use crate::syntax::discriminant::DiscriminantSet;
use crate::syntax::file::{Item, ItemForeignMod};
use crate::syntax::report::Errors;
use crate::syntax::Atom::*;
use crate::syntax::{
attrs, error, Api, Doc, Enum, ExternFn, ExternType, Impl, Include, IncludeKind, Lang,
Namespace, Pair, Receiver, Ref, ResolvableName, Signature, Slice, Struct, Ty1, Type, TypeAlias,
Var, Variant,
};
use proc_macro2::{Delimiter, Group, Span, TokenStream, TokenTree};
use quote::{format_ident, quote, quote_spanned};
use syn::parse::{ParseStream, Parser};
use syn::punctuated::Punctuated;
use syn::{
Abi, Attribute, Error, Fields, FnArg, ForeignItem, ForeignItemFn, ForeignItemType,
GenericArgument, GenericParam, Generics, Ident, ItemEnum, ItemImpl, ItemStruct, LitStr, Pat,
PathArguments, Result, ReturnType, Token, Type as RustType, TypeBareFn, TypePath,
TypeReference, TypeSlice,
};
pub mod kw {
syn::custom_keyword!(Pin);
syn::custom_keyword!(Result);
}
pub fn parse_items(
cx: &mut Errors,
items: Vec<Item>,
trusted: bool,
namespace: &Namespace,
) -> Vec<Api> {
let mut apis = Vec::new();
for item in items {
match item {
Item::Struct(item) => match parse_struct(cx, item, namespace) {
Ok(strct) => apis.push(strct),
Err(err) => cx.push(err),
},
Item::Enum(item) => match parse_enum(cx, item, namespace) {
Ok(enm) => apis.push(enm),
Err(err) => cx.push(err),
},
Item::ForeignMod(foreign_mod) => {
parse_foreign_mod(cx, foreign_mod, &mut apis, trusted, namespace)
}
Item::Impl(item) => match parse_impl(item, namespace) {
Ok(imp) => apis.push(imp),
Err(err) => cx.push(err),
},
Item::Use(item) => cx.error(item, error::USE_NOT_ALLOWED),
Item::Other(item) => cx.error(item, "unsupported item"),
}
}
apis
}
fn parse_struct(cx: &mut Errors, item: ItemStruct, namespace: &Namespace) -> Result<Api> {
let generics = &item.generics;
if !generics.params.is_empty() || generics.where_clause.is_some() {
let struct_token = item.struct_token;
let ident = &item.ident;
let where_clause = &generics.where_clause;
let span = quote!(#struct_token #ident #generics #where_clause);
return Err(Error::new_spanned(
span,
"struct with generic parameters is not supported yet",
));
}
let mut doc = Doc::new();
let mut derives = Vec::new();
let mut namespace = namespace.clone();
attrs::parse(
cx,
&item.attrs,
attrs::Parser {
doc: Some(&mut doc),
derives: Some(&mut derives),
namespace: Some(&mut namespace),
..Default::default()
},
);
let named_fields = match item.fields {
Fields::Named(fields) => fields,
Fields::Unit => return Err(Error::new_spanned(item, "unit structs are not supported")),
Fields::Unnamed(_) => {
return Err(Error::new_spanned(item, "tuple structs are not supported"));
}
};
let fields = named_fields
.named
.into_iter()
.map(|field| {
Ok(Var {
ident: field.ident.unwrap(),
ty: parse_type(&field.ty, &namespace)?,
})
})
.collect::<Result<_>>()?;
Ok(Api::Struct(Struct {
doc,
derives,
struct_token: item.struct_token,
name: Pair::new(namespace, item.ident),
brace_token: named_fields.brace_token,
fields,
}))
}
fn parse_enum(cx: &mut Errors, item: ItemEnum, namespace: &Namespace) -> Result<Api> {
let generics = &item.generics;
if !generics.params.is_empty() || generics.where_clause.is_some() {
let enum_token = item.enum_token;
let ident = &item.ident;
let where_clause = &generics.where_clause;
