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spike: Working on abstractions, Topology, Score, Capability, Maestro for strong type safety and nice UX/DX

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Jean-Gabriel Gill-Couture 2025-03-25 08:03:45 -04:00
parent 2433c02de9
commit 3962238f0d
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10
examples/topology/Cargo.toml Normal file
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[package]
name = "example-topology"
edition = "2024"
version.workspace = true
readme.workspace = true
license.workspace = true
publish = false
[dependencies]
rand.workspace = true

332
examples/topology/src/main.rs Normal file
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use std::process::Command;
use rand::Rng; // Add rand dependency
// ===== Capability Traits =====
/// Base trait for all capabilities
pub trait Capability {}
/// Capability for executing shell commands on a host
pub trait CommandCapability: Capability {
fn execute_command(&self, command: &str, args: &[&str]) -> Result<String, String>;
}
/// Capability for interacting with a Kubernetes cluster
pub trait KubernetesCapability: Capability {
fn apply_manifest(&self, manifest: &str) -> Result<(), String>;
fn get_resource(&self, resource_type: &str, name: &str) -> Result<String, String>;
}
// ===== Topology Traits =====
/// Base trait for all topologies
pub trait Topology {
// Base topology methods that don't depend on capabilities
fn name(&self) -> &str;
}
// ===== Score Traits =====
/// Generic Score trait with an associated Capability type
pub trait Score<T: Topology> {
fn apply(&self, topology: &T) -> Result<(), String>;
fn name(&self) -> &str;
}
// ===== Concrete Topologies =====
/// A topology representing a Linux host
pub struct LinuxHostTopology {
name: String,
host: String,
}
// Implement the base Capability trait for LinuxHostTopology
impl Capability for LinuxHostTopology {}
impl LinuxHostTopology {
pub fn new(name: String, host: String) -> Self {
Self { name, host }
}
}
impl Topology for LinuxHostTopology {
fn name(&self) -> &str {
&self.name
}
}
impl CommandCapability for LinuxHostTopology {
fn execute_command(&self, command: &str, args: &[&str]) -> Result<String, String> {
println!("Executing on {}: {} {:?}", self.host, command, args);
// In a real implementation, this would SSH to the host and execute the command
let output = Command::new(command)
.args(args)
.output()
.map_err(|e| e.to_string())?;
if output.status.success() {
Ok(String::from_utf8_lossy(&output.stdout).to_string())
} else {
Err(String::from_utf8_lossy(&output.stderr).to_string())
}
}
}
/// A topology representing a K3D Kubernetes cluster
pub struct K3DTopology {
name: String,
linux_host: LinuxHostTopology,
cluster_name: String,
}
// Implement the base Capability trait for K3DTopology
impl Capability for K3DTopology {}
impl K3DTopology {
pub fn new(name: String, linux_host: LinuxHostTopology, cluster_name: String) -> Self {
Self {
name,
linux_host,
cluster_name,
}
}
}
impl Topology for K3DTopology {
fn name(&self) -> &str {
&self.name
}
}
impl CommandCapability for K3DTopology {
fn execute_command(&self, command: &str, args: &[&str]) -> Result<String, String> {
// Delegate to the underlying Linux host
self.linux_host.execute_command(command, args)
}
}
impl KubernetesCapability for K3DTopology {
fn apply_manifest(&self, manifest: &str) -> Result<(), String> {
println!("Applying manifest to K3D cluster '{}'", self.cluster_name);
// Write manifest to a temporary file
//let temp_file = format!("/tmp/manifest-{}.yaml", rand::thread_rng().gen::<u32>());
let temp_file = format!("/tmp/manifest-TODO_RANDOM_NUMBER.yaml");
// Use the linux_host directly to avoid capability trait bounds
