1 // This file is Copyright its original authors, visible in version control
4 // This file is licensed under the Apache License, Version 2.0 <LICENSE-APACHE>
5 // or the MIT license <LICENSE-MIT>, at your option.
6 // You may not use this file except in accordance with one or both of these
9 //! Converts a rust crate into a rust crate containing a number of C-exported wrapper functions and
10 //! classes (which is exportable using cbindgen).
11 //! In general, supports convering:
12 //! * structs as a pointer to the underlying type (either owned or not owned),
13 //! * traits as a void-ptr plus a jump table,
14 //! * enums as an equivalent enum with all the inner fields mapped to the mapped types,
15 //! * certain containers (tuples, slices, Vecs, Options, and Results currently) to a concrete
16 //! version of a defined container template.
18 //! It also generates relevant memory-management functions and free-standing functions with
19 //! parameters mapped.
21 use std::collections::{HashMap, hash_map};
24 use std::io::{Read, Write};
25 use std::iter::FromIterator;
28 use proc_macro2::Span;
29 use quote::format_ident;
37 const DEFAULT_IMPORTS: &'static str = "
38 use alloc::str::FromStr;
39 use core::ffi::c_void;
40 use core::convert::Infallible;
41 use bitcoin::hashes::Hash;
42 use crate::c_types::*;
43 #[cfg(feature=\"no-std\")]
44 use alloc::{vec::Vec, boxed::Box};
48 /// str.rsplit_once but with an older MSRV
49 fn rsplit_once<'a>(inp: &'a str, pattern: &str) -> Option<(&'a str, &'a str)> {
50 let mut iter = inp.rsplitn(2, pattern);
51 let second_entry = iter.next().unwrap();
52 Some((iter.next().unwrap(), second_entry))
55 // *************************************
56 // *** Manually-expanded conversions ***
57 // *************************************
59 /// Convert "impl trait_path for for_ty { .. }" for manually-mapped types (ie (de)serialization)
60 fn maybe_convert_trait_impl<W: std::io::Write>(w: &mut W, trait_path: &syn::Path, for_ty: &syn::Type, types: &mut TypeResolver, generics: &GenericTypes) {
61 if let Some(t) = types.maybe_resolve_path(&trait_path, Some(generics)) {
64 let mut has_inner = false;
65 if let syn::Type::Path(ref p) = for_ty {
66 let resolved_path = types.resolve_path(&p.path, Some(generics));
67 for_obj = format!("{}", p.path.segments.last().unwrap().ident);
68 full_obj_path = format!("crate::{}", resolved_path);
69 has_inner = types.c_type_has_inner_from_path(&resolved_path);
71 // We assume that anything that isn't a Path is somehow a generic that ends up in our
72 // derived-types module.
73 let mut for_obj_vec = Vec::new();
74 types.write_c_type(&mut for_obj_vec, for_ty, Some(generics), false);
75 full_obj_path = String::from_utf8(for_obj_vec).unwrap();
76 assert!(full_obj_path.starts_with(TypeResolver::generated_container_path()));
77 for_obj = full_obj_path[TypeResolver::generated_container_path().len() + 2..].into();
81 "lightning::util::ser::Writeable" => {
82 writeln!(w, "#[no_mangle]").unwrap();
83 writeln!(w, "/// Serialize the {} object into a byte array which can be read by {}_read", for_obj, for_obj).unwrap();
84 writeln!(w, "pub extern \"C\" fn {}_write(obj: &{}) -> crate::c_types::derived::CVec_u8Z {{", for_obj, full_obj_path).unwrap();
86 let ref_type: syn::Type = syn::parse_quote!(&#for_ty);
87 assert!(!types.write_from_c_conversion_new_var(w, &format_ident!("obj"), &ref_type, Some(generics)));
89 write!(w, "\tcrate::c_types::serialize_obj(").unwrap();
90 types.write_from_c_conversion_prefix(w, &ref_type, Some(generics));
91 write!(w, "unsafe {{ &*obj }}").unwrap();
92 types.write_from_c_conversion_suffix(w, &ref_type, Some(generics));
93 writeln!(w, ")").unwrap();
95 writeln!(w, "}}").unwrap();
97 writeln!(w, "#[no_mangle]").unwrap();
98 writeln!(w, "pub(crate) extern \"C\" fn {}_write_void(obj: *const c_void) -> crate::c_types::derived::CVec_u8Z {{", for_obj).unwrap();
99 writeln!(w, "\tcrate::c_types::serialize_obj(unsafe {{ &*(obj as *const native{}) }})", for_obj).unwrap();
100 writeln!(w, "}}").unwrap();
103 "lightning::util::ser::Readable"|"lightning::util::ser::ReadableArgs"|"lightning::util::ser::MaybeReadable" => {
104 // Create the Result<Object, DecodeError> syn::Type
105 let mut res_ty: syn::Type = parse_quote!(Result<#for_ty, lightning::ln::msgs::DecodeError>);
107 writeln!(w, "#[no_mangle]").unwrap();
108 writeln!(w, "/// Read a {} from a byte array, created by {}_write", for_obj, for_obj).unwrap();
109 write!(w, "pub extern \"C\" fn {}_read(ser: crate::c_types::u8slice", for_obj).unwrap();
111 let mut arg_conv = Vec::new();
112 if t == "lightning::util::ser::ReadableArgs" {
113 assert!(trait_path.leading_colon.is_none());
114 let args_seg = trait_path.segments.iter().last().unwrap();
115 assert_eq!(format!("{}", args_seg.ident), "ReadableArgs");
116 if let syn::PathArguments::AngleBracketed(args) = &args_seg.arguments {
117 assert_eq!(args.args.len(), 1);
118 if let syn::GenericArgument::Type(args_ty) = args.args.iter().next().unwrap() {
119 macro_rules! write_arg_conv {
120 ($ty: expr, $arg_name: expr) => {
121 write!(w, ", {}: ", $arg_name).unwrap();
122 types.write_c_type(w, $ty, Some(generics), false);
124 write!(&mut arg_conv, "\t").unwrap();
125 if types.write_from_c_conversion_new_var(&mut arg_conv, &format_ident!("{}", $arg_name), &$ty, Some(generics)) {
126 write!(&mut arg_conv, "\n\t").unwrap();
129 write!(&mut arg_conv, "let {}_conv = ", $arg_name).unwrap();
130 types.write_from_c_conversion_prefix(&mut arg_conv, &$ty, Some(generics));
131 write!(&mut arg_conv, "{}", $arg_name).unwrap();
132 types.write_from_c_conversion_suffix(&mut arg_conv, &$ty, Some(generics));
133 write!(&mut arg_conv, ";\n").unwrap();
137 if let syn::Type::Tuple(tup) = args_ty {
138 // Crack open tuples and make them separate arguments instead of
139 // converting the full tuple. This makes it substantially easier to
140 // reason about things like references in the tuple fields.
141 let mut arg_conv_res = Vec::new();
142 for (idx, elem) in tup.elems.iter().enumerate() {
143 let arg_name = format!("arg_{}", ('a' as u8 + idx as u8) as char);
144 write_arg_conv!(elem, arg_name);
145 write!(&mut arg_conv_res, "{}_conv{}", arg_name, if idx != tup.elems.len() - 1 { ", " } else { "" }).unwrap();
147 writeln!(&mut arg_conv, "\tlet arg_conv = ({});", String::from_utf8(arg_conv_res).unwrap()).unwrap();
149 write_arg_conv!(args_ty, "arg");
151 } else { unreachable!(); }
152 } else { unreachable!(); }
153 } else if t == "lightning::util::ser::MaybeReadable" {
154 res_ty = parse_quote!(Result<Option<#for_ty>, lightning::ln::msgs::DecodeError>);
156 write!(w, ") -> ").unwrap();
157 types.write_c_type(w, &res_ty, Some(generics), false);
158 writeln!(w, " {{").unwrap();
160 if t == "lightning::util::ser::ReadableArgs" {
161 w.write(&arg_conv).unwrap();
164 write!(w, "\tlet res: ").unwrap();
165 // At least in one case we need type annotations here, so provide them.
166 types.write_rust_type(w, Some(generics), &res_ty, false);
168 if t == "lightning::util::ser::ReadableArgs" {
169 writeln!(w, " = crate::c_types::deserialize_obj_arg(ser, arg_conv);").unwrap();
170 } else if t == "lightning::util::ser::MaybeReadable" {
171 writeln!(w, " = crate::c_types::maybe_deserialize_obj(ser);").unwrap();
173 writeln!(w, " = crate::c_types::deserialize_obj(ser);").unwrap();
175 write!(w, "\t").unwrap();
176 if types.write_to_c_conversion_new_var(w, &format_ident!("res"), &res_ty, Some(generics), false) {
177 write!(w, "\n\t").unwrap();
179 types.write_to_c_conversion_inline_prefix(w, &res_ty, Some(generics), false);
180 write!(w, "res").unwrap();
181 types.write_to_c_conversion_inline_suffix(w, &res_ty, Some(generics), false);
182 writeln!(w, "\n}}").unwrap();
189 /// Convert "TraitA : TraitB" to a single function name and return type.
191 /// This is (obviously) somewhat over-specialized and only useful for TraitB's that only require a
192 /// single function (eg for serialization).
193 fn convert_trait_impl_field(trait_path: &str) -> (&'static str, String, &'static str) {
195 "lightning::util::ser::Writeable" => ("Serialize the object into a byte array", "write".to_owned(), "crate::c_types::derived::CVec_u8Z"),
196 _ => unimplemented!(),
200 /// Companion to convert_trait_impl_field, write an assignment for the function defined by it for
201 /// `for_obj` which implements the the trait at `trait_path`.
202 fn write_trait_impl_field_assign<W: std::io::Write>(w: &mut W, trait_path: &str, for_obj: &syn::Ident) {
204 "lightning::util::ser::Writeable" => {
205 writeln!(w, "\t\twrite: {}_write_void,", for_obj).unwrap();
207 _ => unimplemented!(),
211 /// Write out the impl block for a defined trait struct which has a supertrait
212 fn do_write_impl_trait<W: std::io::Write>(w: &mut W, trait_path: &str, _trait_name: &syn::Ident, for_obj: &str) {
214 "lightning::util::ser::Writeable" => {
215 writeln!(w, "impl {} for {} {{", trait_path, for_obj).unwrap();
216 writeln!(w, "\tfn write<W: lightning::util::ser::Writer>(&self, w: &mut W) -> Result<(), crate::c_types::io::Error> {{").unwrap();
217 writeln!(w, "\t\tlet vec = (self.write)(self.this_arg);").unwrap();
218 writeln!(w, "\t\tw.write_all(vec.as_slice())").unwrap();
219 writeln!(w, "\t}}\n}}").unwrap();
225 /// Returns true if an instance of the given type must never exist
226 fn is_type_unconstructable(path: &str) -> bool {
227 path == "core::convert::Infallible" || path == "crate::c_types::NotConstructable"
230 // *******************************
231 // *** Per-Type Printing Logic ***
232 // *******************************
234 macro_rules! walk_supertraits { ($t: expr, $types: expr, ($( $($pat: pat)|* => $e: expr),*) ) => { {
235 if $t.colon_token.is_some() {
236 for st in $t.supertraits.iter() {
238 syn::TypeParamBound::Trait(supertrait) => {
239 if supertrait.paren_token.is_some() || supertrait.lifetimes.is_some() {
242 // First try to resolve path to find in-crate traits, but if that doesn't work
243 // assume its a prelude trait (eg Clone, etc) and just use the single ident.
244 let types_opt: Option<&TypeResolver> = $types;
245 if let Some(types) = types_opt {
246 if let Some(path) = types.maybe_resolve_path(&supertrait.path, None) {
247 let last_seg = supertrait.path.segments.iter().last().unwrap();
248 match (&path as &str, &last_seg.ident, &last_seg.arguments) {
249 $( $($pat)|* => $e, )*
254 if let Some(ident) = supertrait.path.get_ident() {
255 match (&format!("{}", ident) as &str, &ident, &syn::PathArguments::None) {
256 $( $($pat)|* => $e, )*
258 } else if types_opt.is_some() {
259 panic!("Supertrait unresolvable and not single-ident");
262 syn::TypeParamBound::Lifetime(_) => unimplemented!(),
268 macro_rules! get_module_type_resolver {
269 ($module: expr, $crate_libs: expr, $crate_types: expr) => { {
270 let module: &str = &$module;
271 let mut module_iter = module.rsplitn(2, "::");
272 module_iter.next().unwrap();
273 let module = module_iter.next().unwrap();
274 let imports = ImportResolver::new(module.splitn(2, "::").next().unwrap(), &$crate_types.lib_ast.dependencies,
275 module, &$crate_types.lib_ast.modules.get(module).unwrap().items);
276 TypeResolver::new(module, imports, $crate_types)
280 /// Prints a C-mapped trait object containing a void pointer and a jump table for each function in
281 /// the original trait.
282 /// Implements the native Rust trait and relevant parent traits for the new C-mapped trait.
284 /// Finally, implements Deref<MappedTrait> for MappedTrait which allows its use in types which need
285 /// a concrete Deref to the Rust trait.
286 fn writeln_trait<'a, 'b, W: std::io::Write>(w: &mut W, t: &'a syn::ItemTrait, types: &mut TypeResolver<'b, 'a>, extra_headers: &mut File, cpp_headers: &mut File) {
287 let trait_name = format!("{}", t.ident);
289 match export_status(&t.attrs) {
290 ExportStatus::Export => { implementable = true; }
291 ExportStatus::NotImplementable => { implementable = false; },
292 ExportStatus::NoExport|ExportStatus::TestOnly => return,
294 writeln_docs(w, &t.attrs, "");
296 let mut gen_types = GenericTypes::new(Some(format!("{}::{}", types.module_path, trait_name)));
298 // Add functions which may be required for supertrait implementations.
299 // Due to borrow checker limitations, we only support one in-crate supertrait here.
301 let supertrait_resolver;
302 walk_supertraits!(t, Some(&types), (
304 if let Some(supertrait) = types.crate_types.traits.get(s) {
305 supertrait_name = s.to_string();
306 supertrait_resolver = get_module_type_resolver!(supertrait_name, types.crate_libs, types.crate_types);
307 gen_types.learn_associated_types(&supertrait, &supertrait_resolver);
313 assert!(gen_types.learn_generics(&t.generics, types));
314 gen_types.learn_associated_types(&t, types);
316 writeln!(w, "#[repr(C)]\npub struct {} {{", trait_name).unwrap();
317 writeln!(w, "\t/// An opaque pointer which is passed to your function implementations as an argument.").unwrap();
318 writeln!(w, "\t/// This has no meaning in the LDK, and can be NULL or any other value.").unwrap();
319 writeln!(w, "\tpub this_arg: *mut c_void,").unwrap();
320 // We store every field's (name, Option<clone_fn>, docs) except this_arg, used in Clone generation
321 // docs is only set if its a function which should be callable on the object itself in C++
322 let mut generated_fields = Vec::new();
323 for item in t.items.iter() {
325 &syn::TraitItem::Method(ref m) => {
326 match export_status(&m.attrs) {
327 ExportStatus::NoExport => {
328 // NoExport in this context means we'll hit an unimplemented!() at runtime,
332 ExportStatus::Export => {},
333 ExportStatus::TestOnly => continue,
334 ExportStatus::NotImplementable => panic!("(C-not implementable) must only appear on traits"),
337 let mut meth_gen_types = gen_types.push_ctx();
338 assert!(meth_gen_types.learn_generics(&m.sig.generics, types));
340 writeln_fn_docs(w, &m.attrs, "\t", types, Some(&meth_gen_types), m.sig.inputs.iter(), &m.sig.output);
342 if let syn::ReturnType::Type(_, rtype) = &m.sig.output {
343 if let syn::Type::Reference(r) = &**rtype {
344 // We have to do quite a dance for trait functions which return references
345 // - they ultimately require us to have a native Rust object stored inside
346 // our concrete trait to return a reference to. However, users may wish to
347 // update the value to be returned each time the function is called (or, to
348 // make C copies of Rust impls equivalent, we have to be able to).
