ROS 2 Engineering Skills

A progressive-disclosure skill for ROS 2 development — from first workspace to

production fleet deployment. Each section below gives you the essential decision

framework; detailed patterns, code templates, and anti-patterns live in the

references/ directory. Read the relevant reference file before writing code.

How to use this skill

1. Identify what the user is building (see Decision Router below).
2. Read the matching references/*.md file for detailed guidance.
3. Apply the Core Engineering Principles in every piece of code you generate.
4. When multiple domains intersect (e.g. Nav2 + ros2_control), read both files.

Decision router

| User is doing... | Read |

|---------------------------------------------------|-----------------------------------|

| Creating a workspace, package, or build config | references/workspace-build.md |

| Writing nodes, executors, callback groups | references/nodes-executors.md |

| Topics, services, actions, custom interfaces, QoS | references/communication.md |

| Lifecycle nodes, component loading, composition | references/lifecycle-components.md |

| Launch files, conditional logic, event handlers | references/launch-system.md |

| tf2, URDF, xacro, robot_state_publisher | references/tf2-urdf.md |

| ros2_control, hardware interfaces, controllers | references/hardware-interface.md |

| Real-time constraints, PREEMPT_RT, memory, jitter | references/realtime.md |

| Nav2, SLAM, costmaps, behavior trees | references/navigation.md |

| MoveIt 2, planning scene, grasp pipelines | references/manipulation.md |

| Camera, LiDAR, PCL, cv_bridge, depth processing | references/perception.md |

| Unit tests, integration tests, launch_testing, CI | references/testing.md |

| ros2 doctor, tracing, profiling, rosbag2 | references/debugging.md |

| Docker, cross-compile, fleet deployment, OTA | references/deployment.md |

| Gazebo, Isaac Sim, sim-to-real, use_sim_time | references/simulation.md |

| SROS2, DDS security, certificates, supply chain | references/security.md |

| micro-ROS, MCU/RTOS, XRCE-DDS, rclc | references/micro-ros.md |

| Multi-robot fleet, Open-RMF, DDS discovery scale | references/multi-robot.md |

| Message types, units, covariance, frame conventions | references/message-types.md |

| ROS 1 migration, ros1_bridge, hybrid operation | references/migration-ros1.md |

When a task spans multiple domains, read all relevant files and reconcile

conflicting recommendations by favoring safety, then determinism, then simplicity.

Cross-cutting concern — Security: Security is not isolated to references/security.md.

Every domain should consider its security implications: hardware interfaces need safe

shutdown on auth failure, DDS topics may need encryption, deployment images need supply

chain verification, and fleet communication must use TLS. When reviewing code in any

domain, check whether the data path crosses a trust boundary.

Core engineering principles

These apply to every ROS 2 artifact you produce, regardless of domain.

1. Distro awareness

Always ask which ROS 2 distribution the user targets. Key differences:

| Feature | Foxy (EOL) | Humble (LTS) | Jazzy (LTS) | Kilted (non-LTS) | Rolling |

|---------------------------|----------------------|--------------------|--------------------|--------------------|--------------------|

| EOL | Jun 2023 (ended) | May 2027 | May 2029 | Nov 2025 | Rolling |

| Ubuntu | 20.04 | 22.04 | 24.04 | 24.04 | Latest |

| Default DDS | Fast DDS | Fast DDS | Fast DDS | Fast DDS | Fast DDS |

| Zenoh support | — | — | — | Tier 1 | Tier 1 |

| Type description support | No | No | Yes | Yes | Yes |

| Service introspection | No | No | Yes | Yes | Yes |

| EventsExecutor | No | No | Experimental | Stable (+ rclpy) | Stable (+ rclpy) |

| Default bag format | sqlite3 | sqlite3 | MCAP | MCAP | MCAP |

| ros2_control interface | N/A (separate) | 2.x | 4.x | 4.x | Latest |

| CMake recommendation | ament_target_deps | ament_target_deps | either | target_link_libs | target_link_libs |

When the user does not specify, default to the latest LTS (Jazzy).

Pin the exact distro in Dockerfile, CI, and documentation so builds are reproducible.