self.linux_host.execute_command("bash", &["-c", &format!("cat > {}", temp_file)])?;
// Apply with kubectl
self.linux_host.execute_command(
"kubectl",
&["--context", &format!("k3d-{}", self.cluster_name), "apply", "-f", &temp_file]
)?;
Ok(())
}
fn get_resource(&self, resource_type: &str, name: &str) -> Result<String, String> {
println!("Getting resource {}/{} from K3D cluster '{}'", resource_type, name, self.cluster_name);
self.linux_host.execute_command(
"kubectl",
&[
"--context",
&format!("k3d-{}", self.cluster_name),
"get",
resource_type,
name,
"-o",
"yaml",
]
)
}
}
// ===== Concrete Scores =====
/// A score that executes commands on a topology
pub struct CommandScore {
name: String,
command: String,
args: Vec<String>,
}
impl CommandScore {
pub fn new(name: String, command: String, args: Vec<String>) -> Self {
Self { name, command, args }
}
}
impl<T> Score<T> for CommandScore
where
T: Topology + CommandCapability
{
fn apply(&self, topology: &T) -> Result<(), String> {
println!("Applying CommandScore '{}' to topology '{}'", self.name, topology.name());
let args_refs: Vec<&str> = self.args.iter().map(|s| s.as_str()).collect();
topology.execute_command(&self.command, &args_refs)?;
Ok(())
}
fn name(&self) -> &str {
&self.name
}
}
/// A score that applies Kubernetes resources to a topology
pub struct K8sResourceScore {
name: String,
manifest: String,
}
impl K8sResourceScore {
pub fn new(name: String, manifest: String) -> Self {
Self { name, manifest }
}
}
impl<T> Score<T> for K8sResourceScore
where
T: Topology + KubernetesCapability
{
fn apply(&self, topology: &T) -> Result<(), String> {
println!("Applying K8sResourceScore '{}' to topology '{}'", self.name, topology.name());
topology.apply_manifest(&self.manifest)
}
fn name(&self) -> &str {
&self.name
}
}
// ===== Maestro Orchestrator =====
/// Type-safe orchestrator that enforces capability requirements at compile time
pub struct Maestro<T: Topology> {
topology: T,
scores: Vec<Box<dyn ScoreWrapper<T>>>,
}
/// A trait object wrapper that hides the specific Score type but preserves its
/// capability requirements
trait ScoreWrapper<T: Topology> {
fn apply(&self, topology: &T) -> Result<(), String>;
fn name(&self) -> &str;
}
/// Implementation of ScoreWrapper for any Score that works with topology T
impl<T, S> ScoreWrapper<T> for S
where
T: Topology,
S: Score<T> + 'static
{
fn apply(&self, topology: &T) -> Result<(), String> {
<S as Score<T>>::apply(self, topology)
}
fn name(&self) -> &str {
<S as Score<T>>::name(self)
}
}
impl<T: Topology> Maestro<T> {
pub fn new(topology: T) -> Self {
Self {
topology,
scores: Vec::new(),
}
}
/// Register a score that is compatible with this topology's capabilities
pub fn register_score<S>(&mut self, score: S)
where
S: Score<T> + 'static
{
println!("Registering score '{}' for topology '{}'", score.name(), self.topology.name());
self.scores.push(Box::new(score));
}
/// Apply all registered scores to the topology
pub fn orchestrate(&self) -> Result<(), String> {
println!("Orchestrating topology '{}'", self.topology.name());
for score in &self.scores {
score.apply(&self.topology)?;
}
Ok(())
}
}
// ===== Example Usage =====
fn main() {
// Create a Linux host topology
let linux_host = LinuxHostTopology::new(
"dev-machine".to_string(),
"localhost".to_string()
);
// Create a maestro for the Linux host
let mut linux_maestro = Maestro::new(linux_host);
// Register a command score that works with any topology having CommandCapability
linux_maestro.register_score(CommandScore::new(
"check-disk".to_string(),
"df".to_string(),
vec!["-h".to_string()]
));
// This would fail to compile if we tried to register a K8sResourceScore
// because LinuxHostTopology doesn't implement KubernetesCapability
// linux_maestro.register_score(K8sResourceScore::new(...));
