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# checker-dummy - How to Build a happyDomain Checker
This repository is a **fully working, educational example** of a happyDomain checker. It is intentionally simple: instead of performing real monitoring, it returns a random score and a user-configurable message. This lets you focus on learning the structure without dealing with external dependencies.
Use this as a template when you create your own checker.
---
## Table of Contents
1. [What is a Checker?](#what-is-a-checker)
2. [Architecture Overview](#architecture-overview)
3. [Repository Structure](#repository-structure)
4. [Step-by-Step Walkthrough](#step-by-step-walkthrough)
- [Step 1: Define Your Data Types](#step-1-define-your-data-types)
- [Step 2: Create the Provider](#step-2-create-the-provider)
- [Step 3: Implement Data Collection](#step-3-implement-data-collection)
- [Step 4: Describe Your Checker (Definition)](#step-4-describe-your-checker-definition)
- [Step 5: Write Evaluation Rules](#step-5-write-evaluation-rules)
- [Step 6: Wire It Up (main.go)](#step-6-wire-it-up-maingo)
- [Step 7: Create the Plugin Entrypoint](#step-7-create-the-plugin-entrypoint)
5. [Running the Checker](#running-the-checker)
6. [Testing with curl](#testing-with-curl)
7. [Deploying to happyDomain](#deploying-to-happydomain)
8. [License & happyDomain compatibility](#license--happydomain-compatibility)
9. [Going Further](#going-further)
---
## What is a Checker?
A **checker** is a small, self-contained program that monitors one aspect of a domain's DNS infrastructure. happyDomain runs checkers periodically and displays their results in its dashboard.
Every checker does three things:
1. **Collect:** Gather raw observation data (e.g., ping a server, query an API, measure DNS response time).
2. **Evaluate:** Compare the collected data against user-defined thresholds to produce a status: OK, Warning, or Critical.
3. **Report** *(optional)*: Extract time-series metrics or generate HTML reports for the dashboard.
## Architecture Overview
A checker can run in three modes:
### Standalone HTTP Server (External Checker)
The checker runs as its own process and exposes an HTTP API. happyDomain communicates with it over the network. This is the most flexible option: you can write your checker in any language, deploy it independently, and scale it separately.
```
┌─────────────┐ HTTP ┌─────────────────┐
│ happyDomain │ ──────────► │ checker-dummy │
│ server │ ◄────────── │ (this program) │
└─────────────┘ └─────────────────┘
```
### In-Process Plugin
The checker is compiled as a Go plugin (`.so` file) and loaded directly into the happyDomain process. This is simpler to deploy (single binary) but requires the checker to be written in Go.
```
┌──────────────────────────────────────┐
│ happyDomain server │
│ │
│ ┌──────────────────────────────┐ │
│ │ checker-dummy.so (plugin) │ │
│ │ checker-ping.so (plugin) │ │
│ │ checker-matrix.so (plugin) │ │
│ │ checker-....so (plugin) │ │
│ └──────────────────────────────┘ │
└──────────────────────────────────────┘
```
### Built-in Checker
The checker package can be imported directly into the happyDomain server and registered at init time: no plugin loading, no separate process. This avoids the operational burden of Go's plugin system (matching toolchain versions, CGO, `.so` distribution) entirely.
```go
// happydomain/checkers/ping.go
package checkers
import (
ping "git.happydns.org/checker-ping/checker"
"git.happydns.org/internal/checker"
)
func init() {
checker.RegisterObservationProvider(ping.Provider())
checker.RegisterExternalizableChecker(ping.Definition())
}
```
This mode is reserved for checkers maintained as part of the happyDomain project itself. Or if you compile yourself your own version of happyDomain.
**Both standalone, plugin and built-in modes use the same checker code; only the entry point differs.**
## Repository Structure
```
checker-dummy/
├── main.go # Entry point for standalone HTTP server mode
├── checker/
│ ├── types.go # Data structures (what the checker observes)
│ ├── provider.go # The provider: glues everything together
│ ├── collect.go # Collection logic (the actual monitoring)
│ ├── definition.go # Checker metadata (options, rules, intervals)
│ └── rule.go # Evaluation rules (OK / Warning / Critical)
├── plugin/
│ └── plugin.go # Entry point for plugin mode
├── go.mod # Go module definition
├── Makefile # Build targets
├── Dockerfile # Container image
└── .gitignore
```
Each file has a single, clear responsibility. This is the recommended layout for all happyDomain checkers.
---
## Step-by-Step Walkthrough
### Step 1: Define Your Data Types
**File: `checker/types.go`**
Start by defining the data structure that your checker will produce during collection. This struct is serialised to JSON by the SDK, stored by happyDomain, and later deserialised during evaluation.
