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//! Structured values. //! //! This crate contains the [`ValueBag`] type, a container for an anonymous structured value. //! `ValueBag`s can be captured in various ways and then formatted, inspected, and serialized //! without losing their original structure. #![cfg_attr(value_bag_capture_const_type_id, feature(const_type_id))] #![doc(html_root_url = "https://docs.rs/value-bag/1.0.0-alpha.6")] #![no_std] #[cfg(any(feature = "std", test))] #[macro_use] #[allow(unused_imports)] extern crate std; #[cfg(not(any(feature = "std", test)))] #[macro_use] #[allow(unused_imports)] extern crate core as std; mod error; pub mod fill; mod impls; mod internal; pub mod visit; #[cfg(any(test, feature = "test"))] pub mod test; pub use self::error::Error; /// A dynamic structured value. /// /// # Capturing values /// /// There are a few ways to capture a value: /// /// - Using the `ValueBag::capture_*` and `ValueBag::from_*` methods. /// - Using the standard `From` trait. /// - Using the `Fill` API. /// /// ## Using the `ValueBag::capture_*` methods /// /// `ValueBag` offers a few constructor methods that capture values of different kinds. /// These methods require a `T: 'static` to support downcasting. /// /// ``` /// use value_bag::ValueBag; /// /// let value = ValueBag::capture_debug(&42i32); /// /// assert_eq!(Some(42), value.to_i64()); /// ``` /// /// Capturing a value using these methods will retain type information so that /// the contents of the bag can be serialized using an appropriate type. /// /// For cases where the `'static` bound can't be satisfied, there's also a few /// constructors that exclude it. /// /// ``` /// # use std::fmt::Debug; /// use value_bag::ValueBag; /// /// let value = ValueBag::from_debug(&42i32); /// /// assert_eq!(None, value.to_i64()); /// ``` /// /// These `ValueBag::from_*` methods are lossy though and `ValueBag::capture_*` should be preferred. /// /// ## Using the standard `From` trait /// /// Primitive types can be converted into a `ValueBag` using the standard `From` trait. /// /// ``` /// use value_bag::ValueBag; /// /// let value = ValueBag::from(42i32); /// /// assert_eq!(Some(42), value.to_i64()); /// ``` /// /// ## Using the `Fill` API /// /// The [`fill`] module provides a way to bridge APIs that may not be directly /// compatible with other constructor methods. /// /// The `Fill` trait is automatically implemented for closures, so can usually /// be used in libraries that can't implement the trait themselves. /// /// ``` /// use value_bag::{ValueBag, fill::Slot}; /// /// let value = ValueBag::from_fill(&|slot: &mut Slot| { /// #[derive(Debug)] /// struct MyShortLivedValue; /// /// slot.fill_debug(&MyShortLivedValue) /// }); /// /// assert_eq!("MyShortLivedValue", format!("{:?}", value)); /// ``` /// /// The trait can also be implemented manually: /// /// ``` /// # use std::fmt::Debug; /// use value_bag::{ValueBag, Error, fill::{Slot, Fill}}; /// /// struct FillDebug; /// /// impl Fill for FillDebug { /// fn fill(&self, slot: &mut Slot) -> Result<(), Error> { /// slot.fill_debug(&42i32 as &dyn Debug) /// } /// } /// /// let value = ValueBag::from_fill(&FillDebug); /// /// assert_eq!