// Create a K3D topology which has both Command and Kubernetes capabilities
let k3d_host = LinuxHostTopology::new(
"k3d-host".to_string(),
"localhost".to_string()
);
let k3d_topology = K3DTopology::new(
"dev-cluster".to_string(),
k3d_host,
"devcluster".to_string()
);
// Create a maestro for the K3D topology
let mut k3d_maestro = Maestro::new(k3d_topology);
// We can register both command scores and kubernetes scores
k3d_maestro.register_score(CommandScore::new(
"check-nodes".to_string(),
"kubectl".to_string(),
vec!["get".to_string(), "nodes".to_string()]
));
k3d_maestro.register_score(K8sResourceScore::new(
"deploy-nginx".to_string(),
r#"
apiVersion: apps/v1
kind: Deployment
metadata:
name: nginx
spec:
replicas: 1
selector:
matchLabels:
app: nginx
template:
metadata:
labels:
app: nginx
spec:
containers:
- name: nginx
image: nginx:latest
ports:
- containerPort: 80
"#.to_string()
));
// Orchestrate both topologies
linux_maestro.orchestrate().unwrap();
k3d_maestro.orchestrate().unwrap();
}

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examples/topology/src/main_claudev1.rs Normal file
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use std::marker::PhantomData;
use std::process::Command;
// ===== Capability Traits =====
/// Base trait for all capabilities
pub trait Capability {}
/// Capability for executing shell commands on a host
pub trait CommandCapability: Capability {
fn execute_command(&self, command: &str, args: &[&str]) -> Result<String, String>;
}
/// Capability for interacting with a Kubernetes cluster
pub trait KubernetesCapability: Capability {
fn apply_manifest(&self, manifest: &str) -> Result<(), String>;
fn get_resource(&self, resource_type: &str, name: &str) -> Result<String, String>;
}
// ===== Topology Traits =====
/// Base trait for all topologies
pub trait Topology {
// Base topology methods that don't depend on capabilities
fn name(&self) -> &str;
}
// ===== Score Traits =====
/// Generic Score trait with an associated Capability type
pub trait Score<T: Topology> {
fn apply(&self, topology: &T) -> Result<(), String>;
fn name(&self) -> &str;
}
// ===== Concrete Topologies =====
/// A topology representing a Linux host
pub struct LinuxHostTopology {
name: String,
host: String,
}
impl LinuxHostTopology {
pub fn new(name: String, host: String) -> Self {
Self { name, host }
}
}
impl Topology for LinuxHostTopology {
fn name(&self) -> &str {
&self.name
}
}
impl CommandCapability for LinuxHostTopology {
fn execute_command(&self, command: &str, args: &[&str]) -> Result<String, String> {
println!("Executing on {}: {} {:?}", self.host, command, args);
// In a real implementation, this would SSH to the host and execute the command
let output = Command::new(command)
.args(args)
.output()
.map_err(|e| e.to_string())?;
if output.status.success() {
Ok(String::from_utf8_lossy(&output.stdout).to_string())
} else {
Err(String::from_utf8_lossy(&output.stderr).to_string())
}
}
}
/// A topology representing a K3D Kubernetes cluster
pub struct K3DTopology {
name: String,
linux_host: LinuxHostTopology,
cluster_name: String,
}
impl K3DTopology {
pub fn new(name: String, linux_host: LinuxHostTopology, cluster_name: String) -> Self {
Self {
name,
linux_host,
cluster_name,
}
}
}
impl Topology for K3DTopology {
fn name(&self) -> &str {
&self.name
}
}
impl CommandCapability for K3DTopology {
fn execute_command(&self, command: &str, args: &[&str]) -> Result<String, String> {
// Delegate to the underlying Linux host
self.linux_host.execute_command(command, args)
}
}
impl KubernetesCapability for K3DTopology {
fn apply_manifest(&self, manifest: &str) -> Result<(), String> {
println!("Applying manifest to K3D cluster '{}'", self.cluster_name);
// Write manifest to a temporary file
