// Copyright 2018-2022 the Deno authors. All rights reserved. MIT license. use serde::de::{self, Visitor}; use serde::Deserialize; use crate::error::{Error, Result}; use crate::keys::{v8_struct_key, KeyCache}; use crate::magic::transl8::FromV8; use crate::magic::transl8::{visit_magic, MagicType}; use crate::payload::ValueType; use crate::{ magic, ByteString, DetachedBuffer, StringOrBuffer, U16String, ZeroCopyBuf, }; pub struct Deserializer<'a, 'b, 's> { input: v8::Local<'a, v8::Value>, scope: &'b mut v8::HandleScope<'s>, _key_cache: Option<&'b mut KeyCache>, } impl<'a, 'b, 's> Deserializer<'a, 'b, 's> { pub fn new( scope: &'b mut v8::HandleScope<'s>, input: v8::Local<'a, v8::Value>, key_cache: Option<&'b mut KeyCache>, ) -> Self { Deserializer { input, scope, _key_cache: key_cache, } } } // from_v8 deserializes a v8::Value into a Deserializable / rust struct pub fn from_v8<'de, 'a, 'b, 's, T>( scope: &'b mut v8::HandleScope<'s>, input: v8::Local<'a, v8::Value>, ) -> Result where T: Deserialize<'de>, { let mut deserializer = Deserializer::new(scope, input, None); let t = T::deserialize(&mut deserializer)?; Ok(t) } // like from_v8 except accepts a KeyCache to optimize struct key decoding pub fn from_v8_cached<'de, 'a, 'b, 's, T>( scope: &'b mut v8::HandleScope<'s>, input: v8::Local<'a, v8::Value>, key_cache: &mut KeyCache, ) -> Result where T: Deserialize<'de>, { let mut deserializer = Deserializer::new(scope, input, Some(key_cache)); let t = T::deserialize(&mut deserializer)?; Ok(t) } macro_rules! wip { ($method:ident) => { fn $method(self, _v: V) -> Result where V: Visitor<'de>, { unimplemented!() } }; } // TODO: maybe check for BigInt truncation ? // (i.e: values larger than i64/u64 can hold) macro_rules! deserialize_signed { ($dmethod:ident, $vmethod:ident, $t:tt) => { fn $dmethod(self, visitor: V) -> Result where V: Visitor<'de>, { visitor.$vmethod( if let Ok(x) = v8::Local::::try_from(self.input) { x.value() as $t } else if let Ok(x) = v8::Local::::try_from(self.input) { x.i64_value().0 as $t } else if let Some(x) = self.input.number_value(self.scope) { x as $t } else if let Some(x) = self.input.to_big_int(self.scope) { x.i64_value().0 as $t } else { return Err(Error::ExpectedInteger); }, ) } }; } macro_rules! deserialize_unsigned { ($dmethod:ident, $vmethod:ident, $t:tt) => { fn $dmethod(self, visitor: V) -> Result where V: Visitor<'de>, { visitor.$vmethod( if let Ok(x) = v8::Local::::try_from(self.input) { x.value() as $t } else if let Ok(x) = v8::Local::::try_from(self.input) { x.u64_value().0 as $t } else if let Some(x) = self.input.number_value(self.scope) { x as $t } else if let Some(x) = self.input.to_big_int(self.scope) { x.u64_value().0 as $t } else { return Err(Error::ExpectedInteger); }, ) } }; } impl<'de, 'a, 'b, 's, 'x> de::Deserializer<'de> for &'x mut Deserializer<'a, 'b, 's> { type Error = Error; fn deserialize_any(self, visitor: V) -> Result where V: Visitor<'de>, { match ValueType::from_v8(self.input) { ValueType::Null => self.deserialize_unit(visitor), ValueType::Bool => self.deserialize_bool(visitor), // Handle floats & ints separately to work with loosely-typed serde_json ValueType::Number => { if self.input.is_uint32() { self.deserialize_u32(visitor) } else if self.input.is_int32() { self.deserialize_i32(visitor) } else { self.deserialize_f64(visitor) } } ValueType::String => self.deserialize_string(visitor), ValueType::Array => self.deserialize_seq(visitor), ValueType::Object => self.deserialize_map(visitor), // Map to Vec when deserialized via deserialize_any // e.g: for untagged enums or StringOrBuffer ValueType::ArrayBufferView | ValueType::ArrayBuffer => { magic::v8slice::V8Slice::from_v8(&mut *self.scope, self.input) .and_then(|zb| visitor.visit_byte_buf(Vec::from(&*zb))) } } } fn deserialize_bool(self, visitor: V) -> Result where V: Visitor<'de>, { // Relaxed typechecking, will map all non-true vals to false visitor.visit_bool(self.input.is_true()) } // signed deserialize_signed!(deserialize_i8, visit_i8, i8); deserialize_signed!(deserialize_i16, visit_i16, i16); deserialize_signed!(deserialize_i32, visit_i32, i32); deserialize_signed!(deserialize_i64, visit_i64, i64); // unsigned deserialize_unsigned!(deserialize_u8, visit_u8, u8); deserialize_unsigned!(deserialize_u16, visit_u16, u16); deserialize_unsigned!(deserialize_u32, visit_u32, u32); deserialize_unsigned!(deserialize_u64, visit_u64, u64); fn deserialize_f32(self, visitor: V) -> Result where V: Visitor<'de>, { self.deserialize_f64(visitor) } fn deserialize_f64(self, visitor: V) -> Result where V: Visitor<'de>, { visitor.visit_f64( if let Ok(x) = v8::Local::::try_from(self.input) { x.value() as f64 } else if let Ok(x) = v8::Local::::try_from(self.input) { bigint_to_f64(x) } else if let Some(x) = self.input.number_value(self.scope) { x as f64 } else if let Some(x) = self.input.to_big_int(self.scope) { bigint_to_f64(x) } else { return Err(Error::ExpectedNumber); }, ) } wip!(deserialize_char); fn deserialize_str(self, visitor: V) -> Result where V: Visitor<'de>, { self.deserialize_string(visitor) } fn deserialize_string(self, visitor: V) -> Result where V: Visitor<'de>, { if self.input.is_string() { let v8_string = v8::Local::::try_from(self.input).unwrap(); let string = to_utf8(v8_string, self.scope); visitor.visit_string(string) } else { Err(Error::ExpectedString) } } wip!(deserialize_bytes); wip!(deserialize_byte_buf); fn deserialize_option(self, visitor: V) -> Result where V: Visitor<'de>, { if self.input.is_null_or_undefined() { visitor.visit_none() } else { visitor.visit_some(self) } } fn deserialize_unit(self, visitor: V) -> Result where V: Visitor<'de>, { visitor.visit_unit() } fn deserialize_unit_struct( self, _name: &'static str, visitor: V, ) -> Result where V: Visitor<'de>, { self.deserialize_unit(visitor) } // As is done here, serializers are encouraged to treat newtype structs as // insignificant wrappers around the data they contain. That means not // parsing anything other than the contained value. fn deserialize_newtype_struct( self, _name: &'static str, visitor: V, ) -> Result where V: Visitor<'de>, { visitor.visit_newtype_struct(self) } fn deserialize_seq(self, visitor: V) -> Result where V: Visitor<'de>, { let arr = v8::Local::::try_from(self.input) .map_err(|_| Error::ExpectedArray)?; let len = arr.length(); let obj = v8::Local::::from(arr); let seq = SeqAccess { pos: 0, len, obj, scope: self.scope, }; visitor.visit_seq(seq) } // Like deserialize_seq except it prefers tuple's length over input array's length fn deserialize_tuple(self, len: usize, visitor: V) -> Result where V: Visitor<'de>, { // TODO: error on length mismatch let obj = v8::Local::::try_from(self.input).unwrap(); let seq = SeqAccess { pos: 