```go
const ObservationKeyDummy = "dummy"
type DummyData struct {
Message string `json:"message"`
Score float64 `json:"score"`
CollectedAt time.Time `json:"collected_at"`
}
```
Key points:
- **`ObservationKeyDummy`** is a unique string that identifies observations produced by this checker. Every checker needs at least one key.
- **Design for evaluation**: include everything your rules will need to decide OK/Warning/Critical. The evaluation step only sees this struct; it cannot re-collect data.
### Step 2: Create the Provider
**File: `checker/provider.go`**
The **provider** is the central object of your checker. It must implement the `ObservationProvider` interface:
```go
type ObservationProvider interface {
Key() ObservationKey
Collect(ctx context.Context, opts CheckerOptions) (any, error)
}
```
You can also implement optional interfaces to unlock additional features:
| Interface | What it enables |
|-------------------------------|------------------------------------------|
| `CheckerDefinitionProvider` | `/definition` and `/evaluate` endpoints |
| `CheckerMetricsReporter` | `/report` endpoint (JSON metrics) |
| `CheckerHTMLReporter` | `/report` endpoint (HTML) |
In this example, we implement all three optional interfaces:
```go
type dummyProvider struct{}
func (p *dummyProvider) Key() ObservationKey { return ObservationKeyDummy }
func (p *dummyProvider) Definition() *CheckerDefinition { return Definition() }
func (p *dummyProvider) ExtractMetrics(raw json.RawMessage, collectedAt time.Time) ([]CheckMetric, error) { ... }
```
The `Key()` method must return the same string as your `ObservationKeyDummy` constant.
### Step 3: Implement Data Collection
**File: `checker/collect.go`**
This is where the real work happens. The `Collect` method is called every time happyDomain runs your check.
```go
func (p *dummyProvider) Collect(ctx context.Context, opts CheckerOptions) (any, error) {
// Read options using SDK helpers
message := "Hello from the dummy checker!"
if v, ok := sdk.GetOption[string](opts, "message"); ok && v != "" {
message = v
}
// Do your monitoring work here!
// In a real checker, you would: ping a server, query an API,
// measure DNS response time, check TLS certificates, etc.
score := rand.Float64() * 100
return &DummyData{
Message: message,
Score: score,
CollectedAt: time.Now(),
}, nil
}
```
Key points:
- **Always honour `ctx`**: happyDomain may cancel long-running checks.
- **Use SDK option helpers** (`sdk.GetOption`, `sdk.GetFloatOption`, `sdk.GetIntOption`, `sdk.GetBoolOption`) to read options. They handle type coercion between in-process (native Go types) and HTTP mode (JSON-decoded types).
- **Return your data struct**: the SDK serialises it to JSON automatically.
- **Return an error** only if collection failed entirely. Partial results are fine.
### Step 4: Describe Your Checker (Definition)
**File: `checker/definition.go`**
The `CheckerDefinition` tells happyDomain everything about your checker:
```go
func Definition() *CheckerDefinition {
return &CheckerDefinition{
ID: "dummy", // Unique, stable identifier (never change after release)
Name: "Dummy (example)", // Human-readable label for the UI
Version: Version, // Optional; injected at build time via -ldflags
Availability: CheckerAvailability{
ApplyToDomain: true, // Show in the "Domain checks" section
},
ObservationKeys: []ObservationKey{ObservationKeyDummy},
Options: CheckerOptionsDocumentation{
UserOpts: []CheckerOptionDocumentation{
{Id: "message", Type: "string", Label: "Custom message", Default: "Hello!"},
{Id: "warningThreshold", Type: "number", Label: "Warning threshold", Default: float64(50)},
...
},
},
Rules: []CheckRule{Rule()},
Interval: &CheckIntervalSpec{
Min: 1 * time.Minute, Max: 1 * time.Hour, Default: 5 * time.Minute,
},
HasMetrics: true,
}
}
```
**Version**: declare a package-level `var Version = "built-in"` in your checker package and reference it from the definition. The default is fine when the package is imported directly (built-in or plugin mode). For the standalone binary, declare a separate `var Version = "custom-build"` in `main.go` and propagate it in `init()`:
```go
// main.go
var Version = "custom-build"
func init() {
dummy.Version = Version
}
```
The CI can then override the standalone binary's version with a simple flag, without having to know the nested package path:
```bash
go build -ldflags "-X main.Version=$(git describe --tags)" .
