use conjure_object::serde::{ser, de};
use conjure_object::serde::ser::SerializeMap as SerializeMap_;
use conjure_object::private::{UnionField_, UnionTypeField_};
use std::fmt;
#[derive(Debug, Clone, conjure_object::private::DeriveWith)]
#[derive_with(PartialEq, Eq, PartialOrd, Ord, Hash)]
pub enum ComputableNode {
Ranges(super::SummarizeRanges),
Series(super::SummarizeSeries),
Value(Box<super::SelectValue>),
Cartesian(super::SummarizeCartesian),
Cartesian3d(super::SummarizeCartesian3d),
Frequency(Box<super::FrequencyDomain>),
FrequencyV2(Box<super::FrequencyDomainV2>),
Histogram(Box<super::Histogram>),
Curve(super::CurveFit),
Multivariate(super::SummarizeMultivariate),
Unknown(Unknown),
}
impl ser::Serialize for ComputableNode {
fn serialize<S>(&self, s: S) -> Result<S::Ok, S::Error>
where
S: ser::Serializer,
{
let mut map = s.serialize_map(Some(2))?;
match self {
ComputableNode::Ranges(value) => {
map.serialize_entry(&"type", &"ranges")?;
map.serialize_entry(&"ranges", value)?;
}
ComputableNode::Series(value) => {
map.serialize_entry(&"type", &"series")?;
map.serialize_entry(&"series", value)?;
}
ComputableNode::Value(value) => {
map.serialize_entry(&"type", &"value")?;
map.serialize_entry(&"value", value)?;
}
ComputableNode::Cartesian(value) => {
map.serialize_entry(&"type", &"cartesian")?;
map.serialize_entry(&"cartesian", value)?;
}
ComputableNode::Cartesian3d(value) => {
map.serialize_entry(&"type", &"cartesian3d")?;
map.serialize_entry(&"cartesian3d", value)?;
}
ComputableNode::Frequency(value) => {
map.serialize_entry(&"type", &"frequency")?;
map.serialize_entry(&"frequency", value)?;
}
ComputableNode::FrequencyV2(value) => {
map.serialize_entry(&"type", &"frequencyV2")?;
map.serialize_entry(&"frequencyV2", value)?;
}
ComputableNode::Histogram(value) => {
map.serialize_entry(&"type", &"histogram")?;
map.serialize_entry(&"histogram", value)?;
}
ComputableNode::Curve(value) => {
map.serialize_entry(&"type", &"curve")?;
map.serialize_entry(&"curve", value)?;
}
ComputableNode::Multivariate(value) => {
map.serialize_entry(&"type", &"multivariate")?;
map.serialize_entry(&"multivariate", value)?;
}
ComputableNode::Unknown(value) => {
map.serialize_entry(&"type", &value.type_)?;
map.serialize_entry(&value.type_, &value.value)?;
}
}
map.end()
}
}
impl<'de> de::Deserialize<'de> for ComputableNode {
fn deserialize<D>(d: D) -> Result<ComputableNode, D::Error>
where
D: de::Deserializer<'de>,
{
d.deserialize_map(Visitor_)
}
}
struct Visitor_;
impl<'de> de::Visitor<'de> for Visitor_ {
type Value = ComputableNode;
fn expecting(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
fmt.write_str("union ComputableNode")
}
fn visit_map<A>(self, mut map: A) -> Result<ComputableNode, A::Error>
where
A: de::MapAccess<'de>,
{
let v = match map.next_key::<UnionField_<Variant_>>()? {
Some(UnionField_::Type) => {
let variant = map.next_value()?;
let key = map.next_key()?;
match (variant, key) {
(Variant_::Ranges, Some(Variant_::Ranges)) => {
let value = map.next_value()?;
ComputableNode::Ranges(value)
}
(Variant_::Series, Some(Variant_::Series)) => {
let value = map.next_value()?;
ComputableNode::Series(value)
}
(Variant_::Value, Some(Variant_::Value)) => {
let value = map.next_value()?;
ComputableNode::Value(value)
}
(Variant_::Cartesian, Some(Variant_::Cartesian)) => {
let value = map.next_value()?;
ComputableNode::Cartesian(value)
}
(Variant_::Cartesian3d, Some(Variant_::Cartesian3d)) => {
let value = map.next_value()?;
ComputableNode::Cartesian3d(value)
}
(Variant_::Frequency, Some(Variant_::Frequency)) => {
let value = map.next_value()?;
ComputableNode::Frequency(value)
}
(Variant_::FrequencyV2, Some(Variant_::FrequencyV2)) => {
let value = map.next_value()?;
ComputableNode::FrequencyV2(value)
}
(Variant_::Histogram, Some(Variant_::Histogram)) => {
let value = map.next_value()?;
ComputableNode::Histogram(value)
}
(Variant_::Curve, Some(Variant_::Curve)) => {