let span = quote!(#enum_token #ident #generics #where_clause);
return Err(Error::new_spanned(
span,
"enums with generic parameters are not allowed",
));
}
let mut doc = Doc::new();
let mut repr = None;
let mut namespace = namespace.clone();
attrs::parse(
cx,
&item.attrs,
attrs::Parser {
doc: Some(&mut doc),
repr: Some(&mut repr),
namespace: Some(&mut namespace),
..Default::default()
},
);
let mut variants = Vec::new();
let mut discriminants = DiscriminantSet::new(repr);
for variant in item.variants {
match variant.fields {
Fields::Unit => {}
_ => {
cx.error(variant, "enums with data are not supported yet");
break;
}
}
let expr = variant.discriminant.as_ref().map(|(_, expr)| expr);
let try_discriminant = match &expr {
Some(lit) => discriminants.insert(lit),
None => discriminants.insert_next(),
};
let discriminant = match try_discriminant {
Ok(discriminant) => discriminant,
Err(err) => {
cx.error(variant, err);
break;
}
};
let expr = variant.discriminant.map(|(_, expr)| expr);
variants.push(Variant {
ident: variant.ident,
discriminant,
expr,
});
}
let enum_token = item.enum_token;
let brace_token = item.brace_token;
let mut repr = U8;
match discriminants.inferred_repr() {
Ok(inferred) => repr = inferred,
Err(err) => {
let span = quote_spanned!(brace_token.span=> #enum_token {});
cx.error(span, err);
variants.clear();
}
}
let ident = Ident::new(repr.as_ref(), Span::call_site());
let repr_type = Type::Ident(ResolvableName::new(ident));
Ok(Api::Enum(Enum {
doc,
enum_token,
name: Pair::new(namespace, item.ident),
brace_token,
variants,
repr,
repr_type,
}))
}
fn parse_foreign_mod(
cx: &mut Errors,
foreign_mod: ItemForeignMod,
out: &mut Vec<Api>,
trusted: bool,
namespace: &Namespace,
) {
let lang = match parse_lang(&foreign_mod.abi) {
Ok(lang) => lang,
Err(err) => return cx.push(err),
};
match lang {
Lang::Rust => {
if foreign_mod.unsafety.is_some() {
let unsafety = foreign_mod.unsafety;
let abi = &foreign_mod.abi;
let span = quote!(#unsafety #abi);
cx.error(span, "extern \"Rust\" block does not need to be unsafe");
}
}
Lang::Cxx => {}
}
let trusted = trusted || foreign_mod.unsafety.is_some();
let mut namespace = namespace.clone();
attrs::parse(
cx,
&foreign_mod.attrs,
attrs::Parser {
namespace: Some(&mut namespace),
..Default::default()
},
);
let mut items = Vec::new();
for foreign in &foreign_mod.items {
match foreign {
ForeignItem::Type(foreign) => {
match parse_extern_type(cx, foreign, lang, trusted, &namespace) {
Ok(ety) => items.push(ety),
Err(err) => cx.push(err),
}
}
ForeignItem::Fn(foreign) => {
match parse_extern_fn(cx, foreign, lang, trusted, &namespace) {
Ok(efn) => items.push(efn),
Err(err) => cx.push(err),
}
}
ForeignItem::Macro(foreign) if foreign.mac.path.is_ident("include") => {
match foreign.mac.parse_body_with(parse_include) {
Ok(include) => items.push(Api::Include(include)),
Err(err) => cx.push(err),
}
}
ForeignItem::Verbatim(tokens) => {
match parse_extern_verbatim(cx, tokens, lang, &namespace) {
Ok(api) => items.push(api),
Err(err) => cx.push(err),
}
}
_ => cx.error(foreign, "unsupported foreign item"),
}
}
if !trusted
&& items.iter().any(|api| match api {
Api::CxxFunction(efn) => efn.unsafety.is_none(),
_ => false,
})
{
cx.error(
foreign_mod.abi,
"block must be declared `unsafe extern \"C++\"` if it contains any safe-to-call C++ functions",
);
}