let temp_file = format!("/tmp/manifest-{}.yaml", rand::random::<u32>());
self.execute_command("bash", &["-c", &format!("cat > {}", temp_file)])?;
// Apply with kubectl
self.execute_command(
"kubectl",
&["--context", &format!("k3d-{}", self.cluster_name), "apply", "-f", &temp_file]
)?;
Ok(())
}
fn get_resource(&self, resource_type: &str, name: &str) -> Result<String, String> {
println!("Getting resource {}/{} from K3D cluster '{}'", resource_type, name, self.cluster_name);
self.execute_command(
"kubectl",
&[
"--context",
&format!("k3d-{}", self.cluster_name),
"get",
resource_type,
name,
"-o",
"yaml",
]
)
}
}
// ===== Concrete Scores =====
/// A score that executes commands on a topology
pub struct CommandScore {
name: String,
command: String,
args: Vec<String>,
}
impl CommandScore {
pub fn new(name: String, command: String, args: Vec<String>) -> Self {
Self { name, command, args }
}
}
impl<T> Score<T> for CommandScore
where
T: Topology + CommandCapability
{
fn apply(&self, topology: &T) -> Result<(), String> {
println!("Applying CommandScore '{}' to topology '{}'", self.name, topology.name());
let args_refs: Vec<&str> = self.args.iter().map(|s| s.as_str()).collect();
topology.execute_command(&self.command, &args_refs)?;
Ok(())
}
fn name(&self) -> &str {
&self.name
}
}
/// A score that applies Kubernetes resources to a topology
pub struct K8sResourceScore {
name: String,
manifest: String,
}
impl K8sResourceScore {
pub fn new(name: String, manifest: String) -> Self {
Self { name, manifest }
}
}
impl<T> Score<T> for K8sResourceScore
where
T: Topology + KubernetesCapability
{
fn apply(&self, topology: &T) -> Result<(), String> {
println!("Applying K8sResourceScore '{}' to topology '{}'", self.name, topology.name());
topology.apply_manifest(&self.manifest)
}
fn name(&self) -> &str {
&self.name
}
}
// ===== Maestro Orchestrator =====
/// Type-safe orchestrator that enforces capability requirements at compile time
pub struct Maestro<T: Topology> {
topology: T,
scores: Vec<Box<dyn ScoreWrapper<T>>>,
}
/// A trait object wrapper that hides the specific Score type but preserves its
/// capability requirements
trait ScoreWrapper<T: Topology> {
fn apply(&self, topology: &T) -> Result<(), String>;
fn name(&self) -> &str;
}
/// Implementation of ScoreWrapper for any Score that works with topology T
impl<T, S> ScoreWrapper<T> for S
where
T: Topology,
S: Score<T> + 'static
{
fn apply(&self, topology: &T) -> Result<(), String> {
<S as Score<T>>::apply(self, topology)
}
fn name(&self) -> &str {
<S as Score<T>>::name(self)
}
}
impl<T: Topology> Maestro<T> {
pub fn new(topology: T) -> Self {
Self {
topology,
scores: Vec::new(),
}
}
/// Register a score that is compatible with this topology's capabilities
pub fn register_score<S>(&mut self, score: S)
where
S: Score<T> + 'static
{
println!("Registering score '{}' for topology '{}'", score.name(), self.topology.name());
self.scores.push(Box::new(score));
}
/// Apply all registered scores to the topology
pub fn orchestrate(&self) -> Result<(), String> {
println!("Orchestrating topology '{}'", self.topology.name());
for score in &self.scores {
score.apply(&self.topology)?;
}
Ok(())
}
}
// ===== Example Usage =====
fn main() {
// Create a Linux host topology
let linux_host = LinuxHostTopology::new(
"dev-machine".to_string(),
"localhost".to_string()
);
// Create a maestro for the Linux host
let mut linux_maestro = Maestro::new(linux_host);
// Register a command score that works with any topology having CommandCapability
linux_maestro.register_score(CommandScore::new(
"check-disk".to_string(),
"df".to_string(),
vec!["-h".to_string()]
));
// This would fail to compile if we tried to register a K8sResourceScore
// because LinuxHostTopology doesn't implement KubernetesCapability
