writeln!(w, "\t/// An opaque pointer which is passed to your function implementations as an argument.").unwrap();
writeln!(w, "\t/// This has no meaning in the LDK, and can be NULL or any other value.").unwrap();
writeln!(w, "\tpub this_arg: *mut c_void,").unwrap();
- let mut generated_fields = Vec::new(); // Every field's (name, Option<clone_fn>) except this_arg, used in Clone generation
+ // We store every field's (name, Option<clone_fn>, docs) except this_arg, used in Clone generation
+ // docs is only set if its a function which should be callable on the object itself in C++
+ let mut generated_fields = Vec::new();
for item in t.items.iter() {
match item {
&syn::TraitItem::Method(ref m) => {
let mut meth_gen_types = gen_types.push_ctx();
assert!(meth_gen_types.learn_generics(&m.sig.generics, types));
- writeln_docs(w, &m.attrs, "\t");
+ writeln_fn_docs(w, &m.attrs, "\t", types, Some(&meth_gen_types), m.sig.inputs.iter(), &m.sig.output);
if let syn::ReturnType::Type(_, rtype) = &m.sig.output {
if let syn::Type::Reference(r) = &**rtype {
// happen) as well as provide an Option<>al function pointer which is
// 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), None));
+ generated_fields.push((format!("{}", m.sig.ident), None, None));
types.write_c_type(w, &*r.elem, Some(&meth_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();
writeln!(w, "\t/// This function pointer may be NULL if {} is filled in when this object is created and never needs updating.", m.sig.ident).unwrap();
writeln!(w, "\tpub set_{}: Option<extern \"C\" fn(&{})>,", m.sig.ident, trait_name).unwrap();
- generated_fields.push((format!("set_{}", m.sig.ident), None));
+ generated_fields.push((format!("set_{}", m.sig.ident), None, None));
// Note that cbindgen will now generate
// typedef struct Thing {..., set_thing: (const struct Thing*), ...} Thing;
// which does not compile since Thing is not defined before it is used.
writeln!(w, "\t#[must_use]").unwrap();
}
+ let mut cpp_docs = Vec::new();
+ writeln_fn_docs(&mut cpp_docs, &m.attrs, "\t * ", types, Some(&meth_gen_types), m.sig.inputs.iter(), &m.sig.output);
+ let docs_string = "\t/**\n".to_owned() + &String::from_utf8(cpp_docs).unwrap().replace("///", "") + "\t */\n";
+
write!(w, "\tpub {}: extern \"C\" fn (", m.sig.ident).unwrap();
- generated_fields.push((format!("{}", m.sig.ident), None));
+ generated_fields.push((format!("{}", m.sig.ident), None, Some(docs_string)));
write_method_params(w, &m.sig, "c_void", types, Some(&meth_gen_types), true, false);
writeln!(w, ",").unwrap();
},
writeln!(w, "\t/// The new {} is provided, and should be mutated as needed to perform a", trait_name).unwrap();
writeln!(w, "\t/// deep copy of the object pointed to by this_arg or avoid any double-freeing.").unwrap();
writeln!(w, "\tpub cloned: Option<extern \"C\" fn (new_{}: &mut {})>,", trait_name, trait_name).unwrap();
- generated_fields.push(("cloned".to_owned(), None));
+ generated_fields.push(("cloned".to_owned(), None, None));
},
("std::cmp::Eq", _)|("core::cmp::Eq", _) => {
- writeln!(w, "\t/// Checks if two objects are equal given this object's this_arg pointer and another object.").unwrap();
+ let eq_docs = "Checks if two objects are equal given this object's this_arg pointer and another object.";
+ writeln!(w, "\t/// {}", eq_docs).unwrap();
writeln!(w, "\tpub eq: extern \"C\" fn (this_arg: *const c_void, other_arg: &{}) -> bool,", trait_name).unwrap();
- generated_fields.push(("eq".to_owned(), None));
+ generated_fields.push(("eq".to_owned(), None, Some(format!("\t/** {} */\n", eq_docs))));
},
("std::hash::Hash", _)|("core::hash::Hash", _) => {
- writeln!(w, "\t/// Calculate a succinct non-cryptographic hash for an object given its this_arg pointer.").unwrap();
- writeln!(w, "\t/// This is used, for example, for inclusion of this object in a hash map.").unwrap();
+ let hash_docs_a = "Calculate a succinct non-cryptographic hash for an object given its this_arg pointer.";
+ let hash_docs_b = "This is used, for example, for inclusion of this object in a hash map.";
+ writeln!(w, "\t/// {}", hash_docs_a).unwrap();
+ writeln!(w, "\t/// {}", hash_docs_b).unwrap();
writeln!(w, "\tpub hash: extern \"C\" fn (this_arg: *const c_void) -> u64,").unwrap();
- generated_fields.push(("hash".to_owned(), None));
+ generated_fields.push(("hash".to_owned(), None,
+ Some(format!("\t/**\n\t * {}\n\t * {}\n\t */\n", hash_docs_a, hash_docs_b))));
},
("Send", _) => {}, ("Sync", _) => {},
(s, i) => {
+ // TODO: Both of the below should expose supertrait methods in C++, but doing so is
+ // nontrivial.
