use std::collections::HashMap;
use std::fs::File;
use std::io::Write;
+use std::hash;
use proc_macro2::{TokenTree, Span};
} else { None }
}
-pub fn assert_single_path_seg<'a>(p: &'a syn::Path) -> &'a syn::Ident {
- if p.leading_colon.is_some() { unimplemented!(); }
- get_single_remaining_path_seg(&mut p.segments.iter()).unwrap()
-}
-
pub fn single_ident_generic_path_to_ident(p: &syn::Path) -> Option<&syn::Ident> {
if p.segments.len() == 1 {
Some(&p.segments.iter().next().unwrap().ident)
/// Learn the generics in generics in the current context, given a TypeResolver.
pub fn learn_generics<'b, 'c>(&mut self, generics: &'a syn::Generics, types: &'b TypeResolver<'a, 'c>) -> bool {
+ // First learn simple generics...
for generic in generics.params.iter() {
match generic {
syn::GenericParam::Type(type_param) => {
}
assert_simple_bound(&trait_bound);
- if let Some(mut path) = types.maybe_resolve_path(&trait_bound.path) {
+ if let Some(mut path) = types.maybe_resolve_path(&trait_bound.path, None) {
if types.skip_path(&path) { continue; }
if non_lifetimes_processed { return false; }
non_lifetimes_processed = true;
_ => {},
}
}
+ // Then find generics where we are required to pass a Deref<Target=X> and pretend its just X.
if let Some(wh) = &generics.where_clause {
for pred in wh.predicates.iter() {
if let syn::WherePredicate::Type(t) = pred {
if non_lifetimes_processed { return false; }
non_lifetimes_processed = true;
assert_simple_bound(&trait_bound);
- *gen = ("crate::".to_string() + &types.resolve_path(&trait_bound.path),
+ *gen = ("crate::".to_string() + &types.resolve_path(&trait_bound.path, None),
Some(&trait_bound.path));
}
}
true
}
+ /// Learn the associated types from the trait in the current context.
+ pub fn learn_associated_types<'b, 'c>(&mut self, t: &'a syn::ItemTrait, types: &'b TypeResolver<'a, 'c>) {
+ for item in t.items.iter() {
+ match item {
+ &syn::TraitItem::Type(ref t) => {
+ if t.default.is_some() || t.generics.lt_token.is_some() { unimplemented!(); }
+ let mut bounds_iter = t.bounds.iter();
+ match bounds_iter.next().unwrap() {
+ syn::TypeParamBound::Trait(tr) => {
+ assert_simple_bound(&tr);
+ if let Some(mut path) = types.maybe_resolve_path(&tr.path, None) {
+ if types.skip_path(&path) { continue; }
+ // In general we handle Deref<Target=X> as if it were just X (and
+ // implement Deref<Target=Self> for relevant types). We don't
+ // bother to implement it for associated types, however, so we just
+ // ignore such bounds.
+ let new_ident = if path != "std::ops::Deref" {
+ path = "crate::".to_string() + &path;
+ Some(&tr.path)
+ } else { None };
+ self.typed_generics.last_mut().unwrap().insert(&t.ident, (path, new_ident));
+ } else { unimplemented!(); }
+ },
+ _ => unimplemented!(),
+ }
+ if bounds_iter.next().is_some() { unimplemented!(); }
+ },
+ _ => {},
+ }
+ }
+ }
+
/// Attempt to resolve an Ident as a generic parameter and return the full path.
pub fn maybe_resolve_ident<'b>(&'b self, ident: &syn::Ident) -> Option<&'b String> {
for gen in self.typed_generics.iter().rev() {
return Some(res);
}
}
+ } else {
+ // Associated types are usually specified as "Self::Generic", so we check for that
+ // explicitly here.
+ let mut it = path.segments.iter();
+ if path.segments.len() == 2 && format!("{}", it.next().unwrap().ident) == "Self" {
+ let ident = &it.next().unwrap().ident;
+ for gen in self.typed_generics.iter().rev() {
+ if let Some(res) = gen.get(ident).map(|(a, b)| (a, b.unwrap())) {
+ return Some(res);
+ }
+ }
+ }
}
None
}
EnumIgnored,
}
+// templates_defined is walked to write the C++ header, so if we use the default hashing it get
+// reordered on each genbindings run. Instead, we use SipHasher (which defaults to 0-keys) so that
+// the sorting is stable across runs. It is deprecated, but the "replacement" doesn't actually
+// accomplish the same goals, so we just ignore it.