let value = map.next_value()?;
ComputableNode::Curve(value)
}
(Variant_::Multivariate, Some(Variant_::Multivariate)) => {
let value = map.next_value()?;
ComputableNode::Multivariate(value)
}
(Variant_::Unknown(type_), Some(Variant_::Unknown(b))) => {
if type_ == b {
let value = map.next_value()?;
ComputableNode::Unknown(Unknown { type_, value })
} else {
return Err(
de::Error::invalid_value(de::Unexpected::Str(&type_), &&*b),
)
}
}
(variant, Some(key)) => {
return Err(
de::Error::invalid_value(
de::Unexpected::Str(key.as_str()),
&variant.as_str(),
),
);
}
(variant, None) => {
return Err(de::Error::missing_field(variant.as_str()));
}
}
}
Some(UnionField_::Value(variant)) => {
let value = match &variant {
Variant_::Ranges => {
let value = map.next_value()?;
ComputableNode::Ranges(value)
}
Variant_::Series => {
let value = map.next_value()?;
ComputableNode::Series(value)
}
Variant_::Value => {
let value = map.next_value()?;
ComputableNode::Value(value)
}
Variant_::Cartesian => {
let value = map.next_value()?;
ComputableNode::Cartesian(value)
}
Variant_::Cartesian3d => {
let value = map.next_value()?;
ComputableNode::Cartesian3d(value)
}
Variant_::Frequency => {
let value = map.next_value()?;
ComputableNode::Frequency(value)
}
Variant_::FrequencyV2 => {
let value = map.next_value()?;
ComputableNode::FrequencyV2(value)
}
Variant_::Histogram => {
let value = map.next_value()?;
ComputableNode::Histogram(value)
}
Variant_::Curve => {
let value = map.next_value()?;
ComputableNode::Curve(value)
}
Variant_::Multivariate => {
let value = map.next_value()?;
ComputableNode::Multivariate(value)
}
Variant_::Unknown(type_) => {
let value = map.next_value()?;
ComputableNode::Unknown(Unknown {
type_: type_.clone(),
value,
})
}
};
if map.next_key::<UnionTypeField_>()?.is_none() {
return Err(de::Error::missing_field("type"));
}
let type_variant = map.next_value::<Variant_>()?;
if variant != type_variant {
return Err(
de::Error::invalid_value(
de::Unexpected::Str(type_variant.as_str()),
&variant.as_str(),
),
);
}
value
}
None => return Err(de::Error::missing_field("type")),
};
if map.next_key::<UnionField_<Variant_>>()?.is_some() {
return Err(de::Error::invalid_length(3, &"type and value fields"));
}
Ok(v)
}
}
#[derive(PartialEq)]
enum Variant_ {
Ranges,
Series,
Value,
Cartesian,
Cartesian3d,
Frequency,
FrequencyV2,
Histogram,
Curve,
Multivariate,
Unknown(Box<str>),
}
impl Variant_ {
fn as_str(&self) -> &'static str {
match *self {
Variant_::Ranges => "ranges",
Variant_::Series => "series",
Variant_::Value => "value",
Variant_::Cartesian => "cartesian",
Variant_::Cartesian3d => "cartesian3d",
Variant_::Frequency => "frequency",
Variant_::FrequencyV2 => "frequencyV2",
Variant_::Histogram => "histogram",
Variant_::Curve => "curve",
Variant_::Multivariate => "multivariate",
Variant_::Unknown(_) => "unknown variant",
}
}
}
impl<'de> de::Deserialize<'de> for Variant_ {
fn deserialize<D>(d: D) -> Result<Variant_, D::Error>
where
D: de::Deserializer<'de>,
{
d.deserialize_str(VariantVisitor_)
}
}
struct VariantVisitor_;
impl<'de> de::Visitor<'de> for VariantVisitor_ {
type Value = Variant_;
fn expecting(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
fmt.write_str("string")
}
fn visit_str<E>(self, value: &str) -> Result<Variant_, E>
where
E: de::Error,
{
let v = match value {
"ranges" => Variant_::Ranges,
"series" => Variant_::Series,
"value" => Variant_::Value,
"cartesian" => Variant_::Cartesian,
"cartesian3d" => Variant_::Cartesian3d,
"frequency" => Variant_::Frequency,
"frequencyV2" => Variant_::FrequencyV2,
"histogram" => Variant_::Histogram,
"curve" => Variant_::Curve,
"multivariate" => Variant_::Multivariate,
value => Variant_::Unknown(value.to_string().into_boxed_str()),
};
Ok(v)
}
}
#[derive(Debug, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct Unknown {
type_: Box<str>,
value: conjure_object::Any,
}
impl Unknown {
#[inline]
pub fn type_(&self) -> &str {
&self.type_
}
}