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use crate::ast::{Enum, Field, Input, Struct, Variant};
use crate::attr::Attrs;
use quote::ToTokens;
use std::collections::BTreeSet as Set;
use syn::{Error, GenericArgument, Member, PathArguments, Result, Type};
impl Input<'_> {
pub(crate) fn validate(&self) -> Result<()> {
match self {
Input::Struct(input) => input.validate(),
Input::Enum(input) => input.validate(),
}
}
}
impl Struct<'_> {
fn validate(&self) -> Result<()> {
check_non_field_attrs(&self.attrs)?;
if let Some(transparent) = self.attrs.transparent {
if self.fields.len() != 1 {
return Err(Error::new_spanned(
transparent.original,
"#[error(transparent)] requires exactly one field",
));
}
if let Some(source) = self.fields.iter().find_map(|f| f.attrs.source) {
return Err(Error::new_spanned(
source,
"transparent error struct can't contain #[source]",
));
}
}
check_field_attrs(&self.fields)?;
for field in &self.fields {
field.validate()?;
}
Ok(())
}
}
impl Enum<'_> {
fn validate(&self) -> Result<()> {
check_non_field_attrs(&self.attrs)?;
let has_display = self.has_display();
for variant in &self.variants {
variant.validate()?;
if has_display && variant.attrs.display.is_none() && variant.attrs.transparent.is_none()
{
return Err(Error::new_spanned(
variant.original,
"missing #[error(\"...\")] display attribute",
));
}
}
let mut from_types = Set::new();
for variant in &self.variants {
if let Some(from_field) = variant.from_field() {
let repr = from_field.ty.to_token_stream().to_string();
if !from_types.insert(repr) {
return Err(Error::new_spanned(
from_field.original,
"cannot derive From because another variant has the same source type",
));
}
}
}
Ok(())
}
}
impl Variant<'_> {
fn validate(&self) -> Result<()> {
check_non_field_attrs(&self.attrs)?;
if self.attrs.transparent.is_some() {
if self.fields.len() != 1 {
return Err(Error::new_spanned(
self.original,
"#[error(transparent)] requires exactly one field",
));
}
if let Some(source) = self.fields.iter().find_map(|f| f.attrs.source) {
return Err(Error::new_spanned(
source,
"transparent variant can't contain #[source]",
));
}
}
check_field_attrs(&self.fields)?;
for field in &self.fields {
field.validate()?;
}
Ok(())
}
}
impl Field<'_> {
fn validate(&self) -> Result<()> {
if let Some(display) = &self.attrs.display {
return Err(Error::new_spanned(
display.original,
"not expected here; the #[error(...)] attribute belongs on top of a struct or an enum variant",
));
}
Ok(())
}
}
fn check_non_field_attrs(attrs: &Attrs) -> Result<()> {
if let Some(from) = &attrs.from {
return Err(Error::new_spanned(
from,
"not expected here; the #[from] attribute belongs on a specific field",
));
}
if let Some(source) = &attrs.source {
return Err(Error::new_spanned(
source,
"not expected here; the #[source] attribute belongs on a specific field",
));
}
if let Some(backtrace) = &attrs.backtrace {
return Err(Error::new_spanned(
backtrace,
"not expected here; the #[backtrace] attribute belongs on a specific field",
));
}
if let Some(display) = &attrs.display {
if attrs.transparent.is_some() {
return Err(Error::new_spanned(
display.original,
"cannot have both #[error(transparent)] and a display attribute",
));
}
}
Ok(())
}
fn check_field_attrs(fields: &[Field]) -> Result<()> {
let mut from_field = None;
let mut source_field = None;
let mut backtrace_field = None;
let mut has_backtrace = false;
for field in fields {
if let Some(from) = field.attrs.from {
if from_field.is_some() {
return Err(Error::new_spanned(from, "duplicate #[from] attribute"));
}
from_field = Some(field);
}
if let Some(source) = field.attrs.source {
if source_field.is_some() {
return Err(Error::new_spanned(source, "duplicate #[source] attribute"));
}
source_field = Some(field);
}
if let Some(backtrace) = field.attrs.backtrace {
if backtrace_field.is_some() {
return Err(Error::new_spanned(
backtrace,
"duplicate #[backtrace] attribute",
));
}
backtrace_field = Some(field);
has_backtrace = true;
}
if let Some(transparent) = field.attrs.transparent {
return Err(Error::new_spanned(
transparent.original,
"#[error(transparent)] needs to go outside the enum or struct, not on an individual field",
));
}
has_backtrace |= field.is_backtrace();
}
if let (Some(from_field), Some(source_field)) = (from_field, source_field) {
if !same_member(from_field, source_field) {
return Err(Error::new_spanned(
from_field.attrs.from,
"#[from] is only supported on the source field, not any other field",
));
}
}
if let Some(from_field) = from_field {
if fields.len() > 1 + has_backtrace as usize {
return Err(Error::new_spanned(
from_field.attrs.from,
"deriving From requires no fields other than source and backtrace",
));
}
}
if let Some(source_field) = source_field.or(from_field) {
if contains_non_static_lifetime(&source_field.ty) {
return Err(Error::new_spanned(
&source_field.original.ty,
"non-static lifetimes are not allowed in the source of an error, because std::error::Error requires the source is dyn Error + 'static",
));
}
}
Ok(())
}
fn same_member(one: &Field, two: &Field) -> bool {
match (&one.member, &two.member) {
(Member::Named(one), Member::Named(two)) => one == two,
(Member::Unnamed(one), Member::Unnamed(two)) => one.index == two.index,
_ => unreachable!(),
}
}
fn contains_non_static_lifetime(ty: &Type) -> bool {
match ty {
Type::Path(ty) => {
let bracketed = match &ty.path.segments.last().unwrap().arguments {
PathArguments::AngleBracketed(bracketed) => bracketed,
_ => return false,
};
for arg in &bracketed.args {
match arg {
GenericArgument::Type(ty) if contains_non_static_lifetime(ty) => return true,
GenericArgument::Lifetime(lifetime) if lifetime.ident != "static" => {
return true
}
_ => {}
}
}
false
}
Type::Reference(ty) => ty
.lifetime
.as_ref()
.map_or(false, |lifetime| lifetime.ident != "static"),
_ => false,
}
}