:
- 速度模式运行
- 位置模式运行 (相对/绝对)
- 位置读取和清零
- 使能/禁用控制
通信协议:
- 帧格式: [设备ID] [功能码] [数据...] [校验位=0x6B]
- 响应长度根据功能码决定
"""
def __init__(
self,
port: str,
baudrate: int = 115200,
device_id: int = 1,
timeout: float = 0.5,
debug: bool = False
):
"""
初始化 ZDT X42 电机驱动
Args:
port: 串口设备路径
baudrate: 波特率 (默认 115200)
device_id: 设备地址 (1-255)
timeout: 通信超时时间(秒)
debug: 是否启用调试输出
"""
super().__init__()
self.id = device_id
self.debug = debug
self.lock = threading.RLock()
self.status = "idle" # 对应注册表中的 status (str)
self.position = 0 # 对应注册表中的 position (int)
try:
self.ser = serial.Serial(
port=port,
baudrate=baudrate,
timeout=timeout,
bytesize=serial.EIGHTBITS,
parity=serial.PARITY_NONE,
stopbits=serial.STOPBITS_ONE
)
# 启用 RS485 模式
try:
self.ser.rs485_mode = RS485Settings(
rts_level_for_tx=True,
rts_level_for_rx=False
)
except Exception:
pass # RS485 模式是可选的
self.logger.info(
f"ZDT X42 Motor connected: {port} "
f"(Baud: {baudrate}, ID: {device_id})"
)
# 自动使能电机,确保初始状态可运动
self.enable(True)
# 启动背景轮询线程,确保 position 实时刷新
self._stop_event = threading.Event()
self._polling_thread = threading.Thread(
target=self._update_loop,
name=f"ZDTPolling_{port}",
daemon=True
)
self._polling_thread.start()
except Exception as e:
self.logger.error(f"Failed to open serial port {port}: {e}")
self.ser = None
def _update_loop(self):
"""背景循环读取电机位置"""
while not self._stop_event.is_set():
try:
self.get_position()
except Exception as e:
if self.debug:
self.logger.error(f"Polling error: {e}")
time.sleep(1.0) # 每1秒刷新一次位置数据
def _send(self, func_code: int, payload: list) -> bytes:
"""
发送指令并接收响应
Args:
func_code: 功能码
payload: 数据负载 (list of bytes)
Returns:
响应数据 (bytes)
"""
if not self.ser:
self.logger.error("Serial port not available")
return b""
with self.lock:
# 清空输入缓冲区
self.ser.reset_input_buffer()
# 构建消息: [ID] [功能码] [数据...] [校验位=0x6B]
message = bytes([self.id, func_code] + payload + [0x6B])
# 发送
self.ser.write(message)
# 根据功能码决定响应长度
# 查询类指令返回 10 字节,控制类指令返回 4 字节
read_len = 10 if func_code in [0x31, 0x32, 0x35, 0x24, 0x27] else 4
response = self.ser.read(read_len)
# 调试输出
if self.debug:
sent_hex = message.hex().upper()
recv_hex = response.hex().upper() if response else 'TIMEOUT'
print(f"[ID {self.id}] TX: {sent_hex} → RX: {recv_hex}")
return response
def enable(self, on: bool = True) -> bool:
"""
使能/禁用电机
Args:
on: True=使能(锁轴), False=禁用(松轴)
Returns:
是否成功
"""
state = 1 if on else 0
resp = self._send(0xF3, [0xAB, state, 0])
return len(resp) >= 4
def move_speed(
self,
speed_rpm: int,
direction: str = "CW",
acceleration: int = 10
) -> bool:
"""
速度模式运行
Args:
speed_rpm: 转速 (RPM)
direction: 方向 ("CW"=顺时针, "CCW"=逆时针)
acceleration: 加速度 (0-255)
Returns:
是否成功
"""
dir_val = 0 if direction.upper() in ["CW", "顺时针"] else 1
speed_bytes = struct.pack('>H', int(speed_rpm))
self.status = f"moving@{speed_rpm}rpm"
resp = self._send(0xF6, [dir_val, speed_bytes[0], speed_bytes[1], acceleration, 0])
return len(resp) >= 4
def move_position(
self,
pulses: int,
speed_rpm: int,
direction: str = "CW",
acceleration: int = 10,
absolute: bool = False
) -> bool:
"""
位置模式运行
Args:
pulses: 脉冲数
speed_rpm: 转速 (RPM)
direction: 方向 ("CW"=顺时针, "CCW"=逆时针)
acceleration: 加速度 (0-255)
absolute: True=绝对位置, False=相对位置
Returns:
是否成功
"""
dir_val = 0 if direction.upper() in ["CW", "顺时针"] else 1
speed_bytes = struct.pack('>H', int(speed_rpm))
self.status = f"moving_to_{pulses}"
pulse_bytes = struct.pack('>I', int(pulses))
abs_flag = 1 if absolute else 0
payload = [
dir_val,
speed_bytes[0], speed_bytes[1],
acceleration,
pulse_bytes[0], pulse_bytes[1], pulse_bytes[2], pulse_bytes[3],
abs_flag,
0
]
resp = self._send(0xFD, payload)
return len(resp) >= 4
def stop(self) -> bool:
"""
停止电机
Returns:
是否成功
"""
self.status = "idle"
resp = self._send(0xFE, [0x98, 0])
return len(resp) >= 4
def rotate_quarter(self, speed_rpm: int = 60, direction: str = "CW") -> bool:
"""
电机旋转 1/4 圈 (阻塞式)
假设电机细分为 3200 脉冲/圈1/4 圈 = 800 脉冲
"""
pulses = 800
success = self.move_position(pulses=pulses, speed_rpm=speed_rpm, direction=direction, absolute=False)
if success:
# 计算预估旋转时间并进行阻塞等待 (Time = revolutions / (RPM/60))
# 1/4 rev / (RPM/60) = 15.0 / RPM
estimated_time = 15.0 / max(1, speed_rpm)
time.sleep(estimated_time + 0.5) # 额外给 0.5 秒缓冲
self.status = "idle"
return success
def wait_time(self, duration_s: float) -> bool:
"""
等待指定时间 (秒)
"""
self.logger.info(f"Waiting for {duration_s} seconds...")
time.sleep(duration_s)
return True
def set_zero(self) -> bool:
"""
清零当前位置
Returns:
是否成功
"""
resp = self._send(0x0A, [])
return len(resp) >= 4
def get_position(self) -> Optional[int]:
"""
读取当前位置 (脉冲数)
Returns:
当前位置脉冲数,失败返回 None
"""
resp = self._send(0x32, [])
if len(resp) >= 8:
# 响应格式: [ID] [Func] [符号位] [数值4字节] [校验]
sign = resp[2] # 0=正, 1=负
value = struct.unpack('>I', resp[3:7])[0]
self.position = -value if sign == 1 else value
if self.debug:
print(f"[Position] Raw: {resp.hex().upper()}, Parsed: {self.position}")
return self.position
self.logger.warning("Failed to read position")
return None
def close(self):
"""关闭串口连接并停止线程"""
if hasattr(self, '_stop_event'):
self._stop_event.set()
if self.ser and self.ser.is_open:
self.ser.close()
self.logger.info("Serial port closed")
# ============================================================
# 测试和调试代码
# ============================================================
def test_motor():
"""基础功能测试"""
logging.basicConfig(level=logging.INFO)
print("="*60)
print("ZDT X42 电机驱动测试")
print("="*60)
driver = ZDTX42Driver(
port="/dev/tty.usbserial-3110",
baudrate=115200,
device_id=2,
debug=True
)
if not driver.ser:
print("❌ 串口打开失败")
return
try:
# 测试 1: 读取位置
print("\n[1] 读取当前位置")
pos = driver.get_position()
print(f"✓ 当前位置: {pos} 脉冲")
# 测试 2: 使能
print("\n[2] 使能电机")
driver.enable(True)
time.sleep(0.3)
print("✓ 电机已锁定")
# 测试 3: 相对位置运动
print("\n[3] 相对位置运动 (1000脉冲)")
driver.move_position(pulses=1000, speed_rpm=60, direction="CW")
time.sleep(2)
pos = driver.get_position()
print(f"✓ 新位置: {pos}")
# 测试 4: 速度运动
print("\n[4] 速度模式 (30RPM, 3秒)")
driver.move_speed(speed_rpm=30, direction="CW")
time.sleep(3)
driver.stop()
pos = driver.get_position()
print(f"✓ 停止后位置: {pos}")
# 测试 5: 禁用
print("\n[5] 禁用电机")
driver.enable(False)
print("✓ 电机已松开")
print("\n" + "="*60)
print("✅ 测试完成")
print("="*60)
except Exception as e:
print(f"\n❌ 测试失败: {e}")
import traceback
traceback.print_exc()
finally:
driver.close()
if __name__ == "__main__":
test_motor()