(None, value.to_i64()); /// ``` /// /// # Inspecting values /// /// Once you have a `ValueBag` there are also a few ways to inspect it: /// /// - Using `std::fmt` /// - Using `sval` /// - Using `serde` /// - Using the `ValueBag::visit` method. /// - Using the `ValueBag::to_*` methods. /// - Using the `ValueBag::downcast_ref` method. /// /// ## Using the `ValueBag::visit` method /// /// The [`visit`] module provides a simple visitor API that can be used to inspect /// the structure of primitives stored in a `ValueBag`. /// More complex datatypes can then be handled using `std::fmt`, `sval`, or `serde`. /// /// ``` /// #[cfg(not(feature = "std"))] fn main() {} /// #[cfg(feature = "std")] /// # fn main() -> Result<(), Box<dyn std::error::Error>> { /// # fn escape(buf: &[u8]) -> &[u8] { buf } /// # fn itoa_fmt<T>(num: T) -> Vec<u8> { vec![] } /// # fn ryu_fmt<T>(num: T) -> Vec<u8> { vec![] } /// # use std::io::Write; /// use value_bag::{ValueBag, Error, visit::Visit}; /// /// // Implement some simple custom serialization /// struct MyVisit(Vec<u8>); /// impl<'v> Visit<'v> for MyVisit { /// fn visit_any(&mut self, v: ValueBag) -> Result<(), Error> { /// // Fallback to `Debug` if we didn't visit the value specially /// write!(&mut self.0, "{:?}", v).map_err(|_| Error::msg("failed to write value")) /// } /// /// fn visit_u64(&mut self, v: u64) -> Result<(), Error> { /// self.0.extend_from_slice(itoa_fmt(v).as_slice()); /// Ok(()) /// } /// /// fn visit_i64(&mut self, v: i64) -> Result<(), Error> { /// self.0.extend_from_slice(itoa_fmt(v).as_slice()); /// Ok(()) /// } /// /// fn visit_f64(&mut self, v: f64) -> Result<(), Error> { /// self.0.extend_from_slice(ryu_fmt(v).as_slice()); /// Ok(()) /// } /// /// fn visit_str(&mut self, v: &str) -> Result<(), Error> { /// self.0.push(b'\"'); /// self.0.extend_from_slice(escape(v.as_bytes())); /// self.0.push(b'\"'); /// Ok(()) /// } /// /// fn visit_bool(&mut self, v: bool) -> Result<(), Error> { /// self.0.extend_from_slice(if v { b"true" } else { b"false" }); /// Ok(()) /// } /// } /// /// let value = ValueBag::from(42i64); /// /// let mut visitor = MyVisit(vec![]); /// value.visit(&mut visitor)?; /// # Ok(()) /// # } /// ``` /// /// ## Using `std::fmt` /// /// Any `ValueBag` can be formatted using the `std::fmt` machinery as either `Debug` /// or `Display`. /// /// ``` /// use value_bag::ValueBag; /// /// let value = ValueBag::from(true); /// /// assert_eq!("true", format!("{:?}", value)); /// ``` /// /// ## Using `sval` /// /// When the `sval1` feature is enabled, any `ValueBag` can be serialized using `sval`. /// This makes it possible to visit any typed structure captured in the `ValueBag`, /// including complex datatypes like maps and sequences. /// /// `sval` doesn't need to allocate so can be used in no-std environments. /// /// First, enable the `sval1` feature in your `Cargo.toml`: /// /// ```toml /// [dependencies.value-bag] /// features = ["sval1"] /// ``` /// /// Then stream the contents of the `ValueBag` using `sval`. /// /// ``` /// #[cfg(not(all(feature = "std", feature = "sval1")))] fn main() {} /// #[cfg(all(feature = "std", feature = "sval1"))] /// # fn main() -> Result<(), Box<dyn std::error::Error>> { /// # extern crate sval1_json as sval_json; /// use value_bag::ValueBag; /// /// let value = ValueBag::from(42i64); /// let json = sval_json::to_string(value)?; /// # Ok(()) /// # } /// ``` /// /// ``` /// #[cfg(not(all(feature = "std", feature = "sval1")))] fn main() {} /// #[cfg(all(feature = "std", feature = "sval1"))] /// # fn main() -> Result<(), Box<dyn std::error::Error>> { /// # extern crate sval1_lib as sval; /// # fn escape(buf: &[u8]) -> &[u8] { buf } /// # fn itoa_fmt<T>(num: T) -> Vec<u8> { vec![] } /// # fn ryu_fmt<T>(num: T) -> Vec<u8> { vec![] } /// use value_bag::ValueBag; /// use sval::stream::{self, Stream}; /// /// // Implement