+#[allow(deprecated)]
+type NonRandomHash = hash::BuildHasherDefault<hash::SipHasher>;
+
/// Top-level struct tracking everything which has been defined while walking the crate.
pub struct CrateTypes<'a> {
/// This may contain structs or enums, but only when either is mapped as
pub mirrored_enums: HashMap<String, &'a syn::ItemEnum>,
/// Traits which are mapped as a pointer + jump table
pub traits: HashMap<String, &'a syn::ItemTrait>,
+ /// Aliases from paths to some other Type
+ pub type_aliases: HashMap<String, syn::Type>,
/// Template continer types defined, map from mangled type name -> whether a destructor fn
/// exists.
///
/// This is used at the end of processing to make C++ wrapper classes
- pub templates_defined: HashMap<String, bool>,
+ pub templates_defined: HashMap<String, bool, NonRandomHash>,
/// The output file for any created template container types, written to as we find new
/// template containers which need to be defined.
pub template_file: &'a mut File,
pub crate_types: &'mod_lifetime mut CrateTypes<'crate_lft>,
}
+/// Returned by write_empty_rust_val_check_suffix to indicate what type of dereferencing needs to
+/// happen to get the inner value of a generic.
+enum EmptyValExpectedTy {
+ /// A type which has a flag for being empty (eg an array where we treat all-0s as empty).
+ NonPointer,
+ /// A pointer that we want to dereference and move out of.
+ OwnedPointer,
+ /// A pointer which we want to convert to a reference.
+ ReferenceAsPointer,
+}
+
impl<'a, 'c: 'a> TypeResolver<'a, 'c> {
pub fn new(orig_crate: &'a str, module_path: &'a str, crate_types: &'a mut CrateTypes<'c>) -> Self {
let mut imports = HashMap::new();
"bitcoin::secp256k1::Error" if !is_ref => Some("crate::c_types::Secp256k1Error"),
"bitcoin::blockdata::script::Script" if is_ref => Some("crate::c_types::u8slice"),
"bitcoin::blockdata::script::Script" if !is_ref => Some("crate::c_types::derived::CVec_u8Z"),
- "bitcoin::blockdata::transaction::OutPoint" if is_ref => Some("crate::chain::transaction::OutPoint"),
- "bitcoin::blockdata::transaction::Transaction" if is_ref && !ptr_for_ref => Some("crate::c_types::Transaction"),
- "bitcoin::blockdata::transaction::Transaction" => Some("crate::c_types::derived::CVec_u8Z"),
+ "bitcoin::blockdata::transaction::OutPoint" => Some("crate::chain::transaction::OutPoint"),
+ "bitcoin::blockdata::transaction::Transaction" => Some("crate::c_types::Transaction"),
"bitcoin::blockdata::transaction::TxOut" if !is_ref => Some("crate::c_types::TxOut"),
- "bitcoin::OutPoint" => Some("crate::chain::transaction::OutPoint"),
"bitcoin::network::constants::Network" => Some("crate::bitcoin::network::Network"),
"bitcoin::blockdata::block::BlockHeader" if is_ref => Some("*const [u8; 80]"),
"bitcoin::blockdata::block::Block" if is_ref => Some("crate::c_types::u8slice"),
"bitcoin::hash_types::Txid" if !is_ref => Some("crate::c_types::ThirtyTwoBytes"),
"bitcoin::hash_types::BlockHash" if is_ref => Some("*const [u8; 32]"),
"bitcoin::hash_types::BlockHash" if !is_ref => Some("crate::c_types::ThirtyTwoBytes"),
+ "bitcoin::secp256k1::Message" if !is_ref => Some("crate::c_types::ThirtyTwoBytes"),
"ln::channelmanager::PaymentHash" if is_ref => Some("*const [u8; 32]"),
"ln::channelmanager::PaymentHash" if !is_ref => Some("crate::c_types::ThirtyTwoBytes"),
"ln::channelmanager::PaymentPreimage" if is_ref => Some("*const [u8; 32]"),
"bitcoin::blockdata::script::Script" if is_ref => Some("&::bitcoin::blockdata::script::Script::from(Vec::from("),
"bitcoin::blockdata::script::Script" if !is_ref => Some("::bitcoin::blockdata::script::Script::from("),
"bitcoin::blockdata::transaction::Transaction" if is_ref => Some("&"),
- "bitcoin::blockdata::transaction::Transaction" => Some("::bitcoin::consensus::encode::deserialize(&"),
+ "bitcoin::blockdata::transaction::Transaction" => Some(""),
"bitcoin::blockdata::transaction::TxOut" if !is_ref => Some(""),
"bitcoin::network::constants::Network" => Some(""),
