$( $pat => $e, )*
}
} else {
- let path = $types.resolve_path(&supertrait.path);
+ let path = $types.resolve_path(&supertrait.path, None);
match (&path as &str, &supertrait.path.segments.iter().last().unwrap().ident) {
$( $pat => $e, )*
}
}
} } }
-/// Gets a HashMap from name idents to the bounding trait for associated types.
-/// eg if a native trait has a "type T = TraitA", this will return a HashMap containing a mapping
-/// from "T" to "TraitA".
-fn learn_associated_types<'a>(t: &'a syn::ItemTrait) -> HashMap<&'a syn::Ident, &'a syn::Ident> {
- let mut associated_types = HashMap::new();
- for item in t.items.iter() {
- match item {
- &syn::TraitItem::Type(ref t) => {
- if t.default.is_some() || t.generics.lt_token.is_some() { unimplemented!(); }
- let mut bounds_iter = t.bounds.iter();
- match bounds_iter.next().unwrap() {
- syn::TypeParamBound::Trait(tr) => {
- assert_simple_bound(&tr);
- associated_types.insert(&t.ident, assert_single_path_seg(&tr.path));
- },
- _ => unimplemented!(),
- }
- if bounds_iter.next().is_some() { unimplemented!(); }
- },
- _ => {},
- }
- }
- associated_types
-}
-
/// Prints a C-mapped trait object containing a void pointer and a jump table for each function in
/// the original trait.
/// Implements the native Rust trait and relevant parent traits for the new C-mapped trait.
}
writeln_docs(w, &t.attrs, "");
+ let mut gen_types = GenericTypes::new();
+ assert!(gen_types.learn_generics(&t.generics, types));
+ gen_types.learn_associated_types(&t, types);
+
writeln!(w, "#[repr(C)]\npub struct {} {{", trait_name).unwrap();
writeln!(w, "\tpub this_arg: *mut c_void,").unwrap();
- let associated_types = learn_associated_types(t);
let mut generated_fields = Vec::new(); // Every field's name except this_arg, used in Clone generation
for item in t.items.iter() {
match item {
match export_status(&m.attrs) {
ExportStatus::NoExport => {
// NoExport in this context means we'll hit an unimplemented!() at runtime,
- // so add a comment noting that this needs to change in the output.
- writeln!(w, "\t//XXX: Need to export {}", m.sig.ident).unwrap();
- continue;
+ // so bail out.
+ unimplemented!();
},
ExportStatus::Export => {},
ExportStatus::TestOnly => continue,
}
if m.default.is_some() { unimplemented!(); }
+ gen_types.push_ctx();
+ assert!(gen_types.learn_generics(&m.sig.generics, types));
+
writeln_docs(w, &m.attrs, "\t");
if let syn::ReturnType::Type(_, rtype) = &m.sig.output {
// called when the trait method is called which allows updating on the fly.
write!(w, "\tpub {}: ", m.sig.ident).unwrap();
generated_fields.push(format!("{}", m.sig.ident));
- types.write_c_type(w, &*r.elem, None, false);
+ types.write_c_type(w, &*r.elem, Some(&gen_types), false);
writeln!(w, ",").unwrap();
writeln!(w, "\t/// Fill in the {} field as a reference to it will be given to Rust after this returns", m.sig.ident).unwrap();
writeln!(w, "\t/// Note that this takes a pointer to this object, not the this_ptr like other methods do").unwrap();
// which does not compile since Thing is not defined before it is used.