0, len: len as u32, obj, scope: self.scope, }; visitor.visit_seq(seq) } // Tuple structs look just like sequences in JSON. fn deserialize_tuple_struct( self, _name: &'static str, len: usize, visitor: V, ) -> Result where V: Visitor<'de>, { self.deserialize_tuple(len, visitor) } fn deserialize_map(self, visitor: V) -> Result where V: de::Visitor<'de>, { // Assume object, then get_own_property_names let obj = v8::Local::::try_from(self.input) .map_err(|_| Error::ExpectedObject)?; let prop_names = obj.get_own_property_names(self.scope); let mut keys: Vec = match prop_names { Some(names) => from_v8(self.scope, names.into()).unwrap(), None => vec![], }; let keys: Vec> = keys .drain(..) .map(|x| x.into()) // Filter keys to drop keys whose value is undefined // TODO: optimize, since this doubles our get calls .filter(|key| !obj.get(self.scope, *key).unwrap().is_undefined()) .collect(); let map = MapAccess { obj, keys, pos: 0, scope: self.scope, }; visitor.visit_map(map) } fn deserialize_struct( self, name: &'static str, fields: &'static [&'static str], visitor: V, ) -> Result where V: Visitor<'de>, { match name { ZeroCopyBuf::MAGIC_NAME => { visit_magic(visitor, ZeroCopyBuf::from_v8(self.scope, self.input)?) } DetachedBuffer::MAGIC_NAME => { visit_magic(visitor, DetachedBuffer::from_v8(self.scope, self.input)?) } ByteString::MAGIC_NAME => { visit_magic(visitor, ByteString::from_v8(self.scope, self.input)?) } U16String::MAGIC_NAME => { visit_magic(visitor, U16String::from_v8(self.scope, self.input)?) } StringOrBuffer::MAGIC_NAME => { visit_magic(visitor, StringOrBuffer::from_v8(self.scope, self.input)?) } magic::Value::MAGIC_NAME => { visit_magic(visitor, magic::Value::from_v8(self.scope, self.input)?) } _ => { // Regular struct let obj = self.input.try_into().or(Err(Error::ExpectedObject))?; visitor.visit_seq(StructAccess { fields, obj, pos: 0, scope: self.scope, _cache: None, }) } } } /// To be compatible with `serde-json`, we expect enums to be: /// - `"Variant"`: strings for unit variants, i.e: Enum::Variant /// - `{ Variant: payload }`: single K/V pairs, converted to `Enum::Variant { payload }` fn deserialize_enum( self, _name: &str, _variants: &'static [&'static str], visitor: V, ) -> Result where V: Visitor<'de>, { // Unit variant if self.input.is_string() { let payload = v8::undefined(self.scope).into(); visitor.visit_enum(EnumAccess { scope: self.scope, tag: self.input, payload, }) } // Struct or tuple variant else if self.input.is_object() { // Assume object let obj = v8::Local::::try_from(self.input).unwrap(); // Unpack single-key let tag = { let prop_names = obj.get_own_property_names(self.scope); let prop_names = prop_names.ok_or(Error::ExpectedEnum)?; if prop_names.length() != 1 { return Err(Error::LengthMismatch); } prop_names.get_index(self.scope, 0).unwrap() }; let payload = obj.get(self.scope, tag).unwrap(); visitor.visit_enum(EnumAccess { scope: self.scope, tag, payload, }) } else { // TODO: improve error Err(Error::ExpectedEnum) } } // An identifier in Serde is the type that identifies a field of a struct or // the variant of an enum. In JSON, struct fields and enum variants are // represented as strings. In other formats they may be represented as // numeric indices. fn deserialize_identifier(self, visitor: V) -> Result where V: Visitor<'de>, { self.deserialize_str(visitor) } fn