"bitcoin::blockdata::block::BlockHeader" => Some("&::bitcoin::consensus::encode::deserialize(unsafe { &*"),
"bitcoin::secp256k1::key::SecretKey" if is_ref => Some("}[..]).unwrap()"),
"bitcoin::blockdata::script::Script" if is_ref => Some(".to_slice()))"),
"bitcoin::blockdata::script::Script" if !is_ref => Some(".into_rust())"),
- "bitcoin::blockdata::transaction::Transaction" if is_ref => Some(".into_bitcoin()"),
- "bitcoin::blockdata::transaction::Transaction" => Some(".into_rust()[..]).unwrap()"),
+ "bitcoin::blockdata::transaction::Transaction" => Some(".into_bitcoin()"),
"bitcoin::blockdata::transaction::TxOut" if !is_ref => Some(".into_rust()"),
"bitcoin::network::constants::Network" => Some(".into_bitcoin()"),
"bitcoin::blockdata::block::BlockHeader" => Some(" }).unwrap()"),
"bitcoin::secp256k1::Error" if !is_ref => Some("crate::c_types::Secp256k1Error::from_rust("),
"bitcoin::blockdata::script::Script" if is_ref => Some("crate::c_types::u8slice::from_slice(&"),
"bitcoin::blockdata::script::Script" if !is_ref => Some(""),
- "bitcoin::blockdata::transaction::Transaction" if is_ref && !ptr_for_ref => Some("crate::c_types::Transaction::from_slice(&local_"),
- "bitcoin::blockdata::transaction::Transaction" => Some("local_"),
+ "bitcoin::blockdata::transaction::Transaction" => Some("crate::c_types::Transaction::from_vec(local_"),
+ "bitcoin::blockdata::transaction::OutPoint" => Some("crate::c_types::bitcoin_to_C_outpoint("),
"bitcoin::blockdata::transaction::TxOut" if !is_ref => Some("crate::c_types::TxOut::from_rust("),
"bitcoin::blockdata::block::BlockHeader" if is_ref => Some("&local_"),
"bitcoin::blockdata::block::Block" if is_ref => Some("crate::c_types::u8slice::from_slice(&local_"),
"bitcoin::hash_types::Txid" if is_ref => Some(""),
"bitcoin::hash_types::BlockHash" if is_ref => Some(""),
"bitcoin::hash_types::BlockHash" => Some("crate::c_types::ThirtyTwoBytes { data: "),
+ "bitcoin::secp256k1::Message" if !is_ref => Some("crate::c_types::ThirtyTwoBytes { data: "),
"ln::channelmanager::PaymentHash" if is_ref => Some("&"),
"ln::channelmanager::PaymentHash" if !is_ref => Some("crate::c_types::ThirtyTwoBytes { data: "),
"ln::channelmanager::PaymentPreimage" if is_ref => Some("&"),
"bitcoin::secp256k1::Error" if !is_ref => Some(")"),
"bitcoin::blockdata::script::Script" if is_ref => Some("[..])"),
"bitcoin::blockdata::script::Script" if !is_ref => Some(".into_bytes().into()"),
- "bitcoin::blockdata::transaction::Transaction" if is_ref && !ptr_for_ref => Some(")"),
- "bitcoin::blockdata::transaction::Transaction" => Some(".into()"),
+ "bitcoin::blockdata::transaction::Transaction" => Some(")"),
+ "bitcoin::blockdata::transaction::OutPoint" => Some(")"),
"bitcoin::blockdata::transaction::TxOut" if !is_ref => Some(")"),
"bitcoin::blockdata::block::BlockHeader" if is_ref => Some(""),
"bitcoin::blockdata::block::Block" if is_ref => Some(")"),
"bitcoin::hash_types::Txid" if is_ref => Some(".as_inner()"),
"bitcoin::hash_types::BlockHash" if is_ref => Some(".as_inner()"),
"bitcoin::hash_types::BlockHash" => Some(".into_inner() }"),
+ "bitcoin::secp256k1::Message" if !is_ref => Some(".as_ref().clone() }"),
"ln::channelmanager::PaymentHash" if is_ref => Some(".0"),
"ln::channelmanager::PaymentHash" => Some(".0 }"),
"ln::channelmanager::PaymentPreimage" if is_ref => Some(".0"),
fn empty_val_check_suffix_from_path(&self, full_path: &str) -> Option<&str> {
match full_path {
"ln::channelmanager::PaymentSecret" => Some(".data == [0; 32]"),
+ "bitcoin::secp256k1::key::PublicKey" => Some(".is_null()"),
+ "bitcoin::secp256k1::Signature" => Some(".is_null()"),
_ => None
}
}
fn is_known_container(&self, full_path: &str, is_ref: bool) -> bool {
(full_path == "Result" && !is_ref) || (full_path == "Vec" && !is_ref) || full_path.ends_with("Tuple")
}
- fn to_c_conversion_container_new_var<'b>(&self, full_path: &str, is_ref: bool, single_contained: Option<&syn::Type>, var_name: &syn::Ident, var_access: &str)
