use crate::node::{CompiledU64Op, GkNode, NodeMeta, Port, PortType, Slot, Value};
pub struct EpochScale {
meta: NodeMeta,
factor: u64,
}
impl EpochScale {
pub fn millis() -> Self { Self::new(1) }
pub fn seconds() -> Self { Self::new(1_000) }
pub fn minutes() -> Self { Self::new(60_000) }
pub fn hours() -> Self { Self::new(3_600_000) }
pub fn new(factor: u64) -> Self {
Self {
meta: NodeMeta {
name: "epoch_scale".into(),
outs: vec![Port::u64("output")],
ins: vec![Slot::Wire(Port::u64("input"))],
},
factor,
}
}
}
impl GkNode for EpochScale {
fn meta(&self) -> &NodeMeta { &self.meta }
fn eval(&self, inputs: &[Value], outputs: &mut [Value]) {
outputs[0] = Value::U64(inputs[0].as_u64().wrapping_mul(self.factor));
}
fn compiled_u64(&self) -> Option<CompiledU64Op> {
let factor = self.factor;
Some(Box::new(move |inputs, outputs| {
outputs[0] = inputs[0].wrapping_mul(factor);
}))
}
}
pub struct EpochOffset {
meta: NodeMeta,
base: u64,
}
impl EpochOffset {
pub fn new(base_epoch_ms: u64) -> Self {
Self {
meta: NodeMeta {
name: "epoch_offset".into(),
outs: vec![Port::u64("output")],
ins: vec![Slot::Wire(Port::u64("input"))],
},
base: base_epoch_ms,
}
}
pub fn from_2024() -> Self { Self::new(1_704_067_200_000) }
pub fn from_2025() -> Self { Self::new(1_735_689_600_000) }
}
impl GkNode for EpochOffset {
fn meta(&self) -> &NodeMeta { &self.meta }
fn eval(&self, inputs: &[Value], outputs: &mut [Value]) {
outputs[0] = Value::U64(inputs[0].as_u64().wrapping_add(self.base));
}
fn compiled_u64(&self) -> Option<CompiledU64Op> {
let base = self.base;
Some(Box::new(move |inputs, outputs| {
outputs[0] = inputs[0].wrapping_add(base);
}))
}
}
pub struct ToTimestamp {
meta: NodeMeta,
}
impl Default for ToTimestamp {
fn default() -> Self {
Self::new()
}
}
impl ToTimestamp {
pub fn new() -> Self {
Self {
meta: NodeMeta {
name: "to_timestamp".into(),
outs: vec![Port::new("output", PortType::Str)],
ins: vec![Slot::Wire(Port::u64("input"))],
},
}
}
}
impl GkNode for ToTimestamp {
fn meta(&self) -> &NodeMeta { &self.meta }
fn eval(&self, inputs: &[Value], outputs: &mut [Value]) {
outputs[0] = Value::Str(epoch_ms_to_iso(inputs[0].as_u64()).into());
}
}
pub struct DateComponents {
meta: NodeMeta,
}
impl Default for DateComponents {
fn default() -> Self {
Self::new()
}
}
impl DateComponents {
pub fn new() -> Self {
Self {
meta: NodeMeta {
name: "date_components".into(),
outs: vec![
Port::u64("year"), Port::u64("month"), Port::u64("day"),
Port::u64("hour"), Port::u64("minute"), Port::u64("second"),
Port::u64("millis"),
],
ins: vec![Slot::Wire(Port::u64("input"))],
},
}
}
}
impl GkNode for DateComponents {
fn meta(&self) -> &NodeMeta { &self.meta }
fn eval(&self, inputs: &[Value], outputs: &mut [Value]) {
let (y, mo, d, h, mi, s, ms) = decompose_epoch_ms(inputs[0].as_u64());
outputs[0] = Value::U64(y);
outputs[1] = Value::U64(mo);
outputs[2] = Value::U64(d);
outputs[3] = Value::U64(h);
outputs[4] = Value::U64(mi);
outputs[5] = Value::U64(s);
outputs[6] = Value::U64(ms);
}
}
const MILLIS_PER_SEC: u64 = 1_000;
#[allow(dead_code)]
const MILLIS_PER_MIN: u64 = 60_000;
#[allow(dead_code)]
const MILLIS_PER_HOUR: u64 = 3_600_000;
#[allow(dead_code)]
const MILLIS_PER_DAY: u64 = 86_400_000;
fn is_leap_year(y: u64) -> bool {
(y.is_multiple_of(4) && !y.is_multiple_of(100)) || y.is_multiple_of(400)
}
fn days_in_month(y: u64, m: u64) -> u64 {
match m {