let mut types = items.iter().filter_map(|item| match item {
Api::CxxType(ety) | Api::RustType(ety) => Some(&ety.name),
Api::TypeAlias(alias) => Some(&alias.name),
_ => None,
});
if let (Some(single_type), None) = (types.next(), types.next()) {
let single_type = single_type.clone();
for item in &mut items {
if let Api::CxxFunction(efn) | Api::RustFunction(efn) = item {
if let Some(receiver) = &mut efn.receiver {
if receiver.ty.is_self() {
receiver.ty = ResolvableName::new(single_type.rust.clone());
}
}
}
}
}
out.extend(items);
}
fn parse_lang(abi: &Abi) -> Result<Lang> {
let name = match &abi.name {
Some(name) => name,
None => {
return Err(Error::new_spanned(
abi,
"ABI name is required, extern \"C++\" or extern \"Rust\"",
));
}
};
match name.value().as_str() {
"C++" => Ok(Lang::Cxx),
"Rust" => Ok(Lang::Rust),
_ => Err(Error::new_spanned(
abi,
"unrecognized ABI, requires either \"C++\" or \"Rust\"",
)),
}
}
fn parse_extern_type(
cx: &mut Errors,
foreign_type: &ForeignItemType,
lang: Lang,
trusted: bool,
namespace: &Namespace,
) -> Result<Api> {
let mut doc = Doc::new();
let mut namespace = namespace.clone();
attrs::parse(
cx,
&foreign_type.attrs,
attrs::Parser {
doc: Some(&mut doc),
namespace: Some(&mut namespace),
..Default::default()
},
);
let type_token = foreign_type.type_token;
let ident = foreign_type.ident.clone();
let semi_token = foreign_type.semi_token;
let api_type = match lang {
Lang::Cxx => Api::CxxType,
Lang::Rust => Api::RustType,
};
Ok(api_type(ExternType {
doc,
type_token,
name: Pair::new(namespace, ident),
semi_token,
trusted,
}))
}
fn parse_extern_fn(
cx: &mut Errors,
foreign_fn: &ForeignItemFn,
lang: Lang,
trusted: bool,
namespace: &Namespace,
) -> Result<Api> {
let generics = &foreign_fn.sig.generics;
if generics.where_clause.is_some()
|| generics.params.iter().any(|param| match param {
GenericParam::Lifetime(lifetime) => !lifetime.bounds.is_empty(),
GenericParam::Type(_) | GenericParam::Const(_) => true,
})
{
return Err(Error::new_spanned(
foreign_fn,
"extern function with generic parameters is not supported yet",
));
}
if let Some(variadic) = &foreign_fn.sig.variadic {
return Err(Error::new_spanned(
variadic,
"variadic function is not supported yet",
));
}
if foreign_fn.sig.asyncness.is_some() {
return Err(Error::new_spanned(
foreign_fn,
"async function is not directly supported yet, but see https://cxx.rs/async.html for a working approach",
));
}
if foreign_fn.sig.constness.is_some() {
return Err(Error::new_spanned(
foreign_fn,
"const extern function is not supported",
));
}
if let Some(abi) = &foreign_fn.sig.abi {
return Err(Error::new_spanned(
abi,
"explicit ABI on extern function is not supported",
));
}
let mut doc = Doc::new();
let mut cxx_name = None;
let mut rust_name = None;
let mut namespace = namespace.clone();
attrs::parse(
cx,
&foreign_fn.attrs,
attrs::Parser {
doc: Some(&mut doc),
cxx_name: Some(&mut cxx_name),
rust_name: Some(&mut rust_name),
namespace: Some(&mut namespace),
..Default::default()
},
);
let mut receiver = None;
let mut args = Punctuated::new();
for arg in foreign_fn.sig.inputs.pairs() {
let (arg, comma) = arg.into_tuple();
match arg {
FnArg::Receiver(arg) => {
if let Some((ampersand, lifetime)) = &arg.reference {
receiver = Some(Receiver {
pinned: false,
ampersand: *ampersand,
lifetime: lifetime.clone(),