350 // Thus, we store a copy of the C-mapped type (which is just a pointer to
351 // the Rust type and a flag to indicate whether deallocation needs to
352 // happen) as well as provide an Option<>al function pointer which is
353 // called when the trait method is called which allows updating on the fly.
354 write!(w, "\tpub {}: ", m.sig.ident).unwrap();
355 generated_fields.push((format!("{}", m.sig.ident), None, None));
356 types.write_c_type(w, &*r.elem, Some(&meth_gen_types), false);
357 writeln!(w, ",").unwrap();
358 writeln!(w, "\t/// Fill in the {} field as a reference to it will be given to Rust after this returns", m.sig.ident).unwrap();
359 writeln!(w, "\t/// Note that this takes a pointer to this object, not the this_ptr like other methods do").unwrap();
360 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();
361 writeln!(w, "\tpub set_{}: Option<extern \"C\" fn(&{})>,", m.sig.ident, trait_name).unwrap();
362 generated_fields.push((format!("set_{}", m.sig.ident), None, None));
363 // Note that cbindgen will now generate
364 // typedef struct Thing {..., set_thing: (const struct Thing*), ...} Thing;
365 // which does not compile since Thing is not defined before it is used.
366 writeln!(extra_headers, "struct LDK{};", trait_name).unwrap();
369 // Sadly, this currently doesn't do what we want, but it should be easy to get
370 // cbindgen to support it. See https://github.com/eqrion/cbindgen/issues/531
371 writeln!(w, "\t#[must_use]").unwrap();
374 let mut cpp_docs = Vec::new();
375 writeln_fn_docs(&mut cpp_docs, &m.attrs, "\t * ", types, Some(&meth_gen_types), m.sig.inputs.iter(), &m.sig.output);
376 let docs_string = "\t/**\n".to_owned() + &String::from_utf8(cpp_docs).unwrap().replace("///", "") + "\t */\n";
378 write!(w, "\tpub {}: extern \"C\" fn (", m.sig.ident).unwrap();
379 generated_fields.push((format!("{}", m.sig.ident), None, Some(docs_string)));
380 write_method_params(w, &m.sig, "c_void", types, Some(&meth_gen_types), true, false);
381 writeln!(w, ",").unwrap();
383 &syn::TraitItem::Type(_) => {},
384 _ => unimplemented!(),
387 // Add functions which may be required for supertrait implementations.
388 walk_supertraits!(t, Some(&types), (
390 writeln!(w, "\t/// Called, if set, after this {} has been cloned into a duplicate object.", trait_name).unwrap();
391 writeln!(w, "\t/// The new {} is provided, and should be mutated as needed to perform a", trait_name).unwrap();
392 writeln!(w, "\t/// deep copy of the object pointed to by this_arg or avoid any double-freeing.").unwrap();
393 writeln!(w, "\tpub cloned: Option<extern \"C\" fn (new_{}: &mut {})>,", trait_name, trait_name).unwrap();
394 generated_fields.push(("cloned".to_owned(), None, None));
396 ("std::cmp::Eq", _, _)|("core::cmp::Eq", _, _) => {
397 let eq_docs = "Checks if two objects are equal given this object's this_arg pointer and another object.";
398 writeln!(w, "\t/// {}", eq_docs).unwrap();
399 writeln!(w, "\tpub eq: extern \"C\" fn (this_arg: *const c_void, other_arg: &{}) -> bool,", trait_name).unwrap();
400 generated_fields.push(("eq".to_owned(), None, Some(format!("\t/** {} */\n", eq_docs))));
402 ("std::hash::Hash", _, _)|("core::hash::Hash", _, _) => {
403 let hash_docs_a = "Calculate a succinct non-cryptographic hash for an object given its this_arg pointer.";
404 let hash_docs_b = "This is used, for example, for inclusion of this object in a hash map.";
405 writeln!(w, "\t/// {}", hash_docs_a).unwrap();
406 writeln!(w, "\t/// {}", hash_docs_b).unwrap();
407 writeln!(w, "\tpub hash: extern \"C\" fn (this_arg: *const c_void) -> u64,").unwrap();
408 generated_fields.push(("hash".to_owned(), None,
409 Some(format!("\t/**\n\t * {}\n\t * {}\n\t */\n", hash_docs_a, hash_docs_b))));
411 ("Send", _, _) => {}, ("Sync", _, _) => {},
412 ("std::fmt::Debug", _, _)|("core::fmt::Debug", _, _) => {
413 let debug_docs = "Return a human-readable \"debug\" string describing this object";
414 writeln!(w, "\t/// {}", debug_docs).unwrap();
415 writeln!(w, "\tpub debug_str: extern \"C\" fn (this_arg: *const c_void) -> crate::c_types::Str,").unwrap();
416 generated_fields.push(("debug_str".to_owned(), None,
417 Some(format!("\t/**\n\t * {}\n\t */\n", debug_docs))));
420 // TODO: Both of the below should expose supertrait methods in C++, but doing so is
422 generated_fields.push(if types.crate_types.traits.get(s).is_none() {
423 let (docs, name, ret) = convert_trait_impl_field(s);
424 writeln!(w, "\t/// {}", docs).unwrap();
425 writeln!(w, "\tpub {}: extern \"C\" fn (this_arg: *const c_void) -> {},", name, ret).unwrap();
426 (name, None, None) // Assume clonable
428 // For in-crate supertraits, just store a C-mapped copy of the supertrait as a member.
429 writeln!(w, "\t/// Implementation of {} for this object.", i).unwrap();
430 let is_clonable = types.is_clonable(s);
431 writeln!(w, "\tpub {}: crate::{},", i, s).unwrap();
432 (format!("{}", i), if !is_clonable {
433 Some(format!("crate::{}_clone_fields", s))
434 } else { None }, None)
438 writeln!(w, "\t/// Frees any resources associated with this object given its this_arg pointer.").unwrap();
439 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();
440 writeln!(w, "\tpub free: Option<extern \"C\" fn(this_arg: *mut c_void)>,").unwrap();
441 generated_fields.push(("free".to_owned(), None, None));
442 writeln!(w, "}}").unwrap();
444 macro_rules! impl_trait_for_c {
445 ($t: expr, $impl_accessor: expr, $type_resolver: expr, $generic_impls: expr) => {
446 let mut trait_gen_types = gen_types.push_ctx();
447 assert!(trait_gen_types.learn_generics_with_impls(&$t.generics, $generic_impls, $type_resolver));
448 for item in $t.items.iter() {
450 syn::TraitItem::Method(m) => {
451 if let ExportStatus::TestOnly = export_status(&m.attrs) { continue; }
452 if m.sig.constness.is_some() || m.sig.asyncness.is_some() || m.sig.unsafety.is_some() ||
453 m.sig.abi.is_some() || m.sig.variadic.is_some() {
456 let mut meth_gen_types = trait_gen_types.push_ctx();
457 assert!(meth_gen_types.learn_generics(&m.sig.generics, $type_resolver));
458 // Note that we do *not* use the method generics when printing "native"
459 // rust parts - if the method is generic, we need to print a generic
461 write!(w, "\tfn {}", m.sig.ident).unwrap();
462 $type_resolver.write_rust_generic_param(w, Some(&gen_types), m.sig.generics.params.iter());
463 write!(w, "(").unwrap();
464 for inp in m.sig.inputs.iter() {
466 syn::FnArg::Receiver(recv) => {
467 if !recv.attrs.is_empty() || recv.reference.is_none() { panic!("2"); }
468 write!(w, "&").unwrap();
469 if let Some(lft) = &recv.reference.as_ref().unwrap().1 {
470 write!(w, "'{} ", lft.ident).unwrap();
472 if recv.mutability.is_some() {
473 write!(w, "mut self").unwrap();
475 write!(w, "self").unwrap();
478 syn::FnArg::Typed(arg) => {
479 if !arg.attrs.is_empty() { panic!("3"); }
481 syn::Pat::Ident(ident) => {
482 if !ident.attrs.is_empty() || ident.by_ref.is_some() ||
483 ident.mutability.is_some() || ident.subpat.is_some() {
486 write!(w, ", mut {}{}: ", if $type_resolver.skip_arg(&*arg.ty, Some(&meth_gen_types)) { "_" } else { "" }, ident.ident).unwrap();
490 $type_resolver.write_rust_type(w, Some(&gen_types), &*arg.ty, false);
494 write!(w, ")").unwrap();
495 match &m.sig.output {
496 syn::ReturnType::Type(_, rtype) => {
497 write!(w, " -> ").unwrap();
498 $type_resolver.write_rust_type(w, Some(&gen_types), &*rtype, false)
502 write!(w, " {{\n\t\t").unwrap();
503 match export_status(&m.attrs) {
504 ExportStatus::NoExport => {
509 if let syn::ReturnType::Type(_, rtype) = &m.sig.output {
510 if let syn::Type::Reference(r) = &**rtype {
511 assert_eq!(m.sig.inputs.len(), 1); // Must only take self!
512 writeln!(w, "if let Some(f) = self{}.set_{} {{", $impl_accessor, m.sig.ident).unwrap();
513 writeln!(w, "\t\t\t(f)(&self{});", $impl_accessor).unwrap();
514 write!(w, "\t\t}}\n\t\t").unwrap();
515 $type_resolver.write_from_c_conversion_to_ref_prefix(w, &*r.elem, Some(&meth_gen_types));
516 write!(w, "self{}.{}", $impl_accessor, m.sig.ident).unwrap();
517 $type_resolver.write_from_c_conversion_to_ref_suffix(w, &*r.elem, Some(&meth_gen_types));
518 writeln!(w, "\n\t}}").unwrap();
522 write_method_var_decl_body(w, &m.sig, "\t", $type_resolver, Some(&meth_gen_types), true);
523 write!(w, "(self{}.{})(", $impl_accessor, m.sig.ident).unwrap();
524 let mut args = Vec::new();
525 write_method_call_params(&mut args, &m.sig, "\t", $type_resolver, Some(&meth_gen_types), "", true);
526 w.write_all(String::from_utf8(args).unwrap().replace("self", &format!("self{}", $impl_accessor)).as_bytes()).unwrap();
528 writeln!(w, "\n\t}}").unwrap();
530 &syn::TraitItem::Type(ref t) => {
531 if t.default.is_some() || t.generics.lt_token.is_some() { panic!("10"); }
532 let mut bounds_iter = t.bounds.iter();
534 match bounds_iter.next().unwrap() {
535 syn::TypeParamBound::Trait(tr) => {
536 writeln!(w, "\ttype {} = crate::{};", t.ident, $type_resolver.resolve_path(&tr.path, Some(&gen_types))).unwrap();
537 for bound in bounds_iter {
538 if let syn::TypeParamBound::Trait(_) = bound { panic!("11"); }
542 syn::TypeParamBound::Lifetime(_) => {},
552 writeln!(w, "unsafe impl Send for {} {{}}", trait_name).unwrap();
553 writeln!(w, "unsafe impl Sync for {} {{}}", trait_name).unwrap();
555 writeln!(w, "#[no_mangle]").unwrap();
556 writeln!(w, "pub(crate) extern \"C\" fn {}_clone_fields(orig: &{}) -> {} {{", trait_name, trait_name, trait_name).unwrap();
557 writeln!(w, "\t{} {{", trait_name).unwrap();
558 writeln!(w, "\t\tthis_arg: orig.this_arg,").unwrap();
559 for (field, clone_fn, _) in generated_fields.iter() {
560 if let Some(f) = clone_fn {
561 // If the field isn't clonable, blindly assume its a trait and hope for the best.
562 writeln!(w, "\t\t{}: {}(&orig.{}),", field, f, field).unwrap();
564 writeln!(w, "\t\t{}: Clone::clone(&orig.{}),", field, field).unwrap();
567 writeln!(w, "\t}}\n}}").unwrap();
569 // Implement supertraits for the C-mapped struct.
570 walk_supertraits!(t, Some(&types), (
571 ("std::cmp::Eq", _, _)|("core::cmp::Eq", _, _) => {
572 writeln!(w, "impl core::cmp::Eq for {} {{}}", trait_name).unwrap();
573 writeln!(w, "impl core::cmp::PartialEq for {} {{", trait_name).unwrap();
574 writeln!(w, "\tfn eq(&self, o: &Self) -> bool {{ (self.eq)(self.this_arg, o) }}\n}}").unwrap();
576 ("std::hash::Hash", _, _)|("core::hash::Hash", _, _) => {
577 writeln!(w, "impl core::hash::Hash for {} {{", trait_name).unwrap();
578 writeln!(w, "\tfn hash<H: core::hash::Hasher>(&self, hasher: &mut H) {{ hasher.write_u64((self.hash)(self.this_arg)) }}\n}}").unwrap();
580 ("Send", _, _) => {}, ("Sync", _, _) => {},
582 writeln!(w, "#[no_mangle]").unwrap();
583 writeln!(w, "/// Creates a copy of a {}", trait_name).unwrap();
584 writeln!(w, "pub extern \"C\" fn {}_clone(orig: &{}) -> {} {{", trait_name, trait_name, trait_name).unwrap();
585 writeln!(w, "\tlet mut res = {}_clone_fields(orig);", trait_name).unwrap();
586 writeln!(w, "\tif let Some(f) = orig.cloned {{ (f)(&mut res) }};").unwrap();
587 writeln!(w, "\tres\n}}").unwrap();
588 writeln!(w, "impl Clone for {} {{", trait_name).unwrap();
589 writeln!(w, "\tfn clone(&self) -> Self {{").unwrap();
590 writeln!(w, "\t\t{}_clone(self)", trait_name).unwrap();
591 writeln!(w, "\t}}\n}}").unwrap();
593 ("std::fmt::Debug", _, _)|("core::fmt::Debug", _, _) => {
594 writeln!(w, "impl core::fmt::Debug for {} {{", trait_name).unwrap();
595 writeln!(w, "\tfn fmt(&self, f: &mut core::fmt::Formatter) -> Result<(), core::fmt::Error> {{").unwrap();
596 writeln!(w, "\t\tf.write_str((self.debug_str)(self.this_arg).into_str())").unwrap();
597 writeln!(w, "\t}}").unwrap();
598 writeln!(w, "}}").unwrap();
600 (s, i, generic_args) => {
601 if let Some(supertrait) = types.crate_types.traits.get(s) {
602 let resolver = get_module_type_resolver!(s, types.crate_libs, types.crate_types);
604 // Blindly assume that the same imports where `supertrait` is defined are also
605 // imported here. This will almost certainly break at some point, but it should be
606 // a compilation failure when it does so.