2. C++ vs Python decision

Choose the language based on the node's role, not personal preference.

Use rclcpp (C++) when:

• The node sits in a control loop running ≥100 Hz
• Deterministic memory allocation matters (real-time path)
• The node is a hardware driver or controller plugin
• Intra-process zero-copy communication is required

Use rclpy (Python) when:

• The node is orchestration, monitoring, or parameter management
• Rapid prototyping with frequent iteration
• Heavy use of ML frameworks (PyTorch, TensorFlow) that are Python-native
• The node does not sit in a latency-critical path

Mixed stacks are normal. A typical robot has C++ drivers/controllers and Python

orchestration/monitoring. Note: component_container (composition) only loads

C++ components via pluginlib. Python nodes run as separate processes, but can

share a launch file and communicate via zero-overhead intra-host DDS.

Intra-process communication works for any nodes sharing a process — not only

composable components. Any nodes instantiated in the same process with

use_intra_process_comms(true) can use zero-copy transfer.

3. Package structure conventions

Every package should follow this layout. Consistency across a workspace reduces

onboarding time and makes CI scripts portable.

my_package/
├── CMakeLists.txt          # or setup.py for pure Python
├── package.xml             # format 3, with <depend> tags
├── config/
│   └── params.yaml         # default parameters
├── launch/
│   └── bringup.launch.py   # Python launch file
├── include/my_package/     # C++ public headers (if library)
├── src/                    # C++ source files
├── my_package/             # Python modules (if ament_python or mixed)
├── test/                   # gtest, pytest, launch_testing
├── urdf/                   # URDF/xacro (if applicable)
├── msg/ srv/ action/       # custom interfaces (dedicated _interfaces package preferred)
└── README.md

Separate interface definitions into a *_interfaces package so downstream

packages can depend on interfaces without pulling in implementation.

4. Parameter discipline

• Declare every parameter with a type, description, range, and default

in the node constructor — never use undeclared parameters.

• Use ParameterDescriptor with FloatingPointRange or IntegerRange

for numeric bounds. The parameter server rejects out-of-range values at set time.

• Group related parameters under a namespace prefix:

controller.kp, controller.ki, controller.kd.

• Load defaults from a config/params.yaml; allow launch-time overrides.
• For dynamic reconfiguration, register a set_parameters_callback and

validate new values atomically before accepting.

5. Error handling philosophy

• Nodes must not silently swallow errors. Log at the appropriate severity,

then take a safe action (stop motion, request help, transition to error state).

• Prefer lifecycle node error transitions over ad-hoc boolean flags.
• When calling a service, always handle the "service not available" and

"future timed out" cases explicitly.

• For hardware drivers, distinguish transient errors (retry with backoff)

from fatal errors (transition to FINALIZED and alert the operator).

6. Quality of Service defaults

Start from these profiles and adjust per use case:

| Use case | Reliability | Durability | History | Depth | Deadline | Lifespan |

|-----------------------|---------------|------------------|---------|-------|-------------|-------------|

| Sensor stream | BEST_EFFORT | VOLATILE | KEEP_LAST | 5 | — | — |

| Command velocity | RELIABLE | VOLATILE | KEEP_LAST | 1 | 100 ms | 200 ms |

| Map (latched) | RELIABLE | TRANSIENT_LOCAL | KEEP_LAST | 1 | — | — |

| Diagnostics | RELIABLE | VOLATILE | KEEP_LAST | 10 | — | — |

| Parameter events | RELIABLE | VOLATILE | KEEP_LAST | 1000| — | — |

| Action feedback | RELIABLE | VOLATILE | KEEP_LAST | 1 | — | — |

| Safety heartbeat | RELIABLE | VOLATILE | KEEP_LAST | 1 | 500 ms | 1 s |

QoS mismatches are the #1 cause of "I published but nobody receives."

Always check compatibility with ros2 topic info -v when debugging.

DEADLINE and LIFESPAN are critical for safety-critical systems. DEADLINE fires an

event when no message arrives within the specified period (detect stale data). LIFESPAN

discards messages older than the specified duration before delivery (prevent acting on

stale data). See references/communication.md section 9 for full API and examples.

