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/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
use crate::literal::convert_default_value;
use crate::InterfaceCollector;
use anyhow::{bail, Result};
use uniffi_meta::{
CallbackInterfaceMetadata, FieldMetadata, RecordMetadata, TraitMethodMetadata, VariantMetadata,
};
mod callables;
mod enum_;
mod interface;
/// Trait to help convert WedIDL syntax nodes into `InterfaceCollector` objects.
///
/// This trait does structural matching on the various weedle AST nodes and converts
/// them into appropriate structs that we can use to build up the contents of a
/// `InterfaceCollector`. It is basically the `TryFrom` trait except that the conversion
/// always happens in the context of a given `InterfaceCollector`, which is used for
/// resolving e.g. type definitions.
///
/// The difference between this trait and `APIBuilder` is that `APIConverter` treats the
/// `InterfaceCollector` as a read-only data source for resolving types, while `APIBuilder`
/// actually mutates the `InterfaceCollector` to add new definitions.
pub(crate) trait APIConverter<T> {
fn convert(&self, ci: &mut InterfaceCollector) -> Result<T>;
}
// Convert UDL docstring into metadata docstring
pub(crate) fn convert_docstring(docstring: &str) -> String {
textwrap::dedent(docstring)
}
/// Convert a list of weedle items into a list of `InterfaceCollector` items,
/// by doing a direct item-by-item mapping.
impl<U, T: APIConverter<U>> APIConverter<Vec<U>> for Vec<T> {
fn convert(&self, ci: &mut InterfaceCollector) -> Result<Vec<U>> {
self.iter().map(|v| v.convert(ci)).collect::<Result<_>>()
}
}
impl APIConverter<VariantMetadata> for weedle::interface::OperationInterfaceMember<'_> {
fn convert(&self, ci: &mut InterfaceCollector) -> Result<VariantMetadata> {
if self.special.is_some() {
bail!("special operations not supported");
}
if let Some(weedle::interface::StringifierOrStatic::Stringifier(_)) = self.modifier {
bail!("stringifiers are not supported");
}
// OK, so this is a little weird.
// The syntax we use for enum interface members is `Name(type arg, ...);`, which parses
// as an anonymous operation where `Name` is the return type. We re-interpret it to
// use `Name` as the name of the variant.
if self.identifier.is_some() {
bail!("enum interface members must not have a method name");
}
let name: String = {
use weedle::types::{
NonAnyType::{self, Identifier},
ReturnType,
SingleType::NonAny,
Type::Single,
};
match &self.return_type {
ReturnType::Type(Single(NonAny(Identifier(id)))) => id.type_.0.to_owned(),
// Using recognized/parsed types as enum variant names can lead to the bail error because they match
// before `Identifier`. `Error` is one that's likely to be common, so we're circumventing what is
// likely a parsing issue here. As an example of the issue `Promise` (`Promise(PromiseType<'a>)`) as
// a variant matches the `Identifier` arm, but `DataView` (`DataView(MayBeNull<term!(DataView)>)`)
// fails.