1 => 31, 2 => if is_leap_year(y) { 29 } else { 28 },
3 => 31, 4 => 30, 5 => 31, 6 => 30,
7 => 31, 8 => 31, 9 => 30, 10 => 31, 11 => 30, 12 => 31,
_ => 30,
}
}
fn decompose_epoch_ms(epoch_ms: u64) -> (u64, u64, u64, u64, u64, u64, u64) {
let mut remaining = epoch_ms;
let ms = remaining % MILLIS_PER_SEC;
remaining /= MILLIS_PER_SEC;
let sec = remaining % 60;
remaining /= 60;
let min = remaining % 60;
remaining /= 60;
let hour = remaining % 24;
let mut days = remaining / 24;
let mut year = 1970u64;
loop {
let days_in_year = if is_leap_year(year) { 366 } else { 365 };
if days < days_in_year { break; }
days -= days_in_year;
year += 1;
}
let mut month = 1u64;
loop {
let dim = days_in_month(year, month);
if days < dim { break; }
days -= dim;
month += 1;
}
let day = days + 1;
(year, month, day, hour, min, sec, ms)
}
fn epoch_ms_to_iso(epoch_ms: u64) -> String {
let (y, mo, d, h, mi, s, ms) = decompose_epoch_ms(epoch_ms);
format!("{y:04}-{mo:02}-{d:02}T{h:02}:{mi:02}:{s:02}.{ms:03}Z")
}
use crate::dsl::registry::{Arity, FuncCategory, FuncSig, ParamSpec};
use crate::node::SlotType;
pub fn signatures() -> &'static [FuncSig] {
use FuncCategory as C;
&[
FuncSig {
name: "epoch_scale", category: C::Datetime,
outputs: 1, description: "scale u64 to epoch millis",
identity: None, variadic_ctor: None,
params: &[
ParamSpec { name: "input", slot_type: SlotType::Wire, required: true, example: "cycle", constraint: None },
ParamSpec { name: "factor", slot_type: SlotType::ConstU64, required: true, example: "10", constraint: None },
],
arity: Arity::Fixed,
commutativity: crate::node::Commutativity::Positional,
help: "Scale a u64 to epoch milliseconds by multiplying by a factor.\nUse to convert a counter in coarse units to millisecond timestamps.\nParameters:\n input — u64 wire input (e.g., a cycle counter)\n factor — milliseconds per input unit (u64)\nExample: epoch_scale(cycle, 1000) // treat input as seconds -> millis",
default_resolver: None,
output_type: crate::dsl::registry::OutputType::Fixed,
},
FuncSig {
name: "epoch_offset", category: C::Datetime,
outputs: 1, description: "add base epoch offset",
identity: None, variadic_ctor: None,
params: &[
ParamSpec { name: "input", slot_type: SlotType::Wire, required: true, example: "cycle", constraint: None },
ParamSpec { name: "base", slot_type: SlotType::ConstU64, required: true, example: "1000000", constraint: None },
],
arity: Arity::Fixed,
commutativity: crate::node::Commutativity::Positional,
help: "Add a base epoch offset (milliseconds) to a u64 value.\nShifts a relative millisecond value into absolute epoch time.\nParameters:\n input — u64 wire input (relative millis)\n base — epoch milliseconds to add (e.g., 1704067200000 for 2024-01-01)\nExample: epoch_offset(epoch_scale(cycle, 1000), 1704067200000)",
default_resolver: None,
output_type: crate::dsl::registry::OutputType::Fixed,
},
FuncSig {
name: "to_timestamp", category: C::Datetime,
outputs: 1, description: "format epoch millis as ISO-8601",
identity: None, variadic_ctor: None,
params: &[
ParamSpec { name: "input", slot_type: SlotType::Wire, required: true, example: "cycle", constraint: None },
],
arity: Arity::Fixed,
commutativity: crate::node::Commutativity::Positional,
help: "Format an epoch-millis u64 as an ISO-8601 timestamp string.\nProduces: \"YYYY-MM-DDThh:mm:ss.mmmZ\" (UTC, no timezone conversion).\nParameters:\n input — u64 epoch milliseconds\nExample: to_timestamp(epoch_offset(epoch_scale(cycle, 1000), 1704067200000))",