generated_fields.push(if types.crate_types.traits.get(s).is_none() {
let (docs, name, ret) = convert_trait_impl_field(s);
writeln!(w, "\t/// {}", docs).unwrap();
writeln!(w, "\tpub {}: extern \"C\" fn (this_arg: *const c_void) -> {},", name, ret).unwrap();
- (name, None) // Assume clonable
+ (name, None, None) // Assume clonable
} else {
// For in-crate supertraits, just store a C-mapped copy of the supertrait as a member.
writeln!(w, "\t/// Implementation of {} for this object.", i).unwrap();
writeln!(w, "\tpub {}: crate::{},", i, s).unwrap();
(format!("{}", i), if !is_clonable {
Some(format!("crate::{}_clone_fields", s))
- } else { None })
+ } else { None }, None)
});
}
) );
writeln!(w, "\t/// Frees any resources associated with this object given its this_arg pointer.").unwrap();
writeln!(w, "\t/// Does not need to free the outer struct containing function pointers and may be NULL is no resources need to be freed.").unwrap();
writeln!(w, "\tpub free: Option<extern \"C\" fn(this_arg: *mut c_void)>,").unwrap();
- generated_fields.push(("free".to_owned(), None));
+ generated_fields.push(("free".to_owned(), None, None));
writeln!(w, "}}").unwrap();
macro_rules! impl_trait_for_c {
writeln!(w, "pub(crate) extern \"C\" fn {}_clone_fields(orig: &{}) -> {} {{", trait_name, trait_name, trait_name).unwrap();
writeln!(w, "\t{} {{", trait_name).unwrap();
writeln!(w, "\t\tthis_arg: orig.this_arg,").unwrap();
- for (field, clone_fn) in generated_fields.iter() {
+ for (field, clone_fn, _) in generated_fields.iter() {
if let Some(f) = clone_fn {
// If the field isn't clonable, blindly assume its a trait and hope for the best.
writeln!(w, "\t\t{}: {}(&orig.{}),", field, f, field).unwrap();
writeln!(w, "\t\t\tf(self.this_arg);").unwrap();
writeln!(w, "\t\t}}\n\t}}\n}}").unwrap();
- write_cpp_wrapper(cpp_headers, &trait_name, true);
+ write_cpp_wrapper(cpp_headers, &trait_name, true, Some(generated_fields.drain(..)