113
unilabos/devices/separator/chinwe.py
View File

@@ -623,6 +623,119 @@ class ChinweDevice(UniversalDriver):
time.sleep(duration)
return True
def separation_step(self, motor_id: int = 5, speed: int = 60, pulses: int = 700,
max_cycles: int = 0, timeout: int = 300) -> bool:
"""
分液步骤 - 液位传感器与电机联动
当液位传感器检测到"有液"时,电机顺时针旋转指定脉冲数
当液位传感器检测到"无液"时,电机逆时针旋转指定脉冲数
:param motor_id: 电机ID (必须在初始化时配置的motor_ids中)
:param speed: 电机转速 (RPM)
:param pulses: 每次旋转的脉冲数 (默认700约为1/4圈,假设3200脉冲/圈)
:param max_cycles: 最大执行循环次数 (0=无限制,默认0)
:param timeout: 整体超时时间 (秒)
:return: 成功返回True,超时或失败返回False
"""
motor_id = int(motor_id)
speed = int(speed)
pulses = int(pulses)
max_cycles = int(max_cycles)
timeout = int(timeout)
# 检查电机是否存在
if motor_id not in self.motors:
self.logger.error(f"Motor {motor_id} not found in configured motors: {list(self.motors.keys())}")
return False
# 检查传感器是否可用
if not self.sensor:
self.logger.error("Sensor not initialized")
return False
motor = self.motors[motor_id]
# 停止轮询线程,避免与 separation_step 同时读取传感器造成串口冲突
self.logger.info("Stopping polling thread for separation_step...")
self._stop_event.set()
if self._poll_thread and self._poll_thread.is_alive():
self._poll_thread.join(timeout=2.0)
# 使能电机
self.logger.info(f"Enabling motor {motor_id}...")
motor.enable(True)
time.sleep(0.2)
self.logger.info(f"Starting separation step: motor_id={motor_id}, speed={speed} RPM, "
f"pulses={pulses}, max_cycles={max_cycles}, timeout={timeout}s")
# 记录上一次的液位状态
last_level = None
cycle_count = 0
start_time = time.time()
error_count = 0
try:
while True:
# 检查超时
if time.time() - start_time > timeout:
self.logger.warning(f"Separation step timeout after {timeout} seconds")
return False
# 检查循环次数限制
if max_cycles > 0 and cycle_count >= max_cycles:
self.logger.info(f"Separation step completed: reached max_cycles={max_cycles}")
return True
# 读取传感器数据
data = self.sensor.read_level()
if data is None:
error_count += 1
if error_count > 5:
self.logger.warning("Sensor read failed multiple times, retrying...")
error_count = 0
time.sleep(0.5)
continue
error_count = 0
current_level = data['level']
rssi = data['rssi']
# 检测状态变化 (包括首次检测)
if current_level != last_level:
cycle_count += 1
if current_level:
# 有液 -> 电机顺时针旋转
self.logger.info(f"[Cycle {cycle_count}] Liquid detected (RSSI={rssi}), "
f"rotating motor {motor_id} clockwise {pulses} pulses")
motor.run_position(pulses=pulses, speed_rpm=speed, direction=0, absolute=False)
# 等待电机完成 (预估时间)
estimated_time = 15.0 / max(1, speed)
time.sleep(estimated_time + 0.5)
else:
# 无液 -> 电机逆时针旋转
self.logger.info(f"[Cycle {cycle_count}] No liquid detected (RSSI={rssi}), "
f"rotating motor {motor_id} counter-clockwise {pulses} pulses")
motor.run_position(pulses=pulses, speed_rpm=speed, direction=1, absolute=False)
# 等待电机完成 (预估时间)
estimated_time = 15.0 / max(1, speed)
time.sleep(estimated_time + 0.5)
# 更新状态
last_level = current_level
# 轮询间隔
time.sleep(0.1)
finally:
# 恢复轮询线程
self.logger.info("Restarting polling thread...")
self._start_polling()
def execute_command_from_outer(self, command_dict: Dict[str, Any]) -> bool:
"""支持标准 JSON 指令调用"""
return super().execute_command_from_outer(command_dict)