some simple custom serialization /// struct MyStream(Vec<u8>); /// impl Stream for MyStream { /// fn u64(&mut self, v: u64) -> stream::Result { /// self.0.extend_from_slice(itoa_fmt(v).as_slice()); /// Ok(()) /// } /// /// fn i64(&mut self, v: i64) -> stream::Result { /// self.0.extend_from_slice(itoa_fmt(v).as_slice()); /// Ok(()) /// } /// /// fn f64(&mut self, v: f64) -> stream::Result { /// self.0.extend_from_slice(ryu_fmt(v).as_slice()); /// Ok(()) /// } /// /// fn str(&mut self, v: &str) -> stream::Result { /// self.0.push(b'\"'); /// self.0.extend_from_slice(escape(v.as_bytes())); /// self.0.push(b'\"'); /// Ok(()) /// } /// /// fn bool(&mut self, v: bool) -> stream::Result { /// self.0.extend_from_slice(if v { b"true" } else { b"false" }); /// Ok(()) /// } /// } /// /// let value = ValueBag::from(42i64); /// /// let mut stream = MyStream(vec![]); /// sval::stream(&mut stream, &value)?; /// # Ok(()) /// # } /// ``` /// /// ## Using `serde` /// /// When the `serde1` feature is enabled, any `ValueBag` can be serialized using `serde`. /// This makes it possible to visit any typed structure captured in the `ValueBag`, /// including complex datatypes like maps and sequences. /// /// `serde` needs a few temporary allocations, so also brings in the `std` feature. /// /// First, enable the `serde1` feature in your `Cargo.toml`: /// /// ```toml /// [dependencies.value-bag] /// features = ["serde1"] /// ``` /// /// Then stream the contents of the `ValueBag` using `serde`. /// /// ``` /// #[cfg(not(all(feature = "std", feature = "serde1")))] fn main() {} /// #[cfg(all(feature = "std", feature = "serde1"))] /// # fn main() -> Result<(), Box<dyn std::error::Error>> { /// # extern crate serde1_json as serde_json; /// use value_bag::ValueBag; /// /// let value = ValueBag::from(42i64); /// let json = serde_json::to_string(&value)?; /// # Ok(()) /// # } /// ``` /// /// Also see [`serde.rs`](https://serde.rs) for more examples of writing your own serializers. /// /// ## Using the `ValueBag::to_*` methods /// /// `ValueBag` provides a set of methods for attempting to pull a concrete value out. /// These are useful for ad-hoc analysis but aren't intended for exhaustively serializing /// the contents of a `ValueBag`. /// /// ``` /// use value_bag::ValueBag; /// /// let value = ValueBag::capture_display(&42u64); /// /// assert_eq!(Some(42u64), value.to_u64()); /// ``` /// /// ## Using the `ValueBag::downcast_ref` method /// /// When a `ValueBag` is created using one of the `capture_*` constructors, it can be downcast /// back to its original value. /// This can also be useful for ad-hoc analysis where there's a common possible non-primitive /// type that could be captured. /// /// ``` /// # #[derive(Debug)] struct SystemTime; /// # fn now() -> SystemTime { SystemTime } /// use value_bag::ValueBag; /// /// let timestamp = now(); /// let value = ValueBag::capture_debug(×tamp); /// /// assert!(value.downcast_ref::<SystemTime>().is_some()); /// ``` #[derive(Clone)] pub struct ValueBag<'v> { inner: internal::Internal<'v>, } #[cfg(test)] mod tests { use super::*; use crate::std::mem; #[test] fn value_bag_size() { let size = mem::size_of::<ValueBag<'_>>(); let limit = mem::size_of::<u64>() * 4; if size > limit { panic!( "`ValueBag` size ({} bytes) is too large (expected up to {} bytes)\n`Primitive`: {} bytes\n`(`&dyn` + `TypeId`): {} bytes", size, limit, mem::size_of::<internal::Primitive<'_>>(), mem::size_of::<(&dyn internal::fmt::Debug, crate::std::any::TypeId)>(), ); } } }