Derive Macro snafu::Snafu [−][src]
#[derive(Snafu)]
{
// Attributes available to this derive:
#[snafu]
}
Expand description
The Snafu macro is the entrypoint to defining your own error
types. It is designed to require little configuration for the
recommended and typical usecases while still offering flexibility for
unique situations.
Controlling Display
You can specify how the Display trait will be implemented for each
variant. The argument is a format string and the arguments. All of the
fields of the variant will be available and you can call methods on
them, such as filename.display(). As an extension to the current
format string capabilities, a shorthand is available for named
arguments that match a field.
Example
#[derive(Debug, Snafu)]
enum Error {
#[snafu(display("{username} may not log in until they pay USD {amount:E}"))]
UserMustPayForService { username: String, amount: f32 },
}
fn main() {
assert_eq!(
UserMustPayForServiceSnafu {
username: "Stefani",
amount: 1_000_000.0,
}
.build()
.to_string(),
"Stefani may not log in until they pay USD 1E6",
);
}The default Display implementation
It is recommended that you provide a value for snafu(display), but
if it is omitted, the summary of the documentation comment will be
used. If that is not present, the name of the variant will be used.
#[derive(Debug, Snafu)]
enum Error {
/// No user available.
/// You may need to specify one.
MissingUser,
MissingPassword,
}
fn main() {
assert_eq!(
MissingUserSnafu.build().to_string(),
"No user available. You may need to specify one.",
);
assert_eq!(MissingPasswordSnafu.build().to_string(), "MissingPassword");
}Controlling context
Changing the context selector suffix
When context selectors are generated, any Error suffix is removed
and the suffix Snafu is added by default. If you’d prefer a
different suffix, such as Ctx or Context, you can specify that
with #[snafu(context(suffix(SomeIdentifier)))]. If you’d like to
disable the suffix entirely, you can use
#[snafu(context(suffix(false)))].
Example
#[derive(Debug, Snafu)]
enum Error {
UsesTheDefaultSuffixError,
#[snafu(context(suffix(Ctx)))]
HasAnotherSuffix,
#[snafu(context(suffix(false)))]
DoesNotHaveASuffix,
}
fn my_code() -> Result<(), Error> {
UsesTheDefaultSuffixSnafu.fail()?;
HasAnotherSuffixCtx.fail()?;
DoesNotHaveASuffix.fail()?;
Ok(())
}#[snafu(context(suffix))] can be specified on an enum as the default
suffix for variants of the enum. In that case, if you wish to have one
variant with a suffix, you will need to express it explicitly with
#[snafu(context(suffix(SomeIdentifier)))].
Disabling the context selector
Sometimes, an underlying error can only occur in exactly one context
and there’s no additional information that can be provided to the
caller. In these cases, you can use #[snafu(context(false))] to
indicate that no context selector should be created. This allows using
the ? operator directly on the underlying error.
Please think about your end users before making liberal use of this feature. Adding context to an error is often what distinguishes an actionable error from a frustrating one.
Example
#[derive(Debug, Snafu)]
enum Error {
#[snafu(context(false))]
NeedsNoIntroduction { source: VeryUniqueError },
}
fn my_code() -> Result<i32, Error> {
let val = do_something_unique()?;
Ok(val + 10)
}
fn do_something_unique() -> Result<i32, VeryUniqueError> {
// ...
}Controlling visibility
By default, each of the context selectors and their inherent methods will be private. It is our opinion that each module should have one or more error types that are scoped to that module, reducing the need to deal with unrelated errors when matching and increasing cohesiveness.
If you need to access the context selectors from outside of their
module, you can use the #[snafu(visibility)] attribute. This can
be applied to the error type as a default visibility or to
specific context selectors.
There are multiple forms of the attribute:
-
#[snafu(visibility(X))]Xis a normal Rust visibility modifier (pub,pub(crate),pub(in some::path), etc.). -
#[snafu(visibility)]will reset back to private visibility.
#[derive(Debug, Snafu)]
#[snafu(visibility(pub(crate)))] // Sets the default visibility for these context selectors
pub(crate) enum Error {
IsPubCrate, // Uses the default
#[snafu(visibility)]
IsPrivate, // Will be private
}It should be noted that API stability of context selectors is not guaranteed. Therefore, exporting them in a crate’s public API could cause semver breakage for such crates, should SNAFU internals change.
Placing context selectors in modules
When you have multiple error enums that would generate conflicting
context selectors, you can choose to place the context selectors into
a module using snafu(module):
use snafu::prelude::*;
#[derive(Debug, Snafu)]
#[snafu(module)]
enum ReadError {
Opening,
}
fn example() -> Result<(), ReadError> {
read_error::OpeningSnafu.fail()
}
#[derive(Debug, Snafu)]
enum WriteError {
Opening, // Would conflict if `snafu(module)` was not used above.