379
unilabos/devices/separator/xkc_sensor.py Normal file
View File

@@ -0,0 +1,379 @@
# -*- coding: utf-8 -*-
"""
XKC RS485 液位传感器 (Modbus RTU)
说明:
1. 遵循 Modbus-RTU 协议。
2. 数据寄存器: 0x0001 (液位状态, 1=有液, 0=无液), 0x0002 (RSSI 信号强度)。
3. 地址寄存器: 0x0004 (可读写, 范围 1-254)。
4. 波特率寄存器: 0x0005 (可写, 代码表见 change_baudrate 方法)。
"""
import struct
import threading
import time
import logging
import serial
from typing import Optional, Dict, Any, List
from unilabos.device_comms.universal_driver import UniversalDriver
class TransportManager:
"""
统一通信管理类。
仅支持 串口 (Serial/有线) 连接。
"""
def __init__(self, port: str, baudrate: int = 9600, timeout: float = 3.0, logger=None):
self.port = port
self.baudrate = baudrate
self.timeout = timeout
self.logger = logger
self.lock = threading.RLock() # 线程锁,确保多设备共用一个连接时不冲突
self.serial = None
self._connect_serial()
def _connect_serial(self):
try:
self.serial = serial.Serial(
port=self.port,
baudrate=self.baudrate,
timeout=self.timeout
)
except Exception as e:
raise ConnectionError(f"Serial open failed: {e}")
def close(self):
"""关闭连接"""
if self.serial and self.serial.is_open:
self.serial.close()
def clear_buffer(self):
"""清空缓冲区 (Thread-safe)"""
with self.lock:
if self.serial:
self.serial.reset_input_buffer()
def write(self, data: bytes):
"""发送原始字节"""
with self.lock:
if self.serial:
self.serial.write(data)
def read(self, size: int) -> bytes:
"""读取指定长度字节"""
if self.serial:
return self.serial.read(size)
return b''
class XKCSensorDriver(UniversalDriver):
"""XKC RS485 液位传感器 (Modbus RTU)"""
def __init__(self, port: str, baudrate: int = 9600, device_id: int = 6,
threshold: int = 300, timeout: float = 3.0, debug: bool = False):
super().__init__()
self.port = port
self.baudrate = baudrate
self.device_id = device_id
self.threshold = threshold
self.timeout = timeout
self.debug = debug
self.level = False
self.rssi = 0
self.status = {"level": self.level, "rssi": self.rssi}
try:
self.transport = TransportManager(port, baudrate, timeout, logger=self.logger)
self.logger.info(f"XKCSensorDriver connected to {port} (ID: {device_id})")
except Exception as e:
self.logger.error(f"Failed to connect XKCSensorDriver: {e}")
self.transport = None
# 启动背景轮询线程,确保 status 实时刷新
self._stop_event = threading.Event()
self._polling_thread = threading.Thread(
target=self._update_loop,
name=f"XKCPolling_{port}",
daemon=True
)
if self.transport:
self._polling_thread.start()
def _update_loop(self):
"""背景循环读取传感器数据"""
while not self._stop_event.is_set():
try:
self.read_level()
except Exception as e:
if self.debug:
self.logger.error(f"Polling error: {e}")
time.sleep(2.0) # 每2秒刷新一次数据
def _crc(self, data: bytes) -> bytes:
crc = 0xFFFF
for byte in data:
crc ^= byte
for _ in range(8):
if crc & 0x0001: crc = (crc >> 1) ^ 0xA001
else: crc >>= 1
return struct.pack('<H', crc)
def read_level(self) -> Optional[Dict[str, Any]]:
"""
读取液位。
返回: {'level': bool, 'rssi': int}
"""
if not self.transport:
return None
with self.transport.lock:
self.transport.clear_buffer()
# Modbus Read Registers: 01 03 00 01 00 02 CRC
payload = struct.pack('>HH', 0x0001, 0x0002)
msg = struct.pack('BB', self.device_id, 0x03) + payload
msg += self._crc(msg)
if self.debug:
self.logger.info(f"TX (ID {self.device_id}): {msg.hex().upper()}")
self.transport.write(msg)
# Read header
h = self.transport.read(3) # Addr, Func, Len
if self.debug:
self.logger.info(f"RX Header: {h.hex().upper()}")
if len(h) < 3: return None
length = h[2]
# Read body + CRC
body = self.transport.read(length + 2)
if self.debug:
self.logger.info(f"RX Body+CRC: {body.hex().upper()}")
if len(body) < length + 2:
# Firmware bug fix specific to some modules
if len(body) == 4 and length == 4:
pass
else:
return None
data = body[:-2]
# 根据手册说明:
# 寄存器 0x0001 (data[0:2]): 液位状态 (00 01 为有液, 00 00 为无液)
# 寄存器 0x0002 (data[2:4]): 信号强度 RSSI
hw_level = False
rssi = 0
if len(data) >= 4:
hw_level = ((data[0] << 8) | data[1]) == 1
rssi = (data[2] << 8) | data[3]
elif len(data) == 2:
# 兼容模式: 某些老固件可能只返回 1 个寄存器
rssi = (data[0] << 8) | data[1]
hw_level = rssi > self.threshold
else:
return None
# 最终判定: 优先使用硬件层级的 level 判定,但 RSSI 阈值逻辑作为补充/校验
# 注意: 如果用户显式设置了 THRESHOLD我们可以在逻辑中做权衡
self.level = hw_level or (rssi > self.threshold)
self.rssi = rssi
result = {
'level': self.level,
'rssi': self.rssi
}
self.status = result
return result
def wait_level(self, target_state: bool, timeout: float = 60.0) -> bool:
"""
等待液位达到目标状态 (阻塞式)
"""
self.logger.info(f"Waiting for level: {target_state}")
start_time = time.time()
while (time.time() - start_time) < timeout:
res = self.read_level()
if res and res.get('level') == target_state:
return True
time.sleep(0.5)
self.logger.warning(f"Wait level timeout ({timeout}s)")