+ .filter_map(|(name, _, docs)| if let Some(docs) = docs { Some((name, docs)) } else { None }).collect()));
}
/// Write out a simple "opaque" type (eg structs) which contain a pointer to the native Rust type
writeln!(w, "}}\n").unwrap();
writeln!(w, "impl Drop for {} {{\n\tfn drop(&mut self) {{", struct_name).unwrap();
writeln!(w, "\t\tif self.is_owned && !<*mut native{}>::is_null(self.inner) {{", ident).unwrap();
- writeln!(w, "\t\t\tlet _ = unsafe {{ Box::from_raw(self.inner) }};\n\t\t}}\n\t}}\n}}").unwrap();
+ writeln!(w, "\t\t\tlet _ = unsafe {{ Box::from_raw(ObjOps::untweak_ptr(self.inner)) }};\n\t\t}}\n\t}}\n}}").unwrap();
writeln!(w, "/// Frees any resources used by the {}, if is_owned is set and inner is non-NULL.", struct_name).unwrap();
writeln!(w, "#[no_mangle]\npub extern \"C\" fn {}_free(this_obj: {}) {{ }}", struct_name, struct_name).unwrap();
writeln!(w, "#[allow(unused)]").unwrap();
writeln!(w, "extern \"C\" fn {}_free_void(this_ptr: *mut c_void) {{", struct_name).unwrap();
writeln!(w, "\tunsafe {{ let _ = Box::from_raw(this_ptr as *mut native{}); }}\n}}", struct_name).unwrap();
writeln!(w, "#[allow(unused)]").unwrap();
- writeln!(w, "/// When moving out of the pointer, we have to ensure we aren't a reference, this makes that easy").unwrap();
writeln!(w, "impl {} {{", struct_name).unwrap();
+ writeln!(w, "\tpub(crate) fn get_native_ref(&self) -> &'static native{} {{", struct_name).unwrap();
+ writeln!(w, "\t\tunsafe {{ &*ObjOps::untweak_ptr(self.inner) }}").unwrap();
+ writeln!(w, "\t}}").unwrap();
+ writeln!(w, "\tpub(crate) fn get_native_mut_ref(&self) -> &'static mut native{} {{", struct_name).unwrap();
+ writeln!(w, "\t\tunsafe {{ &mut *ObjOps::untweak_ptr(self.inner) }}").unwrap();
+ writeln!(w, "\t}}").unwrap();
+ writeln!(w, "\t/// When moving out of the pointer, we have to ensure we aren't a reference, this makes that easy").unwrap();
writeln!(w, "\tpub(crate) fn take_inner(mut self) -> *mut native{} {{", struct_name).unwrap();
writeln!(w, "\t\tassert!(self.is_owned);").unwrap();
- writeln!(w, "\t\tlet ret = self.inner;").unwrap();
+ writeln!(w, "\t\tlet ret = ObjOps::untweak_ptr(self.inner);").unwrap();
writeln!(w, "\t\tself.inner = std::ptr::null_mut();").unwrap();
writeln!(w, "\t\tret").unwrap();
writeln!(w, "\t}}\n}}").unwrap();
- write_cpp_wrapper(cpp_headers, &format!("{}", ident), true);
+ write_cpp_wrapper(cpp_headers, &format!("{}", ident), true, None);
}
/// Writes out all the relevant mappings for a Rust struct, deferring to writeln_opaque to generate
and_token: syn::Token!(&)(Span::call_site()), lifetime: None, mutability: None,
elem: Box::new(field.ty.clone()) });
if types.understood_c_type(&ref_type, Some(&gen_types)) {
- writeln_docs(w, &field.attrs, "");
+ writeln_arg_docs(w, &field.attrs, "", types, Some(&gen_types), vec![].drain(..), Some(&ref_type));
write!(w, "#[no_mangle]\npub extern \"C\" fn {}_get_{}(this_ptr: &{}) -> ", struct_name, ident, struct_name).unwrap();
types.write_c_type(w, &ref_type, Some(&gen_types), true);
- write!(w, " {{\n\tlet mut inner_val = &mut unsafe {{ &mut *this_ptr.inner }}.{};\n\t", ident).unwrap();
+ write!(w, " {{\n\tlet mut inner_val = &mut this_ptr.get_native_mut_ref().{};\n\t", ident).unwrap();
let local_var = types.write_to_c_conversion_new_var(w, &format_ident!("inner_val"), &ref_type, Some(&gen_types), true);
if local_var { write!(w, "\n\t").unwrap(); }
types.write_to_c_conversion_inline_prefix(w, &ref_type, Some(&gen_types), true);
}
if types.understood_c_type(&field.ty, Some(&gen_types)) {
- writeln_docs(w, &field.attrs, "");