ReturnType::Type(Single(NonAny(NonAnyType::Error(_)))) => "Error".to_string(),
_ => bail!("enum interface members must have plain identifiers as names"),
}
};
Ok(VariantMetadata {
name,
discr: None,
fields: self
.args
.body
.list
.iter()
.map(|arg| arg.convert(ci))
.collect::<Result<Vec<_>>>()?,
docstring: self.docstring.as_ref().map(|v| convert_docstring(&v.0)),
})
}
}
impl APIConverter<RecordMetadata> for weedle::DictionaryDefinition<'_> {
fn convert(&self, ci: &mut InterfaceCollector) -> Result<RecordMetadata> {
if self.attributes.is_some() {
bail!("dictionary attributes are not supported yet");
}
if self.inheritance.is_some() {
bail!("dictionary inheritance is not supported");
}
Ok(RecordMetadata {
module_path: ci.module_path(),
name: self.identifier.0.to_string(),
fields: self.members.body.convert(ci)?,
docstring: self.docstring.as_ref().map(|v| convert_docstring(&v.0)),
})
}
}
impl APIConverter<FieldMetadata> for weedle::dictionary::DictionaryMember<'_> {
fn convert(&self, ci: &mut InterfaceCollector) -> Result<FieldMetadata> {
if self.attributes.is_some() {
bail!("dictionary member attributes are not supported yet");
}
let type_ = ci.resolve_type_expression(&self.type_)?;
let default = match self.default {
None => None,
Some(v) => Some(convert_default_value(&v.value, &type_)?),
};
Ok(FieldMetadata {
name: self.identifier.0.to_string(),
ty: type_,
default,
docstring: self.docstring.as_ref().map(|v| convert_docstring(&v.0)),
})
}
}
impl APIConverter<CallbackInterfaceMetadata> for weedle::CallbackInterfaceDefinition<'_> {
fn convert(&self, ci: &mut InterfaceCollector) -> Result<CallbackInterfaceMetadata> {
if self.attributes.is_some() {
bail!("callback interface attributes are not supported yet");
}
if self.inheritance.is_some() {
bail!("callback interface inheritance is not supported");
}
let object_name = self.identifier.0;
for (index, member) in self.members.body.iter().enumerate() {
match member {
weedle::interface::InterfaceMember::Operation(t) => {
let mut method: TraitMethodMetadata = t.convert(ci)?;
// A CallbackInterface is described in Rust as a trait, but uniffi
// generates a struct implementing the trait and passes the concrete version
// of that.
// This really just reflects the fact that CallbackInterface and Object
// should be merged; we'd still need a way to ask for a struct delegating to
// foreign implementations be done.
// But currently they are passed as a concrete type with no associated types.
method.trait_name = object_name.to_string();
method.index = index as u32;
ci.items.insert(method.into());
}
_ => bail!(
"no support for callback interface member type {:?} yet",
member
),
}
}
Ok(CallbackInterfaceMetadata {
module_path: ci.module_path(),
name: object_name.to_string(),
docstring: self.docstring.as_ref().map(|v| convert_docstring(&v.0)),
})
}
}
#[cfg(test)]
mod test {
use super::*;
use uniffi_meta::{LiteralMetadata, Metadata, Radix, Type};
#[test]
fn test_multiple_record_types() {
const UDL: &str = r#"
namespace test{};
dictionary Empty {};
dictionary Simple {
u32 field;
};
dictionary Complex {
string? key;
u32 value = 0;
required boolean spin;
};
"#;
let mut ci = InterfaceCollector::from_webidl(UDL, "crate-name").unwrap();
assert_eq!(ci.items.len(), 3);
match &ci.items.pop_first().unwrap() {
Metadata::Record(record) => {
assert_eq!(record.name, "Complex");
assert_eq!(record.fields.len(), 3);
assert_eq!(record.fields[0].name, "key");
assert_eq!(
record.fields[0].ty,
Type::Optional {
inner_type: Box::new(Type::String)
}
);
assert!(record.fields[0].default.is_none());
assert_eq!(record.fields[1].name, "value");
assert_eq!(record.fields[1].ty, Type::UInt32);
assert!(matches!(
record.fields[1].default,
Some(LiteralMetadata::UInt(0, Radix::Decimal, Type::UInt32))
));
assert_eq!(record.fields[2].name, "spin");
assert_eq!(record.fields[2].ty, Type::Boolean);
assert!(record.fields[2].default.is_none());
}
_ => unreachable!(),
}
match &ci.items.pop_first().unwrap() {
Metadata::Record(record) => {
assert_eq!(record.name, "Empty");
assert_eq!(record.fields.len(), 0);
}
_ => unreachable!(),
}
match &ci.items.pop_first().unwrap() {
Metadata::Record(record) => {
assert_eq!(record.name, "Simple");
assert_eq!(record.fields.len(), 1);
assert_eq!(record.fields[0].name, "field");
assert_eq!(record.fields[0].ty, Type::UInt32);
assert!(record.fields[0].default.is_none());
}
_ => unreachable!(),
}
}
}