use crate::de::ParserNumber; use crate::error::Error; #[cfg(feature = "arbitrary_precision")] use crate::error::ErrorCode; #[cfg(feature = "arbitrary_precision")] use alloc::borrow::ToOwned; #[cfg(feature = "arbitrary_precision")] use alloc::string::{String, ToString}; use core::fmt::{self, Debug, Display}; #[cfg(not(feature = "arbitrary_precision"))] use core::hash::{Hash, Hasher}; use serde::de::{self, Unexpected, Visitor}; #[cfg(feature = "arbitrary_precision")] use serde::de::{IntoDeserializer, MapAccess}; use serde::{forward_to_deserialize_any, Deserialize, Deserializer, Serialize, Serializer}; #[cfg(feature = "arbitrary_precision")] pub(crate) const TOKEN: &str = "$serde_json::private::Number"; /// Represents a JSON number, whether integer or floating point. #[derive(Clone, PartialEq, Eq, Hash)] pub struct Number { n: N, } #[cfg(not(feature = "arbitrary_precision"))] #[derive(Copy, Clone)] enum N { PosInt(u64), /// Always less than zero. NegInt(i64), /// Always finite. Float(f64), } #[cfg(not(feature = "arbitrary_precision"))] impl PartialEq for N { fn eq(&self, other: &Self) -> bool { match (self, other) { (N::PosInt(a), N::PosInt(b)) => a == b, (N::NegInt(a), N::NegInt(b)) => a == b, (N::Float(a), N::Float(b)) => a == b, _ => false, } } } // Implementing Eq is fine since any float values are always finite. #[cfg(not(feature = "arbitrary_precision"))] impl Eq for N {} #[cfg(not(feature = "arbitrary_precision"))] impl Hash for N { fn hash(&self, h: &mut H) { match *self { N::PosInt(i) => i.hash(h), N::NegInt(i) => i.hash(h), N::Float(f) => { if f == 0.0f64 { // There are 2 zero representations, +0 and -0, which // compare equal but have different bits. We use the +0 hash // for both so that hash(+0) == hash(-0). 0.0f64.to_bits().hash(h); } else { f.to_bits().hash(h); } } } } } #[cfg(feature = "arbitrary_precision")] type N = String; impl Number { /// Returns true if the `Number` is an integer between `i64::MIN` and /// `i64::MAX`. /// /// For any Number on which `is_i64` returns true, `as_i64` is guaranteed to /// return the integer value. /// /// ``` /// # use serde_json::json; /// # /// let big = i64::max_value() as u64 + 10; /// let v = json!({ "a": 64, "b": big, "c": 256.0 }); /// /// assert!(v["a"].is_i64()); /// /// // Greater than i64::MAX. /// assert!(!v["b"].is_i64()); /// /// // Numbers with a decimal point are not considered integers. /// assert!(!v["c"].is_i64()); /// ``` #[inline] pub fn is_i64(&self) -> bool { #[cfg(not(feature = "arbitrary_precision"))] match self.n { N::PosInt(v) => v <= i64::max_value() as u64, N::NegInt(_) => true, N::Float(_) => false, } #[cfg(feature = "arbitrary_precision")] self.as_i64().is_some() } /// Returns true if the `Number` is an integer between zero and `u64::MAX`. /// /// For any Number on which `is_u64` returns true, `as_u64` is guaranteed to /// return the integer value. /// /// ``` /// # use serde_json::json; /// # /// let v = json!({ "a": 64, "b": -64, "c": 256.0 }); /// /// assert!(v["a"].is_u64()); /// /// // Negative integer. /// assert!(!v["b"].is_u64()); /// /// // Numbers with a decimal point are not considered integers. /// assert!