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ros2-messaging-patterns
ROS2 messaging patterns and best practices with Clean Architecture (Python & C++)
用 Codex 或 Claude 帮你安装 复制这段 Prompt,粘贴到 Codex、Claude 或其他助手里,让它检查 Skill 页面并帮你完成安装。
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ROS2 messaging patterns and best practices with Clean Architecture (Python & C++)
用 Codex 或 Claude 帮你安装 复制这段 Prompt,粘贴到 Codex、Claude 或其他助手里,让它检查 Skill 页面并帮你完成安装。
基于 SOC 职业分类
Author a new asset for this .claude/ template — a rule, skill, slash command, or sub-agent — following the project's conventions and wiring it into the CLAUDE.md / README.md indexes. Trigger when the user wants to add or extend a command, skill, agent, or rule (make the template itself extensible).
Bootstrap a complete ROS 2 colcon workspace from scratch — directory layout, .gitignore, top-level README, this .claude/ config, an interfaces package and a first Clean Architecture package, and a bringup package. Trigger when the user asks to create a new workspace / start a new ROS 2 project from zero.
Scaffold a Behavior Tree leaf node — plain BehaviorTree.CPP (SyncActionNode / StatefulActionNode / ConditionNode) or a BehaviorTree.ROS2 wrapper (RosActionNode / RosServiceNode / RosTopicPubNode / RosTopicSubNode) — with ports, factory/plugin registration, and XML v4 usage. Trigger when the user asks to write a behavior-tree node (not Nav 2-specific).
Scaffold a ros2_control hardware component (SystemInterface / ActuatorInterface / SensorInterface) and its bringup — the plugin (on_init/on_configure/on_activate, RT-safe read()/write()), URDF <ros2_control> wiring, controllers.yaml + launch, pluginlib export. Trigger when the user asks to integrate hardware or bring up a robot under ros2_control.
Scaffold or extend a ros2_control controller or broadcaster (ControllerInterface / ChainableControllerInterface) — base-class choice, command/state interface configuration, lifecycle, real-time-safe update(), generate_parameter_library, pluginlib export, tests. Trigger when the user asks to write a ros2_control controller or broadcaster.
Bridge a VDA 5050 v3.0.0 fleet-control interface (MQTT/JSON) onto Nav 2 under Clean Architecture — domain entities, MQTT/Nav 2 adapters behind ports, order→NavigateThroughPoses mapping, state aggregation, action handlers. Trigger when the user asks to build or extend a VDA 5050 connector / fleet bridge.
| name | ROS2 Messaging Patterns |
| description | ROS2 messaging patterns and best practices with Clean Architecture (Python & C++) |
This skill covers ROS2 messaging patterns adhering to Clean Architecture principles, protecting the domain layer from ROS2 dependencies.
See previous Python example.
// infrastructure/ros2/publishers/state_publisher.hpp
#pragma once
#include <rclcpp/rclcpp.hpp>
#include "domain/entities/robot_state.hpp"
#include "robot_interfaces/msg/robot_state.hpp"
namespace infrastructure::ros2::publishers {
template<typename T>
class IStatePublisher {
public:
virtual void publish(const T& state) = 0;
virtual ~IStatePublisher() = default;
};
class RobotStatePublisher : public IStatePublisher<domain::entities::RobotState> {
public:
RobotStatePublisher(rclcpp::Node::SharedPtr node, const std::string& topic, const rclcpp::QoS& qos)
: node_(node) {
publisher_ = node_->create_publisher<robot_interfaces::msg::RobotState>(topic, qos);
}
void publish(const domain::entities::RobotState& state) override {
robot_interfaces::msg::RobotState msg;
msg.mode = static_cast<int>(state.mode);
// ... mapping ...
publisher_->publish(msg);
}
private:
rclcpp::Node::SharedPtr node_;
rclcpp::Publisher<robot_interfaces::msg::RobotState>::SharedPtr publisher_;
};
} // namespace
// infrastructure/ros2/subscribers/base_subscriber.hpp
#pragma once
#include <rclcpp/rclcpp.hpp>
#include <functional>
namespace infrastructure::ros2::subscribers {
template<typename MsgT, typename EntityT>
class BaseSubscriber {
public:
BaseSubscriber(rclcpp::Node::SharedPtr node,
const std::string& topic,
const rclcpp::QoS& qos,
std::function<void(const EntityT&)> callback)
: callback_(callback) {
subscription_ = node->create_subscription<MsgT>(
topic, qos,
[this](const typename MsgT::SharedPtr msg) {
this->handle_message(msg);
}
);
}
virtual ~BaseSubscriber() = default;
protected:
virtual EntityT convert_to_entity(const typename MsgT::SharedPtr msg) = 0;
private:
void handle_message(const typename MsgT::SharedPtr msg) {
auto entity = convert_to_entity(msg);
callback_(entity);
}
rclcpp::Subscription<MsgT>::SharedPtr subscription_;
std::function<void(const EntityT&)> callback_;
};
} // namespace
Using message_filters in C++.
// infrastructure/ros2/sync/time_sync.hpp
#pragma once
#include <rclcpp/rclcpp.hpp>
#include <message_filters/subscriber.h>
#include <message_filters/sync_policies/approximate_time.h>
#include <message_filters/synchronizer.h>
#include <sensor_msgs/msg/image.hpp>
#include <sensor_msgs/msg/camera_info.hpp>
namespace infrastructure::ros2::sync {
class CameraSync {
public:
CameraSync(rclcpp::Node::SharedPtr node) {
image_sub_.subscribe(node, "image_raw");
info_sub_.subscribe(node, "camera_info");
sync_ = std::make_shared<Sync>(MySyncPolicy(10), image_sub_, info_sub_);
sync_->registerCallback(&CameraSync::callback, this);
}
private:
void callback(const sensor_msgs::msg::Image::ConstSharedPtr& image,
const sensor_msgs::msg::CameraInfo::ConstSharedPtr& info) {
// Handle synchronized messages
}
message_filters::Subscriber<sensor_msgs::msg::Image> image_sub_;
message_filters::Subscriber<sensor_msgs::msg::CameraInfo> info_sub_;
typedef message_filters::sync_policies::ApproximateTime<
sensor_msgs::msg::Image, sensor_msgs::msg::CameraInfo> MySyncPolicy;
typedef message_filters::Synchronizer<MySyncPolicy> Sync;
std::shared_ptr<Sync> sync_;
};
} // namespace
// infrastructure/ros2/events/event_bus.hpp
#pragma once
#include <rclcpp/rclcpp.hpp>
#include <std_msgs/msg/string.hpp>
#include <nlohmann/json.hpp> // External dependency
class EventBus {
public:
EventBus(rclcpp::Node::SharedPtr node) {
pub_ = node->create_publisher<std_msgs::msg::String>("/events/all", 10);
// ... subscriber setup ...
}
void emit(const std::string& type, const nlohmann::json& payload) {
std_msgs::msg::String msg;
nlohmann::json data;
data["type"] = type;
data["payload"] = payload;
msg.data = data.dump();
pub_->publish(msg);
}
private:
rclcpp::Publisher<std_msgs::msg::String>::SharedPtr pub_;
};
std::mutex for shared resources in C++ callbacks.