+ writeln_arg_docs(w, &field.attrs, "", types, Some(&gen_types), vec![("val".to_owned(), &field.ty)].drain(..), None);
write!(w, "#[no_mangle]\npub extern \"C\" fn {}_set_{}(this_ptr: &mut {}, mut val: ", struct_name, ident, struct_name).unwrap();
types.write_c_type(w, &field.ty, Some(&gen_types), false);
write!(w, ") {{\n\t").unwrap();
let local_var = types.write_from_c_conversion_new_var(w, &format_ident!("val"), &field.ty, Some(&gen_types));
if local_var { write!(w, "\n\t").unwrap(); }
- write!(w, "unsafe {{ &mut *this_ptr.inner }}.{} = ", ident).unwrap();
+ write!(w, "unsafe {{ &mut *ObjOps::untweak_ptr(this_ptr.inner) }}.{} = ", ident).unwrap();
types.write_from_c_conversion_prefix(w, &field.ty, Some(&gen_types));
write!(w, "val").unwrap();
types.write_from_c_conversion_suffix(w, &field.ty, Some(&gen_types));
write!(w, "\n\t").unwrap();
}
}
- writeln!(w, "{} {{ inner: Box::into_raw(Box::new(native{} {{", struct_name, s.ident).unwrap();
+ writeln!(w, "{} {{ inner: ObjOps::heap_alloc(native{} {{", struct_name, s.ident).unwrap();
for field in fields.named.iter() {
write!(w, "\t\t{}: ", field.ident.as_ref().unwrap()).unwrap();
types.write_from_c_conversion_prefix(w, &field.ty, Some(&gen_types));
types.write_from_c_conversion_suffix(w, &field.ty, Some(&gen_types));
writeln!(w, ",").unwrap();
}
- writeln!(w, "\t}})), is_owned: true }}\n}}").unwrap();
+ writeln!(w, "\t}}), is_owned: true }}\n}}").unwrap();
}
}
}
// 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 rust_obj = {} {{ inner: ObjOps::heap_alloc(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, "/// This copies the `inner` pointer in this_arg and thus the returned {} must be freed before this_arg is", trait_obj.ident).unwrap();
write!(w, "#[no_mangle]\npub extern \"C\" fn {}_as_{}(this_arg: &{}) -> 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();
+ writeln!(w, "\t\tthis_arg: unsafe {{ ObjOps::untweak_ptr((*this_arg).inner) as *mut c_void }},").unwrap();
writeln!(w, "\t\tfree: None,").unwrap();
macro_rules! write_meth {
(s, t) => {
if let Some(supertrait_obj) = types.crate_types.traits.get(s) {
writeln!(w, "\t\t{}: crate::{} {{", t, s).unwrap();
- writeln!(w, "\t\t\tthis_arg: unsafe {{ (*this_arg).inner as *mut c_void }},").unwrap();
+ writeln!(w, "\t\t\tthis_arg: unsafe {{ ObjOps::untweak_ptr((*this_arg).inner) as *mut c_void }},").unwrap();
writeln!(w, "\t\t\tfree: None,").unwrap();
for item in supertrait_obj.items.iter() {
match item {
} else if path_matches_nongeneric(&trait_path.1, &["Default"]) {
writeln!(w, "/// Creates a \"default\" {}. See struct and individual field documentaiton for details on which values are used.", ident).unwrap();
write!(w, "#[must_use]\n#[no_mangle]\npub extern \"C\" fn {}_default() -> {} {{\n", ident, ident).unwrap();
- write!(w, "\t{} {{ inner: Box::into_raw(Box::new(Default::default())), is_owned: true }}\n", ident).unwrap();
+ write!(w, "\t{} {{ inner: ObjOps::heap_alloc(Default::default()), is_owned: true }}\n", ident).unwrap();
write!(w, "}}\n").unwrap();
} else if path_matches_nongeneric(&trait_path.1, &["core", "cmp", "PartialEq"]) {
} else if path_matches_nongeneric(&trait_path.1, &["core", "cmp", "Eq"]) {
writeln!(w, "\tfn clone(&self) -> Self {{").unwrap();
writeln!(w, "\t\tSelf {{").unwrap();
writeln!(w, "\t\t\tinner: if <*mut native{}>::is_null(self.inner) {{ std::ptr::null_mut() }} else {{", ident).unwrap();
- writeln!(w, "\t\t\t\tBox::into_raw(Box::new(unsafe {{ &*self.inner }}.clone())) }},").unwrap();
+ writeln!(w, "\t\t\t\tObjOps::heap_alloc(unsafe {{ &*ObjOps::untweak_ptr(self.inner) }}.clone()) }},").unwrap();