(!v["c"].is_u64()); /// ``` #[inline] pub fn is_u64(&self) -> bool { #[cfg(not(feature = "arbitrary_precision"))] match self.n { N::PosInt(_) => true, N::NegInt(_) | N::Float(_) => false, } #[cfg(feature = "arbitrary_precision")] self.as_u64().is_some() } /// Returns true if the `Number` can be represented by f64. /// /// For any Number on which `is_f64` returns true, `as_f64` is guaranteed to /// return the floating point value. /// /// Currently this function returns true if and only if both `is_i64` and /// `is_u64` return false but this is not a guarantee in the future. /// /// ``` /// # use serde_json::json; /// # /// let v = json!({ "a": 256.0, "b": 64, "c": -64 }); /// /// assert!(v["a"].is_f64()); /// /// // Integers. /// assert!(!v["b"].is_f64()); /// assert!(!v["c"].is_f64()); /// ``` #[inline] pub fn is_f64(&self) -> bool { #[cfg(not(feature = "arbitrary_precision"))] match self.n { N::Float(_) => true, N::PosInt(_) | N::NegInt(_) => false, } #[cfg(feature = "arbitrary_precision")] { for c in self.n.chars() { if c == '.' || c == 'e' || c == 'E' { return self.n.parse::().ok().map_or(false, f64::is_finite); } } false } } /// If the `Number` is an integer, represent it as i64 if possible. Returns /// None otherwise. /// /// ``` /// # use serde_json::json; /// # /// let big = i64::max_value() as u64 + 10; /// let v = json!({ "a": 64, "b": big, "c": 256.0 }); /// /// assert_eq!(v["a"].as_i64(), Some(64)); /// assert_eq!(v["b"].as_i64(), None); /// assert_eq!(v["c"].as_i64(), None); /// ``` #[inline] pub fn as_i64(&self) -> Option { #[cfg(not(feature = "arbitrary_precision"))] match self.n { N::PosInt(n) => { if n <= i64::max_value() as u64 { Some(n as i64) } else { None } } N::NegInt(n) => Some(n), N::Float(_) => None, } #[cfg(feature = "arbitrary_precision")] self.n.parse().ok() } /// If the `Number` is an integer, represent it as u64 if possible. Returns /// None otherwise. /// /// ``` /// # use serde_json::json; /// # /// let v = json!({ "a": 64, "b": -64, "c": 256.0 }); /// /// assert_eq!(v["a"].as_u64(), Some(64)); /// assert_eq!(v["b"].as_u64(), None); /// assert_eq!(v["c"].as_u64(), None); /// ``` #[inline] pub fn as_u64(&self) -> Option { #[cfg(not(feature = "arbitrary_precision"))] match self.n { N::PosInt(n) => Some(n), N::NegInt(_) | N::Float(_) => None, } #[cfg(feature = "arbitrary_precision")] self.n.parse().ok() } /// Represents the number as f64 if possible. Returns None otherwise. /// /// ``` /// # use serde_json::json; /// # /// let v = json!({ "a": 256.0, "b": 64, "c": -64 }); /// /// assert_eq!(v["a"].as_f64(), Some(256.0)); /// assert_eq!(v["b"].as_f64(), Some(64.0)); /// assert_eq!(v["c"].as_f64(), Some(-64.0)); /// ``` #[inline] pub fn as_f64(&self) -> Option { #[cfg(not(feature = "arbitrary_precision"))] match self.n { N::PosInt(n) => Some(n as f64), N::NegInt(n) => Some(n as f64), N::Float(n) => Some(n), } #[cfg(feature = "arbitrary_precision")] self.n.parse::().ok().filter(|float| float.is_finite()) } /// Converts a finite `f64` to a `Number`. Infinite or NaN values are not JSON /// numbers. /// /// ``` /// # use std::f64; /// # /// # use serde_json::Number; /// # /// assert!(Number::from_f64(256.0).is_some()); /// /// assert!