+ fn to_c_conversion_container_new_var<'b>(&self, generics: Option<&GenericTypes>, full_path: &str, is_ref: bool, single_contained: Option<&syn::Type>, var_name: &syn::Ident, var_access: &str)
// Returns prefix + Vec<(prefix, var-name-to-inline-convert)> + suffix
// expecting one element in the vec per generic type, each of which is inline-converted
-> Option<(&'b str, Vec<(String, String)>, &'b str)> {
},
"Option" => {
if let Some(syn::Type::Path(p)) = single_contained {
- if self.c_type_has_inner_from_path(&self.resolve_path(&p.path)) {
+ if self.c_type_has_inner_from_path(&self.resolve_path(&p.path, generics)) {
if is_ref {
return Some(("if ", vec![
(".is_none() { std::ptr::null() } else { ".to_owned(), format!("({}.as_ref().unwrap())", var_access))
}
if let Some(t) = single_contained {
let mut v = Vec::new();
- self.write_empty_rust_val(&mut v, t);
+ self.write_empty_rust_val(generics, &mut v, t);
let s = String::from_utf8(v).unwrap();
return Some(("if ", vec![
(format!(".is_none() {{ {} }} else {{ ", s), format!("({}.unwrap())", var_access))
/// only_contained_has_inner implies that there is only one contained element in the container
/// and it has an inner field (ie is an "opaque" type we've defined).
- fn from_c_conversion_container_new_var<'b>(&self, full_path: &str, is_ref: bool, single_contained: Option<&syn::Type>, var_name: &syn::Ident, var_access: &str)
+ fn from_c_conversion_container_new_var<'b>(&self, generics: Option<&GenericTypes>, full_path: &str, is_ref: bool, single_contained: Option<&syn::Type>, var_name: &syn::Ident, var_access: &str)
// Returns prefix + Vec<(prefix, var-name-to-inline-convert)> + suffix
// expecting one element in the vec per generic type, each of which is inline-converted
-> Option<(&'b str, Vec<(String, String)>, &'b str)> {
},
"Option" => {
if let Some(syn::Type::Path(p)) = single_contained {
- if self.c_type_has_inner_from_path(&self.resolve_path(&p.path)) {
+ if self.c_type_has_inner_from_path(&self.resolve_path(&p.path, generics)) {
if is_ref {
return Some(("if ", vec![(".inner.is_null() { None } else { Some((*".to_string(), format!("{}", var_name))], ").clone()) }"))
} else {
if let Some(t) = single_contained {
let mut v = Vec::new();
- let needs_deref = self.write_empty_rust_val_check_suffix(&mut v, t);
+ let ret_ref = self.write_empty_rust_val_check_suffix(generics, &mut v, t);
let s = String::from_utf8(v).unwrap();
- if needs_deref {
- return Some(("if ", vec![
- (format!("{} {{ None }} else {{ Some(", s), format!("unsafe {{ &mut *{} }}", var_access))
- ], ") }"));
- } else {
- return Some(("if ", vec![
- (format!("{} {{ None }} else {{ Some(", s), format!("{}", var_access))
- ], ") }"));
+ match ret_ref {
+ EmptyValExpectedTy::ReferenceAsPointer =>
+ return Some(("if ", vec![
+ (format!("{} {{ None }} else {{ Some(", s), format!("unsafe {{ &mut *{} }}", var_access))
+ ], ") }")),
+ EmptyValExpectedTy::OwnedPointer =>
+ return Some(("if ", vec![
+ (format!("{} {{ None }} else {{ Some(", s), format!("unsafe {{ *Box::from_raw({}) }}", var_access))
+ ], ") }")),
+ EmptyValExpectedTy::NonPointer =>
+ return Some(("if ", vec![
+ (format!("{} {{ None }} else {{ Some(", s), format!("{}", var_access))
+ ], ") }")),
}
} else { unreachable!(); }
},
let new_path = format!("{}", p.ident);
self.process_use_intern(w, &p.tree, &new_path);
},
+ syn::UseTree::Name(n) => {
+ let full_path = format!("{}", n.ident);
+ self.imports.insert(n.ident.clone(), full_path);
+ },
_ => unimplemented!(),
}
if u.leading_colon.is_some() { unimplemented!() }
} else { None }
}
- pub fn maybe_resolve_path(&self, p: &syn::Path) -> Option<String> {
+ pub fn maybe_resolve_path(&self, p_arg: &syn::Path, generics: Option<&GenericTypes>) -> Option<String> {
+ let p = if let Some(gen_types) = generics {
+ if let Some((_, synpath)) = gen_types.maybe_resolve_path(p_arg) {
+ synpath
+ } else { p_arg }
+ } else { p_arg };
+
if p.leading_colon.is_some() {
- // At some point we may need this, but for now, its unused, so just fail.