mutable: arg.mutability.is_some(),
var: arg.self_token,
ty: ResolvableName::make_self(arg.self_token.span),
shorthand: true,
pin_tokens: None,
mutability: arg.mutability,
});
continue;
}
return Err(Error::new_spanned(arg, "unsupported signature"));
}
FnArg::Typed(arg) => {
let ident = match arg.pat.as_ref() {
Pat::Ident(pat) => pat.ident.clone(),
Pat::Wild(pat) => {
Ident::new(&format!("_{}", args.len()), pat.underscore_token.span)
}
_ => return Err(Error::new_spanned(arg, "unsupported signature")),
};
let ty = parse_type(&arg.ty, &namespace)?;
if ident != "self" {
args.push_value(Var { ident, ty });
if let Some(comma) = comma {
args.push_punct(*comma);
}
continue;
}
if let Type::Ref(reference) = ty {
if let Type::Ident(ident) = reference.inner {
receiver = Some(Receiver {
pinned: reference.pinned,
ampersand: reference.ampersand,
lifetime: reference.lifetime,
mutable: reference.mutable,
var: Token),
ty: ident,
shorthand: false,
pin_tokens: reference.pin_tokens,
mutability: reference.mutability,
});
continue;
}
}
return Err(Error::new_spanned(arg, "unsupported method receiver"));
}
}
}
let mut throws_tokens = None;
let ret = parse_return_type(&foreign_fn.sig.output, &mut throws_tokens, &namespace)?;
let throws = throws_tokens.is_some();
let unsafety = foreign_fn.sig.unsafety;
let fn_token = foreign_fn.sig.fn_token;
let name = Pair::new_from_differing_names(
namespace,
cxx_name.unwrap_or(foreign_fn.sig.ident.clone()),
rust_name.unwrap_or(foreign_fn.sig.ident.clone()),
);
let generics = generics.clone();
let paren_token = foreign_fn.sig.paren_token;
let semi_token = foreign_fn.semi_token;
let api_function = match lang {
Lang::Cxx => Api::CxxFunction,
Lang::Rust => Api::RustFunction,
};
Ok(api_function(ExternFn {
lang,
doc,
name,
sig: Signature {
unsafety,
fn_token,
generics,
receiver,
args,
ret,
throws,
paren_token,
throws_tokens,
},
semi_token,
trusted,
}))
}
fn parse_extern_verbatim(
cx: &mut Errors,
tokens: &TokenStream,
lang: Lang,
namespace: &Namespace,
) -> Result<Api> {
let parse = |input: ParseStream| -> Result<TypeAlias> {
let attrs = input.call(Attribute::parse_outer)?;
let type_token: Token![type] = match input.parse()? {
Some(type_token) => type_token,
None => {
let span = input.cursor().token_stream();
return Err(Error::new_spanned(span, "unsupported foreign item"));
}
};
let ident: Ident = input.parse()?;
let eq_token: Token![=] = input.parse()?;
let ty: RustType = input.parse()?;
let semi_token: Token![;] = input.parse()?;
let mut doc = Doc::new();
let mut namespace = namespace.clone();
attrs::parse(
cx,
&attrs,
attrs::Parser {
doc: Some(&mut doc),
namespace: Some(&mut namespace),
..Default::default()
},
);
Ok(TypeAlias {
doc,
type_token,
name: Pair::new(namespace, ident),
eq_token,
ty,
semi_token,
})
};
let type_alias = parse.parse2(tokens.clone())?;
match lang {
Lang::Cxx => Ok(Api::TypeAlias(type_alias)),
Lang::Rust => {
let (type_token, semi_token) = (type_alias.type_token, type_alias.semi_token);
let span = quote!(#type_token #semi_token);
let msg = "type alias in extern \"Rust\" block is not supported";
Err(Error::new_spanned(span, msg))
}
}
}
fn parse_impl(imp: ItemImpl, namespace: &Namespace) -> Result<Api> {
if !imp.items.is_empty() {
let mut span = Group::new(Delimiter::Brace, TokenStream::new());
span.set_span(imp.brace_token.span);