(Number::from_f64(f64::NAN).is_none()); /// ``` #[inline] pub fn from_f64(f: f64) -> Option { if f.is_finite() { let n = { #[cfg(not(feature = "arbitrary_precision"))] { N::Float(f) } #[cfg(feature = "arbitrary_precision")] { ryu::Buffer::new().format_finite(f).to_owned() } }; Some(Number { n }) } else { None } } pub(crate) fn as_f32(&self) -> Option { #[cfg(not(feature = "arbitrary_precision"))] match self.n { N::PosInt(n) => Some(n as f32), N::NegInt(n) => Some(n as f32), N::Float(n) => Some(n as f32), } #[cfg(feature = "arbitrary_precision")] self.n.parse::().ok().filter(|float| float.is_finite()) } pub(crate) fn from_f32(f: f32) -> Option { if f.is_finite() { let n = { #[cfg(not(feature = "arbitrary_precision"))] { N::Float(f as f64) } #[cfg(feature = "arbitrary_precision")] { ryu::Buffer::new().format_finite(f).to_owned() } }; Some(Number { n }) } else { None } } #[cfg(feature = "arbitrary_precision")] /// Not public API. Only tests use this. #[doc(hidden)] #[inline] pub fn from_string_unchecked(n: String) -> Self { Number { n } } } impl Display for Number { #[cfg(not(feature = "arbitrary_precision"))] fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { match self.n { N::PosInt(u) => formatter.write_str(itoa::Buffer::new().format(u)), N::NegInt(i) => formatter.write_str(itoa::Buffer::new().format(i)), N::Float(f) => formatter.write_str(ryu::Buffer::new().format_finite(f)), } } #[cfg(feature = "arbitrary_precision")] fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { Display::fmt(&self.n, formatter) } } impl Debug for Number { fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result { write!(formatter, "Number({})", self) } } impl Serialize for Number { #[cfg(not(feature = "arbitrary_precision"))] #[inline] fn serialize(&self, serializer: S) -> Result where S: Serializer, { match self.n { N::PosInt(u) => serializer.serialize_u64(u), N::NegInt(i) => serializer.serialize_i64(i), N::Float(f) => serializer.serialize_f64(f), } } #[cfg(feature = "arbitrary_precision")] #[inline] fn serialize(&self, serializer: S) -> Result where S: Serializer, { use serde::ser::SerializeStruct; let mut s = serializer.serialize_struct(TOKEN, 1)?; s.serialize_field(TOKEN, &self.n)?; s.end() } } impl<'de> Deserialize<'de> for Number { #[inline] fn deserialize(deserializer: D) -> Result where D: Deserializer<'de>, { struct NumberVisitor; impl<'de> Visitor<'de> for NumberVisitor { type Value = Number; fn expecting(&self, formatter: &mut fmt::Formatter) -> fmt::Result { formatter.write_str("a JSON number") } #[inline] fn visit_i64(self, value: i64) -> Result { Ok(value.into()) } #[inline] fn visit_u64(self, value: u64) -> Result { Ok(value.into()) } #[inline] fn visit_f64(self, value: f64) -> Result where E: de::Error, { Number::from_f64(value).ok_or_else(|| de::Error::custom("not a JSON number")) } #[cfg(feature = "arbitrary_precision")] #[inline] fn visit_map(self, mut visitor: V) -> Result where V: de::MapAccess<'de>, { let value = visitor.next_key::()?; if value.is_none() { return Err(de::Error::invalid_type(Unexpected::Map, &self)); } let v: NumberFromString = visitor.next_value()?; Ok(v.value) } } deserializer.deserialize_any(NumberVisitor) } } #[cfg(feature = "arbitrary_precision")] struct NumberKey; #[cfg(feature = "arbitrary_precision")] impl<'de> de::Deserialize<'de> for NumberKey { fn deserialize(deserializer: D) -> Result where D: de::Deserializer<'de>, { struct FieldVisitor; impl<'de> de::Visitor<'de> for FieldVisitor { type Value = (); fn expecting(&self, formatter: &mut fmt::Formatter) -> fmt::Result { formatter.write_str("a valid number field") } fn visit_str(self, s: &str) -> Result<(), E> where E: de::Error, { if s == TOKEN { Ok(()) } else { Err(de::Error::custom("expected field with custom name")) } } } deserializer.deserialize_identifier(FieldVisitor)?; Ok(NumberKey) } } #[cfg(feature = "arbitrary_precision")] pub struct NumberFromString { pub value: Number, } #[cfg(feature = "arbitrary_precision")] impl<'de> de::Deserialize<'de> for NumberFromString { fn deserialize(deserializer: D) -> Result where D: de::Deserializer<'de>, { struct Visitor; impl<'de> de::Visitor<'de> for Visitor { type Value = NumberFromString; fn expecting(&self, formatter: &mut fmt::Formatter) -> fmt::Result { formatter.write_str("string containing a number") } fn visit_str(self, s: &str) -> Result where E: de::Error, { let n = tri!(s.parse().map_err(de::Error::custom)); Ok(NumberFromString { value: n }) } } deserializer.deserialize_str(Visitor) } } #[cfg(feature = "arbitrary_precision")] fn invalid_number() -> Error { Error::syntax(ErrorCode::InvalidNumber, 0, 0) } macro_rules! deserialize_any { (@expand [$($num_string:tt)*]) => { #[cfg(not(feature = "arbitrary_precision"))] #[inline] fn deserialize_any(self, visitor: V) -> Result where V: Visitor<'de>, { match self.n { N::PosInt(u) => visitor.visit_u64(u), N::NegInt(i) => visitor.visit_i64(i), N::Float(f) => visitor.visit_f64(f), } } #[cfg(feature = "arbitrary_precision")] #[inline] fn deserialize_any(self, visitor: V) -> Result where V: Visitor<'de> { if let Some(u) = self.as_u64() { return visitor.visit_u64(u); } else if let Some(i) = self.as_i64() { return visitor.visit_i64(i); } else if let Some(f) = self.as_f64() { if ryu::Buffer::new().format_finite(f) == self.n || f.to_string() == self.n { return visitor.visit_f64(f); } } visitor.visit_map(NumberDeserializer { number: Some(self.$($num_string)*), }) } }; (owned) => { deserialize_any!(@expand [n]); }; (ref) => { deserialize_any!(@expand [n.clone()]); }; } macro_rules! deserialize_number { ($deserialize:ident => $visit:ident) => { #[cfg(not(feature = "arbitrary_precision"))] fn $deserialize(self, visitor: V) -> Result where V: Visitor<'de>, { self.deserialize_any(visitor) } #[cfg(feature = "arbitrary_precision")] fn $deserialize(self, visitor: V) -> Result where V: de::Visitor<'de>, { visitor.$visit(self.n.parse().map_err(|_| invalid_number())?) } }; } impl<'de> Deserializer<'de> for Number { type Error = Error; deserialize_any!(owned); deserialize_number!(deserialize_i8 => visit_i8); deserialize_number!(deserialize_i16 => visit_i16); deserialize_number!(deserialize_i32 => visit_i32); deserialize_number!(deserialize_i64 => visit_i64); deserialize_number!(deserialize_i128 => visit_i128); deserialize_number!(deserialize_u8 => visit_u8); deserialize_number!(deserialize_u16 => visit_u16); deserialize_number!(deserialize_u32 => visit_u32); deserialize_number!(deserialize_u64 => visit_u64); deserialize_number!(deserialize_u128 => visit_u128); deserialize_number!(deserialize_f32 => visit_f32); deserialize_number!(deserialize_f64 => visit_f64); forward_to_deserialize_any! { bool char str string bytes byte_buf option unit unit_struct newtype_struct seq tuple tuple_struct map struct enum identifier ignored_any } } impl<'de, 'a> Deserializer<'de> for &'a Number { type Error = Error; deserialize_any!(ref); deserialize_number!(deserialize_i8 => visit_i8); deserialize_number!(deserialize_i16 => visit_i16); deserialize_number!(deserialize_i32 => visit_i32); deserialize_number!(deserialize_i64 => visit_i64); deserialize_number!(deserialize_i128 => visit_i128); deserialize_number!(deserialize_u8 => visit_u8); deserialize_number!