- return None;
+ Some(p.segments.iter().enumerate().map(|(idx, seg)| {
+ format!("{}{}", if idx == 0 { "" } else { "::" }, seg.ident)
+ }).collect())
} else if let Some(id) = p.get_ident() {
self.maybe_resolve_ident(id)
} else {
let mut seg_iter = p.segments.iter();
let first_seg = seg_iter.next().unwrap();
let remaining: String = seg_iter.map(|seg| {
- if let syn::PathArguments::None = seg.arguments {
- format!("{}", seg.ident)
- } else {
- format!("{}", seg.ident)
- }
+ format!("::{}", seg.ident)
}).collect();
if let Some(imp) = self.imports.get(&first_seg.ident) {
if remaining != "" {
- Some(imp.clone() + "::" + &remaining)
+ Some(imp.clone() + &remaining)
} else {
Some(imp.clone())
}
} else { None }
}
}
- pub fn resolve_path(&self, p: &syn::Path) -> String {
- self.maybe_resolve_path(p).unwrap()
+ pub fn resolve_path(&self, p: &syn::Path, generics: Option<&GenericTypes>) -> String {
+ self.maybe_resolve_path(p, generics).unwrap()
}
// ***********************************
// *** Original Rust Type Printing ***
// ***********************************
- fn write_rust_path<W: std::io::Write>(&self, w: &mut W, path: &syn::Path) {
- if let Some(resolved) = self.maybe_resolve_path(&path) {
+ fn in_rust_prelude(resolved_path: &str) -> bool {
+ match resolved_path {
+ "Vec" => true,
+ "Result" => true,
+ "Option" => true,
+ _ => false,
+ }
+ }
+
+ fn write_rust_path<W: std::io::Write>(&self, w: &mut W, generics_resolver: Option<&GenericTypes>, path: &syn::Path) {
+ if let Some(resolved) = self.maybe_resolve_path(&path, generics_resolver) {
if self.is_primitive(&resolved) {
write!(w, "{}", path.get_ident().unwrap()).unwrap();
} else {
- if resolved.starts_with("ln::") || resolved.starts_with("chain::") || resolved.starts_with("util::") {
- write!(w, "lightning::{}", resolved).unwrap();
+ // TODO: We should have a generic "is from a dependency" check here instead of
+ // checking for "bitcoin" explicitly.
