//! Deserialisation from Nix to Rust values. use bstr::ByteSlice; use serde::de::value::{MapDeserializer, SeqDeserializer}; use serde::de::{self, EnumAccess, VariantAccess}; use tvix_eval::{EvalIO, EvalMode, EvaluationBuilder, Value}; use crate::error::Error; struct NixDeserializer { value: tvix_eval::Value, } impl NixDeserializer { fn new(value: Value) -> Self { if let Value::Thunk(thunk) = value { Self::new(thunk.value().clone()) } else { Self { value } } } } impl de::IntoDeserializer<'_, Error> for NixDeserializer { type Deserializer = Self; fn into_deserializer(self) -> Self::Deserializer { self } } /// Evaluate the Nix code in `src` and attempt to deserialise the /// value it returns to `T`. pub fn from_str<'code, T>(src: &'code str) -> Result where T: serde::Deserialize<'code>, { from_str_with_config(src, |b| /* no extra config */ b) } /// Evaluate the Nix code in `src`, with extra configuration for the /// `tvix_eval::Evaluation` provided by the given closure. pub fn from_str_with_config<'code, T, F>(src: &'code str, config: F) -> Result where T: serde::Deserialize<'code>, F: for<'co, 'ro, 'env> FnOnce( EvaluationBuilder<'co, 'ro, 'env, Box>, ) -> EvaluationBuilder<'co, 'ro, 'env, Box>, { // First step is to evaluate the Nix code ... let eval = config(EvaluationBuilder::new_pure().mode(EvalMode::Strict)).build(); let result = eval.evaluate(src, None); if !result.errors.is_empty() { return Err(Error::NixErrors { errors: result.errors, }); } let de = NixDeserializer::new(result.value.expect("value should be present on success")); T::deserialize(de) } fn unexpected(expected: &'static str, got: &Value) -> Error { Error::UnexpectedType { expected, got: got.type_of(), } } fn visit_integer>(v: &Value) -> Result { match v { Value::Integer(i) => I::try_from(*i).map_err(|_| Error::IntegerConversion { got: *i, need: std::any::type_name::(), }), _ => Err(unexpected("integer", v)), } } impl<'de> de::Deserializer<'de> for NixDeserializer { type Error = Error; fn deserialize_any(self, visitor: V) -> Result where V: de::Visitor<'de>, { match self.value { Value::Null => visitor.visit_unit(), Value::Bool(b) => visitor.visit_bool(b), Value::Integer(i) => visitor.visit_i64(i), Value::Float(f) => visitor.visit_f64(f), Value::String(s) => visitor.visit_string(s.to_string()), Value::Path(p) => visitor.visit_string(p.to_string_lossy().into()), // TODO: hmm Value::Attrs(_) => self.deserialize_map(visitor), Value::List(_) => self.deserialize_seq(visitor), // tvix-eval types that can not be deserialized through serde. Value::Closure(_) | Value::Builtin(_) | Value::Thunk(_) | Value::AttrNotFound | Value::Blueprint(_) | Value::DeferredUpvalue(_) | Value::UnresolvedPath(_) | Value::Catchable(_) | Value::FinaliseRequest(_) => Err(Error::Unserializable { value_type: self.value.type_of(), }), } } fn deserialize_bool(self, visitor: V) -> Result where V: de::Visitor<'de>, { match self.value { Value::Bool(b) => visitor.visit_bool(b), _ => Err(unexpected("bool", &self.value)), } } fn deserialize_i8(self, visitor: V) -> Result where V: de::Visitor<'de>, { visitor.visit_i8(visit_integer(&self.value)?) } fn deserialize_i16(self, visitor: V) -> Result where V: de::Visitor<'de>, { visitor.visit_i16(visit_integer(&self.value)?) } fn deserialize_i32(self, visitor: V) -> Result where V: de::Visitor<'de>, { visitor.visit_i32(visit_integer(&self.value)?) } fn deserialize_i64(self, visitor: V) -> Result where V: de::Visitor<'de>, { visitor.visit_i64(visit_integer(&self.value)?) } fn deserialize_u8(self, visitor: V) -> Result where V: de::Visitor<'de>, { visitor.visit_u8(visit_integer(&self.value)?) } fn deserialize_u16(self, visitor: V) -> Result where V: de::Visitor<'de>, { visitor.visit_u16(visit_integer(&self.value)?) } fn deserialize_u32(self, visitor: V) -> Result where V: de::Visitor<'de>, { visitor.visit_u32(visit_integer(&self.value)?) } fn deserialize_u64(self, visitor: V) -> Result where V: de::Visitor<'de>, { visitor.visit_u64(visit_integer(&self.value)?) } fn deserialize_f32(self, visitor: V) -> Result where V: de::Visitor<'de>, { if let Value::Float(f) = self.value { return visitor.visit_f32(f as f32); } Err(unexpected("float", &self.value)) } fn deserialize_f64(self, visitor: V) -> Result where V: de::Visitor<'de>, { if let Value::Float(f) = self.value { return visitor.visit_f64(f); } Err(unexpected("float", &self.value)) } fn deserialize_char(self, visitor: V) -> Result where V: de::Visitor<'de>, { if let Value::String(s) = &self.value { let chars = s.chars().collect::>(); if chars.len() == 1 { return visitor.visit_char(chars[0]); } } Err(unexpected("char", &self.value)) } fn deserialize_str(self, visitor: V) -> Result where V: de::Visitor<'de>, { if let Value::String(s) = &self.value { if let Ok(s) = s.to_str() { return visitor.visit_str(s); } } Err(unexpected("string", &self.value)) } fn deserialize_string(self, visitor: V) -> Result where V: de::Visitor<'de>, { if let Value::String(s) = &self.value { if let Ok(s) = s.to_str() { return visitor.visit_str(s); } } Err(unexpected("string", &self.value)) } fn deserialize_bytes(self, _visitor: V) -> Result where V: de::Visitor<'de>, { unimplemented!