deserialize_ignored_any(self, visitor: V) -> Result where V: Visitor<'de>, { visitor.visit_none() } } struct MapAccess<'a, 'b, 's> { obj: v8::Local<'a, v8::Object>, scope: &'b mut v8::HandleScope<'s>, keys: Vec>, pos: usize, } impl<'de> de::MapAccess<'de> for MapAccess<'_, '_, '_> { type Error = Error; fn next_key_seed>( &mut self, seed: K, ) -> Result> { Ok(match self.keys.get(self.pos) { Some(key) => { let mut deserializer = Deserializer::new(self.scope, *key, None); Some(seed.deserialize(&mut deserializer)?) } None => None, }) } fn next_value_seed>( &mut self, seed: V, ) -> Result { if self.pos >= self.keys.len() { return Err(Error::LengthMismatch); } let key = self.keys[self.pos]; self.pos += 1; let v8_val = self.obj.get(self.scope, key).unwrap(); let mut deserializer = Deserializer::new(self.scope, v8_val, None); seed.deserialize(&mut deserializer) } fn next_entry_seed< K: de::DeserializeSeed<'de>, V: de::DeserializeSeed<'de>, >( &mut self, kseed: K, vseed: V, ) -> Result> { if self.pos >= self.keys.len() { return Ok(None); } let v8_key = self.keys[self.pos]; self.pos += 1; let mut kdeserializer = Deserializer::new(self.scope, v8_key, None); Ok(Some((kseed.deserialize(&mut kdeserializer)?, { let v8_val = self.obj.get(self.scope, v8_key).unwrap(); let mut deserializer = Deserializer::new(self.scope, v8_val, None); vseed.deserialize(&mut deserializer)? }))) } } struct StructAccess<'a, 'b, 's> { obj: v8::Local<'a, v8::Object>, scope: &'b mut v8::HandleScope<'s>, fields: &'static [&'static str], pos: usize, _cache: Option<&'b mut KeyCache>, } impl<'de> de::SeqAccess<'de> for StructAccess<'_, '_, '_> { type Error = Error; fn next_element_seed>( &mut self, seed: T, ) -> Result> { if self.pos >= self.fields.len() { return Ok(None); } let pos = self.pos; self.pos += 1; let field = self.fields[pos]; let key = v8_struct_key(self.scope, field).into(); let val = self.obj.get(self.scope, key).unwrap(); let mut deserializer = Deserializer::new(self.scope, val, None); match seed.deserialize(&mut deserializer) { Ok(val) => Ok(Some(val)), // Fallback to Ok(None) for #[serde(Default)] at cost of error quality ... // TODO(@AaronO): double check that there's no better solution Err(_) if val.is_undefined() => Ok(None), Err(e) => Err(e), } } } struct SeqAccess<'a, 'b, 's> { obj: v8::Local<'a, v8::Object>, scope: &'b mut v8::HandleScope<'s>, len: u32, pos: u32, } impl<'de> de::SeqAccess<'de> for SeqAccess<'_, '_, '_> { type Error = Error; fn next_element_seed>( &mut self, seed: T, ) -> Result> { let pos = self.pos; self.pos += 1; if pos < self.len { let val = self.obj.get_index(self.scope, pos).unwrap(); let mut deserializer = Deserializer::new(self.scope, val, None); Ok(Some(seed.deserialize(&mut deserializer)?)) } else { Ok(None) } } fn size_hint(&self) -> Option { Some((self.len - self.pos) as usize) } } struct EnumAccess<'a, 'b, 's> { tag: v8::Local<'a, v8::Value>, payload: v8::Local<'a, v8::Value>, scope: &'b mut v8::HandleScope<'s>, // p1: std::marker::PhantomData<&'x ()>, } impl<'de, 'a, 'b, 's, 'x> de::EnumAccess<'de> for EnumAccess<'a, 'b, 's> { type Error = Error; type Variant = VariantDeserializer<'a, 'b, 's>; fn variant_seed>( self, seed: V, ) -> Result<(V::Value, Self::Variant)> { let seed = { let mut dtag = Deserializer::new(self.scope, self.tag, None); seed.deserialize(&mut dtag) }; let dpayload = VariantDeserializer::<'a, 'b, 