+ if resolved.starts_with("bitcoin::") || Self::in_rust_prelude(&resolved) {
+ write!(w, "{}", resolved).unwrap();
+ // If we're printing a generic argument, it needs to reference the crate, otherwise
+ // the original crate:
+ } else if self.maybe_resolve_path(&path, None).as_ref() == Some(&resolved) {
+ write!(w, "{}::{}", self.orig_crate, resolved).unwrap();
} else {
- write!(w, "{}", resolved).unwrap(); // XXX: Probably doens't work, get_ident().unwrap()
+ write!(w, "crate::{}", resolved).unwrap();
}
}
if let syn::PathArguments::AngleBracketed(args) = &path.segments.iter().last().unwrap().arguments {
- self.write_rust_generic_arg(w, args.args.iter());
+ self.write_rust_generic_arg(w, generics_resolver, args.args.iter());
}
} else {
if path.leading_colon.is_some() {
if idx != 0 { write!(w, "::").unwrap(); }
write!(w, "{}", seg.ident).unwrap();
if let syn::PathArguments::AngleBracketed(args) = &seg.arguments {
- self.write_rust_generic_arg(w, args.args.iter());
+ self.write_rust_generic_arg(w, generics_resolver, args.args.iter());
}
}
}
}
- pub fn write_rust_generic_param<'b, W: std::io::Write>(&self, w: &mut W, generics: impl Iterator<Item=&'b syn::GenericParam>) {
+ pub fn write_rust_generic_param<'b, W: std::io::Write>(&self, w: &mut W, generics_resolver: Option<&GenericTypes>, generics: impl Iterator<Item=&'b syn::GenericParam>) {
let mut had_params = false;
for (idx, arg) in generics.enumerate() {
if idx != 0 { write!(w, ", ").unwrap(); } else { write!(w, "<").unwrap(); }
match bound {
syn::TypeParamBound::Trait(tb) => {
if tb.paren_token.is_some() || tb.lifetimes.is_some() { unimplemented!(); }
- self.write_rust_path(w, &tb.path);
+ self.write_rust_path(w, generics_resolver, &tb.path);
},
_ => unimplemented!(),
}
if had_params { write!(w, ">").unwrap(); }
}
- pub fn write_rust_generic_arg<'b, W: std::io::Write>(&self, w: &mut W, generics: impl Iterator<Item=&'b syn::GenericArgument>) {
+ pub fn write_rust_generic_arg<'b, W: std::io::Write>(&self, w: &mut W, generics_resolver: Option<&GenericTypes>, generics: impl Iterator<Item=&'b syn::GenericArgument>) {
write!(w, "<").unwrap();
for (idx, arg) in generics.enumerate() {
if idx != 0 { write!(w, ", ").unwrap(); }
match arg {
- syn::GenericArgument::Type(t) => self.write_rust_type(w, t),
+ syn::GenericArgument::Type(t) => self.write_rust_type(w, generics_resolver, t),
_ => unimplemented!(),
}
}
write!(w, ">").unwrap();
}
- pub fn write_rust_type<W: std::io::Write>(&self, w: &mut W, t: &syn::Type) {
+ pub fn write_rust_type<W: std::io::Write>(&self, w: &mut W, generics: Option<&GenericTypes>, t: &syn::Type) {
match t {
syn::Type::Path(p) => {
if p.qself.is_some() || p.path.leading_colon.is_some() {
unimplemented!();
}
- self.write_rust_path(w, &p.path);
+ self.write_rust_path(w, generics, &p.path);
},
syn::Type::Reference(r) => {
write!(w, "&").unwrap();
if r.mutability.is_some() {
write!(w, "mut ").unwrap();
}
- self.write_rust_type(w, &*r.elem);
+ self.write_rust_type(w, generics, &*r.elem);
},
syn::Type::Array(a) => {
write!(w, "[").unwrap();
- self.write_rust_type(w, &a.elem);
+ self.write_rust_type(w, generics, &a.elem);
if let syn::Expr::Lit(l) = &a.len {
if let syn::Lit::Int(i) = &l.lit {
write!(w, "; {}]", i).unwrap();
}
syn::Type::Slice(s) => {
write!(w, "[").unwrap();
- self.write_rust_type(w, &s.elem);
+ self.write_rust_type(w, generics, &s.elem);
write!(w, "]").unwrap();
},
syn::Type::Tuple(s) => {
write!(w, "(").unwrap();
for (idx, t) in s.elems.iter().enumerate() {
if idx != 0 { write!(w, ", ").unwrap(); }
- self.write_rust_type(w, &t);
+ self.write_rust_type(w, generics, &t);
}
write!(w, ")").unwrap();
},
/// Prints a constructor for something which is "uninitialized" (but obviously not actually
/// unint'd memory).
- pub fn write_empty_rust_val<W: std::io::Write>(&self, w: &mut W, t: &syn::Type) {
+ pub fn write_empty_rust_val<W: std::io::Write>(&self, generics: Option<&GenericTypes>, w: &mut W, t: &syn::Type) {
match t {
syn::Type::Path(p) => {
- let resolved = self.resolve_path(&p.path);
+ let resolved = self.resolve_path(&p.path, generics);
if self.crate_types.opaques.get(&resolved).is_some() {
write!(w, "crate::{} {{ inner: std::ptr::null_mut(), is_owned: true }}", resolved).unwrap();
} else {
}
}
- /// Prints a suffix to determine if a variable is empty (ie was set by write_empty_rust_val),
- /// returning whether we need to dereference the inner value before using it (ie it is a
- /// pointer).