() } fn deserialize_byte_buf(self, _visitor: V) -> Result where V: de::Visitor<'de>, { unimplemented!() } // Note that this can not distinguish between a serialisation of // `Some(())` and `None`. fn deserialize_option(self, visitor: V) -> Result where V: de::Visitor<'de>, { if let Value::Null = self.value { visitor.visit_none() } else { visitor.visit_some(self) } } fn deserialize_unit(self, visitor: V) -> Result where V: de::Visitor<'de>, { if let Value::Null = self.value { return visitor.visit_unit(); } Err(unexpected("null", &self.value)) } fn deserialize_unit_struct( self, _name: &'static str, visitor: V, ) -> Result where V: de::Visitor<'de>, { self.deserialize_unit(visitor) } fn deserialize_newtype_struct( self, _name: &'static str, visitor: V, ) -> Result where V: de::Visitor<'de>, { visitor.visit_newtype_struct(self) } fn deserialize_seq(self, visitor: V) -> Result where V: de::Visitor<'de>, { if let Value::List(list) = self.value { let mut seq = SeqDeserializer::new(list.into_iter().map(NixDeserializer::new)); let result = visitor.visit_seq(&mut seq)?; seq.end()?; return Ok(result); } Err(unexpected("list", &self.value)) } fn deserialize_tuple(self, _len: usize, visitor: V) -> Result where V: de::Visitor<'de>, { // just represent tuples as lists ... self.deserialize_seq(visitor) } fn deserialize_tuple_struct( self, _name: &'static str, _len: usize, visitor: V, ) -> Result where V: de::Visitor<'de>, { // same as above self.deserialize_seq(visitor) } fn deserialize_map(self, visitor: V) -> Result where V: de::Visitor<'de>, { if let Value::Attrs(attrs) = self.value { let mut map = MapDeserializer::new(attrs.into_iter().map(|(k, v)| { ( NixDeserializer::new(Value::from(k)), NixDeserializer::new(v), ) })); let result = visitor.visit_map(&mut map)?; map.end()?; return Ok(result); } Err(unexpected("map", &self.value)) } fn deserialize_struct( self, _name: &'static str, _fields: &'static [&'static str], visitor: V, ) -> Result where V: de::Visitor<'de>, { self.deserialize_map(visitor) } // This method is responsible for deserializing the externally // tagged enum variant serialisation. fn deserialize_enum( self, name: &'static str, _variants: &'static [&'static str], visitor: V, ) -> Result where V: de::Visitor<'de>, { match self.value { // a string represents a unit variant Value::String(ref s) => { if let Ok(s) = s.to_str() { visitor.visit_enum(de::value::StrDeserializer::new(s)) } else { Err(unexpected(name, &self.value)) } } // an attribute set however represents an externally // tagged enum with content Value::Attrs(attrs) => visitor.visit_enum(Enum(*attrs)), _ => Err(unexpected(name, &self.value)), } } fn deserialize_identifier(self, visitor: V) -> Result where V: de::Visitor<'de>, { self.deserialize_str(visitor) } fn deserialize_ignored_any(self, visitor: V) -> Result where V: de::Visitor<'de>, { visitor.visit_unit() } } struct Enum(tvix_eval::NixAttrs); impl<'de> EnumAccess<'de> for Enum { type Error = Error; type Variant = NixDeserializer; // TODO: pass the known variants down here and check against them fn variant_seed(self, seed: V) -> Result<(V::Value, Self::Variant), Self::Error> where V: de::DeserializeSeed<'de>, { if self.0.len() != 1 { return Err(Error::AmbiguousEnum); } let (key, value) = self.0.into_iter().next().expect("length asserted above"); if let Ok(k) = key.to_str() { let val = seed.deserialize(de::value::StrDeserializer::::new(k))?; Ok((val, NixDeserializer::new(value))) } else { Err(unexpected("string", &key.clone().into())) } } } impl<'de> VariantAccess<'de> for NixDeserializer { type Error = Error; fn unit_variant(self) -> Result<(), Self::Error> { // If this case is hit, a user specified the name of a unit // enum variant but gave it content. Unit enum deserialisation // is handled in `deserialize_enum` above. Err(Error::UnitEnumContent) } fn newtype_variant_seed(self, seed: T) -> Result where T: de::DeserializeSeed<'de>, { seed.deserialize(self) } fn tuple_variant(self, _len: usize, visitor: V) -> Result where V: de::Visitor<'de>, { de::Deserializer::deserialize_seq(self, visitor) } fn struct_variant( self, _fields: &'static [&'static str], visitor: V, ) -> Result where V: de::Visitor<'de>, { de::Deserializer::deserialize_map(self, visitor) } }