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use core::fmt::{self, Display, Debug}; use {Causes, Fail}; use backtrace::Backtrace; use context::Context; use compat::Compat; #[cfg(feature = "std")] use box_std::BoxStd; #[cfg_attr(feature = "small-error", path = "./error_impl_small.rs")] mod error_impl; use self::error_impl::ErrorImpl; #[cfg(feature = "std")] use std::error::Error as StdError; /// The `Error` type, which can contain any failure. /// /// Functions which accumulate many kinds of errors should return this type. /// All failures can be converted into it, so functions which catch those /// errors can be tried with `?` inside of a function that returns this kind /// of error. /// /// In addition to implementing `Debug` and `Display`, this type carries `Backtrace` /// information, and can be downcast into the failure that underlies it for /// more detailed inspection. pub struct Error { imp: ErrorImpl, } impl<F: Fail> From<F> for Error { fn from(failure: F) -> Error { Error { imp: ErrorImpl::from(failure) } } } impl Error { /// Creates an `Error` from `Box<std::error::Error>`. /// /// This method is useful for comparability with code, /// which does not use the `Fail` trait. /// /// # Example /// /// ``` /// use std::error::Error as StdError; /// use failure::Error; /// /// fn app_fn() -> Result<i32, Error> { /// let x = library_fn().map_err(Error::from_boxed_compat)?; /// Ok(x * 2) /// } /// /// fn library_fn() -> Result<i32, Box<StdError + Sync + Send + 'static>> { /// Ok(92) /// } /// ``` #[cfg(feature = "std")] pub fn from_boxed_compat(err: Box<StdError + Sync + Send + 'static>) -> Error { Error::from(BoxStd(err)) } /// Return a reference to the underlying failure that this `Error` /// contains. pub fn as_fail(&self) -> &Fail { self.imp.failure() } /// Returns a reference to the underlying cause of this `Error`. Unlike the /// method on `Fail`, this does not return an `Option`. The `Error` type /// always has an underlying failure. /// /// This method has been deprecated in favor of the [Error::as_fail] method, /// which does the same thing. #[deprecated(since = "0.1.2", note = "please use 'as_fail()' method instead")] pub fn cause(&self) -> &Fail { self.as_fail() } /// Gets a reference to the `Backtrace` for this `Error`. /// /// If the failure this wrapped carried a backtrace, that backtrace will /// be returned. Otherwise, the backtrace will have been constructed at /// the point that failure was cast into the `Error` type. pub fn backtrace(&self) -> &Backtrace { self.imp.failure().backtrace().unwrap_or(&self.imp.backtrace()) } /// Provides context for this `Error`. /// /// This can provide additional information about this error, appropriate /// to the semantics of the current layer. That is, if you have a /// lower-level error, such as an IO error, you can provide additional context /// about what that error means in the context of your function. This /// gives users of this function more information about what has gone /// wrong. /// /// This takes any type that implements `Display`, as well as /// `Send`/`Sync`/`'static`. In practice, this means it can take a `String` /// or a string literal, or a failure, or some other custom context-carrying /// type. pub fn context<D: Display + Send + Sync + 'static>(self, context: D) -> Context<D> { Context::with_err(context, self) } /// Wraps `Error` in a compatibility type. /// /// This type implements the `Error` trait from `std::error`. If you need /// to pass failure's `Error` to an interface that takes any `Error`, you /// can use this method to get a compatible type. pub fn compat(self) -> Compat<Error> { Compat { error: self } } /// Attempts to downcast this `Error` to a particular `Fail` type. /// /// This downcasts by value, returning an owned `T` if the underlying /// failure is of the type `T`. For this reason it returns a `Result` - in /// the case that the underlying error is of a different type, the /// original `Error` is returned. pub fn downcast<T: Fail>(self) -> Result<T, Error> { self.imp.downcast().map_err(|imp| Error { imp }) } /// Returns the "root cause" of this error - the last value in the /// cause chain which does not return an underlying `cause`. pub fn find_root_cause(&self) -> &Fail { self.as_fail().find_root_cause() } /// Returns a iterator over the causes of this error with the cause /// of the fail as the first item and the `root_cause` as the final item. /// /// Use `iter_chain` to also include the fail of this error itself. pub fn iter_causes(&self) -> Causes { self.as_fail().iter_causes() } /// Returns a iterator over all fails up the chain from the current /// as the first item up to the `root_cause` as the final item. /// /// This means that the chain also includes the fail itself which /// means that it does *not* start with `cause`. To skip the outermost /// fail use `iter_causes` instead. pub fn iter_chain(&self) -> Causes { self.as_fail().iter_chain() } /// Attempts to downcast this `Error` to a particular `Fail` type by /// reference. /// /// If the underlying error is not of type `T`, this will return `None`. pub fn downcast_ref<T: Fail>(&self) -> Option<&T> { self.imp.failure().downcast_ref() } /// Attempts to downcast this `Error` to a particular `Fail` type by /// mutable reference. /// /// If the underlying error is not of type `T`, this will return `None`. pub fn downcast_mut<T: Fail>(&mut self) -> Option<&mut T> { self.imp.failure_mut().downcast_mut() } /// Deprecated alias to `find_root_cause`. #[deprecated(since = "0.1.2", note = "please use the 'find_root_cause()' method instead")] pub fn root_cause(&self) -> &Fail { ::find_root_cause(self.as_fail()) } /// Deprecated alias to `iter_causes`. #[deprecated(since = "0.1.2", note = "please use the 'iter_chain()' method instead")] pub fn causes(&self) -> Causes { Causes { fail: Some(self.as_fail()) } } } impl Display for Error { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { Display::fmt(&self.imp.failure(), f) } } impl Debug for Error { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { let backtrace = self.imp.backtrace(); if backtrace.is_none() { Debug::fmt(&self.imp.failure(), f) } else { write!(f, "{:?}\n\n{:?}", &self.imp.failure(), backtrace) } } } impl AsRef<Fail> for Error { fn as_ref(&self) -> &Fail { self.as_fail() } } #[cfg(test)] mod test { use std::io; use super::Error; fn assert_just_data<T: Send + Sync + 'static>() { } #[test] fn assert_error_is_just_data() { assert_just_data::<Error>(); } #[test] fn methods_seem_to_work() { let io_error: io::Error = io::Error::new(io::ErrorKind::NotFound, "test"); let error: Error = io::Error::new(io::ErrorKind::NotFound, "test").into(); assert!(error.downcast_ref::<io::Error>().is_some()); let _: ::Backtrace = *error.backtrace(); assert_eq!(format!("{:?}", io_error), format!("{:?}", error)); assert_eq!(format!("{}", io_error), format!("{}", error)); drop(error); assert!(true); } }