- pub fn write_empty_rust_val_check_suffix<W: std::io::Write>(&self, w: &mut W, t: &syn::Type) -> bool {
+ /// Prints a suffix to determine if a variable is empty (ie was set by write_empty_rust_val).
+ /// See EmptyValExpectedTy for information on return types.
+ fn write_empty_rust_val_check_suffix<W: std::io::Write>(&self, generics: Option<&GenericTypes>, w: &mut W, t: &syn::Type) -> EmptyValExpectedTy {
match t {
syn::Type::Path(p) => {
- let resolved = self.resolve_path(&p.path);
+ let resolved = self.resolve_path(&p.path, generics);
if self.crate_types.opaques.get(&resolved).is_some() {
write!(w, ".inner.is_null()").unwrap();
- false
+ EmptyValExpectedTy::NonPointer
} else {
if let Some(suffix) = self.empty_val_check_suffix_from_path(&resolved) {
write!(w, "{}", suffix).unwrap();
- false // We may eventually need to allow empty_val_check_suffix_from_path to specify if we need a deref or not
+ // We may eventually need to allow empty_val_check_suffix_from_path to specify if we need a deref or not
+ EmptyValExpectedTy::NonPointer
} else {
- write!(w, ".is_null()").unwrap();
- false
+ write!(w, " == std::ptr::null_mut()").unwrap();
+ EmptyValExpectedTy::OwnedPointer
}
}
},
if let syn::Expr::Lit(l) = &a.len {
if let syn::Lit::Int(i) = &l.lit {
write!(w, " == [0; {}]", i.base10_digits()).unwrap();
- false
+ EmptyValExpectedTy::NonPointer
} else { unimplemented!(); }
} else { unimplemented!(); }
},
syn::Type::Slice(_) => {
// Option<[]> always implies that we want to treat len() == 0 differently from
// None, so we always map an Option<[]> into a pointer.
- write!(w, ".is_null()").unwrap();
- true
+ write!(w, " == std::ptr::null_mut()").unwrap();
+ EmptyValExpectedTy::ReferenceAsPointer
},
_ => unimplemented!(),
}
}
/// Prints a suffix to determine if a variable is empty (ie was set by write_empty_rust_val).
- pub fn write_empty_rust_val_check<W: std::io::Write>(&self, w: &mut W, t: &syn::Type, var_access: &str) {
+ pub fn write_empty_rust_val_check<W: std::io::Write>(&self, generics: Option<&GenericTypes>, w: &mut W, t: &syn::Type, var_access: &str) {
match t {
syn::Type::Path(_) => {
write!(w, "{}", var_access).unwrap();
- self.write_empty_rust_val_check_suffix(w, t);
+ self.write_empty_rust_val_check_suffix(generics, w, t);
},
syn::Type::Array(a) => {
if let syn::Expr::Lit(l) = &a.len {
self.from_c_conversion_prefix_from_path(&arrty, false).unwrap(),
var_access,
self.from_c_conversion_suffix_from_path(&arrty, false).unwrap()).unwrap();
- self.write_empty_rust_val_check_suffix(w, t);
+ self.write_empty_rust_val_check_suffix(generics, w, t);
} else { unimplemented!(); }
} else { unimplemented!(); }
}
match t {
syn::Type::Path(p) => {
if p.qself.is_some() { unimplemented!(); }
- if let Some(gen_types) = generics {
- if let Some(resolved) = gen_types.maybe_resolve_path(&p.path) {
- return self.skip_path(resolved.0);
- }
- }
- if let Some(full_path) = self.maybe_resolve_path(&p.path) {
+ if let Some(full_path) = self.maybe_resolve_path(&p.path, generics) {
self.skip_path(&full_path)
} else { false }
},
match t {
syn::Type::Path(p) => {
if p.qself.is_some() { unimplemented!(); }
- if let Some(gen_types) = generics {
- if let Some(resolved) = gen_types.maybe_resolve_path(&p.path) {
- write!(w, "{}", self.no_arg_path_to_rust(resolved.0)).unwrap();
- return;
- }
- }
- if let Some(full_path) = self.maybe_resolve_path(&p.path) {
+ if let Some(full_path) = self.maybe_resolve_path(&p.path, generics) {
write!(w, "{}", self.no_arg_path_to_rust(&full_path)).unwrap();
}
},