writeln!(extra_headers, "struct LDK{};", trait_name).unwrap();
writeln!(extra_headers, "typedef struct LDK{} LDK{};", trait_name, trait_name).unwrap();
+ gen_types.pop_ctx();
continue;
}
// Sadly, this currently doesn't do what we want, but it should be easy to get
write!(w, "\tpub {}: extern \"C\" fn (", m.sig.ident).unwrap();
generated_fields.push(format!("{}", m.sig.ident));
- write_method_params(w, &m.sig, &associated_types, "c_void", types, None, true, false);
+ write_method_params(w, &m.sig, "c_void", types, Some(&gen_types), true, false);
writeln!(w, ",").unwrap();
+
+ gen_types.pop_ctx();
},
&syn::TraitItem::Type(_) => {},
_ => unimplemented!(),
generated_fields.push("clone".to_owned());
},
("std::cmp::Eq", _) => {
- writeln!(w, "\tpub eq: extern \"C\" fn (this_arg: *const c_void, other_arg: *const c_void) -> bool,").unwrap();
+ writeln!(w, "\tpub eq: extern \"C\" fn (this_arg: *const c_void, other_arg: &{}) -> bool,", trait_name).unwrap();
+ writeln!(extra_headers, "typedef struct LDK{} LDK{};", trait_name, trait_name).unwrap();
generated_fields.push("eq".to_owned());
},
("std::hash::Hash", _) => {
("std::cmp::Eq", _) => {
writeln!(w, "impl std::cmp::Eq for {} {{}}", trait_name).unwrap();
writeln!(w, "impl std::cmp::PartialEq for {} {{", trait_name).unwrap();
- writeln!(w, "\tfn eq(&self, o: &Self) -> bool {{ (self.eq)(self.this_arg, o.this_arg) }}\n}}").unwrap();
+ writeln!(w, "\tfn eq(&self, o: &Self) -> bool {{ (self.eq)(self.this_arg, o) }}\n}}").unwrap();
},
("std::hash::Hash", _) => {
writeln!(w, "impl std::hash::Hash for {} {{", trait_name).unwrap();
writeln!(w, "\tfn hash<H: std::hash::Hasher>(&self, hasher: &mut H) {{ hasher.write_u64((self.hash)(self.this_arg)) }}\n}}").unwrap();
},
("Clone", _) => {
- writeln!(w, "impl Clone for {} {{", trait_name).unwrap();
- writeln!(w, "\tfn clone(&self) -> Self {{").unwrap();
- writeln!(w, "\t\tSelf {{").unwrap();
- writeln!(w, "\t\tthis_arg: if let Some(f) = self.clone {{ (f)(self.this_arg) }} else {{ self.this_arg }},").unwrap();
+ writeln!(w, "#[no_mangle]").unwrap();
+ writeln!(w, "pub extern \"C\" fn {}_clone(orig: &{}) -> {} {{", trait_name, trait_name, trait_name).unwrap();
+ writeln!(w, "\t{} {{", trait_name).unwrap();
+ writeln!(w, "\t\tthis_arg: if let Some(f) = orig.clone {{ (f)(orig.this_arg) }} else {{ orig.this_arg }},").unwrap();
for field in generated_fields.iter() {
- writeln!(w, "\t\t\t{}: self.{}.clone(),", field, field).unwrap();
+ writeln!(w, "\t\t{}: orig.{}.clone(),", field, field).unwrap();
}
- writeln!(w, "\t\t}}\n\t}}\n}}").unwrap();
+ writeln!(w, "\t}}\n}}").unwrap();
+ writeln!(w, "impl Clone for {} {{", trait_name).unwrap();
+ writeln!(w, "\tfn clone(&self) -> Self {{").unwrap();
+ writeln!(w, "\t\t{}_clone(self)", trait_name).unwrap();
+ writeln!(w, "\t}}\n}}").unwrap();
},
(s, i) => {
if s != "util::events::MessageSendEventsProvider" { unimplemented!(); }
m.sig.abi.is_some() || m.sig.variadic.is_some() {
unimplemented!();
}
+ gen_types.push_ctx();
+ assert!(gen_types.learn_generics(&m.sig.generics, types));
write!(w, "\tfn {}", m.sig.ident).unwrap();
- types.write_rust_generic_param(w, m.sig.generics.params.iter());
+ types.write_rust_generic_param(w, Some(&gen_types), m.sig.generics.params.iter());
write!(w, "(").unwrap();