's> { scope: self.scope, value: self.payload, }; Ok((seed?, dpayload)) } } struct VariantDeserializer<'a, 'b, 's> { value: v8::Local<'a, v8::Value>, scope: &'b mut v8::HandleScope<'s>, } impl<'de, 'a, 'b, 's> de::VariantAccess<'de> for VariantDeserializer<'a, 'b, 's> { type Error = Error; fn unit_variant(self) -> Result<()> { let mut d = Deserializer::new(self.scope, self.value, None); de::Deserialize::deserialize(&mut d) } fn newtype_variant_seed>( self, seed: T, ) -> Result { let mut d = Deserializer::new(self.scope, self.value, None); seed.deserialize(&mut d) } fn tuple_variant>( self, len: usize, visitor: V, ) -> Result { let mut d = Deserializer::new(self.scope, self.value, None); de::Deserializer::deserialize_tuple(&mut d, len, visitor) } fn struct_variant>( self, fields: &'static [&'static str], visitor: V, ) -> Result { let mut d = Deserializer::new(self.scope, self.value, None); de::Deserializer::deserialize_struct(&mut d, "", fields, visitor) } } fn bigint_to_f64(b: v8::Local) -> f64 { // log2(f64::MAX) == log2(1.7976931348623157e+308) == 1024 let mut words: [u64; 16] = [0; 16]; // 1024/64 => 16 64bit words let (neg, words) = b.to_words_array(&mut words); if b.word_count() > 16 { return match neg { true => f64::NEG_INFINITY, false => f64::INFINITY, }; } let sign = if neg { -1.0 } else { 1.0 }; let x: f64 = words .iter() .enumerate() .map(|(i, w)| (*w as f64) * 2.0f64.powi(64 * i as i32)) .sum(); sign * x } pub fn to_utf8( s: v8::Local, scope: &mut v8::HandleScope, ) -> String { to_utf8_fast(s, scope).unwrap_or_else(|| to_utf8_slow(s, scope)) } fn to_utf8_fast( s: v8::Local, scope: &mut v8::HandleScope, ) -> Option { // Over-allocate by 20% to avoid checking string twice let len = s.length(); let capacity = (len as f64 * 1.2) as usize; let mut buf = Vec::with_capacity(capacity); let mut nchars = 0; let data = buf.as_mut_ptr(); let length = s.write_utf8( scope, // SAFETY: we're essentially providing the raw internal slice/buffer owned by the Vec // which fulfills all of from_raw_parts_mut's safety requirements besides "initialization" // and since we're operating on a [u8] not [T] we can safely assume the slice's values // are sufficiently "initialized" for writes unsafe { std::slice::from_raw_parts_mut(data, capacity) }, Some(&mut nchars), v8::WriteOptions::NO_NULL_TERMINATION | v8::WriteOptions::REPLACE_INVALID_UTF8, ); if nchars < len { return None; } // SAFETY: write_utf8 guarantees `length` bytes are initialized & valid utf8 unsafe { buf.set_len(length); Some(String::from_utf8_unchecked(buf)) } } fn to_utf8_slow( s: v8::Local, scope: &mut v8::HandleScope, ) -> String { let capacity = s.utf8_length(scope); let mut buf = Vec::with_capacity(capacity); let data = buf.as_mut_ptr(); let length = s.write_utf8( scope, // SAFETY: we're essentially providing the raw internal slice/buffer owned by the Vec // which fulfills all of from_raw_parts_mut's safety requirements besides "initialization" // and since we're operating on a [u8] not [T] we can safely assume the slice's values // are sufficiently "initialized" for writes unsafe { std::slice::from_raw_parts_mut(data, capacity) }, None, v8::WriteOptions::NO_NULL_TERMINATION | v8::WriteOptions::REPLACE_INVALID_UTF8, ); // SAFETY: write_utf8 guarantees `length` bytes are initialized & valid utf8 unsafe { buf.set_len(length); String::from_utf8_unchecked(buf) } }