```
**Availability**: choose where your checker appears:
| Field | When to use |
|------------------|-----------------------------------------------------|
| `ApplyToDomain` | The check applies to the entire domain |
| `ApplyToZone` | The check applies to a specific DNS zone |
| `ApplyToService` | The check applies to a specific service (e.g., A/AAAA records). Use `LimitToServices` to restrict which service types. |
**Options**: grouped by audience:
| Group | Who sets it | Example |
|---------------|----------------------|--------------------------------------|
| `AdminOpts` | happyDomain admin | API endpoint URL |
| `UserOpts` | End-user in the UI | Thresholds, count, custom messages |
| `DomainOpts` | Auto-filled per domain | `domain_name` (via `AutoFill`) |
| `ServiceOpts` | Auto-filled per service | The service payload (via `AutoFill`) |
| `RunOpts` | Set at collect-time | Runtime overrides |
**Option types** for the UI widget: `"string"`, `"number"`, `"uint"`, `"bool"`. You can also provide `Choices` for dropdown menus.
### Step 5: Write Evaluation Rules
**File: `checker/rule.go`**
A rule implements the `CheckRule` interface:
```go
type CheckRule interface {
Name() string
Description() string
Evaluate(ctx context.Context, obs ObservationGetter, opts CheckerOptions) CheckState
}
```
Optionally, your rule can also implement `ValidateOptions(opts) error` for early validation.
The `Evaluate` method receives an `ObservationGetter` to retrieve the collected data:
```go
func (r *dummyRule) Evaluate(ctx context.Context, obs ObservationGetter, opts CheckerOptions) CheckState {
var data DummyData
if err := obs.Get(ctx, ObservationKeyDummy, &data); err != nil {
return CheckState{Status: StatusError, Message: "..."}
}
warningThreshold := sdk.GetFloatOption(opts, "warningThreshold", 50)
criticalThreshold := sdk.GetFloatOption(opts, "criticalThreshold", 20)
switch {
case data.Score < criticalThreshold:
return CheckState{Status: StatusCrit, ...}
case data.Score < warningThreshold:
return CheckState{Status: StatusWarn, ...}
default:
return CheckState{Status: StatusOK, ...}
}
}
```
**Status values**: `StatusOK`, `StatusWarn`, `StatusCrit`, `StatusError`, `StatusUnknown`.
You can define **multiple rules** per checker. Each rule evaluates the same collected data from a different angle. Users can enable/disable rules individually in the UI.
### Step 6: Wire It Up (main.go)
**File: `main.go`**
The standalone entry point is minimal; the SDK does all the heavy lifting:
```go
func main() {
flag.Parse()
// Propagate the plugin's version to the checker package.
dummy.Version = Version
server := sdk.NewServer(dummy.Provider())
server.ListenAndServe(*listenAddr)
}
```
`sdk.NewServer` inspects your provider and automatically registers HTTP endpoints based on which interfaces it implements:
| Endpoint | Always | Requires |
|--------------------|--------|------------------------------|
| `GET /health` | Yes | - |
| `POST /collect` | Yes | - |
| `GET /definition` | - | `CheckerDefinitionProvider` |
| `POST /evaluate` | - | `CheckerDefinitionProvider` |
| `POST /report` | - | `CheckerMetricsReporter` or `CheckerHTMLReporter` |
### Step 7: Create the Plugin Entrypoint
**File: `plugin/plugin.go`**
For in-process plugin mode, the entrypoint must be a `package main` that exposes a `NewCheckerPlugin` symbol. happyDomain opens the `.so` file with `plugin.Open`, looks up that symbol, and calls it to obtain the checker definition and its observation provider, which the host then registers in its own global registries.
```go
package main
import (
sdk "git.happydns.org/checker-sdk-go/checker"
dummy "git.happydns.org/checker-dummy/checker"
)
var Version = "custom-build"
func NewCheckerPlugin() (*sdk.CheckerDefinition, sdk.ObservationProvider, error) {
// Propagate the plugin's version to the checker package.
dummy.Version = Version
return dummy.Definition(), dummy.Provider(), nil
}
```
Build the plugin with:
```bash
go build -buildmode=plugin -o checker-dummy.so ./plugin
```
Then drop the resulting `checker-dummy.so` into one of happyDomain's configured plugin directories. It will be picked up at startup.
---
## Running the Checker
### Build and run locally
```bash
make build
./checker-dummy -listen :8080
```
### Docker
```bash
make docker
docker run -p 8080:8080 happydomain/checker-dummy
```
---
## Testing with curl
### Health check
```bash
curl http://localhost:8080/health
# {"status":"ok"}
```
### Get the checker definition
```bash
curl http://localhost:8080/definition
```
### Collect an observation
```bash
curl -X POST http://localhost:8080/collect \
-H "Content-Type: application/json" \
-d '{
"key": "dummy",
"options": {
"message": "Testing my checker!"