7. Naming conventions

| Entity | Convention | Example |

|-------------|-----------------------------|--------------------------------|

| Package | snake_case | arm_controller |

| Node | snake_case | joint_state_broadcaster |

| Topic | /snake_case with ns | /arm/joint_states |

| Service | /snake_case | /arm/set_mode |

| Action | /snake_case | /arm/follow_joint_trajectory |

| Parameter | snake_case with dot ns | controller.publish_rate |

| Frame | snake_case | base_link, camera_optical |

| Interface | PascalCase.msg/srv/action | JointState.msg |

8. Thread safety and callbacks

• A MutuallyExclusiveCallbackGroup serializes its callbacks — safe for

shared state without locks, but limits throughput.

• A ReentrantCallbackGroup allows parallel execution — you must protect

shared state with std::mutex (C++) or threading.Lock (Python).

• Calling a service from a callback: The service client must be in a

separate MutuallyExclusiveCallbackGroup from the calling callback. Otherwise

the executor deadlocks — the callback waits for the response while the executor

cannot deliver it. Always use async_send_request with a response callback;

never use spin_until_future_complete inside an executor callback.

• Never do blocking work (file I/O, long computation, sleep) inside a

timer or subscription callback on the default executor. Offload to a

dedicated thread or use a MultiThreadedExecutor with a reentrant group.

• In rclcpp, prefer std::shared_ptr in subscription

callbacks to avoid unnecessary copies and enable zero-copy intra-process.

9. Lifecycle-first design

Default to lifecycle (managed) nodes for anything that owns resources:

hardware drivers, sensor pipelines, planners, controllers.

                 ┌──────────────┐
  create() ──►  │  Unconfigured │
                 └──────┬───────┘
            on_configure │
                 ┌──────▼───────┐
                 │   Inactive    │
                 └──────┬───────┘
            on_activate  │
                 ┌──────▼───────┐
                 │    Active     │
                 └──────┬───────┘
           on_deactivate │
                 ┌──────▼───────┐
                 │   Inactive    │
                 └──────┬───────┘
            on_cleanup   │
                 ┌──────▼───────┐
                 │  Unconfigured │
                 └──────┬───────┘
           on_shutdown   │
                 ┌──────▼───────┐
                 │   Finalized   │
                 └───────────────┘

This gives the system manager (launch file, orchestrator, or operator) explicit

control over when resources are allocated, when the node starts processing,

and how it shuts down. It also makes error recovery predictable.

10. Build and CI hygiene

• Use colcon build --cmake-args -DCMAKE_BUILD_TYPE=RelWithDebInfo for

development; Release for deployment.

• Enable -Wall -Wextra -Wpedantic and treat warnings as errors in CI.
• Run colcon test with --event-handlers console_cohesion+ so test

output groups by package.

• Pin rosdep keys in rosdep.yaml for reproducible dependency resolution.
• Cache /opt/ros/, .ccache/, and build//install/ in CI to cut build

times by 60–80%.

Common anti-patterns

| Anti-pattern | Why it hurts | Fix |

|---|---|---|

| Global variables for node state | Breaks composition, untestable | Store state as class members |

| spin() in main() for multi-node processes | Starves other nodes | Use MultiThreadedExecutor or component composition |

| Hardcoded topic names | Breaks reuse across robots | Use relative names + namespace remapping |

| KEEP_ALL history with no bound | Memory grows unbounded on slow subscribers | Use KEEP_LAST with explicit depth |

| Using time.sleep() / std::this_thread::sleep_for | Blocks the executor thread | Use create_wall_timer or a dedicated thread |

| Monolithic launch file for everything | Unmanageable past 10 nodes | Compose launch files with IncludeLaunchDescription |

| Skipping package.xml dependencies | Builds locally, breaks CI and Docker | Declare every dependency explicitly |

| Publishing in constructor | Subscribers may not be ready, messages lost | Publish in on_activate or after a short timer |

| Ignoring QoS compatibility | Silent communication failure | Match publisher/subscriber QoS or check with ros2 topic info -v |

| Creating timers/subs in callbacks | Resource leak, unpredictable behavior | Create all entities in constructor or on_configure |