607 write!(w, "impl").unwrap();
608 maybe_write_lifetime_generics(w, &supertrait.generics, types);
609 write!(w, " {}", s).unwrap();
610 maybe_write_generics(w, &supertrait.generics, generic_args, types, false);
611 writeln!(w, " for {} {{", trait_name).unwrap();
613 impl_trait_for_c!(supertrait, format!(".{}", i), &resolver, generic_args);
614 writeln!(w, "}}").unwrap();
616 do_write_impl_trait(w, s, i, &trait_name);
621 // Finally, implement the original Rust trait for the newly created mapped trait.
622 writeln!(w, "\nuse {}::{} as rust{};", types.module_path, t.ident, trait_name).unwrap();
624 write!(w, "impl").unwrap();
625 maybe_write_lifetime_generics(w, &t.generics, types);
626 write!(w, " rust{}", t.ident).unwrap();
627 maybe_write_generics(w, &t.generics, &syn::PathArguments::None, types, false);
628 writeln!(w, " for {} {{", trait_name).unwrap();
629 impl_trait_for_c!(t, "", types, &syn::PathArguments::None);
630 writeln!(w, "}}\n").unwrap();
631 writeln!(w, "// We're essentially a pointer already, or at least a set of pointers, so allow us to be used").unwrap();
632 writeln!(w, "// directly as a Deref trait in higher-level structs:").unwrap();
633 writeln!(w, "impl core::ops::Deref for {} {{\n\ttype Target = Self;", trait_name).unwrap();
634 writeln!(w, "\tfn deref(&self) -> &Self {{\n\t\tself\n\t}}\n}}").unwrap();
637 writeln!(w, "/// Calls the free function if one is set").unwrap();
638 writeln!(w, "#[no_mangle]\npub extern \"C\" fn {}_free(this_ptr: {}) {{ }}", trait_name, trait_name).unwrap();
639 writeln!(w, "impl Drop for {} {{", trait_name).unwrap();
640 writeln!(w, "\tfn drop(&mut self) {{").unwrap();
641 writeln!(w, "\t\tif let Some(f) = self.free {{").unwrap();
642 writeln!(w, "\t\t\tf(self.this_arg);").unwrap();
643 writeln!(w, "\t\t}}\n\t}}\n}}").unwrap();
645 write_cpp_wrapper(cpp_headers, &trait_name, true, Some(generated_fields.drain(..)
646 .filter_map(|(name, _, docs)| if let Some(docs) = docs { Some((name, docs)) } else { None }).collect()));
649 /// Write out a simple "opaque" type (eg structs) which contain a pointer to the native Rust type
650 /// and a flag to indicate whether Drop'ing the mapped struct drops the underlying Rust type.
652 /// Also writes out a _free function and a C++ wrapper which handles calling _free.
653 fn writeln_opaque<W: std::io::Write>(w: &mut W, ident: &syn::Ident, struct_name: &str, generics: &syn::Generics, attrs: &[syn::Attribute], types: &TypeResolver, extra_headers: &mut File, cpp_headers: &mut File) {
654 // If we directly read the original type by its original name, cbindgen hits
655 // https://github.com/eqrion/cbindgen/issues/286 Thus, instead, we import it as a temporary
656 // name and then reference it by that name, which works around the issue.
657 write!(w, "\nuse {}::{} as native{}Import;\npub(crate) type native{} = native{}Import", types.module_path, ident, ident, ident, ident).unwrap();
658 maybe_write_generics(w, &generics, &syn::PathArguments::None, &types, true);
659 writeln!(w, ";\n").unwrap();
660 writeln!(extra_headers, "struct native{}Opaque;\ntypedef struct native{}Opaque LDKnative{};", ident, ident, ident).unwrap();
661 writeln_docs(w, &attrs, "");
662 writeln!(w, "#[must_use]\n#[repr(C)]\npub struct {} {{", struct_name).unwrap();
663 writeln!(w, "\t/// A pointer to the opaque Rust object.\n").unwrap();
664 writeln!(w, "\t/// Nearly everywhere, inner must be non-null, however in places where").unwrap();
665 writeln!(w, "\t/// the Rust equivalent takes an Option, it may be set to null to indicate None.").unwrap();
666 writeln!(w, "\tpub inner: *mut native{},", ident).unwrap();
667 writeln!(w, "\t/// Indicates that this is the only struct which contains the same pointer.\n").unwrap();
668 writeln!(w, "\t/// Rust functions which take ownership of an object provided via an argument require").unwrap();
669 writeln!(w, "\t/// this to be true and invalidate the object pointed to by inner.").unwrap();
670 writeln!(w, "\tpub is_owned: bool,").unwrap();
671 writeln!(w, "}}\n").unwrap();
672 writeln!(w, "impl Drop for {} {{\n\tfn drop(&mut self) {{", struct_name).unwrap();
673 writeln!(w, "\t\tif self.is_owned && !<*mut native{}>::is_null(self.inner) {{", ident).unwrap();
674 writeln!(w, "\t\t\tlet _ = unsafe {{ Box::from_raw(ObjOps::untweak_ptr(self.inner)) }};\n\t\t}}\n\t}}\n}}").unwrap();
675 writeln!(w, "/// Frees any resources used by the {}, if is_owned is set and inner is non-NULL.", struct_name).unwrap();
676 writeln!(w, "#[no_mangle]\npub extern \"C\" fn {}_free(this_obj: {}) {{ }}", struct_name, struct_name).unwrap();
677 writeln!(w, "#[allow(unused)]").unwrap();
678 writeln!(w, "/// Used only if an object of this type is returned as a trait impl by a method").unwrap();
679 writeln!(w, "pub(crate) extern \"C\" fn {}_free_void(this_ptr: *mut c_void) {{", struct_name).unwrap();
680 writeln!(w, "\tunsafe {{ let _ = Box::from_raw(this_ptr as *mut native{}); }}\n}}", struct_name).unwrap();
681 writeln!(w, "#[allow(unused)]").unwrap();
682 writeln!(w, "impl {} {{", struct_name).unwrap();
683 writeln!(w, "\tpub(crate) fn get_native_ref(&self) -> &'static native{} {{", struct_name).unwrap();
684 writeln!(w, "\t\tunsafe {{ &*ObjOps::untweak_ptr(self.inner) }}").unwrap();
685 writeln!(w, "\t}}").unwrap();
686 writeln!(w, "\tpub(crate) fn get_native_mut_ref(&self) -> &'static mut native{} {{", struct_name).unwrap();
687 writeln!(w, "\t\tunsafe {{ &mut *ObjOps::untweak_ptr(self.inner) }}").unwrap();
688 writeln!(w, "\t}}").unwrap();
689 writeln!(w, "\t/// When moving out of the pointer, we have to ensure we aren't a reference, this makes that easy").unwrap();
690 writeln!(w, "\tpub(crate) fn take_inner(mut self) -> *mut native{} {{", struct_name).unwrap();
691 writeln!(w, "\t\tassert!(self.is_owned);").unwrap();
692 writeln!(w, "\t\tlet ret = ObjOps::untweak_ptr(self.inner);").unwrap();
693 writeln!(w, "\t\tself.inner = core::ptr::null_mut();").unwrap();
694 writeln!(w, "\t\tret").unwrap();
695 writeln!(w, "\t}}\n}}").unwrap();
697 write_cpp_wrapper(cpp_headers, &format!("{}", ident), true, None);
700 /// Writes out all the relevant mappings for a Rust struct, deferring to writeln_opaque to generate
701 /// the struct itself, and then writing getters and setters for public, understood-type fields and
702 /// a constructor if every field is public.
703 fn writeln_struct<'a, 'b, W: std::io::Write>(w: &mut W, s: &'a syn::ItemStruct, types: &mut TypeResolver<'b, 'a>, extra_headers: &mut File, cpp_headers: &mut File) {
704 if export_status(&s.attrs) != ExportStatus::Export { return; }
706 let struct_name = &format!("{}", s.ident);
707 writeln_opaque(w, &s.ident, struct_name, &s.generics, &s.attrs, types, extra_headers, cpp_headers);
709 let mut self_path_segs = syn::punctuated::Punctuated::new();
710 self_path_segs.push(s.ident.clone().into());
711 let self_path = syn::Path { leading_colon: None, segments: self_path_segs};
712 let mut gen_types = GenericTypes::new(Some(types.resolve_path(&self_path, None)));
713 assert!(gen_types.learn_generics(&s.generics, types));
715 let mut all_fields_settable = true;
716 macro_rules! define_field {
717 ($new_name: expr, $real_name: expr, $field: expr) => {
718 if let syn::Visibility::Public(_) = $field.vis {
719 let export = export_status(&$field.attrs);
721 ExportStatus::Export => {},
722 ExportStatus::NoExport|ExportStatus::TestOnly => {
723 all_fields_settable = false;
726 ExportStatus::NotImplementable => panic!("(C-not implementable) must only appear on traits"),
729 if let Some(ref_type) = types.create_ownable_reference(&$field.ty, Some(&gen_types)) {
730 if types.understood_c_type(&ref_type, Some(&gen_types)) {
731 writeln_arg_docs(w, &$field.attrs, "", types, Some(&gen_types), vec![].drain(..), Some(&ref_type));
732 write!(w, "#[no_mangle]\npub extern \"C\" fn {}_get_{}(this_ptr: &{}) -> ", struct_name, $new_name, struct_name).unwrap();
733 types.write_c_type(w, &ref_type, Some(&gen_types), true);
734 write!(w, " {{\n\tlet mut inner_val = &mut this_ptr.get_native_mut_ref().{};\n\t", $real_name).unwrap();
735 let local_var = types.write_to_c_conversion_from_ownable_ref_new_var(w, &format_ident!("inner_val"), &ref_type, Some(&gen_types));
736 if local_var { write!(w, "\n\t").unwrap(); }
737 types.write_to_c_conversion_inline_prefix(w, &ref_type, Some(&gen_types), true);
738 write!(w, "inner_val").unwrap();
739 types.write_to_c_conversion_inline_suffix(w, &ref_type, Some(&gen_types), true);
740 writeln!(w, "\n}}").unwrap();
742 // If the type isn't reference-able, but is clonable, export a getter that just clones
743 if types.understood_c_type(&$field.ty, Some(&gen_types)) {
744 let mut v = Vec::new();
745 types.write_c_type(&mut v, &$field.ty, Some(&gen_types), true);
746 let s = String::from_utf8(v).unwrap();
747 if types.is_clonable(&s) {
748 writeln_arg_docs(w, &$field.attrs, "", types, Some(&gen_types), vec![].drain(..), Some(&$field.ty));
749 writeln!(w, "///\n/// Returns a copy of the field.").unwrap();
750 write!(w, "#[no_mangle]\npub extern \"C\" fn {}_get_{}(this_ptr: &{}) -> {}", struct_name, $new_name, struct_name, s).unwrap();
751 write!(w, " {{\n\tlet mut inner_val = this_ptr.get_native_mut_ref().{}.clone();\n\t", $real_name).unwrap();
752 let local_var = types.write_to_c_conversion_new_var(w, &format_ident!("inner_val"), &$field.ty, Some(&gen_types), true);
753 if local_var { write!(w, "\n\t").unwrap(); }
754 types.write_to_c_conversion_inline_prefix(w, &$field.ty, Some(&gen_types), true);
755 write!(w, "inner_val").unwrap();
756 types.write_to_c_conversion_inline_suffix(w, &$field.ty, Some(&gen_types), true);
757 writeln!(w, "\n}}").unwrap();
763 if types.understood_c_type(&$field.ty, Some(&gen_types)) {
764 writeln_arg_docs(w, &$field.attrs, "", types, Some(&gen_types), vec![("val".to_owned(), &$field.ty)].drain(..), None);
765 write!(w, "#[no_mangle]\npub extern \"C\" fn {}_set_{}(this_ptr: &mut {}, mut val: ", struct_name, $new_name, struct_name).unwrap();
766 types.write_c_type(w, &$field.ty, Some(&gen_types), false);
767 write!(w, ") {{\n\t").unwrap();
768 let local_var = types.write_from_c_conversion_new_var(w, &format_ident!("val"), &$field.ty, Some(&gen_types));
769 if local_var { write!(w, "\n\t").unwrap(); }
770 write!(w, "unsafe {{ &mut *ObjOps::untweak_ptr(this_ptr.inner) }}.{} = ", $real_name).unwrap();
771 types.write_from_c_conversion_prefix(w, &$field.ty, Some(&gen_types));
772 write!(w, "val").unwrap();
773 types.write_from_c_conversion_suffix(w, &$field.ty, Some(&gen_types));
774 writeln!(w, ";\n}}").unwrap();
775 } else { all_fields_settable = false; }
776 } else { all_fields_settable = false; }
781 syn::Fields::Named(fields) => {
782 for field in fields.named.iter() {
783 if let Some(ident) = &field.ident {
784 define_field!(ident, ident, field);
785 } else { all_fields_settable = false; }
788 syn::Fields::Unnamed(fields) => {
789 for (idx, field) in fields.unnamed.iter().enumerate() {
790 define_field!(('a' as u8 + idx as u8) as char, ('0' as u8 + idx as u8) as char, field);
793 _ => unimplemented!()
796 if all_fields_settable {
797 // Build a constructor!