for inp in m.sig.inputs.iter() {
match inp {
ident.mutability.is_some() || ident.subpat.is_some() {
unimplemented!();
}
- write!(w, ", {}{}: ", if types.skip_arg(&*arg.ty, None) { "_" } else { "" }, ident.ident).unwrap();
+ write!(w, ", {}{}: ", if types.skip_arg(&*arg.ty, Some(&gen_types)) { "_" } else { "" }, ident.ident).unwrap();
}
_ => unimplemented!(),
}
- types.write_rust_type(w, &*arg.ty);
+ types.write_rust_type(w, Some(&gen_types), &*arg.ty);
}
}
}
match &m.sig.output {
syn::ReturnType::Type(_, rtype) => {
write!(w, " -> ").unwrap();
- types.write_rust_type(w, &*rtype)
+ types.write_rust_type(w, Some(&gen_types), &*rtype)
},
_ => {},
}
write!(w, " {{\n\t\t").unwrap();
match export_status(&m.attrs) {
ExportStatus::NoExport => {
- writeln!(w, "unimplemented!();\n\t}}").unwrap();
- continue;
+ unimplemented!();
},
_ => {},
}
writeln!(w, "if let Some(f) = self.set_{} {{", m.sig.ident).unwrap();
writeln!(w, "\t\t\t(f)(self);").unwrap();
write!(w, "\t\t}}\n\t\t").unwrap();
- types.write_from_c_conversion_to_ref_prefix(w, &*r.elem, None);
+ types.write_from_c_conversion_to_ref_prefix(w, &*r.elem, Some(&gen_types));
write!(w, "self.{}", m.sig.ident).unwrap();
- types.write_from_c_conversion_to_ref_suffix(w, &*r.elem, None);
+ types.write_from_c_conversion_to_ref_suffix(w, &*r.elem, Some(&gen_types));
writeln!(w, "\n\t}}").unwrap();
+ gen_types.pop_ctx();
continue;
}
}
- write_method_var_decl_body(w, &m.sig, "\t", types, None, true);
+ write_method_var_decl_body(w, &m.sig, "\t", types, Some(&gen_types), true);
write!(w, "(self.{})(", m.sig.ident).unwrap();
- write_method_call_params(w, &m.sig, &associated_types, "\t", types, None, "", true);
+ write_method_call_params(w, &m.sig, "\t", types, Some(&gen_types), "", true);
writeln!(w, "\n\t}}").unwrap();
+ gen_types.pop_ctx();
},
&syn::TraitItem::Type(ref t) => {
if t.default.is_some() || t.generics.lt_token.is_some() { unimplemented!(); }
let mut bounds_iter = t.bounds.iter();
match bounds_iter.next().unwrap() {
syn::TypeParamBound::Trait(tr) => {
- writeln!(w, "\ttype {} = crate::{};", t.ident, types.resolve_path(&tr.path)).unwrap();
+ writeln!(w, "\ttype {} = crate::{};", t.ident, types.resolve_path(&tr.path, Some(&gen_types))).unwrap();
},
_ => unimplemented!(),
}
writeln!(w, ";\n").unwrap();
writeln!(extra_headers, "struct native{}Opaque;\ntypedef struct native{}Opaque LDKnative{};", ident, ident, ident).unwrap();
writeln_docs(w, &attrs, "");
- writeln!(w, "#[must_use]\n#[repr(C)]\npub struct {} {{\n\t/// Nearly everyhwere, inner must be non-null, however in places where", struct_name).unwrap();
+ writeln!(w, "#[must_use]\n#[repr(C)]\npub struct {} {{\n\t/// Nearly everywhere, inner must be non-null, however in places where", struct_name).unwrap();
writeln!(w, "\t/// the Rust equivalent takes an Option, it may be set to null to indicate None.").unwrap();
writeln!(w, "\tpub inner: *mut native{},\n\tpub is_owned: bool,\n}}\n", ident).unwrap();
writeln!(w, "impl Drop for {} {{\n\tfn drop(&mut self) {{", struct_name).unwrap();
writeln!(w, "pub(crate) extern \"C\" fn {}_clone_void(this_ptr: *const c_void) -> *mut c_void {{", struct_name).unwrap();
writeln!(w, "\tBox::into_raw(Box::new(unsafe {{ (*(this_ptr as *mut native{})).clone() }})) as *mut c_void", struct_name).unwrap();