return Err(Error::new_spanned(span, "expected an empty impl block"));
}
let self_ty = &imp.self_ty;
if let Some((bang, path, for_token)) = &imp.trait_ {
let span = quote!(#bang #path #for_token #self_ty);
return Err(Error::new_spanned(
span,
"unexpected impl, expected something like `impl UniquePtr<T> {}`",
));
}
let generics = &imp.generics;
if !generics.params.is_empty() || generics.where_clause.is_some() {
return Err(Error::new_spanned(
imp,
"generic parameters on an impl is not supported",
));
}
Ok(Api::Impl(Impl {
impl_token: imp.impl_token,
ty: parse_type(&self_ty, namespace)?,
brace_token: imp.brace_token,
}))
}
fn parse_include(input: ParseStream) -> Result<Include> {
if input.peek(LitStr) {
let lit: LitStr = input.parse()?;
let span = lit.span();
return Ok(Include {
path: lit.value(),
kind: IncludeKind::Quoted,
begin_span: span,
end_span: span,
});
}
if input.peek(Token![<]) {
let mut path = String::new();
let langle: Token![<] = input.parse()?;
while !input.is_empty() && !input.peek(Token![>]) {
let token: TokenTree = input.parse()?;
match token {
TokenTree::Ident(token) => path += &token.to_string(),
TokenTree::Literal(token)
if token
.to_string()
.starts_with(|ch: char| ch.is_ascii_digit()) =>
{
path += &token.to_string();
}
TokenTree::Punct(token) => path.push(token.as_char()),
_ => return Err(Error::new(token.span(), "unexpected token in include path")),
}
}
let rangle: Token![>] = input.parse()?;
return Ok(Include {
path,
kind: IncludeKind::Bracketed,
begin_span: langle.span,
end_span: rangle.span,
});
}
Err(input.error("expected \"quoted/path/to\" or <bracketed/path/to>"))
}
fn parse_type(ty: &RustType, namespace: &Namespace) -> Result<Type> {
match ty {
RustType::Reference(ty) => parse_type_reference(ty, namespace),
RustType::Path(ty) => parse_type_path(ty, namespace),
RustType::Slice(ty) => parse_type_slice(ty, namespace),
RustType::BareFn(ty) => parse_type_fn(ty, namespace),
RustType::Tuple(ty) if ty.elems.is_empty() => Ok(Type::Void(ty.paren_token.span)),
_ => Err(Error::new_spanned(ty, "unsupported type")),
}
}
fn parse_type_reference(ty: &TypeReference, namespace: &Namespace) -> Result<Type> {
let inner = parse_type(&ty.elem, namespace)?;
let which = match &inner {
Type::Ident(ident) if ident.rust == "str" => {
if ty.mutability.is_some() {
return Err(Error::new_spanned(ty, "unsupported type"));
} else {
Type::Str
}
}
Type::Slice(slice) => match &slice.inner {
Type::Ident(ident) if ident.rust == U8 && ty.mutability.is_none() => Type::SliceRefU8,
_ => Type::Ref,
},
_ => Type::Ref,
};
Ok(which(Box::new(Ref {
pinned: false,
ampersand: ty.and_token,
lifetime: ty.lifetime.clone(),
mutable: ty.mutability.is_some(),
inner,
pin_tokens: None,
mutability: ty.mutability,
})))
}
fn parse_type_path(ty: &TypePath, namespace: &Namespace) -> Result<Type> {
let path = &ty.path;
if ty.qself.is_none() && path.leading_colon.is_none() && path.segments.len() == 1 {
let segment = &path.segments[0];
let ident = segment.ident.clone();
match &segment.arguments {
PathArguments::None => return Ok(Type::Ident(ResolvableName::new(ident))),
PathArguments::AngleBracketed(generic) => {
if ident == "UniquePtr" && generic.args.len() == 1 {
if let GenericArgument::Type(arg) = &generic.args[0] {
let inner = parse_type(arg, namespace)?;
return Ok(Type::UniquePtr(Box::new(Ty1 {