798 writeln!(w, "/// Constructs a new {} given each field", struct_name).unwrap();
799 write!(w, "#[must_use]\n#[no_mangle]\npub extern \"C\" fn {}_new(", struct_name).unwrap();
802 syn::Fields::Named(fields) => {
803 for (idx, field) in fields.named.iter().enumerate() {
804 if idx != 0 { write!(w, ", ").unwrap(); }
805 write!(w, "mut {}_arg: ", field.ident.as_ref().unwrap()).unwrap();
806 types.write_c_type(w, &field.ty, Some(&gen_types), false);
809 syn::Fields::Unnamed(fields) => {
810 for (idx, field) in fields.unnamed.iter().enumerate() {
811 if idx != 0 { write!(w, ", ").unwrap(); }
812 write!(w, "mut {}_arg: ", ('a' as u8 + idx as u8) as char).unwrap();
813 types.write_c_type(w, &field.ty, Some(&gen_types), false);
818 write!(w, ") -> {} {{\n\t", struct_name).unwrap();
820 syn::Fields::Named(fields) => {
821 for field in fields.named.iter() {
822 let field_ident = format_ident!("{}_arg", field.ident.as_ref().unwrap());
823 if types.write_from_c_conversion_new_var(w, &field_ident, &field.ty, Some(&gen_types)) {
824 write!(w, "\n\t").unwrap();
828 syn::Fields::Unnamed(fields) => {
829 for (idx, field) in fields.unnamed.iter().enumerate() {
830 let field_ident = format_ident!("{}_arg", ('a' as u8 + idx as u8) as char);
831 if types.write_from_c_conversion_new_var(w, &field_ident, &field.ty, Some(&gen_types)) {
832 write!(w, "\n\t").unwrap();
838 write!(w, "{} {{ inner: ObjOps::heap_alloc(", struct_name).unwrap();
840 syn::Fields::Named(fields) => {
841 writeln!(w, "native{} {{", s.ident).unwrap();
842 for field in fields.named.iter() {
843 write!(w, "\t\t{}: ", field.ident.as_ref().unwrap()).unwrap();
844 types.write_from_c_conversion_prefix(w, &field.ty, Some(&gen_types));
845 write!(w, "{}_arg", field.ident.as_ref().unwrap()).unwrap();
846 types.write_from_c_conversion_suffix(w, &field.ty, Some(&gen_types));
847 writeln!(w, ",").unwrap();
849 write!(w, "\t}}").unwrap();
851 syn::Fields::Unnamed(fields) => {
852 assert!(s.generics.lt_token.is_none());
853 writeln!(w, "{} (", types.maybe_resolve_ident(&s.ident).unwrap()).unwrap();
854 for (idx, field) in fields.unnamed.iter().enumerate() {
855 write!(w, "\t\t").unwrap();
856 types.write_from_c_conversion_prefix(w, &field.ty, Some(&gen_types));
857 write!(w, "{}_arg", ('a' as u8 + idx as u8) as char).unwrap();
858 types.write_from_c_conversion_suffix(w, &field.ty, Some(&gen_types));
859 writeln!(w, ",").unwrap();
861 write!(w, "\t)").unwrap();
865 writeln!(w, "), is_owned: true }}\n}}").unwrap();
869 /// Prints a relevant conversion for impl *
871 /// For simple impl Struct {}s, this just outputs the wrapper functions as Struct_fn_name() { .. }.
873 /// For impl Trait for Struct{}s, this non-exported generates wrapper functions as
874 /// Trait_Struct_fn_name and a Struct_as_Trait(&struct) -> Trait function which returns a populated
875 /// Trait struct containing a pointer to the passed struct's inner field and the wrapper functions.
877 /// A few non-crate Traits are hard-coded including Default.
878 fn writeln_impl<W: std::io::Write>(w: &mut W, i: &syn::ItemImpl, types: &mut TypeResolver) {
879 match export_status(&i.attrs) {
880 ExportStatus::Export => {},
881 ExportStatus::NoExport|ExportStatus::TestOnly => return,
882 ExportStatus::NotImplementable => panic!("(C-not implementable) must only appear on traits"),
885 if let syn::Type::Tuple(_) = &*i.self_ty {
886 if types.understood_c_type(&*i.self_ty, None) {
887 let mut gen_types = GenericTypes::new(None);
888 if !gen_types.learn_generics(&i.generics, types) {
889 eprintln!("Not implementing anything for `impl (..)` due to not understood generics");
893 if i.defaultness.is_some() || i.unsafety.is_some() { unimplemented!(); }
894 if let Some(trait_path) = i.trait_.as_ref() {
895 if trait_path.0.is_some() { unimplemented!(); }
896 if types.understood_c_path(&trait_path.1) {
897 eprintln!("Not implementing anything for `impl Trait for (..)` - we only support manual defines");
900 // Just do a manual implementation:
901 maybe_convert_trait_impl(w, &trait_path.1, &*i.self_ty, types, &gen_types);
904 eprintln!("Not implementing anything for plain `impl (..)` block - we only support `impl Trait for (..)` blocks");
910 if let &syn::Type::Path(ref p) = &*i.self_ty {
911 if p.qself.is_some() { unimplemented!(); }
912 let ident = &p.path.segments.last().unwrap().ident;
913 if let Some(resolved_path) = types.maybe_resolve_path(&p.path, None) {
914 if types.crate_types.opaques.contains_key(&resolved_path) || types.crate_types.mirrored_enums.contains_key(&resolved_path) ||
915 // At least for core::infallible::Infallible we need to support mapping an
916 // out-of-crate trait implementation.
917 (types.understood_c_path(&p.path) && first_seg_is_stdlib(resolved_path.split("::").next().unwrap())) {
918 if !types.understood_c_path(&p.path) {
919 eprintln!("Not implementing anything for impl {} as the type is not understood (probably C-not exported)", ident);
923 let mut gen_types = GenericTypes::new(Some(resolved_path.clone()));
924 if !gen_types.learn_generics(&i.generics, types) {
925 eprintln!("Not implementing anything for impl {} due to not understood generics", ident);
929 if i.defaultness.is_some() || i.unsafety.is_some() { unimplemented!(); }
930 if let Some(trait_path) = i.trait_.as_ref() {
931 if trait_path.0.is_some() { unimplemented!(); }
932 if types.understood_c_path(&trait_path.1) {
933 let full_trait_path = types.resolve_path(&trait_path.1, None);
934 let trait_obj = *types.crate_types.traits.get(&full_trait_path).unwrap();
937 let supertrait_resolver;
938 walk_supertraits!(trait_obj, Some(&types), (
940 if let Some(supertrait) = types.crate_types.traits.get(s) {
941 supertrait_name = s.to_string();
942 supertrait_resolver = get_module_type_resolver!(supertrait_name, types.crate_libs, types.crate_types);
943 gen_types.learn_associated_types(&supertrait, &supertrait_resolver);
948 // We learn the associated types maping from the original trait object.
949 // That's great, except that they are unresolved idents, so if we learn
950 // mappings from a trai defined in a different file, we may mis-resolve or
951 // fail to resolve the mapped types. Thus, we have to construct a new
952 // resolver for the module that the trait was defined in here first.
953 let mut trait_resolver = get_module_type_resolver!(full_trait_path, types.crate_libs, types.crate_types);
954 gen_types.learn_associated_types(trait_obj, &trait_resolver);
955 let mut impl_associated_types = HashMap::new();
956 for item in i.items.iter() {
958 syn::ImplItem::Type(t) => {
959 if let syn::Type::Path(p) = &t.ty {
960 if let Some(id) = single_ident_generic_path_to_ident(&p.path) {
961 impl_associated_types.insert(&t.ident, id);
969 let export = export_status(&trait_obj.attrs);
971 ExportStatus::Export|ExportStatus::NotImplementable => {},
972 ExportStatus::NoExport|ExportStatus::TestOnly => return,
975 // For cases where we have a concrete native object which implements a
976 // trait and need to return the C-mapped version of the trait, provide a
977 // From<> implementation which does all the work to ensure free is handled
978 // properly. This way we can call this method from deep in the
979 // type-conversion logic without actually knowing the concrete native type.
980 if !resolved_path.starts_with(types.module_path) {
981 if !first_seg_is_stdlib(resolved_path.split("::").next().unwrap()) {
982 writeln!(w, "use crate::{}::native{} as native{};", resolved_path.rsplitn(2, "::").skip(1).next().unwrap(), ident, ident).unwrap();
983 writeln!(w, "use crate::{};", resolved_path).unwrap();
984 writeln!(w, "use crate::{}_free_void;", resolved_path).unwrap();
986 writeln!(w, "use {} as native{};", resolved_path, ident).unwrap();
989 writeln!(w, "impl From<native{}> for crate::{} {{", ident, full_trait_path).unwrap();
990 writeln!(w, "\tfn from(obj: native{}) -> Self {{", ident).unwrap();
991 if is_type_unconstructable(&resolved_path) {
992 writeln!(w, "\t\tunreachable!();").unwrap();
994 writeln!(w, "\t\tlet mut rust_obj = {} {{ inner: ObjOps::heap_alloc(obj), is_owned: true }};", ident).unwrap();
995 writeln!(w, "\t\tlet mut ret = {}_as_{}(&rust_obj);", ident, trait_obj.ident).unwrap();
996 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();
997 writeln!(w, "\t\trust_obj.inner = core::ptr::null_mut();").unwrap();
998 writeln!(w, "\t\tret.free = Some({}_free_void);", ident).unwrap();
999 writeln!(w, "\t\tret").unwrap();
1001 writeln!(w, "\t}}\n}}").unwrap();
1002 if is_type_unconstructable(&resolved_path) {
1003 // We don't bother with Struct_as_Trait conversion for types which must
1004 // never be instantiated, so just return early.
1008 writeln!(w, "/// Constructs a new {} which calls the relevant methods on this_arg.", trait_obj.ident).unwrap();
1009 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();
1010 write!(w, "#[no_mangle]\npub extern \"C\" fn {}_as_{}(this_arg: &{}) -> crate::{} {{\n", ident, trait_obj.ident, ident, full_trait_path).unwrap();
1011 writeln!(w, "\tcrate::{} {{", full_trait_path).unwrap();
1012 writeln!(w, "\t\tthis_arg: unsafe {{ ObjOps::untweak_ptr((*this_arg).inner) as *mut c_void }},").unwrap();
1013 writeln!(w, "\t\tfree: None,").unwrap();
1015 macro_rules! write_meth {
1016 ($m: expr, $trait: expr, $indent: expr) => {
1017 let trait_method = $trait.items.iter().filter_map(|item| {
1018 if let syn::TraitItem::Method(t_m) = item { Some(t_m) } else { None }
1019 }).find(|trait_meth| trait_meth.sig.ident == $m.sig.ident).unwrap();
1020 match export_status(&trait_method.attrs) {
1021 ExportStatus::Export => {},
1022 ExportStatus::NoExport => {
1023 write!(w, "{}\t\t//XXX: Need to export {}\n", $indent, $m.sig.ident).unwrap();
1026 ExportStatus::TestOnly => continue,
1027 ExportStatus::NotImplementable => panic!("(C-not implementable) must only appear on traits"),
1030 let mut printed = false;
1031 if let syn::ReturnType::Type(_, rtype) = &$m.sig.output {
1032 if let syn::Type::Reference(r) = &**rtype {
1033 write!(w, "\n\t\t{}{}: ", $indent, $m.sig.ident).unwrap();
1034 types.write_empty_rust_val(Some(&gen_types), w, &*r.elem);
1035 writeln!(w, ",\n{}\t\tset_{}: Some({}_{}_set_{}),", $indent, $m.sig.ident, ident, $trait.ident, $m.sig.ident).unwrap();
1040 write!(w, "{}\t\t{}: {}_{}_{},\n", $indent, $m.sig.ident, ident, $trait.ident, $m.sig.ident).unwrap();
1044 for item in trait_obj.items.iter() {
1046 syn::TraitItem::Method(m) => {
1047 write_meth!(m, trait_obj, "");
1052 let mut requires_clone = false;
1053 walk_supertraits!(trait_obj, Some(&types), (
1054 ("Clone", _, _) => {
1055 requires_clone = true;
1056 writeln!(w, "\t\tcloned: Some({}_{}_cloned),", trait_obj.ident, ident).unwrap();
1058 ("Sync", _, _) => {}, ("Send", _, _) => {},
1059 ("std::marker::Sync", _, _) => {}, ("std::marker::Send", _, _) => {},
1060 ("core::fmt::Debug", _, _) => {},
1062 if let Some(supertrait_obj) = types.crate_types.traits.get(s) {
1063 writeln!(w, "\t\t{}: crate::{} {{", t, s).unwrap();
1064 writeln!(w, "\t\t\tthis_arg: unsafe {{ ObjOps::untweak_ptr((*this_arg).inner) as *mut c_void }},").unwrap();
1065 writeln!(w, "\t\t\tfree: None,").unwrap();
1066 for item in supertrait_obj.items.iter() {
1068 syn::TraitItem::Method(m) => {
1069 write_meth!(m, supertrait_obj, "\t");
1074 write!(w, "\t\t}},\n").unwrap();
1076 write_trait_impl_field_assign(w, s, ident);
1080 writeln!(w, "\t}}\n}}\n").unwrap();
1082 macro_rules! impl_meth {
1083 ($m: expr, $trait_meth: expr, $trait_path: expr, $trait: expr, $indent: expr, $types: expr) => {
1084 let trait_method = $trait.items.iter().filter_map(|item| {
1085 if let syn::TraitItem::Method(t_m) = item { Some(t_m) } else { None }
1086 }).find(|trait_meth| trait_meth.sig.ident == $m.sig.ident).unwrap();
1087 match export_status(&trait_method.attrs) {
1088 ExportStatus::Export => {},
1089 ExportStatus::NoExport|ExportStatus::TestOnly => continue,
1090 ExportStatus::NotImplementable => panic!("(C-not implementable) must only appear on traits"),
1093 if let syn::ReturnType::Type(_, _) = &$m.sig.output {
1094 writeln!(w, "#[must_use]").unwrap();
1096 write!(w, "extern \"C\" fn {}_{}_{}(", ident, $trait.ident, $m.sig.ident).unwrap();
1097 let mut meth_gen_types = gen_types.push_ctx();
1098 assert!(meth_gen_types.learn_generics(&$m.sig.generics, $types));
1099 let mut uncallable_function = false;
1100 for inp in $m.sig.inputs.iter() {
1102 syn::FnArg::Typed(arg) => {
1103 if $types.skip_arg(&*arg.ty, Some(&meth_gen_types)) { continue; }
1104 let mut c_type = Vec::new();
1105 $types.write_c_type(&mut c_type, &*arg.ty, Some(&meth_gen_types), false);
1106 if is_type_unconstructable(&String::from_utf8(c_type).unwrap()) {
1107 uncallable_function = true;
1113 write_method_params(w, &$trait_meth.sig, "c_void", &mut trait_resolver, Some(&meth_gen_types), true, true);
1114 write!(w, " {{\n\t").unwrap();
1115 if uncallable_function {
1116 write!(w, "unreachable!();").unwrap();
1118 write_method_var_decl_body(w, &$trait_meth.sig, "", &mut trait_resolver, Some(&meth_gen_types), false);
1119 let mut takes_self = false;
1120 for inp in $m.sig.inputs.iter() {
1121 if let syn::FnArg::Receiver(_) = inp {
1126 let mut t_gen_args = String::new();
1127 for (idx, _) in $trait.generics.params.iter().enumerate() {
1128 if idx != 0 { t_gen_args += ", " };
1131 // rustc doesn't like <_> if the _ is actually a lifetime, so
1132 // if all the parameters are lifetimes just skip it.