return False
def wait_for_liquid(self, target_state: bool, timeout: float = 120.0) -> bool:
"""
实时检测电导率(RSSI)并等待用户指定的“有液”或“无液”状态。
一旦检测到符合目标状态,立即返回。
Args:
target_state: True 为“有液”, False 为“无液”
timeout: 最大等待时间(秒)
"""
state_str = "有液" if target_state else "无液"
self.logger.info(f"开始实时检测电导率,等待状态: {state_str} (超时: {timeout}s)")
start_time = time.time()
while (time.time() - start_time) < timeout:
res = self.read_level() # 内部已更新 self.level 和 self.rssi
if res:
current_level = res.get('level')
current_rssi = res.get('rssi')
if current_level == target_state:
self.logger.info(f"✅ 检测到目标状态: {state_str} (当前电导率/RSSI: {current_rssi})")
return True
if self.debug:
self.logger.debug(f"当前状态: {'有液' if current_level else '无液'}, RSSI: {current_rssi}")
time.sleep(0.2) # 高频采样
self.logger.warning(f"❌ 等待 {state_str} 状态超时 ({timeout}s)")
return False
def set_threshold(self, threshold: int):
"""设置液位判定阈值"""
self.threshold = int(threshold)
self.logger.info(f"Threshold updated to: {self.threshold}")
def change_device_id(self, new_id: int) -> bool:
"""
修改设备的 Modbus 从站地址。
寄存器: 0x0004, 功能码: 0x06
"""
if not (1 <= new_id <= 254):
self.logger.error(f"Invalid device ID: {new_id}. Must be 1-254.")
return False
self.logger.info(f"Changing device ID from {self.device_id} to {new_id}")
success = self._write_single_register(0x0004, new_id)
if success:
self.device_id = new_id # 更新内存中的地址
self.logger.info(f"Device ID update command sent successfully (target {new_id}).")
return success
def change_baudrate(self, baud_code: int) -> bool:
"""
更改通讯波特率 (寄存器: 0x0005)。
设置成功后传感器 LED 会闪烁,通常无数据返回。
波特率代码对照表 (16进制):
05: 2400
06: 4800
07: 9600 (默认)
08: 14400
09: 19200
0A: 28800
0C: 57600
0D: 115200
0E: 128000
0F: 256000
"""
self.logger.info(f"Sending baudrate change command (Code: {baud_code:02X})")
# 写入寄存器 0x0005
self._write_single_register(0x0005, baud_code)
self.logger.info("Baudrate change command executed. Device LED should flash. Please update connection settings.")
return True
def factory_reset(self) -> bool:
"""
恢复出厂设置 (通过广播地址 FF)。
设置地址为 01逻辑为向 0x0004 写入 0x0002
"""
self.logger.info("Sending factory reset command via broadcast address FF...")
# 广播指令通常无回显
self._write_single_register(0x0004, 0x0002, slave_id=0xFF)
self.logger.info("Factory reset command sent. Device address should be 01 now.")
return True
def _write_single_register(self, reg_addr: int, value: int, slave_id: Optional[int] = None) -> bool:
"""内部辅助函数: Modbus 功能码 06 写单个寄存器"""
if not self.transport: return False
target_id = slave_id if slave_id is not None else self.device_id
msg = struct.pack('BBHH', target_id, 0x06, reg_addr, value)
msg += self._crc(msg)
with self.transport.lock:
self.transport.clear_buffer()
if self.debug:
self.logger.info(f"TX Write (Reg {reg_addr:#06x}): {msg.hex().upper()}")
self.transport.write(msg)
# 广播地址、波特率修改或厂家特定指令可能无回显
if target_id == 0xFF or reg_addr == 0x0005:
time.sleep(0.5)
return True
# 等待返回 (正常应返回相同报文)
resp = self.transport.read(len(msg))
if self.debug:
self.logger.info(f"RX Write Response: {resp.hex().upper()}")
return resp == msg
def close(self):
if self.transport:
self.transport.close()
if __name__ == "__main__":
# 快速实例化测试
import logging
# 减少冗余日志,仅显示重要信息
logging.basicConfig(level=logging.INFO, format='%(levelname)s: %(message)s')
# 硬件配置 (根据实际情况修改)
TEST_PORT = "/dev/tty.usbserial-3110"
SLAVE_ID = 1
THRESHOLD = 300
print("\n" + "="*50)
print(f" XKC RS485 传感器独立测试程序")
print(f" 端口: {TEST_PORT} | 地址: {SLAVE_ID} | 阈值: {THRESHOLD}")
print("="*50)
sensor = XKCSensorDriver(port=TEST_PORT, device_id=SLAVE_ID, threshold=THRESHOLD, debug=False)
try:
if sensor.transport:
print(f"\n开始实时连续采样测试 (持续 15 秒)...")
print(f"按 Ctrl+C 可提前停止\n")
start_time = time.time()
duration = 15
count = 0
while time.time() - start_time < duration:
count += 1
res = sensor.read_level()
if res:
rssi = res['rssi']
level = res['level']
status_str = "【有液】" if level else "【无液】"
# 使用 \r 实现单行刷新显示 (或者不刷,直接打印历史)
# 为了方便查看变化,我们直接打印
elapsed = time.time() - start_time
print(f" [{elapsed:4.1f}s] 采样 {count:<3}: 电导率/RSSI = {rssi:<5} | 判定结果: {status_str}")
else:
print(f" [{time.time()-start_time:4.1f}s] 采样 {count:<3}: 通信失败 (无响应)")
time.sleep(0.5) # 每秒采样 2 次
print(f"\n--- 15 秒采样测试完成 (总计 {count} 次) ---")
# [3] 测试动态修改阈值
print(f"\n[3] 动态修改阈值演示...")
new_threshold = 400
sensor.set_threshold(new_threshold)
res = sensor.read_level()
if res:
print(f" 采样 (当前阈值={new_threshold}): 电导率/RSSI = {res['rssi']:<5} | 判定结果: {'【有液】' if res['level'] else '【无液】'}")
sensor.set_threshold(THRESHOLD) # 还原
except KeyboardInterrupt:
print("\n[!] 用户中断测试")
except Exception as e:
print(f"\n[!] 测试运行出错: {e}")
finally:
sensor.close()
print("\n--- 测试程序已退出 ---\n")