writeln!(w, "\t\t\tis_owned: true,").unwrap();
writeln!(w, "\t\t}}\n\t}}\n}}").unwrap();
writeln!(w, "#[allow(unused)]").unwrap();
ExportStatus::NoExport|ExportStatus::TestOnly => continue,
ExportStatus::NotImplementable => panic!("(C-not implementable) must only appear on traits"),
}
+ let mut meth_gen_types = gen_types.push_ctx();
+ assert!(meth_gen_types.learn_generics(&m.sig.generics, types));
if m.defaultness.is_some() { unimplemented!(); }
- writeln_docs(w, &m.attrs, "");
+ writeln_fn_docs(w, &m.attrs, "", types, Some(&meth_gen_types), m.sig.inputs.iter(), &m.sig.output);
if let syn::ReturnType::Type(_, _) = &m.sig.output {
writeln!(w, "#[must_use]").unwrap();
}
DeclType::StructImported => format!("{}", ident),
_ => unimplemented!(),
};
- let mut meth_gen_types = gen_types.push_ctx();
- assert!(meth_gen_types.learn_generics(&m.sig.generics, types));
write_method_params(w, &m.sig, &ret_type, types, Some(&meth_gen_types), false, true);
write!(w, " {{\n\t").unwrap();
write_method_var_decl_body(w, &m.sig, "", types, Some(&meth_gen_types), false);
if takes_owned_self {
write!(w, "(*unsafe {{ Box::from_raw(this_arg.take_inner()) }}).{}(", m.sig.ident).unwrap();
} else if takes_mut_self {
- write!(w, "unsafe {{ &mut (*(this_arg.inner as *mut native{})) }}.{}(", ident, m.sig.ident).unwrap();
+ write!(w, "unsafe {{ &mut (*ObjOps::untweak_ptr(this_arg.inner as *mut native{})) }}.{}(", ident, m.sig.ident).unwrap();
} else {
- write!(w, "unsafe {{ &*this_arg.inner }}.{}(", m.sig.ident).unwrap();
+ write!(w, "unsafe {{ &*ObjOps::untweak_ptr(this_arg.inner) }}.{}(", m.sig.ident).unwrap();
}
},
_ => unimplemented!(),
}
}
+/// Replaces upper case charachters with underscore followed by lower case except the first
+/// charachter and repeated upper case characthers (which are only made lower case).
+fn camel_to_snake_case(camel: &str) -> String {
+ let mut res = "".to_string();
+ let mut last_upper = -1;
+ for (idx, c) in camel.chars().enumerate() {
+ if c.is_uppercase() {
+ if last_upper != idx as isize - 1 { res.push('_'); }
+ res.push(c.to_lowercase().next().unwrap());
+ last_upper = idx as isize;
+ } else {
+ res.push(c);
+ }
+ }
+ res
+}
+
/// Print a mapping of an enum. If all of the enum's fields are C-mapped in some form (or the enum
/// is unitary), we generate an equivalent enum with all types replaced with their C mapped
assert!(gen_types.learn_generics(&e.generics, types));
let mut needs_free = false;
+ let mut constr = Vec::new();
writeln!(w, "#[must_use]\n#[derive(Clone)]\n#[repr(C)]\npub enum {} {{", e.ident).unwrap();
for var in e.variants.iter() {
assert_eq!(export_status(&var.attrs), ExportStatus::Export); // We can't partially-export a mirrored enum
writeln_docs(w, &var.attrs, "\t");
write!(w, "\t{}", var.ident).unwrap();
+ writeln!(&mut constr, "#[no_mangle]\n/// Utility method to constructs a new {}-variant {}", var.ident, e.ident).unwrap();
+ let constr_name = camel_to_snake_case(&format!("{}", var.ident));
+ write!(&mut constr, "pub extern \"C\" fn {}_{}(", e.ident, constr_name).unwrap();
+ let mut empty_tuple_variant = false;
if let syn::Fields::Named(fields) = &var.fields {
needs_free = true;
writeln!(w, " {{").unwrap();
- for field in fields.named.iter() {
+ for (idx, field) in fields.named.iter().enumerate() {
if export_status(&field.attrs) == ExportStatus::TestOnly { continue; }
- writeln_docs(w, &field.attrs, "\t\t");
+ writeln_field_docs(w, &field.attrs, "\t\t", types, Some(&gen_types), &field.ty);
write!(w, "\t\t{}: ", field.ident.as_ref().unwrap()).unwrap();