writeln!(w, "}}").unwrap();
+ writeln!(w, "#[no_mangle]").unwrap();
+ writeln!(w, "pub extern \"C\" fn {}_clone(orig: &{}) -> {} {{", struct_name, struct_name, struct_name).unwrap();
+ writeln!(w, "\t{} {{ inner: Box::into_raw(Box::new(unsafe {{ &*orig.inner }}.clone())), is_owned: true }}", struct_name).unwrap();
+ writeln!(w, "}}").unwrap();
break 'attr_loop;
}
}
if let Some(trait_path) = i.trait_.as_ref() {
if trait_path.0.is_some() { unimplemented!(); }
if types.understood_c_path(&trait_path.1) {
- let full_trait_path = types.resolve_path(&trait_path.1);
+ let full_trait_path = types.resolve_path(&trait_path.1, None);
let trait_obj = *types.crate_types.traits.get(&full_trait_path).unwrap();
// We learn the associated types maping from the original trait object.
// That's great, except that they are unresolved idents, so if we learn
// mappings from a trai defined in a different file, we may mis-resolve or
// fail to resolve the mapped types.
- let trait_associated_types = learn_associated_types(trait_obj);
+ gen_types.learn_associated_types(trait_obj, types);
let mut impl_associated_types = HashMap::new();
for item in i.items.iter() {
match item {
ExportStatus::Export => {},
ExportStatus::NoExport|ExportStatus::TestOnly => return,
}
+
+ // For cases where we have a concrete native object which implements a
+ // trait and need to return the C-mapped version of the trait, provide a
+ // From<> implementation which does all the work to ensure free is handled
+ // properly. This way we can call this method from deep in the
+ // type-conversion logic without actually knowing the concrete native type.
+ writeln!(w, "impl From<native{}> for crate::{} {{", ident, full_trait_path).unwrap();
+ writeln!(w, "\tfn from(obj: native{}) -> Self {{", ident).unwrap();
+ writeln!(w, "\t\tlet mut rust_obj = {} {{ inner: Box::into_raw(Box::new(obj)), is_owned: true }};", ident).unwrap();
+ writeln!(w, "\t\tlet mut ret = {}_as_{}(&rust_obj);", ident, trait_obj.ident).unwrap();
+ writeln!(w, "\t\t// We want to free rust_obj when ret gets drop()'d, not rust_obj, so wipe rust_obj's pointer and set ret's free() fn").unwrap();
+ writeln!(w, "\t\trust_obj.inner = std::ptr::null_mut();").unwrap();
+ writeln!(w, "\t\tret.free = Some({}_free_void);", ident).unwrap();
+ writeln!(w, "\t\tret\n\t}}\n}}").unwrap();
+
write!(w, "#[no_mangle]\npub extern \"C\" fn {}_as_{}(this_arg: *const {}) -> crate::{} {{\n", ident, trait_obj.ident, ident, full_trait_path).unwrap();
writeln!(w, "\tcrate::{} {{", full_trait_path).unwrap();
writeln!(w, "\t\tthis_arg: unsafe {{ (*this_arg).inner as *mut c_void }},").unwrap();
if let syn::ReturnType::Type(_, rtype) = &$m.sig.output {
if let syn::Type::Reference(r) = &**rtype {
write!(w, "\n\t\t{}{}: ", $indent, $m.sig.ident).unwrap();
- types.write_empty_rust_val(w, &*r.elem);
+ types.write_empty_rust_val(Some(&gen_types), w, &*r.elem);
writeln!(w, ",\n{}\t\tset_{}: Some({}_{}_set_{}),", $indent, $m.sig.ident, ident, trait_obj.ident, $m.sig.ident).unwrap();
printed = true;
}
write!(w, "extern \"C\" fn {}_{}_{}(", ident, trait_obj.ident, $m.sig.ident).unwrap();
gen_types.push_ctx();
assert!(gen_types.learn_generics(&$m.sig.generics, types));
- write_method_params(w, &$m.sig, &trait_associated_types, "c_void", types, Some(&gen_types), true, true);