2
unilabos/devices/workstation/bioyond_studio/station.py
View File

@@ -258,7 +258,7 @@ class BioyondResourceSynchronizer(ResourceSynchronizer):
logger.info(f"[同步→Bioyond] 物料不存在于 Bioyond将创建新物料并入库")
# 第1步从配置中获取仓库配置
warehouse_mapping = self.bioyond_config.get("warehouse_mapping", {})
warehouse_mapping = self.workstation.bioyond_config.get("warehouse_mapping", {})
# 确定目标仓库名称
parent_name = None

41
unilabos/registry/devices/chinwe.yaml
View File

@@ -317,6 +317,47 @@ separator.chinwe:
- port
type: object
type: UniLabJsonCommand
separation_step:
goal:
max_cycles: 0
motor_id: 5
pulses: 700
speed: 60
timeout: 300
handles: {}
schema:
description: 分液步骤 - 液位传感器与电机联动 (有液→顺时针, 无液→逆时针)
properties:
goal:
properties:
max_cycles:
default: 0
description: 最大循环次数 (0=无限制)
type: integer
motor_id:
default: '5'
description: 选择电机
enum:
- '4'
- '5'
title: '注: 4=搅拌, 5=旋钮'
type: string
pulses:
default: 700
description: 每次旋转脉冲数 (约1/4圈)
type: integer
speed:
default: 60
description: 电机转速 (RPM)
type: integer
timeout:
default: 300
description: 超时时间 (秒)
type: integer
required:
- motor_id
type: object
type: UniLabJsonCommand
wait_sensor_level:
goal:
target_state: 有液

286
unilabos/registry/devices/motor.yaml Normal file
View File

@@ -0,0 +1,286 @@
motor.zdt_x42:
category:
- motor
class:
action_value_mappings:
auto-enable:
feedback: {}
goal: {}
goal_default:
'on': true
handles: {}
placeholder_keys: {}
result: {}
schema:
description: 使能或禁用电机。使能后电机进入锁轴状态,可接收运动指令;禁用后电机进入松轴状态。
properties:
feedback: {}
goal:
properties:
'on':
default: true
type: boolean
required: []
type: object
result: {}
required:
- goal
title: enable参数
type: object
type: UniLabJsonCommand
auto-get_position:
feedback: {}
goal: {}
goal_default: {}
handles: {}
placeholder_keys: {}
result: {}
schema:
description: 获取当前电机脉冲位置。
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result:
properties:
position:
type: integer
type: object
required:
- goal
title: get_position参数
type: object
type: UniLabJsonCommand
auto-move_position:
feedback: {}
goal: {}
goal_default:
absolute: false
acceleration: 10
direction: CW
pulses: 1000
speed_rpm: 60
handles: {}
placeholder_keys: {}
result: {}
schema:
description: 位置模式运行。控制电机移动到指定脉冲位置或相对于当前位置移动指定脉冲数。
properties:
feedback: {}
goal:
properties:
absolute:
default: false
type: boolean
acceleration:
default: 10
maximum: 255
minimum: 0
type: integer
direction:
default: CW
enum:
- CW
- CCW
type: string
pulses:
default: 1000
type: integer
speed_rpm:
default: 60
minimum: 0
type: integer
required:
- pulses
- speed_rpm
type: object
result: {}
required:
- goal
title: move_position参数
type: object
type: UniLabJsonCommand
auto-move_speed:
feedback: {}
goal: {}
goal_default:
acceleration: 10
direction: CW
speed_rpm: 60
handles: {}
placeholder_keys: {}
result: {}
schema:
description: 速度模式运行。控制电机以指定转速和方向持续转动。
properties:
feedback: {}
goal:
properties:
acceleration:
default: 10
maximum: 255
minimum: 0
type: integer
direction:
default: CW
enum:
- CW
- CCW
type: string
speed_rpm:
default: 60
minimum: 0
type: integer
required:
- speed_rpm
type: object
result: {}
required:
- goal
title: move_speed参数
type: object
type: UniLabJsonCommand
auto-rotate_quarter:
feedback: {}
goal: {}
goal_default:
direction: CW
speed_rpm: 60
handles: {}
placeholder_keys: {}
result: {}
schema:
description: 电机旋转 1/4 圈 (阻塞式)。
properties:
feedback: {}
goal:
properties:
direction:
default: CW
enum:
- CW
- CCW
type: string
speed_rpm:
default: 60
minimum: 1
type: integer
required: []
type: object
result: {}
required:
- goal
title: rotate_quarter参数
type: object
type: UniLabJsonCommand
auto-set_zero:
feedback: {}
goal: {}
goal_default: {}
handles: {}
placeholder_keys: {}
result: {}
schema:
description: 将当前电机位置设为零点。
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: set_zero参数
type: object
type: UniLabJsonCommand
auto-stop:
feedback: {}
goal: {}
goal_default: {}
handles: {}
placeholder_keys: {}
result: {}
schema:
description: 立即停止电机运动。
properties:
feedback: {}
goal:
properties: {}
required: []
type: object
result: {}
required:
- goal
title: stop参数
type: object
type: UniLabJsonCommand
auto-wait_time:
feedback: {}
goal: {}
goal_default:
duration_s: 1.0
handles: {}
placeholder_keys: {}
result: {}
schema:
description: 等待指定时间 (秒)。
properties:
feedback: {}
goal:
properties:
duration_s:
default: 1.0
minimum: 0
type: number
required:
- duration_s
type: object
result: {}
required:
- goal
title: wait_time参数
type: object
type: UniLabJsonCommand
module: unilabos.devices.motor.ZDT_X42:ZDTX42Driver
status_types:
position: int
status: str
type: python
config_info: []
description: ZDT X42 闭环步进电机驱动。支持速度运行、精确位置控制、位置查询和清零功能。适用于各种需要精确运动控制的实验室自动化场景。
handles: []
icon: ''
init_param_schema:
config:
properties:
baudrate:
default: 115200
type: integer
debug:
default: false
type: boolean
device_id:
default: 1
type: integer
port:
type: string
timeout:
default: 0.5
type: number
required:
- port
type: object
data:
properties:
position:
type: integer
status:
type: string
required:
- status
- position
type: object
version: 1.0.0