1133 let mut nonlifetime_param = false;
1134 for param in $trait.generics.params.iter() {
1135 if let syn::GenericParam::Lifetime(_) = param {}
1136 else { nonlifetime_param = true; }
1138 if !nonlifetime_param { t_gen_args = String::new(); }
1140 write!(w, "<native{} as {}<{}>>::{}(unsafe {{ &mut *(this_arg as *mut native{}) }}, ", ident, $trait_path, t_gen_args, $m.sig.ident, ident).unwrap();
1142 write!(w, "<native{} as {}<{}>>::{}(", ident, $trait_path, t_gen_args, $m.sig.ident).unwrap();
1145 let mut real_type = "".to_string();
1146 match &$m.sig.output {
1147 syn::ReturnType::Type(_, rtype) => {
1148 if let Some(mut remaining_path) = first_seg_self(&*rtype) {
1149 if let Some(associated_seg) = get_single_remaining_path_seg(&mut remaining_path) {
1150 real_type = format!("{}", impl_associated_types.get(associated_seg).unwrap());
1156 write_method_call_params(w, &$trait_meth.sig, "", &mut trait_resolver, Some(&meth_gen_types), &real_type, false);
1158 write!(w, "\n}}\n").unwrap();
1159 if let syn::ReturnType::Type(_, rtype) = &$m.sig.output {
1160 if let syn::Type::Reference(r) = &**rtype {
1161 assert_eq!($m.sig.inputs.len(), 1); // Must only take self
1162 writeln!(w, "extern \"C\" fn {}_{}_set_{}(trait_self_arg: &{}) {{", ident, $trait.ident, $m.sig.ident, $trait.ident).unwrap();
1163 writeln!(w, "\t// This is a bit race-y in the general case, but for our specific use-cases today, we're safe").unwrap();
1164 writeln!(w, "\t// Specifically, we must ensure that the first time we're called it can never be in parallel").unwrap();
1165 write!(w, "\tif ").unwrap();
1166 $types.write_empty_rust_val_check(Some(&meth_gen_types), w, &*r.elem, &format!("trait_self_arg.{}", $m.sig.ident));
1167 writeln!(w, " {{").unwrap();
1168 writeln!(w, "\t\tunsafe {{ &mut *(trait_self_arg as *const {} as *mut {}) }}.{} = {}_{}_{}(trait_self_arg.this_arg);", $trait.ident, $trait.ident, $m.sig.ident, ident, $trait.ident, $m.sig.ident).unwrap();
1169 writeln!(w, "\t}}").unwrap();
1170 writeln!(w, "}}").unwrap();
1176 'impl_item_loop: for trait_item in trait_obj.items.iter() {
1178 syn::TraitItem::Method(meth) => {
1179 for item in i.items.iter() {
1181 syn::ImplItem::Method(m) => {
1182 if meth.sig.ident == m.sig.ident {
1183 impl_meth!(m, meth, full_trait_path, trait_obj, "", types);
1184 continue 'impl_item_loop;
1187 syn::ImplItem::Type(_) => {},
1188 _ => unimplemented!(),
1191 assert!(meth.default.is_some());
1192 let old_gen_types = gen_types;
1193 gen_types = GenericTypes::new(Some(resolved_path.clone()));
1194 impl_meth!(meth, meth, full_trait_path, trait_obj, "", &mut trait_resolver);
1195 gen_types = old_gen_types;
1201 writeln!(w, "extern \"C\" fn {}_{}_cloned(new_obj: &mut crate::{}) {{", trait_obj.ident, ident, full_trait_path).unwrap();
1202 writeln!(w, "\tnew_obj.this_arg = {}_clone_void(new_obj.this_arg);", ident).unwrap();
1203 writeln!(w, "\tnew_obj.free = Some({}_free_void);", ident).unwrap();
1204 walk_supertraits!(trait_obj, Some(&types), (
1206 if types.crate_types.traits.get(s).is_some() {
1207 assert!(!types.is_clonable(s)); // We don't currently support cloning with a clonable supertrait
1208 writeln!(w, "\tnew_obj.{}.this_arg = new_obj.this_arg;", t).unwrap();
1209 writeln!(w, "\tnew_obj.{}.free = None;", t).unwrap();
1213 writeln!(w, "}}").unwrap();
1215 write!(w, "\n").unwrap();
1218 if is_type_unconstructable(&resolved_path) {
1219 // Don't bother exposing trait implementations for objects which cannot be
1223 if path_matches_nongeneric(&trait_path.1, &["From"]) {
1224 } else if path_matches_nongeneric(&trait_path.1, &["Default"]) {
1225 writeln!(w, "/// Creates a \"default\" {}. See struct and individual field documentaiton for details on which values are used.", ident).unwrap();
1226 write!(w, "#[must_use]\n#[no_mangle]\npub extern \"C\" fn {}_default() -> {} {{\n", ident, ident).unwrap();
1227 write!(w, "\t{} {{ inner: ObjOps::heap_alloc(Default::default()), is_owned: true }}\n", ident).unwrap();
1228 write!(w, "}}\n").unwrap();
1229 } else if path_matches_nongeneric(&trait_path.1, &["core", "cmp", "PartialEq"]) {
1230 } else if path_matches_nongeneric(&trait_path.1, &["core", "cmp", "Eq"]) {
1231 writeln!(w, "/// Checks if two {}s contain equal inner contents.", ident).unwrap();
1232 writeln!(w, "/// This ignores pointers and is_owned flags and looks at the values in fields.").unwrap();
1233 if types.c_type_has_inner_from_path(&resolved_path) {
1234 writeln!(w, "/// Two objects with NULL inner values will be considered \"equal\" here.").unwrap();
1236 write!(w, "#[no_mangle]\npub extern \"C\" fn {}_eq(a: &{}, b: &{}) -> bool {{\n", ident, ident, ident).unwrap();
1237 if types.c_type_has_inner_from_path(&resolved_path) {
1238 write!(w, "\tif a.inner == b.inner {{ return true; }}\n").unwrap();
1239 write!(w, "\tif a.inner.is_null() || b.inner.is_null() {{ return false; }}\n").unwrap();
1243 let ref_type: syn::Type = syn::parse_quote!(&#path);
1244 assert!(!types.write_to_c_conversion_new_var(w, &format_ident!("a"), &*i.self_ty, Some(&gen_types), false), "We don't support new var conversions when comparing equality");
1246 write!(w, "\tif ").unwrap();
1247 types.write_from_c_conversion_prefix(w, &ref_type, Some(&gen_types));
1248 write!(w, "a").unwrap();
1249 types.write_from_c_conversion_suffix(w, &ref_type, Some(&gen_types));
1250 write!(w, " == ").unwrap();
1251 types.write_from_c_conversion_prefix(w, &ref_type, Some(&gen_types));
1252 write!(w, "b").unwrap();
1253 types.write_from_c_conversion_suffix(w, &ref_type, Some(&gen_types));
1255 writeln!(w, " {{ true }} else {{ false }}\n}}").unwrap();
1256 } else if path_matches_nongeneric(&trait_path.1, &["core", "hash", "Hash"]) {
1257 writeln!(w, "/// Checks if two {}s contain equal inner contents.", ident).unwrap();
1258 write!(w, "#[no_mangle]\npub extern \"C\" fn {}_hash(o: &{}) -> u64 {{\n", ident, ident).unwrap();
1259 if types.c_type_has_inner_from_path(&resolved_path) {
1260 write!(w, "\tif o.inner.is_null() {{ return 0; }}\n").unwrap();
1264 let ref_type: syn::Type = syn::parse_quote!(&#path);
1265 assert!(!types.write_to_c_conversion_new_var(w, &format_ident!("a"), &*i.self_ty, Some(&gen_types), false), "We don't support new var conversions when comparing equality");
1267 writeln!(w, "\t// Note that we'd love to use alloc::collections::hash_map::DefaultHasher but it's not in core").unwrap();
1268 writeln!(w, "\t#[allow(deprecated)]").unwrap();
1269 writeln!(w, "\tlet mut hasher = core::hash::SipHasher::new();").unwrap();
1270 write!(w, "\tcore::hash::Hash::hash(").unwrap();
1271 types.write_from_c_conversion_prefix(w, &ref_type, Some(&gen_types));
1272 write!(w, "o").unwrap();
1273 types.write_from_c_conversion_suffix(w, &ref_type, Some(&gen_types));
1274 writeln!(w, ", &mut hasher);").unwrap();
1275 writeln!(w, "\tcore::hash::Hasher::finish(&hasher)\n}}").unwrap();
1276 } else if (path_matches_nongeneric(&trait_path.1, &["core", "clone", "Clone"]) || path_matches_nongeneric(&trait_path.1, &["Clone"])) &&
1277 types.c_type_has_inner_from_path(&resolved_path) {
1278 writeln!(w, "impl Clone for {} {{", ident).unwrap();
1279 writeln!(w, "\tfn clone(&self) -> Self {{").unwrap();
1280 writeln!(w, "\t\tSelf {{").unwrap();
1281 writeln!(w, "\t\t\tinner: if <*mut native{}>::is_null(self.inner) {{ core::ptr::null_mut() }} else {{", ident).unwrap();
1282 writeln!(w, "\t\t\t\tObjOps::heap_alloc(unsafe {{ &*ObjOps::untweak_ptr(self.inner) }}.clone()) }},").unwrap();
1283 writeln!(w, "\t\t\tis_owned: true,").unwrap();
1284 writeln!(w, "\t\t}}\n\t}}\n}}").unwrap();
1285 writeln!(w, "#[allow(unused)]").unwrap();
1286 writeln!(w, "/// Used only if an object of this type is returned as a trait impl by a method").unwrap();
1287 writeln!(w, "pub(crate) extern \"C\" fn {}_clone_void(this_ptr: *const c_void) -> *mut c_void {{", ident).unwrap();
1288 writeln!(w, "\tBox::into_raw(Box::new(unsafe {{ (*(this_ptr as *mut native{})).clone() }})) as *mut c_void", ident).unwrap();
1289 writeln!(w, "}}").unwrap();
1290 writeln!(w, "#[no_mangle]").unwrap();
1291 writeln!(w, "/// Creates a copy of the {}", ident).unwrap();
1292 writeln!(w, "pub extern \"C\" fn {}_clone(orig: &{}) -> {} {{", ident, ident, ident).unwrap();
1293 writeln!(w, "\torig.clone()").unwrap();
1294 writeln!(w, "}}").unwrap();
1295 } else if path_matches_nongeneric(&trait_path.1, &["FromStr"]) {
1296 let mut err_opt = None;
1297 for item in i.items.iter() {
1299 syn::ImplItem::Type(ty) if format!("{}", ty.ident) == "Err" => {
1300 err_opt = Some(&ty.ty);
1305 let err_ty = err_opt.unwrap();
1306 if let Some(container) = types.get_c_mangled_container_type(vec![&*i.self_ty, &err_ty], Some(&gen_types), "Result") {
1307 writeln!(w, "#[no_mangle]").unwrap();
1308 writeln!(w, "/// Read a {} object from a string", ident).unwrap();
1309 writeln!(w, "pub extern \"C\" fn {}_from_str(s: crate::c_types::Str) -> {} {{", ident, container).unwrap();
1310 writeln!(w, "\tmatch {}::from_str(s.into_str()) {{", resolved_path).unwrap();
1312 writeln!(w, "\t\tOk(r) => {{").unwrap();
1313 let new_var = types.write_to_c_conversion_new_var(w, &format_ident!("r"), &*i.self_ty, Some(&gen_types), false);
1314 write!(w, "\t\t\tcrate::c_types::CResultTempl::ok(\n\t\t\t\t").unwrap();
1315 types.write_to_c_conversion_inline_prefix(w, &*i.self_ty, Some(&gen_types), false);
1316 write!(w, "{}r", if new_var { "local_" } else { "" }).unwrap();
1317 types.write_to_c_conversion_inline_suffix(w, &*i.self_ty, Some(&gen_types), false);
1318 writeln!(w, "\n\t\t\t)\n\t\t}},").unwrap();
1320 writeln!(w, "\t\tErr(e) => {{").unwrap();
1321 let new_var = types.write_to_c_conversion_new_var(w, &format_ident!("e"), &err_ty, Some(&gen_types), false);
1322 write!(w, "\t\t\tcrate::c_types::CResultTempl::err(\n\t\t\t\t").unwrap();
1323 types.write_to_c_conversion_inline_prefix(w, &err_ty, Some(&gen_types), false);
1324 write!(w, "{}e", if new_var { "local_" } else { "" }).unwrap();
1325 types.write_to_c_conversion_inline_suffix(w, &err_ty, Some(&gen_types), false);
1326 writeln!(w, "\n\t\t\t)\n\t\t}},").unwrap();
1328 writeln!(w, "\t}}.into()\n}}").unwrap();
1330 } else if path_matches_nongeneric(&trait_path.1, &["Display"]) {
1331 writeln!(w, "#[no_mangle]").unwrap();
1332 writeln!(w, "/// Get the string representation of a {} object", ident).unwrap();
1333 writeln!(w, "pub extern \"C\" fn {}_to_str(o: &crate::{}) -> Str {{", ident, resolved_path).unwrap();
1335 let self_ty = &i.self_ty;
1336 let ref_type: syn::Type = syn::parse_quote!(&#self_ty);
1337 let new_var = types.write_from_c_conversion_new_var(w, &format_ident!("o"), &ref_type, Some(&gen_types));
1338 write!(w, "\talloc::format!(\"{{}}\", ").unwrap();
1339 types.write_from_c_conversion_prefix(w, &ref_type, Some(&gen_types));
1340 write!(w, "{}o", if new_var { "local_" } else { "" }).unwrap();
1341 types.write_from_c_conversion_suffix(w, &ref_type, Some(&gen_types));
1342 writeln!(w, ").into()").unwrap();
1344 writeln!(w, "}}").unwrap();
1346 //XXX: implement for other things like ToString
1347 // If we have no generics, try a manual implementation:
1348 maybe_convert_trait_impl(w, &trait_path.1, &*i.self_ty, types, &gen_types);
1351 let is_opaque = types.crate_types.opaques.contains_key(&resolved_path);
1352 let is_mirrored_enum = types.crate_types.mirrored_enums.contains_key(&resolved_path);
1353 for item in i.items.iter() {
1355 syn::ImplItem::Method(m) => {
1356 if let syn::Visibility::Public(_) = m.vis {
1357 match export_status(&m.attrs) {
1358 ExportStatus::Export => {},
1359 ExportStatus::NoExport|ExportStatus::TestOnly => continue,
1360 ExportStatus::NotImplementable => panic!("(C-not implementable) must only appear on traits"),
1362 let mut meth_gen_types = gen_types.push_ctx();
1363 assert!(meth_gen_types.learn_generics(&m.sig.generics, types));
1364 if m.defaultness.is_some() { unimplemented!(); }
1365 writeln_fn_docs(w, &m.attrs, "", types, Some(&meth_gen_types), m.sig.inputs.iter(), &m.sig.output);
1366 if let syn::ReturnType::Type(_, _) = &m.sig.output {
1367 writeln!(w, "#[must_use]").unwrap();
1369 write!(w, "#[no_mangle]\npub extern \"C\" fn {}_{}(", ident, m.sig.ident).unwrap();
1370 let ret_type = format!("crate::{}", resolved_path);
1371 write_method_params(w, &m.sig, &ret_type, types, Some(&meth_gen_types), false, true);
1372 write!(w, " {{\n\t").unwrap();
1373 write_method_var_decl_body(w, &m.sig, "", types, Some(&meth_gen_types), false);
1374 let mut takes_self = false;
1375 let mut takes_mut_self = false;
1376 let mut takes_owned_self = false;
1377 for inp in m.sig.inputs.iter() {
1378 if let syn::FnArg::Receiver(r) = inp {
1380 if r.mutability.is_some() { takes_mut_self = true; }
1381 if r.reference.is_none() { takes_owned_self = true; }
1384 if !takes_mut_self && !takes_self {
1385 write!(w, "{}::{}(", resolved_path, m.sig.ident).unwrap();
1387 if is_mirrored_enum {
1388 write!(w, "this_arg.to_native().{}(", m.sig.ident).unwrap();
1389 } else if is_opaque {