+ write_method_params(w, &$m.sig, "c_void", types, Some(&gen_types), true, true);
write!(w, " {{\n\t").unwrap();
write_method_var_decl_body(w, &$m.sig, "", types, Some(&gen_types), false);
let mut takes_self = false;
},
_ => {},
}
- write_method_call_params(w, &$m.sig, &trait_associated_types, "", types, Some(&gen_types), &real_type, false);
+ write_method_call_params(w, &$m.sig, "", types, Some(&gen_types), &real_type, false);
gen_types.pop_ctx();
write!(w, "\n}}\n").unwrap();
if let syn::ReturnType::Type(_, rtype) = &$m.sig.output {
writeln!(w, "\t// This is a bit race-y in the general case, but for our specific use-cases today, we're safe").unwrap();
writeln!(w, "\t// Specifically, we must ensure that the first time we're called it can never be in parallel").unwrap();
write!(w, "\tif ").unwrap();
- types.write_empty_rust_val_check(w, &*r.elem, &format!("trait_self_arg.{}", $m.sig.ident));
+ types.write_empty_rust_val_check(Some(&gen_types), w, &*r.elem, &format!("trait_self_arg.{}", $m.sig.ident));
writeln!(w, " {{").unwrap();
writeln!(w, "\t\tunsafe {{ &mut *(trait_self_arg as *const {} as *mut {}) }}.{} = {}_{}_{}(trait_self_arg.this_arg);", trait_obj.ident, trait_obj.ident, $m.sig.ident, ident, trait_obj.ident, $m.sig.ident).unwrap();
writeln!(w, "\t}}").unwrap();
};
gen_types.push_ctx();
assert!(gen_types.learn_generics(&m.sig.generics, types));
- write_method_params(w, &m.sig, &HashMap::new(), &ret_type, types, Some(&gen_types), false, true);
+ write_method_params(w, &m.sig, &ret_type, types, Some(&gen_types), false, true);
write!(w, " {{\n\t").unwrap();
write_method_var_decl_body(w, &m.sig, "", types, Some(&gen_types), false);
let mut takes_self = false;
} else {
write!(w, "{}::{}::{}(", types.orig_crate, resolved_path, m.sig.ident).unwrap();
}
- write_method_call_params(w, &m.sig, &HashMap::new(), "", types, Some(&gen_types), &ret_type, false);
+ write_method_call_params(w, &m.sig, "", types, Some(&gen_types), &ret_type, false);
gen_types.pop_ctx();
writeln!(w, "\n}}\n").unwrap();
}
if needs_free {
writeln!(w, "#[no_mangle]\npub extern \"C\" fn {}_free(this_ptr: {}) {{ }}", e.ident, e.ident).unwrap();
}
+ writeln!(w, "#[no_mangle]").unwrap();
+ writeln!(w, "pub extern \"C\" fn {}_clone(orig: &{}) -> {} {{", e.ident, e.ident, e.ident).unwrap();
+ writeln!(w, "\torig.clone()").unwrap();
+ writeln!(w, "}}").unwrap();
write_cpp_wrapper(cpp_headers, &format!("{}", e.ident), needs_free);
}
if !gen_types.learn_generics(&f.sig.generics, types) { return; }
write!(w, "#[no_mangle]\npub extern \"C\" fn {}(", f.sig.ident).unwrap();
- write_method_params(w, &f.sig, &HashMap::new(), "", types, Some(&gen_types), false, true);
+ write_method_params(w, &f.sig, "", types, Some(&gen_types), false, true);
write!(w, " {{\n\t").unwrap();
write_method_var_decl_body(w, &f.sig, "", types, Some(&gen_types), false);
write!(w, "{}::{}::{}(", types.orig_crate, types.module_path, f.sig.ident).unwrap();
- write_method_call_params(w, &f.sig, &HashMap::new(), "", types, Some(&gen_types), "", false);
+ write_method_call_params(w, &f.sig, "", types, Some(&gen_types), "", false);
writeln!(w, "\n}}\n").unwrap();
}
/// `out_path` and fills it with wrapper structs/functions to allow calling the things in the AST
/// at `module` from C.