| Synchronous service call in callback | Deadlocks the executor thread | Use async_send_request with a callback or dedicated thread |

| Service client in same callback group as caller | Deadlocks even with async in MultiThreadedExecutor | Put service client in a separate MutuallyExclusiveCallbackGroup |

| No safe command on shutdown | Motors hold last velocity after node exits | Send zero-velocity in on_deactivate AND destructor (see references/hardware-interface.md) |

| Dynamic subscriptions with StaticSingleThreadedExecutor | New subs are never picked up after spin() | Use SingleThreadedExecutor or MultiThreadedExecutor for dynamic entities |

| CPU frequency governor left on powersave/ondemand | 10-100 ms latency spikes in RT path | Set performance governor, disable turbo boost (see references/realtime.md) |

Distro-specific migration notes

When upgrading between distributions, check these breaking changes first:

Foxy → Humble:

• Complete API overhaul. Foxy packages require significant rework.
• ros2_control was not bundled in Foxy — must be built separately.
• Lifecycle node API stabilized in Humble.
• Action server/client API changed significantly.

Humble → Jazzy:

• ros2_control API changed from 2.x to 4.x — export_state_interfaces() and

export_command_interfaces() are now auto-generated by the framework. Manual

overrides use on_export_state_interfaces(). See references/hardware-interface.md.

• Handle get_value() deprecated → use get_optional() on LoanedStateInterface /

LoanedCommandInterface (controller side). Hardware interfaces use set_state() /

get_state() / set_command() / get_command() helpers with fully qualified names.

• All joints in tag must exist in the URDF.
• Controller parameter loading changed — use --param-file with spawner.
• Default bag format changed from sqlite3 to MCAP. Use storage_id='mcap'.
• Default middleware changed internal config paths. Regenerate DDS profiles.
• nav2_params.yaml schema changes — recoveries_server renamed to behavior_server.
• ROS_AUTOMATIC_DISCOVERY_RANGE replaces ROS_LOCALHOST_ONLY (values: LOCALHOST,

SUBNET, OFF, SYSTEM_DEFAULT).

• launch_ros actions have new parameter handling — test launch files explicitly.

Jazzy → Kilted (non-LTS):

• Zenoh promoted to Tier 1 middleware — rmw_zenoh is production-ready.

Install: sudo apt install ros-kilted-rmw-zenoh-cpp, set

RMW_IMPLEMENTATION=rmw_zenoh_cpp. Supports router/peer/client modes.

• EventsExecutor graduated from experimental — available in rclcpp::executors

(no experimental namespace). Also ported to rclpy.

• ament_target_dependencies() deprecated — use target_link_libraries() with

modern CMake targets (e.g. rclcpp::rclcpp, std_msgs::std_msgs__rosidl_typesupport_cpp).

• Multi-bag replay support in ros2 bag play.
• Gazebo Ionic is the paired simulator (Harmonic was Jazzy; Ionic is the Kilted pairing).

ROS 1 → ROS 2:

• See references/migration-ros1.md for a step-by-step strategy.

Quick reference — ros2 CLI

# Workspace
colcon build --symlink-install --packages-select my_pkg
colcon test --packages-select my_pkg
colcon graph --dot                       # dependency graph (DOT format)
source install/setup.bash

# Introspection
ros2 node list
ros2 topic list -t
ros2 topic info /topic_name -v          # shows QoS details
ros2 topic hz /topic_name
ros2 topic bw /topic_name
ros2 service list -t
ros2 action list -t
ros2 param list /node_name
ros2 param describe /node_name param
ros2 interface show std_msgs/msg/String

# ros2_control
ros2 control list_controllers
ros2 control list_hardware_interfaces
ros2 control list_hardware_components

# Debugging
ros2 doctor --report                    # alias: ros2 wtf
ros2 run tf2_tools view_frames
ros2 bag record -a -o my_bag
ros2 bag info my_bag
ros2 bag play my_bag --clock

# Lifecycle
ros2 lifecycle list /node_name
ros2 lifecycle set /node_name configure
ros2 lifecycle set /node_name activate