1390 if takes_owned_self {
1391 write!(w, "(*unsafe {{ Box::from_raw(this_arg.take_inner()) }}).{}(", m.sig.ident).unwrap();
1392 } else if takes_mut_self {
1393 write!(w, "unsafe {{ &mut (*ObjOps::untweak_ptr(this_arg.inner as *mut crate::{}::native{})) }}.{}(", rsplit_once(&resolved_path, "::").unwrap().0, ident, m.sig.ident).unwrap();
1395 write!(w, "unsafe {{ &*ObjOps::untweak_ptr(this_arg.inner) }}.{}(", m.sig.ident).unwrap();
1401 write_method_call_params(w, &m.sig, "", types, Some(&meth_gen_types), &ret_type, false);
1402 writeln!(w, "\n}}\n").unwrap();
1409 } else if let Some(resolved_path) = types.maybe_resolve_ident(&ident) {
1410 create_alias_for_impl(resolved_path, i, types, move |aliased_impl, types| writeln_impl(w, &aliased_impl, types));
1412 eprintln!("Not implementing anything for {} due to no-resolve (probably the type isn't pub)", ident);
1418 fn create_alias_for_impl<F: FnMut(syn::ItemImpl, &mut TypeResolver)>(resolved_path: String, i: &syn::ItemImpl, types: &mut TypeResolver, mut callback: F) {
1419 if let Some(aliases) = types.crate_types.reverse_alias_map.get(&resolved_path).cloned() {
1420 let mut gen_types = Some(GenericTypes::new(Some(resolved_path.clone())));
1421 if !gen_types.as_mut().unwrap().learn_generics(&i.generics, types) {
1424 let alias_module = rsplit_once(&resolved_path, "::").unwrap().0;
1426 'alias_impls: for (alias_resolved, arguments) in aliases {
1427 let mut new_ty_generics = Vec::new();
1428 let mut new_ty_bounds = Vec::new();
1429 let mut need_generics = false;
1431 let alias_resolver_override;
1432 let alias_resolver = if alias_module != types.module_path {
1433 alias_resolver_override = ImportResolver::new(types.types.crate_name, &types.crate_types.lib_ast.dependencies,
1434 alias_module, &types.crate_types.lib_ast.modules.get(alias_module).unwrap().items);
1435 &alias_resolver_override
1436 } else { &types.types };
1437 let mut where_clause = syn::WhereClause { where_token: syn::Token![where](Span::call_site()),
1438 predicates: syn::punctuated::Punctuated::new()
1440 for (idx, gen) in i.generics.params.iter().enumerate() {
1442 syn::GenericParam::Type(type_param) => {
1443 'bounds_check: for bound in type_param.bounds.iter() {
1444 if let syn::TypeParamBound::Trait(trait_bound) = bound {
1445 if let syn::PathArguments::AngleBracketed(ref t) = &arguments {
1446 assert!(idx < t.args.len());
1447 if let syn::GenericArgument::Type(syn::Type::Path(p)) = &t.args[idx] {
1448 let generic_bound = types.maybe_resolve_path(&trait_bound.path, None)
1449 .unwrap_or_else(|| format!("{}::{}", types.module_path, single_ident_generic_path_to_ident(&trait_bound.path).unwrap()));
1451 if let Some(generic_arg) = alias_resolver.maybe_resolve_path(&p.path, None) {
1452 new_ty_generics.push((type_param.ident.clone(), syn::Type::Path(p.clone())));
1453 if let Some(traits_impld) = types.crate_types.trait_impls.get(&generic_arg) {
1454 for trait_impld in traits_impld {
1455 if *trait_impld == generic_bound { continue 'bounds_check; }
1457 eprintln!("struct {}'s generic arg {} didn't match bound {}", alias_resolved, generic_arg, generic_bound);
1458 continue 'alias_impls;
1460 eprintln!("struct {}'s generic arg {} didn't match bound {}", alias_resolved, generic_arg, generic_bound);
1461 continue 'alias_impls;
1463 } else if gen_types.is_some() {
1464 let resp = types.maybe_resolve_path(&p.path, gen_types.as_ref());
1465 if generic_bound == "core::ops::Deref" && resp.is_some() {
1466 new_ty_bounds.push((type_param.ident.clone(),
1467 string_path_to_syn_path("core::ops::Deref")));
1468 let mut bounds = syn::punctuated::Punctuated::new();
1469 bounds.push(syn::TypeParamBound::Trait(syn::TraitBound {
1471 modifier: syn::TraitBoundModifier::None,
1473 path: string_path_to_syn_path(&types.resolve_path(&p.path, gen_types.as_ref())),
1475 let mut path = string_path_to_syn_path(&format!("{}::Target", type_param.ident));
1476 path.leading_colon = None;
1477 where_clause.predicates.push(syn::WherePredicate::Type(syn::PredicateType {
1479 bounded_ty: syn::Type::Path(syn::TypePath { qself: None, path }),
1480 colon_token: syn::Token![:](Span::call_site()),
1484 new_ty_generics.push((type_param.ident.clone(),
1485 gen_types.as_ref().resolve_type(&syn::Type::Path(p.clone())).clone()));
1487 need_generics = true;
1491 } else { unimplemented!(); }
1492 } else { unimplemented!(); }
1493 } else { unimplemented!(); }
1496 syn::GenericParam::Lifetime(_) => {},
1497 syn::GenericParam::Const(_) => unimplemented!(),
1500 let mut params = syn::punctuated::Punctuated::new();
1501 let alias = string_path_to_syn_path(&alias_resolved);
1504 let alias_generics = types.crate_types.opaques.get(&alias_resolved).unwrap().1;
1506 // If we need generics on the alias, create impl generic bounds...
1507 assert_eq!(new_ty_generics.len() + new_ty_bounds.len(), i.generics.params.len());
1508 let mut args = syn::punctuated::Punctuated::new();
1509 for (ident, param) in new_ty_generics.drain(..) {
1510 // TODO: We blindly assume that generics in the type alias and
1511 // the aliased type have the same names, which we really shouldn't.
1512 if alias_generics.params.iter().any(|generic|
1513 if let syn::GenericParam::Type(t) = generic { t.ident == ident } else { false })
1515 args.push(parse_quote!(#ident));
1517 params.push(syn::GenericParam::Type(syn::TypeParam {
1521 bounds: syn::punctuated::Punctuated::new(),
1522 eq_token: Some(syn::token::Eq(Span::call_site())),
1523 default: Some(param),
1526 for (ident, param) in new_ty_bounds.drain(..) {
1527 // TODO: We blindly assume that generics in the type alias and
1528 // the aliased type have the same names, which we really shouldn't.
1529 if alias_generics.params.iter().any(|generic|
1530 if let syn::GenericParam::Type(t) = generic { t.ident == ident } else { false })
1532 args.push(parse_quote!(#ident));
1534 params.push(syn::GenericParam::Type(syn::TypeParam {
1537 colon_token: Some(syn::token::Colon(Span::call_site())),
1538 bounds: syn::punctuated::Punctuated::from_iter(
1539 Some(syn::TypeParamBound::Trait(syn::TraitBound {
1540 path: param, paren_token: None, lifetimes: None,
1541 modifier: syn::TraitBoundModifier::None,
1548 // ... and swap the last segment of the impl self_ty to use the generic bounds.
1549 let mut res = alias.clone();
1550 res.segments.last_mut().unwrap().arguments = syn::PathArguments::AngleBracketed(syn::AngleBracketedGenericArguments {
1552 lt_token: syn::token::Lt(Span::call_site()),
1554 gt_token: syn::token::Gt(Span::call_site()),
1557 } else { alias.clone() };
1558 callback(syn::ItemImpl {
1559 attrs: i.attrs.clone(),
1560 brace_token: syn::token::Brace(Span::call_site()),
1562 generics: syn::Generics {
1566 where_clause: Some(where_clause),
1568 impl_token: syn::Token![impl](Span::call_site()),
1569 items: i.items.clone(),
1570 self_ty: Box::new(syn::Type::Path(syn::TypePath { qself: None, path: real_aliased })),
1571 trait_: i.trait_.clone(),
1576 eprintln!("Not implementing anything for {} due to it being marked not exported", resolved_path);
1580 /// Replaces upper case charachters with underscore followed by lower case except the first
1581 /// charachter and repeated upper case characthers (which are only made lower case).
1582 fn camel_to_snake_case(camel: &str) -> String {
1583 let mut res = "".to_string();
1584 let mut last_upper = -1;
1585 for (idx, c) in camel.chars().enumerate() {
1586 if c.is_uppercase() {
1587 if last_upper != idx as isize - 1 { res.push('_'); }
1588 res.push(c.to_lowercase().next().unwrap());
1589 last_upper = idx as isize;
1598 /// Print a mapping of an enum. If all of the enum's fields are C-mapped in some form (or the enum
1599 /// is unitary), we generate an equivalent enum with all types replaced with their C mapped
1600 /// versions followed by conversion functions which map between the Rust version and the C mapped
1602 fn writeln_enum<'a, 'b, W: std::io::Write>(w: &mut W, e: &'a syn::ItemEnum, types: &mut TypeResolver<'b, 'a>, extra_headers: &mut File, cpp_headers: &mut File) {
1603 match export_status(&e.attrs) {
1604 ExportStatus::Export => {},
1605 ExportStatus::NoExport|ExportStatus::TestOnly => return,
1606 ExportStatus::NotImplementable => panic!("(C-not implementable) must only appear on traits"),
1609 if is_enum_opaque(e) {
1610 eprintln!("Skipping enum {} as it contains non-unit fields", e.ident);
1611 writeln_opaque(w, &e.ident, &format!("{}", e.ident), &e.generics, &e.attrs, types, extra_headers, cpp_headers);
1614 writeln_docs(w, &e.attrs, "");
1616 let mut gen_types = GenericTypes::new(None);
1617 assert!(gen_types.learn_generics(&e.generics, types));
1619 let mut needs_free = false;
1620 let mut constr = Vec::new();
1621 let mut is_clonable = true;
1623 for var in e.variants.iter() {
1624 if let syn::Fields::Named(fields) = &var.fields {
1626 for field in fields.named.iter() {
1627 if export_status(&field.attrs) == ExportStatus::TestOnly { continue; }
1629 let mut ty_checks = Vec::new();
1630 types.write_c_type(&mut ty_checks, &field.ty, Some(&gen_types), false);
1631 if !types.is_clonable(&String::from_utf8(ty_checks).unwrap()) {
1632 is_clonable = false;
1635 } else if let syn::Fields::Unnamed(fields) = &var.fields {
1636 for field in fields.unnamed.iter() {
1637 let mut ty_checks = Vec::new();
1638 types.write_c_type(&mut ty_checks, &field.ty, Some(&gen_types), false);
1639 let ty = String::from_utf8(ty_checks).unwrap();
1640 if ty != "" && !types.is_clonable(&ty) {
1641 is_clonable = false;
1648 writeln!(w, "#[derive(Clone)]").unwrap();
1649 types.crate_types.set_clonable(format!("{}::{}", types.module_path, e.ident));
1651 writeln!(w, "#[must_use]\n#[repr(C)]\npub enum {} {{", e.ident).unwrap();
1652 for var in e.variants.iter() {
1653 assert_eq!(export_status(&var.attrs), ExportStatus::Export); // We can't partially-export a mirrored enum
1654 writeln_docs(w, &var.attrs, "\t");
1655 write!(w, "\t{}", var.ident).unwrap();
1656 writeln!(&mut constr, "#[no_mangle]\n/// Utility method to constructs a new {}-variant {}", var.ident, e.ident).unwrap();
1657 let constr_name = camel_to_snake_case(&format!("{}", var.ident));
1658 write!(&mut constr, "pub extern \"C\" fn {}_{}(", e.ident, constr_name).unwrap();
1659 let mut empty_tuple_variant = false;
1660 if let syn::Fields::Named(fields) = &var.fields {
1662 writeln!(w, " {{").unwrap();
1663 for (idx, field) in fields.named.iter().enumerate() {
1664 if export_status(&field.attrs) == ExportStatus::TestOnly { continue; }
1665 writeln_field_docs(w, &field.attrs, "\t\t", types, Some(&gen_types), &field.ty);
1666 write!(w, "\t\t{}: ", field.ident.as_ref().unwrap()).unwrap();
1667 write!(&mut constr, "{}{}: ", if idx != 0 { ", " } else { "" }, field.ident.as_ref().unwrap()).unwrap();
1668 types.write_c_type(w, &field.ty, Some(&gen_types), true);
1669 types.write_c_type(&mut constr, &field.ty, Some(&gen_types), true);
1670 writeln!(w, ",").unwrap();
1672 write!(w, "\t}}").unwrap();
1673 } else if let syn::Fields::Unnamed(fields) = &var.fields {
1674 if fields.unnamed.len() == 1 {
1675 let mut empty_check = Vec::new();
1676 types.write_c_type(&mut empty_check, &fields.unnamed[0].ty, Some(&gen_types), true);
1677 if empty_check.is_empty() {
1678 empty_tuple_variant = true;
1681 if !empty_tuple_variant {
1683 writeln!(w, "(").unwrap();
1684 for (idx, field) in fields.unnamed.iter().enumerate() {
1685 if export_status(&field.attrs) == ExportStatus::TestOnly { continue; }
1686 writeln_field_docs(w, &field.attrs, "\t\t", types, Some(&gen_types), &field.ty);
1687 write!(w, "\t\t").unwrap();
1688 types.write_c_type(w, &field.ty, Some(&gen_types), true);
1690 write!(&mut constr, "{}: ", ('a' as u8 + idx as u8) as char).unwrap();
1691 types.write_c_type(&mut constr, &field.ty, Some(&gen_types), false);
1692 if idx != fields.unnamed.len() - 1 {
1693 writeln!(w, ",").unwrap();
1694 write!(&mut constr, ",").unwrap();
1697 write!(w, ")").unwrap();
1700 if var.discriminant.is_some() { unimplemented!(); }
1701 write!(&mut constr, ") -> {} {{\n\t{}::{}", e.ident, e.ident, var.ident).unwrap();
1702 if let syn::Fields::Named(fields) = &var.fields {
1703 writeln!(&mut constr, " {{").unwrap();
1704 for field in fields.named.iter() {
1705 writeln!(&mut constr, "\t\t{},", field.ident.as_ref().unwrap()).unwrap();
1707 writeln!(&mut constr, "\t}}").unwrap();
1708 } else if let syn::Fields::Unnamed(fields) = &var.fields {
1709 if !empty_tuple_variant {
1710 write!(&mut constr, "(").unwrap();
1711 for (idx, field) in fields.unnamed.iter().enumerate() {
1712 let mut ref_c_ty = Vec::new();
1713 let mut nonref_c_ty = Vec::new();
1714 types.write_c_type(&mut ref_c_ty, &field.ty, Some(&gen_types), false);
1715 types.write_c_type(&mut nonref_c_ty, &field.ty, Some(&gen_types), true);
1717 if ref_c_ty != nonref_c_ty {
1718 // We blindly assume references in field types are always opaque types, and
1719 // print out an opaque reference -> owned reference conversion here.