fn convert_file<'a, 'b>(libast: &'a FullLibraryAST, crate_types: &mut CrateTypes<'a>, in_dir: &str, out_dir: &str, path: &str, orig_crate: &str, module: &str, header_file: &mut File, cpp_header_file: &mut File) {
- eprintln!("Converting {}...", path);
-
let syntax = if let Some(ast) = libast.files.get(module) { ast } else { return };
assert!(syntax.shebang.is_none()); // Not sure what this is, hope we dont have one
orig_crate, &new_mod, header_file, cpp_header_file);
}
+ eprintln!("Converting {} entries...", path);
+
let mut type_resolver = TypeResolver::new(orig_crate, module, crate_types);
for item in syntax.items.iter() {
// Re-export any primitive-type constants.
if let syn::Visibility::Public(_) = c.vis {
if let syn::Type::Path(p) = &*c.ty {
- let resolved_path = type_resolver.resolve_path(&p.path);
+ let resolved_path = type_resolver.resolve_path(&p.path, None);
if type_resolver.is_primitive(&resolved_path) {
writeln!(out, "\n#[no_mangle]").unwrap();
writeln!(out, "pub static {}: {} = {}::{}::{};", c.ident, resolved_path, orig_crate, module, c.ident).unwrap();
ExportStatus::Export => {},
ExportStatus::NoExport|ExportStatus::TestOnly => continue,
}
- if t.generics.lt_token.is_none() {
- writeln_opaque(&mut out, &t.ident, &format!("{}", t.ident), &t.generics, &t.attrs, &type_resolver, header_file, cpp_header_file);
+
+ let mut process_alias = true;
+ for tok in t.generics.params.iter() {
+ if let syn::GenericParam::Lifetime(_) = tok {}
+ else { process_alias = false; }
+ }
+ if process_alias {
+ match &*t.ty {
+ syn::Type::Path(_) =>
+ writeln_opaque(&mut out, &t.ident, &format!("{}", t.ident), &t.generics, &t.attrs, &type_resolver, header_file, cpp_header_file),
+ _ => {}
+ }
}
}
},
ast_storage.files.insert(module, syntax);
}
+/// Insert ident -> absolute Path resolutions into imports from the given UseTree and path-prefix.