name: ident,
langle: generic.lt_token,
inner,
rangle: generic.gt_token,
})));
}
} else if ident == "CxxVector" && generic.args.len() == 1 {
if let GenericArgument::Type(arg) = &generic.args[0] {
let inner = parse_type(arg, namespace)?;
return Ok(Type::CxxVector(Box::new(Ty1 {
name: ident,
langle: generic.lt_token,
inner,
rangle: generic.gt_token,
})));
}
} else if ident == "Box" && generic.args.len() == 1 {
if let GenericArgument::Type(arg) = &generic.args[0] {
let inner = parse_type(arg, namespace)?;
return Ok(Type::RustBox(Box::new(Ty1 {
name: ident,
langle: generic.lt_token,
inner,
rangle: generic.gt_token,
})));
}
} else if ident == "Vec" && generic.args.len() == 1 {
if let GenericArgument::Type(arg) = &generic.args[0] {
let inner = parse_type(arg, namespace)?;
return Ok(Type::RustVec(Box::new(Ty1 {
name: ident,
langle: generic.lt_token,
inner,
rangle: generic.gt_token,
})));
}
} else if ident == "Pin" && generic.args.len() == 1 {
if let GenericArgument::Type(arg) = &generic.args[0] {
let inner = parse_type(arg, namespace)?;
let pin_token = kw::Pin(ident.span());
if let Type::Ref(mut inner) = inner {
inner.pinned = true;
inner.pin_tokens =
Some((pin_token, generic.lt_token, generic.gt_token));
return Ok(Type::Ref(inner));
}
}
}
}
PathArguments::Parenthesized(_) => {}
}
}
Err(Error::new_spanned(ty, "unsupported type"))
}
fn parse_type_slice(ty: &TypeSlice, namespace: &Namespace) -> Result<Type> {
let inner = parse_type(&ty.elem, namespace)?;
Ok(Type::Slice(Box::new(Slice {
bracket: ty.bracket_token,
inner,
})))
}
fn parse_type_fn(ty: &TypeBareFn, namespace: &Namespace) -> Result<Type> {
if ty.lifetimes.is_some() {
return Err(Error::new_spanned(
ty,
"function pointer with lifetime parameters is not supported yet",
));
}
if ty.variadic.is_some() {
return Err(Error::new_spanned(
ty,
"variadic function pointer is not supported yet",
));
}
let args = ty
.inputs
.iter()
.enumerate()
.map(|(i, arg)| {
let ty = parse_type(&arg.ty, namespace)?;
let ident = match &arg.name {
Some(ident) => ident.0.clone(),
None => format_ident!("_{}", i),
};
Ok(Var { ident, ty })
})
.collect::<Result<_>>()?;
let mut throws_tokens = None;
let ret = parse_return_type(&ty.output, &mut throws_tokens, namespace)?;
let throws = throws_tokens.is_some();
Ok(Type::Fn(Box::new(Signature {
unsafety: ty.unsafety,
fn_token: ty.fn_token,
generics: Generics::default(),
receiver: None,
args,
ret,
throws,
paren_token: ty.paren_token,
throws_tokens,
})))
}
fn parse_return_type(
ty: &ReturnType,
throws_tokens: &mut Option<(kw::Result, Token![<], Token![>])>,
namespace: &Namespace,
) -> Result<Option<Type>> {
let mut ret = match ty {
ReturnType::Default => return Ok(None),
ReturnType::Type(_, ret) => ret.as_ref(),
};
if let RustType::Path(ty) = ret {
let path = &ty.path;
if ty.qself.is_none() && path.leading_colon.is_none() && path.segments.len() == 1 {
let segment = &path.segments[0];
let ident = segment.ident.clone();
if let PathArguments::AngleBracketed(generic) = &segment.arguments {
if ident == "Result" && generic.args.len() == 1 {
if let GenericArgument::Type(arg) = &generic.args[0] {
ret = arg;
*throws_tokens =
Some((kw::Result(ident.span()), generic.lt_token, generic.gt_token));
}
}
}
}
}
match parse_type(ret, namespace)? {
Type::Void(_) => Ok(None),
ty => Ok(Some(ty)),
}
}