feat: Added initial support for native Loki agent nodes in the graph-based agent system

This commit is contained in:
2026-05-13 13:21:45 -06:00
parent 3cd3ba55ff
commit bfcd73c32a
3 changed files with 283 additions and 1 deletions
+93 -1
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@@ -326,7 +326,7 @@ pub async fn handle_supervisor_tool(
} }
} }
fn run_child_agent( pub fn run_child_agent(
mut child_ctx: RequestContext, mut child_ctx: RequestContext,
initial_input: Input, initial_input: Input,
abort_signal: AbortSignal, abort_signal: AbortSignal,
@@ -374,6 +374,98 @@ fn run_child_agent(
}) })
} }
/// Spawn an agent synchronously from a graph node and return its accumulated
/// output. This is similar to `handle_spawn` but runs the child agent in the
/// current task (no tokio::spawn, no supervisor handle registration) so the
/// graph executor can sequence agent nodes directly.
pub async fn run_agent_for_graph(
parent_ctx: &mut RequestContext,
agent_name: &str,
prompt: &str,
) -> Result<String> {
let short_uuid = &Uuid::new_v4().to_string()[..8];
let agent_id = format!("graph_agent_{agent_name}_{short_uuid}");
let current_depth = parent_ctx.current_depth + 1;
if let Some(supervisor) = parent_ctx.supervisor.as_ref().cloned() {
let max_depth = supervisor.read().max_depth();
if current_depth > max_depth {
bail!("Max agent depth exceeded ({current_depth}/{max_depth})");
}
}
if !parent_ctx.app.config.function_calling_support {
bail!("Function calling support must be enabled to spawn agents.");
}
let child_inbox = Arc::new(Inbox::new());
parent_ctx.ensure_root_escalation_queue();
let child_abort = create_abort_signal();
let app_config = Arc::clone(&parent_ctx.app.config);
let current_model = parent_ctx.current_model().clone();
let info_flag = parent_ctx.info_flag;
let child_app_state = Arc::new(AppState {
config: Arc::new(app_config.as_ref().clone()),
vault: parent_ctx.app.vault.clone(),
mcp_factory: parent_ctx.app.mcp_factory.clone(),
rag_cache: parent_ctx.app.rag_cache.clone(),
mcp_config: parent_ctx.app.mcp_config.clone(),
mcp_log_path: parent_ctx.app.mcp_log_path.clone(),
mcp_registry: parent_ctx.app.mcp_registry.clone(),
functions: parent_ctx.app.functions.clone(),
});
let agent = Agent::init(
app_config.as_ref(),
child_app_state.as_ref(),
&current_model,
info_flag,
agent_name,
child_abort.clone(),
)
.await?;
let agent_mcp_servers = agent.mcp_server_names().to_vec();
let session = agent.agent_session().map(|v| v.to_string());
let should_init_supervisor = agent.can_spawn_agents();
let agent_max_concurrent = agent.max_concurrent_agents();
let agent_max_depth = agent.max_agent_depth();
let mut child_ctx = RequestContext::new_for_child(
Arc::clone(&child_app_state),
parent_ctx,
current_depth,
Arc::clone(&child_inbox),
agent_id.clone(),
);
child_ctx.rag = agent.rag();
child_ctx.agent = Some(agent);
if should_init_supervisor {
child_ctx.supervisor = Some(Arc::new(RwLock::new(Supervisor::new(
agent_max_concurrent,
agent_max_depth,
))));
}
if let Some(session) = session {
child_ctx
.use_session(app_config.as_ref(), Some(&session), child_abort.clone())
.await?;
sync_agent_functions_to_ctx(&mut child_ctx)?;
} else {
populate_agent_mcp_runtime(&mut child_ctx, &agent_mcp_servers).await?;
sync_agent_functions_to_ctx(&mut child_ctx)?;
child_ctx.init_agent_shared_variables()?;
}
let input = Input::from_str(&child_ctx, prompt, None);
debug!("Spawning agent '{agent_name}' for graph node as '{agent_id}'");
run_child_agent(child_ctx, input, child_abort).await
}
async fn populate_agent_mcp_runtime(ctx: &mut RequestContext, server_ids: &[String]) -> Result<()> { async fn populate_agent_mcp_runtime(ctx: &mut RequestContext, server_ids: &[String]) -> Result<()> {
if !ctx.app.config.mcp_server_support { if !ctx.app.config.mcp_server_support {
return Ok(()); return Ok(());
+188
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@@ -0,0 +1,188 @@
//! Execution of `agent`-type graph nodes.
//!
//! Spawns a child agent via `function::supervisor::run_agent_for_graph`,
//! interpolating the prompt against current graph state. After the agent
//! finishes, applies the node's `state_updates` (templates can reference
//! `{{output}}` for the agent's stdout).
use super::state::StateManager;
use super::types::AgentNode;
use crate::config::RequestContext;
use crate::function::supervisor::run_agent_for_graph;
use anyhow::{Context, Result};
use serde_json::Value;
use std::time::Duration;
use tokio::time::timeout;
const OUTPUT_KEY: &str = "output";
const DEFAULT_TIMEOUT_SECS: u64 = 300;
pub struct AgentNodeExecutor;
impl AgentNodeExecutor {
/// Interpolate the node's prompt, spawn the agent, wait for it to
/// finish, then apply `state_updates`. Returns the agent's full output.
pub async fn execute(
node: &AgentNode,
state_manager: &mut StateManager,
parent_ctx: &mut RequestContext,
) -> Result<String> {
let prompt = state_manager
.interpolate(&node.prompt)
.with_context(|| format!("Failed to interpolate prompt for agent '{}'", node.agent))?;
let timeout_dur = Duration::from_secs(node.timeout.unwrap_or(DEFAULT_TIMEOUT_SECS));
let output = timeout(
timeout_dur,
run_agent_for_graph(parent_ctx, &node.agent, &prompt),
)
.await
.with_context(|| {
format!(
"Agent '{}' timed out after {}s",
node.agent,
timeout_dur.as_secs()
)
})?