}
}'
```
Response:
```json
{
"data": {
"message": "Testing my checker!",
"score": 73.2,
"collected_at": "2026-01-15T10:30:00Z"
}
}
```
### Evaluate observations
```bash
curl -X POST http://localhost:8080/evaluate \
-H "Content-Type: application/json" \
-d '{
"observations": {
"dummy": "{\"message\":\"test\",\"score\":42.5,\"collected_at\":\"2026-01-15T10:30:00Z\"}"
},
"options": {
"warningThreshold": 50,
"criticalThreshold": 20
}
}'
```
Response (score 42.5 is below the warning threshold of 50):
```json
{
"states": [
{
"status": 3,
"message": "Score: 42.5 - test",
"code": "dummy_score_check"
}
]
}
```
Status codes: `1` = OK, `3` = Warning, `4` = Critical.
### Extract metrics
```bash
curl -X POST http://localhost:8080/report \
-H "Content-Type: application/json" \
-d '{
"data": "{\"message\":\"test\",\"score\":73.2,\"collected_at\":\"2026-01-15T10:30:00Z\"}"
}'
```
---
## Deploying to happyDomain
### As an external checker (recommended)
1. Deploy your checker as a standalone service (Docker, systemd, etc.).
2. In happyDomain, set the checker's `endpoint` admin option to its URL (e.g., `http://checker-dummy:8080`).
3. happyDomain will call `/collect`, `/evaluate`, and `/report` automatically.
### As an in-process plugin
1. Build the plugin:
```bash
go build -buildmode=plugin -o checker-dummy.so ./plugin
```
2. Copy `checker-dummy.so` into one of the directories listed in happyDomain's `PluginsDirectories` configuration.
3. Restart happyDomain. At startup it scans those directories, opens each `.so`, looks up the `NewCheckerPlugin` symbol, and registers the returned definition and provider.
---
## License & happyDomain compatibility
This template is released under the **MIT License**, so you're free to use it as a starting point for any checker, including proprietary ones.
The types and helpers your checker depends on live in [`checker-sdk-go`](https://git.happydns.org/checker-sdk-go), a separate module released under the **Apache License 2.0**. happyDomain itself depends on the same SDK, so plugins and the host share a common, permissively licensed contract instead of linking against AGPL code.
**What this means for the deployment mode you choose:**
- **Standalone HTTP checker:** your checker is a separate process communicating with happyDomain over the network. It is *not* a derivative work of happyDomain and you can license it however you want (proprietary, MIT, GPL, anything).
- **In-process plugin (`.so`):** your checker is loaded into the happyDomain process via `plugin.Open`, but it only links against the Apache-licensed SDK — not against any AGPL code. You are free to license your plugin however you want.
- **Built-in checker** (imported directly into the happyDomain source tree): same as above on the linking side. Built-in checkers maintained inside the happyDomain repository are conventionally distributed under AGPL-3.0 to stay consistent with the rest of the project, but this is a project policy, not a legal requirement coming from the SDK.
If your checker imports anything *else* from the happyDomain repository (for example service abstractions like `happydns.ServiceMessage`), then that code *is* AGPL-licensed and the AGPL constraint comes back. The SDK alone is safe; the rest of happyDomain is not.
---
## Going Further
Now that you understand the structure, here are ideas for your own checker:
- **SMTP checker:** connect to a mail server and verify it responds correctly to EHLO.
- **DNS checker:** query specific DNS record types and verify the response matches expectations.
- **HTTP checker:** send an HTTP request to a domain's web server and check the status code, response time, ...
- **Business logic:** probe your own application from the outside and verify it behaves as expected, e.g. log into your SaaS with a synthetic account and check that the dashboard loads, place a test order and confirm it reaches the order pipeline, hit an internal health endpoint that aggregates queue depth / worker lag / replication status, or check that a license server still hands out valid tokens. This turns happyDomain into a lightweight synthetic-monitoring dashboard for your own services.
For a real-world example, look at [checker-ping](https://git.happydns.org/checker-ping), which implements ICMP ping monitoring with multiple targets, packet loss detection, and RTT metrics.
### Tips
- Keep `Collect` focused on data gathering. Put all threshold logic in `Evaluate`.
- Design your data struct to hold everything rules need; evaluation cannot re-collect.
- Use `sdk.GetFloatOption` / `sdk.GetIntOption` / `sdk.GetBoolOption` instead of raw type assertions. They handle the JSON/native type mismatch transparently.
- Always honour the `context.Context`: set timeouts and check for cancellation.
- Return partial results from `Collect` when possible (only return an error if the entire collection failed).