typederror 0.2.2

A wrapper around anyhow that allows for a primary error type
Documentation 
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# typederror

A wrapper around `anyhow` but with a "primary" error type.

## Motivation

This library aims to be the glue between `anyhow` and `thiserror`.
It allows you to define a primary error type for variants that the caller
should match on, while still capturing any other errors that may have
occurred along the way.

### Documenting the error type of a function

If you simply return an `anyhow::Error`, the caller has no idea what
kind of error to expect. They would need to read your code to determine
what the possible error types are.

By using `TError`, you can specify the primary error type that the caller
should match on. This has the effect of documenting the primary error type
for your function.

```rust
fn my_fallible_function() -> typederror::Result<(), MyError> {
    // Do something that might fail.
    let s = std::fs::read_to_string("file.txt").map_err(|e| MyError::IoError(e))?;
    // NOTE: if `MyError` implements `From<std::io::Error>`,
    // you can do `std::fs::read_to_string("file.txt").terror()?` instead.
    some_operation(s)?; // An error we don't need to match on.
    Ok(())
}
```

The primary error type could be an enum that derives
`thiserror::Error`, where only the meaningful errors are captured by
the enum and any other errors are captured by the `anyhow::Error`
underneath.

You can also implement `DefaultError` so that all other errors are
captured in a special "catch-all" variant of the primary error type.

```rust
#[derive(Debug, thiserror::Error)]
enum MyError {
   #[error("IO error: {0}")]
   IoError(#[from] std::io::Error),
   #[error("{0}")]
   Misc(typederror::anyhow::Error)
}

impl DefaultError for MyError {
    fn from_anyhow(err: typederror::anyhow::Error) -> Self {
        Self::Misc(err)
    }
}
```

### Downcasting to the primary error type

Since `TError` already knows the primary error type, it can provide
convenience methods for downcasting to that type. This allows you to
more easily work with errors of a single type without needing to match
on several different error types.

```rust
if let Err(err) = my_fallible_function() { // returns Result<T, TError<MyError>>
    match err.get() {
        MyError::IoError(e) => { // e is of type `std::io::Error`
            // Handle the error.
        }
        MyError::Misc(e) => { // e is of type `anyhow::Error`
            // Handle the error.
        }
    }
}
```

You can also downcast to other types if needed, the same as you
would with `anyhow`.

```rust
match err.downcast_ref::<serde::Error>() {
    Ok(e) => {
        // Handle serde error.
    }
    Err(e) => {
        // Handle other error.
    }
}
```

### Start simple and add error variants later

To get you started, you can use `TError<()>` as the primary error type.
Or use `typederror::Result<T>` as the return type of your function.
This will effectively work the same as `anyhow`, allowing you to
write your code and worry about error types later.

```rust
fn do_something() -> typederror::Result<()> {
    // Do something.
    my_fallible_function()?;
    Ok(())
}
```

Later, when you want to create specific variants for your function
for easier matching by the caller, you can create an enum,
derive `thiserror::Error`, and use that as the primary error type instead.
You will need to add any necessary conversions, but you only need to add
the variants you want to match on.

All other errors will still be captured as per `anyhow` behaviour, or
they can be captured in a special "catch-all" variant of your enum by
implementing the `DefaultError` trait on the enum.

## Caveats

Unfortunately the `?` operator cannot automatically convert error types
to your primary error type.

For example:
```rust
#[derive(Debug, thiserror::Error)]
enum MyError {
    #[error("IO error: {0}")]
    IoError(#[from] std::io::Error),
    #[error("{0}")]
    Misc(anyhow::Error)
}

impl DefaultError for MyError {
    fn from_anyhow(err: anyhow::Error) -> Self {
        Self::Misc(err)
    }
}

fn my_fallible_function() -> typederror::Result<(), MyError> {
   let s = std::fs::read_to_string("file.txt")?;
   // Do something else with s.
   Ok(())
}

fn main() {
    if let Err(e) = my_fallible_function() {
        match e.get() {
            // ...
        }
    }
}
```

In the above example, the `?` operator will not automatically convert the
`std::io::Error` to `MyError::IoError`, as it would if you had used
`MyError` as the error type directly. The error would instead match as
`MyError::Misc` in the call to `e.get()`.

To capture the `IoError` correctly, change the first line of the function to
```rust
let s = std::fs::read_to_string("file.txt").terror()?;
```

## Minimum Supported Rust Version

The MSRV for `thirtyfour` is currently 1.75 and will be updated as needed by dependencies.

#### License

<sup>
Licensed under either of <a href="LICENSE-APACHE">Apache License, Version
2.0</a> or <a href="LICENSE-MIT">MIT license</a> at your option.
</sup>

<br>

<sub>
Unless you explicitly state otherwise, any contribution intentionally submitted
for inclusion in this crate by you, as defined in the Apache-2.0 license, shall
be dual licensed as above, without any additional terms or conditions.
</sub>

<br>

<sub>
`SPDX-License-Identifier: MIT OR Apache-2.0`
</sub>