.with_context(|| format!("Agent '{}' failed", node.agent))?;
apply_state_updates(node, state_manager, &output);
Ok(output)
}
}
/// Exposes the agent's output as `{{output}}` for template evaluation, then
/// applies every key/template in `state_updates`. The temporary `output`
/// state key is removed at the end so it doesn't leak into subsequent
/// nodes' templates.
fn apply_state_updates(node: &AgentNode, state_manager: &mut StateManager, output: &str) {
let Some(updates) = &node.state_updates else {
return;
};
let prev_output = state_manager.state().get(OUTPUT_KEY).cloned();
state_manager
.state_mut()
.set(OUTPUT_KEY.into(), Value::String(output.to_string()));
for (key, template) in updates {
let value = state_manager.interpolate_lenient(template);
state_manager
.state_mut()
.set(key.clone(), Value::String(value));
}
match prev_output {
Some(v) => state_manager.state_mut().set(OUTPUT_KEY.into(), v),
None => {
state_manager
.state_mut()
.set(OUTPUT_KEY.into(), Value::Null);
}
}
}
#[cfg(test)]
mod tests {
use super::super::types::AgentNode;
use super::*;
use serde_json::json;
use std::collections::HashMap;
fn manager_with(pairs: &[(&str, Value)]) -> StateManager {
let mut map = HashMap::new();
for (k, v) in pairs {
map.insert((*k).into(), v.clone());
}
StateManager::new(map)
}
fn node_with(prompt: &str, updates: Option<HashMap<String, String>>) -> AgentNode {
AgentNode {
agent: "test_agent".into(),
prompt: prompt.into(),
state_updates: updates,
timeout: None,
}
}
#[test]
fn state_updates_use_output_placeholder() {
let node = {
let mut u = HashMap::new();
u.insert("findings".into(), "{{output}}".into());
node_with("hi", Some(u))
};
let mut state = manager_with(&[]);
apply_state_updates(&node, &mut state, "agent finished its work");
assert_eq!(
state.state().get("findings"),
Some(&json!("agent finished its work"))
);
}
#[test]
fn state_updates_can_reference_existing_keys_and_output() {
let node = {
let mut u = HashMap::new();
u.insert("summary".into(), "{{topic}}: {{output}}".into());
node_with("hi", Some(u))
};
let mut state = manager_with(&[("topic", json!("auth"))]);
apply_state_updates(&node, &mut state, "JWT vs sessions");
assert_eq!(
state.state().get("summary"),
Some(&json!("auth: JWT vs sessions"))
);
}
#[test]
fn output_key_is_cleaned_up_after_state_updates() {
let node = {
let mut u = HashMap::new();
u.insert("findings".into(), "{{output}}".into());
node_with("hi", Some(u))
};
let mut state = manager_with(&[]);
apply_state_updates(&node, &mut state, "anything");
assert_eq!(state.state().get("output"), Some(&Value::Null));
}
#[test]
fn pre_existing_output_value_is_preserved() {
let node = {
let mut u = HashMap::new();
u.insert("greeting".into(), "{{output}}".into());
node_with("hi", Some(u))
};
let mut state = manager_with(&[("output", json!("preserved"))]);
apply_state_updates(&node, &mut state, "new agent output");
assert_eq!(
state.state().get("greeting"),
Some(&json!("new agent output"))
);
assert_eq!(state.state().get("output"), Some(&json!("preserved")));
}
#[test]
fn no_state_updates_is_a_noop() {
let node = node_with("hi", None);
let mut state = manager_with(&[("k", json!("v"))]);
apply_state_updates(&node, &mut state, "ignored");
assert_eq!(state.state().get("k"), Some(&json!("v")));
assert!(state.state().get("output").is_none());
}
#[test]
fn interpolate_lenient_on_state_updates_handles_missing_keys() {
let node = {
let mut u = HashMap::new();
u.insert("decorated".into(), "[{{missing}}] {{output}}".into());
node_with("hi", Some(u))
};
let mut state = manager_with(&[]);
apply_state_updates(&node, &mut state, "DATA");
assert_eq!(state.state().get("decorated"), Some(&json!("[] DATA")));
}
}
+2
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@@ -1,12 +1,14 @@
//! Graph-based agent orchestration. Declarative YAML workflows over a shared //! Graph-based agent orchestration. Declarative YAML workflows over a shared
//! JSON state, composed of agent/script/approval/input/end nodes. //! JSON state, composed of agent/script/approval/input/end nodes.
pub mod agent;
pub mod parser; pub mod parser;
pub mod script; pub mod script;
pub mod state; pub mod state;
pub mod types; pub mod types;
pub mod validator; pub mod validator;
pub use agent::AgentNodeExecutor;
pub use parser::{GraphParser, agent_has_graph, load_agent_graph}; pub use parser::{GraphParser, agent_has_graph, load_agent_graph};
pub use script::ScriptExecutor; pub use script::ScriptExecutor;
pub use state::{StateManager, StateRepresentation}; pub use state::{StateManager, StateRepresentation};