(deserialize_u16 => visit_u16); deserialize_number!(deserialize_u32 => visit_u32); deserialize_number!(deserialize_u64 => visit_u64); deserialize_number!(deserialize_u128 => visit_u128); deserialize_number!(deserialize_f32 => visit_f32); deserialize_number!(deserialize_f64 => visit_f64); forward_to_deserialize_any! { bool char str string bytes byte_buf option unit unit_struct newtype_struct seq tuple tuple_struct map struct enum identifier ignored_any } } #[cfg(feature = "arbitrary_precision")] pub(crate) struct NumberDeserializer { pub number: Option, } #[cfg(feature = "arbitrary_precision")] impl<'de> MapAccess<'de> for NumberDeserializer { type Error = Error; fn next_key_seed(&mut self, seed: K) -> Result, Error> where K: de::DeserializeSeed<'de>, { if self.number.is_none() { return Ok(None); } seed.deserialize(NumberFieldDeserializer).map(Some) } fn next_value_seed(&mut self, seed: V) -> Result where V: de::DeserializeSeed<'de>, { seed.deserialize(self.number.take().unwrap().into_deserializer()) } } #[cfg(feature = "arbitrary_precision")] struct NumberFieldDeserializer; #[cfg(feature = "arbitrary_precision")] impl<'de> Deserializer<'de> for NumberFieldDeserializer { type Error = Error; fn deserialize_any(self, visitor: V) -> Result where V: de::Visitor<'de>, { visitor.visit_borrowed_str(TOKEN) } forward_to_deserialize_any! { bool u8 u16 u32 u64 u128 i8 i16 i32 i64 i128 f32 f64 char str string seq bytes byte_buf map struct option unit newtype_struct ignored_any unit_struct tuple_struct tuple enum identifier } } impl From for Number { fn from(value: ParserNumber) -> Self { let n = match value { ParserNumber::F64(f) => { #[cfg(not(feature = "arbitrary_precision"))] { N::Float(f) } #[cfg(feature = "arbitrary_precision")] { f.to_string() } } ParserNumber::U64(u) => { #[cfg(not(feature = "arbitrary_precision"))] { N::PosInt(u) } #[cfg(feature = "arbitrary_precision")] { u.to_string() } } ParserNumber::I64(i) => { #[cfg(not(feature = "arbitrary_precision"))] { N::NegInt(i) } #[cfg(feature = "arbitrary_precision")] { i.to_string() } } #[cfg(feature = "arbitrary_precision")] ParserNumber::String(s) => s, }; Number { n } } } macro_rules! impl_from_unsigned { ( $($ty:ty),* ) => { $( impl From<$ty> for Number { #[inline] fn from(u: $ty) -> Self { let n = { #[cfg(not(feature = "arbitrary_precision"))] { N::PosInt(u as u64) } #[cfg(feature = "arbitrary_precision")] { itoa::Buffer::new().format(u).to_owned() } }; Number { n } } } )* }; } macro_rules! impl_from_signed { ( $($ty:ty),* ) => { $( impl From<$ty> for Number { #[inline] fn from(i: $ty) -> Self { let n = { #[cfg(not(feature = "arbitrary_precision"))] { if i < 0 { N::NegInt(i as i64) } else { N::PosInt(i as u64) } } #[cfg(feature = "arbitrary_precision")] { itoa::Buffer::new().format(i).to_owned() } }; Number { n } } } )* }; } impl_from_unsigned!(u8, u16, u32, u64, usize); impl_from_signed!(i8, i16, i32, i64, isize); #[cfg(feature = "arbitrary_precision")] impl_from_unsigned!(u128); #[cfg(feature = "arbitrary_precision")] impl_from_signed!(i128); impl Number { #[cfg(not(feature = "arbitrary_precision"))] #[cold] pub(crate) fn unexpected(&self) -> Unexpected { match self.n { N::PosInt(u) => Unexpected::Unsigned(u), N::NegInt(i) => Unexpected::Signed(i), N::Float(f) => Unexpected::Float(f), } } #[cfg(feature = "arbitrary_precision")] #[cold] pub(crate) fn unexpected(&self) -> Unexpected { Unexpected::Other("number") } }