// linux_maestro.register_score(K8sResourceScore::new(...));
// Create a K3D topology which has both Command and Kubernetes capabilities
let k3d_host = LinuxHostTopology::new(
"k3d-host".to_string(),
"localhost".to_string()
);
let k3d_topology = K3DTopology::new(
"dev-cluster".to_string(),
k3d_host,
"devcluster".to_string()
);
// Create a maestro for the K3D topology
let mut k3d_maestro = Maestro::new(k3d_topology);
// We can register both command scores and kubernetes scores
k3d_maestro.register_score(CommandScore::new(
"check-nodes".to_string(),
"kubectl".to_string(),
vec!["get".to_string(), "nodes".to_string()]
));
k3d_maestro.register_score(K8sResourceScore::new(
"deploy-nginx".to_string(),
r#"
apiVersion: apps/v1
kind: Deployment
metadata:
name: nginx
spec:
replicas: 1
selector:
matchLabels:
app: nginx
template:
metadata:
labels:
app: nginx
spec:
containers:
- name: nginx
image: nginx:latest
ports:
- containerPort: 80
"#.to_string()
));
// Orchestrate both topologies
linux_maestro.orchestrate().unwrap();
k3d_maestro.orchestrate().unwrap();
}

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examples/topology/src/main_right.rs Normal file
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use std::marker::PhantomData;
// Capability Trait Hierarchy
pub trait Capability {}
// Specific Capability Traits
pub trait ShellAccess: Capability {}
pub trait ContainerRuntime: Capability {}
pub trait KubernetesAccess: Capability {}
pub trait FileSystemAccess: Capability {}
// Topology Trait - Defines the core interface for infrastructure topologies
pub trait Topology {
type Capabilities: Capability;
fn name(&self) -> &str;
}
// Score Trait - Defines the core interface for infrastructure transformation
pub trait Score {
type RequiredCapabilities: Capability;
type OutputTopology: Topology;
fn apply<T: Topology>(&self, topology: T) -> Result<Self::OutputTopology, String>;
}
// Linux Host Topology
pub struct LinuxHostTopology;
impl Topology for LinuxHostTopology {
type Capabilities = dyn ShellAccess + FileSystemAccess;
fn name(&self) -> &str {
"Linux Host"
}
}
impl ShellAccess for LinuxHostTopology {}
impl FileSystemAccess for LinuxHostTopology {}
// K3D Topology
pub struct K3DTopology;
impl Topology for K3DTopology {
type Capabilities = dyn ContainerRuntime + KubernetesAccess + ShellAccess;
fn name(&self) -> &str {
"K3D Kubernetes Cluster"
}
}
impl ContainerRuntime for K3DTopology {}
impl KubernetesAccess for K3DTopology {}
impl ShellAccess for K3DTopology {}
// Command Score - A score that requires shell access
pub struct CommandScore {
command: String,
}
impl Score for CommandScore {
type RequiredCapabilities = dyn ShellAccess;
type OutputTopology = LinuxHostTopology;
fn apply<T: Topology>(&self, _topology: T) -> Result<Self::OutputTopology, String>
where
T: ShellAccess
{
// Simulate command execution
println!("Executing command: {}", self.command);
Ok(LinuxHostTopology)
}
}
// Kubernetes Resource Score
pub struct K8sResourceScore {
resource_definition: String,
}
impl Score for K8sResourceScore {
type RequiredCapabilities = dyn KubernetesAccess;
type OutputTopology = K3DTopology;
fn apply<T: Topology>(&self, _topology: T) -> Result<Self::OutputTopology, String>
where
T: dyn KubernetesAccess
{
// Simulate Kubernetes resource application
println!("Applying K8s resource: {}", self.resource_definition);
Ok(K3DTopology)
}
}
// Maestro - The orchestration coordinator
pub struct Maestro;
impl Maestro {
// Type-safe score application
pub fn apply_score<T, S>(topology: T, score: S) -> Result<S::OutputTopology, String>
where
T: Topology,
S: Score,
T: S::RequiredCapabilities
{
score.apply(topology)
}
}
fn main() {
// Example usage demonstrating type-driven design