148
unilabos/registry/devices/sensor.yaml Normal file
View File

@@ -0,0 +1,148 @@
sensor.xkc_rs485:
category:
- sensor
- separator
class:
action_value_mappings:
auto-change_baudrate:
goal:
baud_code: 7
handles: {}
schema:
description: '更改通讯波特率 (设置成功后无返回,且需手动切换波特率重连)。代码表 (16进制): 05=2400, 06=4800,
07=9600, 08=14400, 09=19200, 0A=28800, 0C=57600, 0D=115200, 0E=128000,
0F=256000'
properties:
goal:
properties:
baud_code:
description: '波特率代码 (例如: 7 为 9600, 13 即 0x0D 为 115200)'
type: integer
required:
- baud_code
type: object
type: UniLabJsonCommand
auto-change_device_id:
goal:
new_id: 1
handles: {}
schema:
description: 修改传感器的 Modbus 从站地址
properties:
goal:
properties:
new_id:
description: 新的从站地址 (1-254)
maximum: 254
minimum: 1
type: integer
required:
- new_id
type: object
type: UniLabJsonCommand
auto-factory_reset:
goal: {}
handles: {}
schema:
description: 恢复出厂设置 (地址重置为 01)
properties:
goal:
type: object
type: UniLabJsonCommand
auto-read_level:
goal: {}
handles: {}
schema:
description: 直接读取当前液位及信号强度
properties:
goal:
type: object
type: object
type: UniLabJsonCommand
auto-set_threshold:
goal:
threshold: 300
handles: {}
schema:
description: 设置液位判定阈值
properties:
goal:
properties:
threshold:
type: integer
required:
- threshold
type: object
type: UniLabJsonCommand
auto-wait_for_liquid:
goal:
target_state: true
timeout: 120
handles: {}
schema:
description: 实时检测电导率(RSSI)并等待用户指定的状态
properties:
goal:
properties:
target_state:
default: true
description: 目标状态 (True=有液, False=无液)
type: boolean
timeout:
default: 120
description: 超时时间 (秒)
required:
- target_state
type: object
type: UniLabJsonCommand
auto-wait_level:
goal:
level: true
timeout: 10
handles: {}
schema:
description: 等待液位达到目标状态
properties:
goal:
properties:
level:
type: boolean
timeout:
type: number
required:
- level
type: object
type: UniLabJsonCommand
module: unilabos.devices.separator.xkc_sensor:XKCSensorDriver
status_types:
level: bool
rssi: int
type: python
config_info: []
description: XKC RS485 非接触式液位传感器 (Modbus RTU)
handles: []
icon: ''
init_param_schema:
config:
properties:
baudrate:
default: 9600
type: integer
debug:
default: false
type: boolean
device_id:
default: 1
type: integer
port:
type: string
threshold:
default: 300
type: integer
timeout:
default: 3.0
type: number
required:
- port
type: object
version: 1.0.0

13
unilabos/registry/resources/bioyond/bottle_carriers.yaml
View File

@@ -46,3 +46,16 @@ BIOYOND_PolymerStation_8StockCarrier:
init_param_schema: {}
registry_type: resource
version: 1.0.0
BIOYOND_PolymerStation_TipBox:
category:
- bottle_carriers
- tip_racks
class:
module: unilabos.resources.bioyond.bottle_carriers:BIOYOND_PolymerStation_TipBox
type: pylabrobot
description: BIOYOND_PolymerStation_TipBox (4x6布局24个枪头孔位)
handles: []
icon: ''
init_param_schema: {}
registry_type: resource
version: 1.0.0

11
unilabos/registry/resources/bioyond/bottles.yaml
View File

@@ -82,14 +82,3 @@ BIOYOND_PolymerStation_Solution_Beaker:
icon: ''
init_param_schema: {}
version: 1.0.0
BIOYOND_PolymerStation_TipBox:
category:
- bottles
- tip_boxes
class:
module: unilabos.resources.bioyond.bottles:BIOYOND_PolymerStation_TipBox
type: pylabrobot
handles: []
icon: ''
init_param_schema: {}
version: 1.0.0