+fn process_use_intern<'a>(u: &'a syn::UseTree, mut path: syn::punctuated::Punctuated<syn::PathSegment, syn::token::Colon2>, imports: &mut HashMap<&'a syn::Ident, syn::Path>) {
+ match u {
+ syn::UseTree::Path(p) => {
+ path.push(syn::PathSegment { ident: p.ident.clone(), arguments: syn::PathArguments::None });
+ process_use_intern(&p.tree, path, imports);
+ },
+ syn::UseTree::Name(n) => {
+ path.push(syn::PathSegment { ident: n.ident.clone(), arguments: syn::PathArguments::None });
+ imports.insert(&n.ident, syn::Path { leading_colon: Some(syn::Token![::](Span::call_site())), segments: path });
+ },
+ syn::UseTree::Group(g) => {
+ for i in g.items.iter() {
+ process_use_intern(i, path.clone(), imports);
+ }
+ },
+ _ => {}
+ }
+}
+
+/// Map all the Paths in a Type into absolute paths given a set of imports (generated via process_use_intern)
+fn resolve_imported_refs(imports: &HashMap<&syn::Ident, syn::Path>, mut ty: syn::Type) -> syn::Type {
+ match &mut ty {
+ syn::Type::Path(p) => {
+ if let Some(ident) = p.path.get_ident() {
+ if let Some(newpath) = imports.get(ident) {
+ p.path = newpath.clone();
+ }
+ } else { unimplemented!(); }
+ },
+ syn::Type::Reference(r) => {
+ r.elem = Box::new(resolve_imported_refs(imports, (*r.elem).clone()));
+ },
+ syn::Type::Slice(s) => {
+ s.elem = Box::new(resolve_imported_refs(imports, (*s.elem).clone()));
+ },
+ syn::Type::Tuple(t) => {
+ for e in t.elems.iter_mut() {
+ *e = resolve_imported_refs(imports, e.clone());
+ }
+ },
+ _ => unimplemented!(),
+ }
+ ty
+}
+
/// Walk the FullLibraryAST, deciding how things will be mapped and adding tracking to CrateTypes.
fn walk_ast<'a>(in_dir: &str, path: &str, module: String, ast_storage: &'a FullLibraryAST, crate_types: &mut CrateTypes<'a>) {
let syntax = if let Some(ast) = ast_storage.files.get(&module) { ast } else { return };
walk_ast(in_dir, &path, new_mod, ast_storage, crate_types);
}
+ let mut import_maps = HashMap::new();
+
for item in syntax.items.iter() {
match item {
+ syn::Item::Use(u) => {
+ process_use_intern(&u.tree, syn::punctuated::Punctuated::new(), &mut import_maps);
+ },
syn::Item::Struct(s) => {
if let syn::Visibility::Public(_) = s.vis {
match export_status(&s.attrs) {
crate_types.traits.insert(trait_path, &t);
}
},
+ syn::Item::Type(t) => {
+ if let syn::Visibility::Public(_) = t.vis {
+ match export_status(&t.attrs) {
+ ExportStatus::Export => {},
+ ExportStatus::NoExport|ExportStatus::TestOnly => continue,
+ }
+ let type_path = format!("{}::{}", module, t.ident);
+ let mut process_alias = true;
+ for tok in t.generics.params.iter() {
+ if let syn::GenericParam::Lifetime(_) = tok {}
+ else { process_alias = false; }
+ }
+ if process_alias {
+ match &*t.ty {
+ syn::Type::Path(_) => {
+ // If its a path with no generics, assume we don't map the aliased type and map it opaque
+ crate_types.opaques.insert(type_path, &t.ident);
+ },
+ _ => {
+ crate_types.type_aliases.insert(type_path, resolve_imported_refs(&import_maps, (*t.ty).clone()));
+ }
+ }
+ }
+ }
+ },
syn::Item::Enum(e) if is_enum_opaque(e) => {
if let syn::Visibility::Public(_) = e.vis {
match export_status(&e.attrs) {
// ...then walk the ASTs tracking what types we will map, and how, so that we can resolve them
// when parsing other file ASTs...
let mut libtypes = CrateTypes { traits: HashMap::new(), opaques: HashMap::new(), mirrored_enums: HashMap::new(),
- templates_defined: HashMap::new(), template_file: &mut derived_templates };
+ type_aliases: HashMap::new(), templates_defined: HashMap::default(), template_file: &mut derived_templates };
walk_ast(&args[1], "/lib.rs", "".to_string(), &libast, &mut libtypes);
// ... finally, do the actual file conversion/mapping, writing out types as we go.