1720 write!(&mut constr, "{} {{ inner: {}.inner, is_owned: false }}, ", String::from_utf8(nonref_c_ty).unwrap(), ('a' as u8 + idx as u8) as char).unwrap();
1722 write!(&mut constr, "{}, ", ('a' as u8 + idx as u8) as char).unwrap();
1725 writeln!(&mut constr, ")").unwrap();
1727 writeln!(&mut constr, "").unwrap();
1730 writeln!(&mut constr, "}}").unwrap();
1731 writeln!(w, ",").unwrap();
1733 writeln!(w, "}}\nuse {}::{} as {}Import;", types.module_path, e.ident, e.ident).unwrap();
1734 write!(w, "pub(crate) type native{} = {}Import", e.ident, e.ident).unwrap();
1735 maybe_write_generics(w, &e.generics, &syn::PathArguments::None, &types, true);
1736 writeln!(w, ";\n\nimpl {} {{", e.ident).unwrap();
1738 macro_rules! write_conv {
1739 ($fn_sig: expr, $to_c: expr, $ref: expr) => {
1740 writeln!(w, "\t#[allow(unused)]\n\tpub(crate) fn {} {{\n\t\tmatch {} {{", $fn_sig, if $to_c { "native" } else { "self" }).unwrap();
1741 for var in e.variants.iter() {
1742 write!(w, "\t\t\t{}{}::{} ", if $to_c { "native" } else { "" }, e.ident, var.ident).unwrap();
1743 let mut empty_tuple_variant = false;
1744 if let syn::Fields::Named(fields) = &var.fields {
1745 write!(w, "{{").unwrap();
1746 for field in fields.named.iter() {
1747 if export_status(&field.attrs) == ExportStatus::TestOnly { continue; }
1748 write!(w, "{}{}, ", if $ref { "ref " } else { "mut " }, field.ident.as_ref().unwrap()).unwrap();
1750 write!(w, "}} ").unwrap();
1751 } else if let syn::Fields::Unnamed(fields) = &var.fields {
1752 if fields.unnamed.len() == 1 {
1753 let mut empty_check = Vec::new();
1754 types.write_c_type(&mut empty_check, &fields.unnamed[0].ty, Some(&gen_types), true);
1755 if empty_check.is_empty() {
1756 empty_tuple_variant = true;
1759 if !empty_tuple_variant || $to_c {
1760 write!(w, "(").unwrap();
1761 for (idx, field) in fields.unnamed.iter().enumerate() {
1762 if export_status(&field.attrs) == ExportStatus::TestOnly { continue; }
1763 write!(w, "{}{}, ", if $ref { "ref " } else { "mut " }, ('a' as u8 + idx as u8) as char).unwrap();
1765 write!(w, ") ").unwrap();
1768 write!(w, "=>").unwrap();
1770 macro_rules! handle_field_a {
1771 ($field: expr, $field_ident: expr) => { {
1772 if export_status(&$field.attrs) == ExportStatus::TestOnly { continue; }
1773 let mut sink = ::std::io::sink();
1774 let mut out: &mut dyn std::io::Write = if $ref { &mut sink } else { w };
1775 let new_var = if $to_c {
1776 types.write_to_c_conversion_new_var(&mut out, $field_ident, &$field.ty, Some(&gen_types), true)
1778 types.write_from_c_conversion_new_var(&mut out, $field_ident, &$field.ty, Some(&gen_types))
1780 if $ref || new_var {
1782 write!(w, "let mut {}_nonref = (*{}).clone();\n\t\t\t\t", $field_ident, $field_ident).unwrap();
1784 let nonref_ident = format_ident!("{}_nonref", $field_ident);
1786 types.write_to_c_conversion_new_var(w, &nonref_ident, &$field.ty, Some(&gen_types), true);
1788 types.write_from_c_conversion_new_var(w, &nonref_ident, &$field.ty, Some(&gen_types));
1790 write!(w, "\n\t\t\t\t").unwrap();
1793 write!(w, "\n\t\t\t\t").unwrap();
1798 if let syn::Fields::Named(fields) = &var.fields {
1799 write!(w, " {{\n\t\t\t\t").unwrap();
1800 for field in fields.named.iter() {
1801 handle_field_a!(field, field.ident.as_ref().unwrap());
1803 } else if let syn::Fields::Unnamed(fields) = &var.fields {
1804 write!(w, " {{\n\t\t\t\t").unwrap();
1805 for (idx, field) in fields.unnamed.iter().enumerate() {
1806 if !empty_tuple_variant {
1807 handle_field_a!(field, &format_ident!("{}", ('a' as u8 + idx as u8) as char));
1810 } else { write!(w, " ").unwrap(); }
1812 write!(w, "{}{}::{}", if $to_c { "" } else { "native" }, e.ident, var.ident).unwrap();
1814 macro_rules! handle_field_b {
1815 ($field: expr, $field_ident: expr) => { {
1816 if export_status(&$field.attrs) == ExportStatus::TestOnly { continue; }
1818 types.write_to_c_conversion_inline_prefix(w, &$field.ty, Some(&gen_types), true);
1820 types.write_from_c_conversion_prefix(w, &$field.ty, Some(&gen_types));
1822 write!(w, "{}{}", $field_ident,
1823 if $ref { "_nonref" } else { "" }).unwrap();
1825 types.write_to_c_conversion_inline_suffix(w, &$field.ty, Some(&gen_types), true);
1827 types.write_from_c_conversion_suffix(w, &$field.ty, Some(&gen_types));
1829 write!(w, ",").unwrap();
1833 if let syn::Fields::Named(fields) = &var.fields {
1834 write!(w, " {{").unwrap();
1835 for field in fields.named.iter() {
1836 if export_status(&field.attrs) == ExportStatus::TestOnly { continue; }
1837 write!(w, "\n\t\t\t\t\t{}: ", field.ident.as_ref().unwrap()).unwrap();
1838 handle_field_b!(field, field.ident.as_ref().unwrap());
1840 writeln!(w, "\n\t\t\t\t}}").unwrap();
1841 write!(w, "\t\t\t}}").unwrap();
1842 } else if let syn::Fields::Unnamed(fields) = &var.fields {
1843 if !empty_tuple_variant || !$to_c {
1844 write!(w, " (").unwrap();
1845 for (idx, field) in fields.unnamed.iter().enumerate() {
1846 write!(w, "\n\t\t\t\t\t").unwrap();
1847 handle_field_b!(field, &format_ident!("{}", ('a' as u8 + idx as u8) as char));
1849 writeln!(w, "\n\t\t\t\t)").unwrap();
1851 write!(w, "\t\t\t}}").unwrap();
1853 writeln!(w, ",").unwrap();
1855 writeln!(w, "\t\t}}\n\t}}").unwrap();
1860 write_conv!(format!("to_native(&self) -> native{}", e.ident), false, true);
1862 write_conv!(format!("into_native(self) -> native{}", e.ident), false, false);
1864 write_conv!(format!("from_native(native: &native{}) -> Self", e.ident), true, true);
1866 write_conv!(format!("native_into(native: native{}) -> Self", e.ident), true, false);
1867 writeln!(w, "}}").unwrap();
1870 writeln!(w, "/// Frees any resources used by the {}", e.ident).unwrap();
1871 writeln!(w, "#[no_mangle]\npub extern \"C\" fn {}_free(this_ptr: {}) {{ }}", e.ident, e.ident).unwrap();
1874 writeln!(w, "/// Creates a copy of the {}", e.ident).unwrap();
1875 writeln!(w, "#[no_mangle]").unwrap();
1876 writeln!(w, "pub extern \"C\" fn {}_clone(orig: &{}) -> {} {{", e.ident, e.ident, e.ident).unwrap();
1877 writeln!(w, "\torig.clone()").unwrap();
1878 writeln!(w, "}}").unwrap();
1880 w.write_all(&constr).unwrap();
1881 write_cpp_wrapper(cpp_headers, &format!("{}", e.ident), needs_free, None);
1884 fn writeln_fn<'a, 'b, W: std::io::Write>(w: &mut W, f: &'a syn::ItemFn, types: &mut TypeResolver<'b, 'a>) {
1885 match export_status(&f.attrs) {
1886 ExportStatus::Export => {},
1887 ExportStatus::NoExport|ExportStatus::TestOnly => return,
1888 ExportStatus::NotImplementable => panic!("(C-not implementable) must only appear on traits"),
1890 let mut gen_types = GenericTypes::new(None);
1891 if !gen_types.learn_generics(&f.sig.generics, types) { return; }
1893 writeln_fn_docs(w, &f.attrs, "", types, Some(&gen_types), f.sig.inputs.iter(), &f.sig.output);
1895 write!(w, "#[no_mangle]\npub extern \"C\" fn {}(", f.sig.ident).unwrap();
1898 write_method_params(w, &f.sig, "", types, Some(&gen_types), false, true);
1899 write!(w, " {{\n\t").unwrap();
1900 write_method_var_decl_body(w, &f.sig, "", types, Some(&gen_types), false);
1901 write!(w, "{}::{}", types.module_path, f.sig.ident).unwrap();
1903 let mut function_generic_args = Vec::new();
1904 maybe_write_generics(&mut function_generic_args, &f.sig.generics, &syn::PathArguments::None, types, true);
1905 if !function_generic_args.is_empty() {
1906 write!(w, "::{}", String::from_utf8(function_generic_args).unwrap()).unwrap();
1908 write!(w, "(").unwrap();
1910 write_method_call_params(w, &f.sig, "", types, Some(&gen_types), "", false);
1911 writeln!(w, "\n}}\n").unwrap();
1914 // ********************************
1915 // *** File/Crate Walking Logic ***
1916 // ********************************
1918 fn convert_priv_mod<'a, 'b: 'a, W: std::io::Write>(w: &mut W, libast: &'b FullLibraryAST, crate_types: &CrateTypes<'b>, out_dir: &str, mod_path: &str, module: &'b syn::ItemMod) {
1919 // We want to ignore all items declared in this module (as they are not pub), but we still need
1920 // to give the ImportResolver any use statements, so we copy them here.
1921 let mut use_items = Vec::new();
1922 for item in module.content.as_ref().unwrap().1.iter() {
1923 if let syn::Item::Use(_) = item {
1924 use_items.push(item);
1927 let import_resolver = ImportResolver::from_borrowed_items(mod_path.splitn(2, "::").next().unwrap(), &libast.dependencies, mod_path, &use_items);
1928 let mut types = TypeResolver::new(mod_path, import_resolver, crate_types);
1930 writeln!(w, "mod {} {{\n{}", module.ident, DEFAULT_IMPORTS).unwrap();
1931 for item in module.content.as_ref().unwrap().1.iter() {
1933 syn::Item::Mod(m) => convert_priv_mod(w, libast, crate_types, out_dir, &format!("{}::{}", mod_path, module.ident), m),
1934 syn::Item::Impl(i) => {
1935 writeln_impl(w, i, &mut types);
1940 writeln!(w, "}}").unwrap();
1943 /// Do the Real Work of mapping an original file to C-callable wrappers. Creates a new file at
1944 /// `out_path` and fills it with wrapper structs/functions to allow calling the things in the AST
1945 /// at `module` from C.
1946 fn convert_file<'a, 'b>(libast: &'a FullLibraryAST, crate_types: &CrateTypes<'a>, out_dir: &str, header_file: &mut File, cpp_header_file: &mut File) {
1947 for (module, astmod) in libast.modules.iter() {
1948 let orig_crate = module.splitn(2, "::").next().unwrap();
1949 let ASTModule { ref attrs, ref items, ref submods } = astmod;
1950 assert_eq!(export_status(&attrs), ExportStatus::Export);
1952 let new_file_path = if submods.is_empty() {
1953 format!("{}/{}.rs", out_dir, module.replace("::", "/"))
1954 } else if module != "" {
1955 format!("{}/{}/mod.rs", out_dir, module.replace("::", "/"))
1957 format!("{}/lib.rs", out_dir)
1959 let _ = std::fs::create_dir((&new_file_path.as_ref() as &std::path::Path).parent().unwrap());
1960 let mut out = std::fs::OpenOptions::new().write(true).create(true).truncate(true)
1961 .open(new_file_path).expect("Unable to open new src file");
1963 writeln!(out, "// This file is Copyright its original authors, visible in version control").unwrap();
1964 writeln!(out, "// history and in the source files from which this was generated.").unwrap();
1965 writeln!(out, "//").unwrap();
1966 writeln!(out, "// This file is licensed under the license available in the LICENSE or LICENSE.md").unwrap();
1967 writeln!(out, "// file in the root of this repository or, if no such file exists, the same").unwrap();
1968 writeln!(out, "// license as that which applies to the original source files from which this").unwrap();
1969 writeln!(out, "// source was automatically generated.").unwrap();
1970 writeln!(out, "").unwrap();
1972 writeln_docs(&mut out, &attrs, "");
1975 // Special-case the top-level lib.rs with various lint allows and a pointer to the c_types
1976 // and bitcoin hand-written modules.
1977 writeln!(out, "//! C Bindings").unwrap();
1978 writeln!(out, "#![allow(unknown_lints)]").unwrap();
1979 writeln!(out, "#![allow(non_camel_case_types)]").unwrap();
1980 writeln!(out, "#![allow(non_snake_case)]").unwrap();
1981 writeln!(out, "#![allow(unused_imports)]").unwrap();
1982 writeln!(out, "#![allow(unused_variables)]").unwrap();
1983 writeln!(out, "#![allow(unused_mut)]").unwrap();
1984 writeln!(out, "#![allow(unused_parens)]").unwrap();
1985 writeln!(out, "#![allow(unused_unsafe)]").unwrap();
1986 writeln!(out, "#![allow(unused_braces)]").unwrap();
1987 // TODO: We need to map deny(missing_docs) in the source crate(s)
1988 //writeln!(out, "#![deny(missing_docs)]").unwrap();
1990 writeln!(out, "#![cfg_attr(not(feature = \"std\"), no_std)]").unwrap();
1991 writeln!(out, "#[cfg(not(any(feature = \"std\", feature = \"no-std\")))]").unwrap();
1992 writeln!(out, "compile_error!(\"at least one of the `std` or `no-std` features must be enabled\");").unwrap();
1993 writeln!(out, "extern crate alloc;").unwrap();
1995 writeln!(out, "pub mod version;").unwrap();
1996 writeln!(out, "pub mod c_types;").unwrap();
1997 writeln!(out, "pub mod bitcoin;").unwrap();
1999 writeln!(out, "{}", DEFAULT_IMPORTS).unwrap();
2003 writeln!(out, "pub mod {};", m).unwrap();
2006 eprintln!("Converting {} entries...", module);
2008 let import_resolver = ImportResolver::new(orig_crate, &libast.dependencies, module, items);
2009 let mut type_resolver = TypeResolver::new(module, import_resolver, crate_types);
2011 for item in items.iter() {
2013 syn::Item::Use(_) => {}, // Handled above
2014 syn::Item::Static(_) => {},
2015 syn::Item::Enum(e) => {
2016 if let syn::Visibility::Public(_) = e.vis {
2017 writeln_enum(&mut out, &e, &mut type_resolver, header_file, cpp_header_file);
2020 syn::Item::Impl(i) => {
2021 writeln_impl(&mut out, &i, &mut type_resolver);
2023 syn::Item::Struct(s) => {
2024 if let syn::Visibility::Public(_) = s.vis {
2025 writeln_struct(&mut out, &s, &mut type_resolver, header_file, cpp_header_file);
2028 syn::Item::Trait(t) => {
2029 if let syn::Visibility::Public(_) = t.vis {
2030 writeln_trait(&mut out, &t, &mut type_resolver, header_file, cpp_header_file);
2033 syn::Item::Mod(m) => {
2034 convert_priv_mod(&mut out, libast, crate_types, out_dir, &format!("{}::{}", module, m.ident), m);
2036 syn::Item::Const(c) => {
2037 // Re-export any primitive-type constants.