109
unilabos/resources/bioyond/bottle_carriers.py
View File

@@ -1,4 +1,4 @@
from pylabrobot.resources import create_homogeneous_resources, Coordinate, ResourceHolder, create_ordered_items_2d
from pylabrobot.resources import create_homogeneous_resources, Coordinate, ResourceHolder, create_ordered_items_2d, Container
from unilabos.resources.itemized_carrier import BottleCarrier
from unilabos.resources.bioyond.bottles import (
@@ -9,6 +9,28 @@ from unilabos.resources.bioyond.bottles import (
BIOYOND_PolymerStation_Reagent_Bottle,
BIOYOND_PolymerStation_Flask,
)
def BIOYOND_PolymerStation_Tip(name: str, size_x: float = 8.0, size_y: float = 8.0, size_z: float = 50.0) -> Container:
"""创建单个枪头资源
Args:
name: 枪头名称
size_x: 枪头宽度 (mm)
size_y: 枪头长度 (mm)
size_z: 枪头高度 (mm)
Returns:
Container: 枪头容器
"""
return Container(
name=name,
size_x=size_x,
size_y=size_y,
size_z=size_z,
category="tip",
model="BIOYOND_PolymerStation_Tip",
)
# 命名约定:试剂瓶-Bottle烧杯-Beaker烧瓶-Flask,小瓶-Vial
@@ -322,3 +344,88 @@ def BIOYOND_Electrolyte_1BottleCarrier(name: str) -> BottleCarrier:
carrier.num_items_z = 1
carrier[0] = BIOYOND_PolymerStation_Solution_Beaker(f"{name}_beaker_1")
return carrier
def BIOYOND_PolymerStation_TipBox(
name: str,
size_x: float = 127.76, # 枪头盒宽度
size_y: float = 85.48, # 枪头盒长度
size_z: float = 100.0, # 枪头盒高度
barcode: str = None,
) -> BottleCarrier:
"""创建4×6枪头盒 (24个枪头) - 使用 BottleCarrier 结构
Args:
name: 枪头盒名称
size_x: 枪头盒宽度 (mm)
size_y: 枪头盒长度 (mm)
size_z: 枪头盒高度 (mm)
barcode: 条形码
Returns:
BottleCarrier: 包含24个枪头孔位的枪头盒载架
布局说明:
- 4行×6列 (A-D, 1-6)
- 枪头孔位间距: 18mm (x方向) × 18mm (y方向)
- 起始位置居中对齐
- 索引顺序: 列优先 (0=A1, 1=B1, 2=C1, 3=D1, 4=A2, ...)
"""
# 枪头孔位参数
num_cols = 6 # 1-6 (x方向)
num_rows = 4 # A-D (y方向)
tip_diameter = 8.0 # 枪头孔位直径
tip_spacing_x = 18.0 # 列间距 (增加到18mm更宽松)
tip_spacing_y = 18.0 # 行间距 (增加到18mm更宽松)
# 计算起始位置 (居中对齐)
total_width = (num_cols - 1) * tip_spacing_x + tip_diameter
total_height = (num_rows - 1) * tip_spacing_y + tip_diameter
start_x = (size_x - total_width) / 2
start_y = (size_y - total_height) / 2
# 使用 create_ordered_items_2d 创建孔位
# create_ordered_items_2d 返回的 key 是数字索引: 0, 1, 2, ...
# 顺序是列优先: 先y后x (即 0=A1, 1=B1, 2=C1, 3=D1, 4=A2, 5=B2, ...)
sites = create_ordered_items_2d(
klass=ResourceHolder,
num_items_x=num_cols,
num_items_y=num_rows,
dx=start_x,
dy=start_y,
dz=5.0,
item_dx=tip_spacing_x,
item_dy=tip_spacing_y,
size_x=tip_diameter,
size_y=tip_diameter,
size_z=50.0, # 枪头深度
)
# 更新 sites 中每个 ResourceHolder 的名称
for k, v in sites.items():
v.name = f"{name}_{v.name}"
# 创建枪头盒载架
# 注意:不设置 category使用默认的 "bottle_carrier",这样前端会显示为完整的矩形载架
tip_box = BottleCarrier(
name=name,
size_x=size_x,
size_y=size_y,
size_z=size_z,
sites=sites, # 直接使用数字索引的 sites
model="BIOYOND_PolymerStation_TipBox",
)
# 设置自定义属性
tip_box.barcode = barcode
tip_box.tip_count = 24 # 4行×6列
tip_box.num_items_x = num_cols
tip_box.num_items_y = num_rows
tip_box.num_items_z = 1
# ⭐ 枪头盒不需要放入子资源
# 与其他 carrier 不同,枪头盒在 Bioyond 中是一个整体
# 不需要追踪每个枪头的状态,保持为空的 ResourceHolder 即可
# 这样前端会显示24个空槽位可以用于放置枪头
return tip_box

56
unilabos/resources/bioyond/bottles.py
View File

@@ -116,7 +116,9 @@ def BIOYOND_PolymerStation_TipBox(
size_z: float = 100.0, # 枪头盒高度
barcode: str = None,
):
"""创建4×6枪头盒 (24个枪头)
"""创建4×6枪头盒 (24个枪头) - 使用 BottleCarrier 结构
注意:此函数已弃用,请使用 bottle_carriers.py 中的版本
Args:
name: 枪头盒名称
@@ -126,55 +128,11 @@ def BIOYOND_PolymerStation_TipBox(
barcode: 条形码
Returns:
TipBoxCarrier: 包含24个枪头孔位的枪头盒
BottleCarrier: 包含24个枪头孔位的枪头盒载架
"""
from pylabrobot.resources import Container, Coordinate
# 创建枪头盒容器
tip_box = Container(
name=name,
size_x=size_x,
size_y=size_y,
size_z=size_z,
category="tip_rack",
model="BIOYOND_PolymerStation_TipBox_4x6",
)
# 设置自定义属性
tip_box.barcode = barcode
tip_box.tip_count = 24 # 4行×6列
tip_box.num_items_x = 6 # 6列
tip_box.num_items_y = 4 # 4行
# 创建24个枪头孔位 (4行×6列)
# 假设孔位间距为 9mm
tip_spacing_x = 9.0 # 列间距
tip_spacing_y = 9.0 # 行间距
start_x = 14.38 # 第一个孔位的x偏移
start_y = 11.24 # 第一个孔位的y偏移
for row in range(4): # A, B, C, D
for col in range(6): # 1-6
spot_name = f"{chr(65 + row)}{col + 1}" # A1, A2, ..., D6
x = start_x + col * tip_spacing_x
y = start_y + row * tip_spacing_y
# 创建枪头孔位容器
tip_spot = Container(
name=spot_name,
size_x=8.0, # 单个枪头孔位大小
size_y=8.0,
size_z=size_z - 10.0, # 略低于盒子高度
category="tip_spot",
)
# 添加到枪头盒
tip_box.assign_child_resource(
tip_spot,
location=Coordinate(x=x, y=y, z=0)
)
return tip_box
# 重定向到 bottle_carriers.py 中的实现
from unilabos.resources.bioyond.bottle_carriers import BIOYOND_PolymerStation_TipBox as TipBox_Carrier
return TipBox_Carrier(name=name, size_x=size_x, size_y=size_y, size_z=size_z, barcode=barcode)
def BIOYOND_PolymerStation_Flask(