let linux_host = LinuxHostTopology;
let k3d_cluster = K3DTopology;
// Command score on Linux host
let command_score = CommandScore {
command: "echo 'Hello, World!'".to_string(),
};
let result = Maestro::apply_score(linux_host, command_score)
.expect("Command score application failed");
// K8s resource score on K3D cluster
let k8s_score = K8sResourceScore {
resource_definition: "apiVersion: v1\nkind: Pod\n...".to_string(),
};
let k8s_result = Maestro::apply_score(k3d_cluster, k8s_score)
.expect("K8s resource score application failed");
}

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mod main_right;
mod main_claude;
// Capability Traits
trait Capability {}
trait LinuxOperations: Capability {
fn execute_command(&self, command: &str) -> Result<String, String>;
}
trait KubernetesOperations: Capability {
fn create_resource(&self, resource: &str) -> Result<String, String>;
fn delete_resource(&self, resource: &str) -> Result<String, String>;
}
// Topology Implementations
struct LinuxHostTopology;
impl LinuxOperations for LinuxHostTopology {
fn execute_command(&self, command: &str) -> Result<String, String> {
// Implementation for executing commands on a Linux host
Ok(format!("Executed command: {}", command))
}
}
impl Capability for LinuxHostTopology {}
struct K3DTopology;
impl KubernetesOperations for K3DTopology {
fn create_resource(&self, resource: &str) -> Result<String, String> {
// Implementation for creating Kubernetes resources in K3D
Ok(format!("Created resource: {}", resource))
}
fn delete_resource(&self, resource: &str) -> Result<String, String> {
// Implementation for deleting Kubernetes resources in K3D
Ok(format!("Deleted resource: {}", resource))
}
}
impl Capability for K3DTopology {}
// Score Implementations
struct K8sResourceScore {
resource: String,
}
impl<T> Score<T> for K8sResourceScore
where
T: KubernetesOperations,
{
fn execute(&self, topology: &T) -> Result<String, String> {
topology.create_resource(&self.resource)
}
}
struct CommandScore {
command: String,
}
impl<T> Score<T> for CommandScore
where
T: LinuxOperations + 'static,
{
fn execute(&self, topology: &T) -> Result<String, String> {
topology.execute_command(&self.command)
}
}
// Score Trait
trait Score<T>
where
T: Capability + 'static,
{
fn execute(&self, topology: &T) -> Result<String, String>;
}
// Maestro Implementation
struct Maestro {
scores: Vec<Box<dyn Score<Box<dyn Capability>>>>,
}
impl Maestro {
fn new() -> Self {
Maestro { scores: Vec::new() }
}
fn register_score<T>(&mut self, score: Box<T>)
where
T: Score<Box<dyn Capability>> + 'static,
{
self.scores.push(Box::new(score));
}
fn execute_scores<T>(&self, topology: &T) -> Result<Vec<String>, String>
where
T: Capability + 'static,
{
let mut results = Vec::new();
for score in &self.scores {
if let Some(score) = score.as_any().downcast_ref::<Box<dyn Score<T>>>() {
results.push(score.execute(topology)?);
}
}
Ok(results)
}
}
// Helper trait for downcasting
trait AsAny {
fn as_any(&self) -> &dyn std::any::Any;
}
impl<T: 'static> AsAny for T {
fn as_any(&self) -> &dyn std::any::Any {
self
}
}
// Main Function
fn main() {
let mut maestro = Maestro::new();
let k8s_score = K8sResourceScore {
resource: "deployment.yaml".to_string(),
};
maestro.register_score(k8s_score);
let command_score = CommandScore {
command: "ls -l".to_string(),
};
maestro.register_score(command_score);
let linux_topology = LinuxHostTopology;
let k3d_topology = K3DTopology;
let linux_results = maestro.execute_scores(&linux_topology).unwrap();
println!("Linux Topology Results:");
for result in linux_results {
println!("{}", result);
}
let k3d_results = maestro.execute_scores(&k3d_topology).unwrap();
println!("K3D Topology Results:");
for result in k3d_results {
println!("{}", result);
}
}