+ write!(&mut constr, "{}{}: ", if idx != 0 { ", " } else { "" }, field.ident.as_ref().unwrap()).unwrap();
types.write_c_type(w, &field.ty, Some(&gen_types), false);
+ types.write_c_type(&mut constr, &field.ty, Some(&gen_types), false);
writeln!(w, ",").unwrap();
}
write!(w, "\t}}").unwrap();
} else if let syn::Fields::Unnamed(fields) = &var.fields {
- let mut empty_tuple_variant = false;
if fields.unnamed.len() == 1 {
let mut empty_check = Vec::new();
types.write_c_type(&mut empty_check, &fields.unnamed[0].ty, Some(&gen_types), false);
write!(w, "(").unwrap();
for (idx, field) in fields.unnamed.iter().enumerate() {
if export_status(&field.attrs) == ExportStatus::TestOnly { continue; }
+ write!(&mut constr, "{}: ", ('a' as u8 + idx as u8) as char).unwrap();
types.write_c_type(w, &field.ty, Some(&gen_types), false);
+ types.write_c_type(&mut constr, &field.ty, Some(&gen_types), false);
if idx != fields.unnamed.len() - 1 {
write!(w, ",").unwrap();
+ write!(&mut constr, ",").unwrap();
}
}
write!(w, ")").unwrap();
}
}
if var.discriminant.is_some() { unimplemented!(); }
+ write!(&mut constr, ") -> {} {{\n\t{}::{}", e.ident, e.ident, var.ident).unwrap();
+ if let syn::Fields::Named(fields) = &var.fields {
+ writeln!(&mut constr, " {{").unwrap();
+ for field in fields.named.iter() {
+ writeln!(&mut constr, "\t\t{},", field.ident.as_ref().unwrap()).unwrap();
+ }
+ writeln!(&mut constr, "\t}}").unwrap();
+ } else if let syn::Fields::Unnamed(fields) = &var.fields {
+ if !empty_tuple_variant {
+ write!(&mut constr, "(").unwrap();
+ for idx in 0..fields.unnamed.len() {
+ write!(&mut constr, "{}, ", ('a' as u8 + idx as u8) as char).unwrap();
+ }
+ writeln!(&mut constr, ")").unwrap();
+ } else {
+ writeln!(&mut constr, "").unwrap();
+ }
+ }
+ writeln!(&mut constr, "}}").unwrap();
writeln!(w, ",").unwrap();
}
writeln!(w, "}}\nuse {}::{} as native{};\nimpl {} {{", types.module_path, e.ident, e.ident, e.ident).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);
+ w.write_all(&constr).unwrap();
+ write_cpp_wrapper(cpp_headers, &format!("{}", e.ident), needs_free, None);
}
fn writeln_fn<'a, 'b, W: std::io::Write>(w: &mut W, f: &'a syn::ItemFn, types: &mut TypeResolver<'b, 'a>) {
ExportStatus::NoExport|ExportStatus::TestOnly => return,
ExportStatus::NotImplementable => panic!("(C-not implementable) must only appear on traits"),
}
- writeln_docs(w, &f.attrs, "");
-
let mut gen_types = GenericTypes::new(None);
if !gen_types.learn_generics(&f.sig.generics, types) { return; }
+ writeln_fn_docs(w, &f.attrs, "", types, Some(&gen_types), f.sig.inputs.iter(), &f.sig.output);
+
write!(w, "#[no_mangle]\npub extern \"C\" fn {}(", f.sig.ident).unwrap();
write_method_params(w, &f.sig, "", types, Some(&gen_types), false, true);
write!(w, " {{\n\t").unwrap();
if let syn::Type::Path(p) = &*c.ty {
let resolved_path = type_resolver.resolve_path(&p.path, None);
if type_resolver.is_primitive(&resolved_path) {
- writeln_docs(&mut out, &c.attrs, "");
+ writeln_field_docs(&mut out, &c.attrs, "", &mut type_resolver, None, &*c.ty);
writeln!(out, "\n#[no_mangle]").unwrap();
writeln!(out, "pub static {}: {} = {}::{};", c.ident, resolved_path, module, c.ident).unwrap();
}
// For container templates which we created while walking the crate, make sure we add C++
// mapped types so that C++ users can utilize the auto-destructors available.
for (ty, has_destructor) in libtypes.templates_defined.borrow().iter() {
- write_cpp_wrapper(&mut cpp_header_file, ty, *has_destructor);
+ write_cpp_wrapper(&mut cpp_header_file, ty, *has_destructor, None);
}
writeln!(cpp_header_file, "}}").unwrap();