2038 if let syn::Visibility::Public(_) = c.vis {
2039 if let syn::Type::Path(p) = &*c.ty {
2040 let resolved_path = type_resolver.resolve_path(&p.path, None);
2041 if type_resolver.is_primitive(&resolved_path) {
2042 writeln_field_docs(&mut out, &c.attrs, "", &mut type_resolver, None, &*c.ty);
2043 writeln!(out, "\n#[no_mangle]").unwrap();
2044 writeln!(out, "pub static {}: {} = {}::{};", c.ident, resolved_path, module, c.ident).unwrap();
2049 syn::Item::Type(t) => {
2050 if let syn::Visibility::Public(_) = t.vis {
2051 match export_status(&t.attrs) {
2052 ExportStatus::Export => {},
2053 ExportStatus::NoExport|ExportStatus::TestOnly => continue,
2054 ExportStatus::NotImplementable => panic!("(C-not implementable) must only appear on traits"),
2058 syn::Type::Path(p) => {
2059 let real_ty = type_resolver.resolve_path(&p.path, None);
2060 let real_generic_bounds = type_resolver.crate_types.opaques.get(&real_ty).map(|t| t.1).or(
2061 type_resolver.crate_types.priv_structs.get(&real_ty).map(|r| *r)).unwrap();
2062 let mut resolved_generics = t.generics.clone();
2064 // Assume blindly that the bounds in the struct definition where
2065 // clause matches any equivalent bounds on the type alias.
2066 assert!(resolved_generics.where_clause.is_none());
2067 resolved_generics.where_clause = real_generic_bounds.where_clause.clone();
2069 if let syn::PathArguments::AngleBracketed(real_generics) = &p.path.segments.last().unwrap().arguments {
2070 for (real_idx, real_param) in real_generics.args.iter().enumerate() {
2071 if let syn::GenericArgument::Type(syn::Type::Path(real_param_path)) = real_param {
2072 for param in resolved_generics.params.iter_mut() {
2073 if let syn::GenericParam::Type(type_param) = param {
2074 if Some(&type_param.ident) == real_param_path.path.get_ident() {
2075 if let syn::GenericParam::Type(real_type_param) = &real_generic_bounds.params[real_idx] {
2076 type_param.bounds = real_type_param.bounds.clone();
2077 type_param.default = real_type_param.default.clone();
2087 writeln_opaque(&mut out, &t.ident, &format!("{}", t.ident), &resolved_generics, &t.attrs, &type_resolver, header_file, cpp_header_file)},
2092 syn::Item::Fn(f) => {
2093 if let syn::Visibility::Public(_) = f.vis {
2094 writeln_fn(&mut out, &f, &mut type_resolver);
2097 syn::Item::Macro(_) => {},
2098 syn::Item::Verbatim(_) => {},
2099 syn::Item::ExternCrate(_) => {},
2100 _ => unimplemented!(),
2104 out.flush().unwrap();
2109 /// Walk the FullLibraryAST, determining if impl aliases need to be marked cloneable.
2110 fn walk_ast_second_pass<'a>(ast_storage: &'a FullLibraryAST, crate_types: &CrateTypes<'a>) {
2111 for (module, astmod) in ast_storage.modules.iter() {
2112 let orig_crate = module.splitn(2, "::").next().unwrap();
2113 let ASTModule { ref attrs, ref items, .. } = astmod;
2114 assert_eq!(export_status(&attrs), ExportStatus::Export);
2116 let import_resolver = ImportResolver::new(orig_crate, &ast_storage.dependencies, module, items);
2117 let mut types = TypeResolver::new(module, import_resolver, crate_types);
2119 for item in items.iter() {
2121 syn::Item::Impl(i) => {
2122 match export_status(&i.attrs) {
2123 ExportStatus::Export => {},
2124 ExportStatus::NoExport|ExportStatus::TestOnly => continue,
2125 ExportStatus::NotImplementable => panic!("(C-not implementable) must only appear on traits"),
2127 if let Some(trait_path) = i.trait_.as_ref() {
2128 if path_matches_nongeneric(&trait_path.1, &["core", "clone", "Clone"]) ||
2129 path_matches_nongeneric(&trait_path.1, &["Clone"])
2131 if let &syn::Type::Path(ref p) = &*i.self_ty {
2132 if let Some(resolved_path) = types.maybe_resolve_path(&p.path, None) {
2133 create_alias_for_impl(resolved_path, i, &mut types, |aliased_impl, types| {
2134 if let &syn::Type::Path(ref p) = &*aliased_impl.self_ty {
2135 if let Some(resolved_aliased_path) = types.maybe_resolve_path(&p.path, None) {
2136 crate_types.set_clonable("crate::".to_owned() + &resolved_aliased_path);
2151 fn walk_private_mod<'a>(ast_storage: &'a FullLibraryAST, orig_crate: &str, module: String, items: &'a syn::ItemMod, crate_types: &mut CrateTypes<'a>) {
2152 let import_resolver = ImportResolver::new(orig_crate, &ast_storage.dependencies, &module, &items.content.as_ref().unwrap().1);
2153 for item in items.content.as_ref().unwrap().1.iter() {
2155 syn::Item::Mod(m) => walk_private_mod(ast_storage, orig_crate, format!("{}::{}", module, m.ident), m, crate_types),
2156 syn::Item::Impl(i) => {
2157 if let &syn::Type::Path(ref p) = &*i.self_ty {
2158 if let Some(trait_path) = i.trait_.as_ref() {
2159 if let Some(tp) = import_resolver.maybe_resolve_path(&trait_path.1, None) {
2160 if let Some(sp) = import_resolver.maybe_resolve_path(&p.path, None) {
2161 match crate_types.trait_impls.entry(sp) {
2162 hash_map::Entry::Occupied(mut e) => { e.get_mut().push(tp); },
2163 hash_map::Entry::Vacant(e) => { e.insert(vec![tp]); },
2175 /// Walk the FullLibraryAST, deciding how things will be mapped and adding tracking to CrateTypes.
2176 fn walk_ast_first_pass<'a>(ast_storage: &'a FullLibraryAST, crate_types: &mut CrateTypes<'a>) {
2177 for (module, astmod) in ast_storage.modules.iter() {
2178 let ASTModule { ref attrs, ref items, submods: _ } = astmod;
2179 assert_eq!(export_status(&attrs), ExportStatus::Export);
2180 let orig_crate = module.splitn(2, "::").next().unwrap();
2181 let import_resolver = ImportResolver::new(orig_crate, &ast_storage.dependencies, module, items);
2183 for item in items.iter() {
2185 syn::Item::Struct(s) => {
2186 if let syn::Visibility::Public(_) = s.vis {
2187 let struct_path = format!("{}::{}", module, s.ident);
2188 match export_status(&s.attrs) {
2189 ExportStatus::Export => {},
2190 ExportStatus::NoExport|ExportStatus::TestOnly => {
2191 crate_types.priv_structs.insert(struct_path, &s.generics);
2194 ExportStatus::NotImplementable => panic!("(C-not implementable) must only appear on traits"),
2196 crate_types.opaques.insert(struct_path, (&s.ident, &s.generics));
2199 syn::Item::Trait(t) => {
2200 if let syn::Visibility::Public(_) = t.vis {
2201 match export_status(&t.attrs) {
2202 ExportStatus::Export|ExportStatus::NotImplementable => {},
2203 ExportStatus::NoExport|ExportStatus::TestOnly => continue,
2205 let trait_path = format!("{}::{}", module, t.ident);
2206 walk_supertraits!(t, None, (
2207 ("Clone", _, _) => {
2208 crate_types.set_clonable("crate::".to_owned() + &trait_path);
2212 crate_types.traits.insert(trait_path, &t);
2215 syn::Item::Type(t) => {
2216 if let syn::Visibility::Public(_) = t.vis {
2217 match export_status(&t.attrs) {
2218 ExportStatus::Export => {},
2219 ExportStatus::NoExport|ExportStatus::TestOnly => continue,
2220 ExportStatus::NotImplementable => panic!("(C-not implementable) must only appear on traits"),
2222 let type_path = format!("{}::{}", module, t.ident);
2224 syn::Type::Path(p) => {
2225 // If its a path with no generics, assume we don't map the aliased type and map it opaque
2226 let args_obj = p.path.segments.last().unwrap().arguments.clone();
2227 match crate_types.reverse_alias_map.entry(import_resolver.maybe_resolve_path(&p.path, None).unwrap()) {
2228 hash_map::Entry::Occupied(mut e) => { e.get_mut().push((type_path.clone(), args_obj)); },
2229 hash_map::Entry::Vacant(e) => { e.insert(vec![(type_path.clone(), args_obj)]); },
2232 crate_types.opaques.insert(type_path, (&t.ident, &t.generics));
2235 crate_types.type_aliases.insert(type_path, import_resolver.resolve_imported_refs((*t.ty).clone()));
2240 syn::Item::Enum(e) if is_enum_opaque(e) => {
2241 if let syn::Visibility::Public(_) = e.vis {
2242 match export_status(&e.attrs) {
2243 ExportStatus::Export => {},
2244 ExportStatus::NoExport|ExportStatus::TestOnly => continue,
2245 ExportStatus::NotImplementable => panic!("(C-not implementable) must only appear on traits"),
2247 let enum_path = format!("{}::{}", module, e.ident);
2248 crate_types.opaques.insert(enum_path, (&e.ident, &e.generics));
2251 syn::Item::Enum(e) => {
2252 if let syn::Visibility::Public(_) = e.vis {
2253 match export_status(&e.attrs) {
2254 ExportStatus::Export => {},
2255 ExportStatus::NoExport|ExportStatus::TestOnly => continue,
2256 ExportStatus::NotImplementable => panic!("(C-not implementable) must only appear on traits"),
2258 let enum_path = format!("{}::{}", module, e.ident);
2259 crate_types.mirrored_enums.insert(enum_path, &e);
2262 syn::Item::Impl(i) => {
2263 if let &syn::Type::Path(ref p) = &*i.self_ty {
2264 if let Some(trait_path) = i.trait_.as_ref() {
2265 if path_matches_nongeneric(&trait_path.1, &["core", "clone", "Clone"]) ||
2266 path_matches_nongeneric(&trait_path.1, &["Clone"]) {
2267 if let Some(full_path) = import_resolver.maybe_resolve_path(&p.path, None) {
2268 crate_types.set_clonable("crate::".to_owned() + &full_path);
2271 if let Some(tp) = import_resolver.maybe_resolve_path(&trait_path.1, None) {
2272 if let Some(sp) = import_resolver.maybe_resolve_path(&p.path, None) {
2273 match crate_types.trait_impls.entry(sp) {
2274 hash_map::Entry::Occupied(mut e) => { e.get_mut().push(tp); },
2275 hash_map::Entry::Vacant(e) => { e.insert(vec![tp]); },
2282 syn::Item::Mod(m) => walk_private_mod(ast_storage, orig_crate, format!("{}::{}", module, m.ident), m, crate_types),
2290 let args: Vec<String> = env::args().collect();
2291 if args.len() != 5 {
2292 eprintln!("Usage: target/dir derived_templates.rs extra/includes.h extra/cpp/includes.hpp");
2296 let mut derived_templates = std::fs::OpenOptions::new().write(true).create(true).truncate(true)
2297 .open(&args[2]).expect("Unable to open new header file");
2298 writeln!(&mut derived_templates, "{}", DEFAULT_IMPORTS).unwrap();
2299 let mut header_file = std::fs::OpenOptions::new().write(true).create(true).truncate(true)
2300 .open(&args[3]).expect("Unable to open new header file");
2301 let mut cpp_header_file = std::fs::OpenOptions::new().write(true).create(true).truncate(true)
2302 .open(&args[4]).expect("Unable to open new header file");
2304 writeln!(header_file, "#if defined(__GNUC__)").unwrap();
2305 writeln!(header_file, "#define MUST_USE_STRUCT __attribute__((warn_unused))").unwrap();
2306 writeln!(header_file, "#define MUST_USE_RES __attribute__((warn_unused_result))").unwrap();
2307 writeln!(header_file, "#else").unwrap();
2308 writeln!(header_file, "#define MUST_USE_STRUCT").unwrap();
2309 writeln!(header_file, "#define MUST_USE_RES").unwrap();
2310 writeln!(header_file, "#endif").unwrap();
2311 writeln!(header_file, "#if defined(__clang__)").unwrap();
2312 writeln!(header_file, "#define NONNULL_PTR _Nonnull").unwrap();
2313 writeln!(header_file, "#else").unwrap();
2314 writeln!(header_file, "#define NONNULL_PTR").unwrap();
2315 writeln!(header_file, "#endif").unwrap();
2316 writeln!(cpp_header_file, "#include <string.h>\nnamespace LDK {{").unwrap();
2318 // Write a few manually-defined types into the C++ header file
2319 write_cpp_wrapper(&mut cpp_header_file, "Str", true, None);
2321 // First parse the full crate's ASTs, caching them so that we can hold references to the AST
2322 // objects in other datastructures:
2323 let mut lib_src = String::new();
2324 std::io::stdin().lock().read_to_string(&mut lib_src).unwrap();
2325 let lib_syntax = syn::parse_file(&lib_src).expect("Unable to parse file");
2326 let libast = FullLibraryAST::load_lib(lib_syntax);
2328 // ...then walk the ASTs tracking what types we will map, and how, so that we can resolve them
2329 // when parsing other file ASTs...
2330 let mut libtypes = CrateTypes::new(&mut derived_templates, &libast);
2331 walk_ast_first_pass(&libast, &mut libtypes);
2333 // ... using the generated data, determine a few additional fields, specifically which type
2334 // aliases are to be clone-able...
2335 walk_ast_second_pass(&libast, &libtypes);
2337 // ... finally, do the actual file conversion/mapping, writing out types as we go.
2338 convert_file(&libast, &libtypes, &args[1], &mut header_file, &mut cpp_header_file);
2340 // For container templates which we created while walking the crate, make sure we add C++
2341 // mapped types so that C++ users can utilize the auto-destructors available.
2342 for (ty, has_destructor) in libtypes.templates_defined.borrow().iter() {
2343 write_cpp_wrapper(&mut cpp_header_file, ty, *has_destructor, None);
2345 writeln!(cpp_header_file, "}}").unwrap();
2347 header_file.flush().unwrap();
2348 cpp_header_file.flush().unwrap();
2349 derived_templates.flush().unwrap();