47
unilabos/resources/graphio.py
View File

@@ -779,9 +779,12 @@ def resource_bioyond_to_plr(bioyond_materials: list[dict], type_mapping: Dict[st
bottle = plr_material[number] = initialize_resource(
{"name": f'{detail["name"]}_{number}', "class": reverse_type_mapping[typeName][0]}, resource_type=ResourcePLR
)
bottle.tracker.liquids = [
(detail["name"], float(detail.get("quantity", 0)) if detail.get("quantity") else 0)
]
# 只有具有 tracker 属性的容器才设置液体信息(如 Bottle, Well
# ResourceHolder 等不支持液体追踪的容器跳过
if hasattr(bottle, "tracker"):
bottle.tracker.liquids = [
(detail["name"], float(detail.get("quantity", 0)) if detail.get("quantity") else 0)
]
bottle.code = detail.get("code", "")
logger.debug(f" └─ [子物料] {detail['name']}{plr_material.name}[{number}] (类型:{typeName})")
else:
@@ -790,9 +793,11 @@ def resource_bioyond_to_plr(bioyond_materials: list[dict], type_mapping: Dict[st
# 只对有 capacity 属性的容器(液体容器)处理液体追踪
if hasattr(plr_material, 'capacity'):
bottle = plr_material[0] if plr_material.capacity > 0 else plr_material
bottle.tracker.liquids = [
(material["name"], float(material.get("quantity", 0)) if material.get("quantity") else 0)
]
# 确保 bottletracker 属性才设置液体信息
if hasattr(bottle, "tracker"):
bottle.tracker.liquids = [
(material["name"], float(material.get("quantity", 0)) if material.get("quantity") else 0)
]
plr_materials.append(plr_material)
@@ -821,24 +826,29 @@ def resource_bioyond_to_plr(bioyond_materials: list[dict], type_mapping: Dict[st
wh_name = loc.get("whName")
logger.debug(f"[物料位置] {unique_name} 尝试放置到 warehouse: {wh_name} (Bioyond坐标: x={loc.get('x')}, y={loc.get('y')}, z={loc.get('z')})")
# Bioyond坐标映射 (重要!): x→行(1=A,2=B...), y→列(1=01,2=02...), z→层(通常=1)
# 必须在warehouse映射之前先获取坐标以便后续调整
x = loc.get("x", 1) # 行号 (1-based: 1=A, 2=B, 3=C, 4=D)
y = loc.get("y", 1) # 列号 (1-based: 1=01, 2=02, 3=03...)
z = loc.get("z", 1) # 层号 (1-based, 通常为1)
# 特殊处理: Bioyond的"堆栈1"需要映射到"堆栈1左"或"堆栈1右"
# 根据列号(x)判断: 1-4映射到左侧, 5-8映射到右侧
# 根据列号(y)判断: 1-4映射到左侧, 5-8映射到右侧
if wh_name == "堆栈1":
x_val = loc.get("x", 1)
if 1 <= x_val <= 4:
if 1 <= y <= 4:
wh_name = "堆栈1左"
elif 5 <= x_val <= 8:
elif 5 <= y <= 8:
wh_name = "堆栈1右"
y = y - 4 # 调整列号: 5-8映射到1-4
else:
logger.warning(f"物料 {material['name']} 的列号 x={x_val} 超出范围无法映射到堆栈1左或堆栈1右")
logger.warning(f"物料 {material['name']} 的列号 y={y} 超出范围无法映射到堆栈1左或堆栈1右")
continue
# 特殊处理: Bioyond的"站内Tip盒堆栈"也需要进行拆分映射
if wh_name == "站内Tip盒堆栈":
y_val = loc.get("y", 1)
if y_val == 1:
if y == 1:
wh_name = "站内Tip盒堆栈(右)"
elif y_val in [2, 3]:
elif y in [2, 3]:
wh_name = "站内Tip盒堆栈(左)"
y = y - 1 # 调整列号,因为左侧仓库对应的 Bioyond y=2 实际上是它的第1列
@@ -846,15 +856,6 @@ def resource_bioyond_to_plr(bioyond_materials: list[dict], type_mapping: Dict[st
warehouse = deck.warehouses[wh_name]
logger.debug(f"[Warehouse匹配] 找到warehouse: {wh_name} (容量: {warehouse.capacity}, 行×列: {warehouse.num_items_x}×{warehouse.num_items_y})")
# Bioyond坐标映射 (重要!): x→行(1=A,2=B...), y→列(1=01,2=02...), z→层(通常=1)
x = loc.get("x", 1) # 行号 (1-based: 1=A, 2=B, 3=C, 4=D)
y = loc.get("y", 1) # 列号 (1-based: 1=01, 2=02, 3=03...)
z = loc.get("z", 1) # 层号 (1-based, 通常为1)
# 如果是右侧堆栈,需要调整列号 (5→1, 6→2, 7→3, 8→4)
if wh_name == "堆栈1右":
y = y - 4 # 将5-8映射到1-4
# 特殊处理竖向warehouse站内试剂存放堆栈、测量小瓶仓库
# 这些warehouse使用 vertical-col-major 布局
if wh_name in ["站内试剂存放堆栈", "测量小瓶仓库(测密度)"]:

6
unilabos/resources/plr_additional_res_reg.py
View File

@@ -18,3 +18,9 @@ def register():
from unilabos.devices.liquid_handling.rviz_backend import UniLiquidHandlerRvizBackend
from unilabos.devices.liquid_handling.laiyu.backend.laiyu_v_backend import UniLiquidHandlerLaiyuBackend
# noinspection PyUnresolvedReferences
from unilabos.resources.bioyond.decks import (
BIOYOND_PolymerReactionStation_Deck,
BIOYOND_PolymerPreparationStation_Deck,
BIOYOND_YB_Deck,
)

1
unilabos/resources/resource_tracker.py
View File

@@ -411,6 +411,7 @@ class ResourceTreeSet(object):
"deck": "deck",
"tip_rack": "tip_rack",
"tip_spot": "tip_spot",
"tip": "tip", # 添加 tip 类型支持
"tube": "tube",
"bottle_carrier": "bottle_carrier",
"material_hole": "material_hole",

29
unilabos/test/experiments/xkc_sensor_test.json Normal file
View File

@@ -0,0 +1,29 @@
{
"nodes": [
{
"id": "Liquid_Sensor_1",
"name": "XKC Sensor",
"children": [],
"parent": null,
"type": "device",
"class": "sensor.xkc_rs485",
"position": {
"x": 0,
"y": 0,
"z": 0
},
"config": {
"port": "/dev/tty.usbserial-3110",
"baudrate": 9600,
"device_id": 1,
"threshold": 300,
"timeout": 3.0
},
"data": {
"level": false,
"rssi": 0
}
}
],
"links": []
}

28
unilabos/test/experiments/zdt_motor_test.json Normal file
View File

@@ -0,0 +1,28 @@
{
"nodes": [
{
"id": "ZDT_Motor",
"name": "ZDT Motor",
"children": [],
"parent": null,
"type": "device",
"class": "motor.zdt_x42",
"position": {
"x": 0,
"y": 0,
"z": 0
},
"config": {
"port": "/dev/tty.usbserial-3110",
"baudrate": 115200,
"device_id": 1,
"debug": true
},
"data": {
"position": 0,
"status": "idle"
}
}
],
"links": []
}