}By default, the module name will be the snake_case equivalent of the
enum name. You can override the default by providing an argument to
#[snafu(module(...))]:
use snafu::prelude::*;
#[derive(Debug, Snafu)]
#[snafu(module(read))]
enum ReadError {
Opening,
}
fn example() -> Result<(), ReadError> {
read::OpeningSnafu.fail()
}As placing the context selectors in a module naturally namespaces
them, you may wish to combine this option with
#[snafu(context(suffix(false)))]:
use snafu::prelude::*;
#[derive(Debug, Snafu)]
#[snafu(module, context(suffix(false)))]
enum ReadError {
Opening,
}
fn example() -> Result<(), ReadError> {
read_error::Opening.fail()
}The generated module starts with use super::*, so any types or
traits used by the context selectors need to be in scope — complicated
paths may need to be simplified or made absolute.
By default, the visibility of the generated module will be private
while the context selectors inside will be pub(super). Using
#[snafu(visibility)] to control the
visibility will change the visibility of both the module and the
context selectors.
Controlling error sources
Selecting the source field
If your error enum variant contains other errors but the field
cannot be named source, or if it contains a field named source
which is not actually an error, you can use #[snafu(source)] to
indicate if a field is an underlying cause or not:
#[derive(Debug, Snafu)]
enum Error {
SourceIsNotAnError {
#[snafu(source(false))]
source: String,
},
CauseIsAnError {
#[snafu(source)]
cause: another::Error,
},
}Transforming the source
If your error type contains an underlying cause that needs to be
transformed, you can use #[snafu(source(from(...)))]. This takes
two arguments: the real type and an expression to transform from
that type to the type held by the error.
#[derive(Debug, Snafu)]
enum Error {
SourceNeedsToBeBoxed {
#[snafu(source(from(another::Error, Box::new)))]
source: Box<another::Error>,
},
}
#[derive(Debug, Snafu)]
#[snafu(source(from(Error, Box::new)))]
struct ApiError(Box<Error>);Note: If you specify #[snafu(source(from(...)))] then the field
will be treated as a source, even if it’s not named “source” - in
other words, #[snafu(source(from(...)))] implies
#[snafu(source)].
Controlling backtraces
If your error enum variant contains a backtrace but the field
cannot be named backtrace, or if it contains a field named
backtrace which is not actually a backtrace, you can use
#[snafu(backtrace)] to indicate if a field is actually a
backtrace or not:
#[derive(Debug, Snafu)]
enum Error {
BacktraceIsNotABacktrace {
#[snafu(backtrace(false))]
backtrace: bool,
},
TraceIsABacktrace {
#[snafu(backtrace)]
trace: Backtrace,
},
}If your error contains other SNAFU errors which can report
backtraces, you may wish to delegate returning a backtrace to
those errors. To specify this, use #[snafu(backtrace)] on the
source field representing the other error:
#[derive(Debug, Snafu)]
enum Error {
MyError {
#[snafu(backtrace)]
source: another::Error,
},
}Controlling implicitly generated data
Sometimes, you can capture contextual error data without needing any
arguments. Backtraces are a common example, but other
global information like the current time or thread ID could also be
useful. In these cases, you can use #[snafu(implicit)] on a field
that implements GenerateImplicitData to remove the need to specify
that data at error construction time:
use snafu::prelude::*;
use std::time::Instant;
#[derive(Debug, PartialEq)]
struct Timestamp(Instant);
impl snafu::GenerateImplicitData for Timestamp {
fn generate() -> Self {
Timestamp(Instant::now())
}
}
#[derive(Debug, Snafu)]
struct RequestError {
#[snafu(implicit)]
timestamp: Timestamp,
}
fn do_request() -> Result<(), RequestError> {
// ...
ensure!(request_count < 3, RequestSnafu);
Ok(())
}You can use #[snafu(implicit(false))] if a field is incorrectly
automatically identified as containing implicit data.
Controlling stringly-typed errors
This allows your custom error type to behave like the Whatever
error type. Since it is your type, you can implement additional
methods or traits. When placed on a struct or enum variant, you will
be able to use the type with the whatever! macro as well as
whatever_context methods, such as ResultExt::whatever_context.
#[derive(Debug, Snafu)]
enum Error {
SpecificError {
username: String,
},
#[snafu(whatever, display("{message}"))]
GenericError {
message: String,
// Having a `source` is optional, but if it is present, it must
// have this specific attribute and type:
#[snafu(source(from(Box<dyn std::error::Error>, Some)))]
source: Option<Box<dyn std::error::Error>>,
},
}Controlling how the snafu crate is resolved
If the snafu crate is not called snafu for some reason, you can
use #[snafu(crate_root)] to instruct the macro how to find the crate
root:
use my_custom_naming_of_snafu::Snafu;
#[derive(Debug, Snafu)]
#[snafu(crate_root(my_custom_naming_of_snafu))]
enum Error {
SomeFailureMode,
}
#[derive(Debug, Snafu)]
#[snafu(crate_root(my_custom_naming_of_snafu))]
struct ApiError(Error);