default_resolver: None,
output_type: crate::dsl::registry::OutputType::Fixed,
},
FuncSig {
name: "date_components", category: C::Datetime, outputs: 7,
description: "decompose epoch to year/month/day/hour/min/sec/ms",
help: "Decompose epoch milliseconds into 7 output ports:\nyear, month (1-12), day (1-31), hour (0-23), minute (0-59),\nsecond (0-59), millisecond (0-999). All values are UTC.\nUse when you need individual date/time fields for structured output.\nParameters:\n input — u64 epoch milliseconds",
identity: None, variadic_ctor: None,
params: &[ParamSpec { name: "input", slot_type: SlotType::Wire, required: true, example: "cycle", constraint: None }],
arity: Arity::Fixed,
commutativity: crate::node::Commutativity::Positional,
default_resolver: None,
output_type: crate::dsl::registry::OutputType::Fixed,
},
]
}
pub(crate) fn build_node(name: &str, _wires: &[crate::assembly::WireRef], _wire_types: &[crate::node::PortType], consts: &[crate::dsl::factory::ConstArg]) -> Option<Result<Box<dyn crate::node::GkNode>, String>> {
match name {
"epoch_scale" => Some(Ok(Box::new(EpochScale::new(consts.first().map(|c| c.as_u64()).unwrap_or(1))))),
"epoch_offset" => Some(Ok(Box::new(EpochOffset::new(consts.first().map(|c| c.as_u64()).unwrap_or(0))))),
"to_timestamp" => Some(Ok(Box::new(ToTimestamp::new()))),
"date_components" => Some(Ok(Box::new(DateComponents::new()))),
_ => None,
}
}
crate::register_nodes!(signatures, build_node);
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn epoch_scale_seconds() {
let node = EpochScale::seconds();
let mut out = [Value::None];
node.eval(&[Value::U64(5)], &mut out);
assert_eq!(out[0].as_u64(), 5000);
}
#[test]
fn epoch_offset_basic() {
let node = EpochOffset::new(1_000_000);
let mut out = [Value::None];
node.eval(&[Value::U64(500)], &mut out);
assert_eq!(out[0].as_u64(), 1_000_500);
}
#[test]
fn to_timestamp_epoch_zero() {
let node = ToTimestamp::new();
let mut out = [Value::None];
node.eval(&[Value::U64(0)], &mut out);
assert_eq!(out[0].as_str(), "1970-01-01T00:00:00.000Z");
}
#[test]
fn to_timestamp_known_date() {
let node = ToTimestamp::new();
let mut out = [Value::None];
node.eval(&[Value::U64(1_704_067_200_000)], &mut out);
assert_eq!(out[0].as_str(), "2024-01-01T00:00:00.000Z");
}
#[test]
fn date_components_epoch_zero() {
let node = DateComponents::new();
let mut out = vec![Value::None; 7];
node.eval(&[Value::U64(0)], &mut out);
assert_eq!(out[0].as_u64(), 1970);
assert_eq!(out[1].as_u64(), 1);
assert_eq!(out[2].as_u64(), 1);
assert_eq!(out[3].as_u64(), 0);
assert_eq!(out[4].as_u64(), 0);
assert_eq!(out[5].as_u64(), 0);
assert_eq!(out[6].as_u64(), 0);
}
#[test]
fn date_components_known() {
let node = DateComponents::new();
let mut out = vec![Value::None; 7];
let epoch = 19797u64 * MILLIS_PER_DAY + 14 * MILLIS_PER_HOUR
+ 30 * MILLIS_PER_MIN + 45 * MILLIS_PER_SEC + 123;
node.eval(&[Value::U64(epoch)], &mut out);
assert_eq!(out[0].as_u64(), 2024);
assert_eq!(out[1].as_u64(), 3);
assert_eq!(out[2].as_u64(), 15);
assert_eq!(out[3].as_u64(), 14);
assert_eq!(out[4].as_u64(), 30);
assert_eq!(out[5].as_u64(), 45);
assert_eq!(out[6].as_u64(), 123);
}
#[test]
fn epoch_scale_compiled() {
let node = EpochScale::seconds();
let op = node.compiled_u64().unwrap();
let mut out = [0u64];
op(&[5], &mut out);
assert_eq!(out[0], 5000);
}
}