ptr_for_ref, tupleconv, prefix, sliceconv, path_lookup, decl_lookup);
},
syn::Type::Path(p) => {
- if p.qself.is_some() || p.path.leading_colon.is_some() {
+ if p.qself.is_some() {
unimplemented!();
}
- if let Some(gen_types) = generics {
- if let Some((_, synpath)) = gen_types.maybe_resolve_path(&p.path) {
- let genpath = self.resolve_path(&synpath);
- assert!(!self.is_known_container(&genpath, is_ref) && !self.is_transparent_container(&genpath, is_ref));
- if let Some(c_type) = path_lookup(&genpath, is_ref, ptr_for_ref) {
- write!(w, "{}", c_type).unwrap();
- return;
- } else {
- let synident = single_ident_generic_path_to_ident(synpath).unwrap();
- if let Some(t) = self.crate_types.traits.get(&genpath) {
- decl_lookup(w, &DeclType::Trait(t), &genpath, is_ref, is_mut);
- return;
- } else if let Some(_) = self.imports.get(synident) {
- // crate_types lookup has to have succeeded:
- panic!("Failed to print inline conversion for {}", synident);
- } else if let Some(decl_type) = self.declared.get(synident) {
- decl_lookup(w, decl_type, &self.maybe_resolve_path(synpath).unwrap(), is_ref, is_mut);
- return;
- } else { unimplemented!(); }
- }
- }
- }
-
- let resolved_path = self.resolve_path(&p.path);
- if let Some(c_type) = path_lookup(&resolved_path, is_ref, ptr_for_ref) {
+ let resolved_path = self.resolve_path(&p.path, generics);
+ if let Some(aliased_type) = self.crate_types.type_aliases.get(&resolved_path) {
+ return self.write_conversion_inline_intern(w, aliased_type, None, is_ref, is_mut, ptr_for_ref, tupleconv, prefix, sliceconv, path_lookup, decl_lookup);
+ } else if let Some(c_type) = path_lookup(&resolved_path, is_ref, ptr_for_ref) {
write!(w, "{}", c_type).unwrap();
} else if self.crate_types.opaques.get(&resolved_path).is_some() {
decl_lookup(w, &DeclType::StructImported, &resolved_path, is_ref, is_mut);
} else if self.crate_types.mirrored_enums.get(&resolved_path).is_some() {
decl_lookup(w, &DeclType::MirroredEnum, &resolved_path, is_ref, is_mut);
+ } else if let Some(t) = self.crate_types.traits.get(&resolved_path) {
+ decl_lookup(w, &DeclType::Trait(t), &resolved_path, is_ref, is_mut);
} else if let Some(ident) = single_ident_generic_path_to_ident(&p.path) {
if let Some(_) = self.imports.get(ident) {
// crate_types lookup has to have succeeded:
} else if let Some(decl_type) = self.declared.get(ident) {
decl_lookup(w, decl_type, &self.maybe_resolve_ident(ident).unwrap(), is_ref, is_mut);
} else { unimplemented!(); }
- }
+ } else { unimplemented!(); }
},
syn::Type::Array(a) => {
// We assume all arrays contain only [int_literal; X]s.
// We assume all slices contain only literals or references.
// This may result in some outputs not compiling.
if let syn::Type::Path(p) = &*s.elem {
- let resolved = self.resolve_path(&p.path);
+ let resolved = self.resolve_path(&p.path, generics);
assert!(self.is_primitive(&resolved));
write!(w, "{}", path_lookup("[u8]", is_ref, ptr_for_ref).unwrap()).unwrap();
} else if let syn::Type::Reference(r) = &*s.elem {
if let syn::Type::Path(p) = &*r.elem {
- write!(w, "{}", sliceconv(self.c_type_has_inner_from_path(&self.resolve_path(&p.path)))).unwrap();
+ write!(w, "{}", sliceconv(self.c_type_has_inner_from_path(&self.resolve_path(&p.path, generics)))).unwrap();
} else { unimplemented!(); }
+ } else if let syn::Type::Tuple(t) = &*s.elem {
+ assert!(!t.elems.is_empty());
+ if prefix {
+ write!(w, "&local_").unwrap();
+ } else {
+ let mut needs_map = false;
+ for e in t.elems.iter() {
+ if let syn::Type::Reference(_) = e {
+ needs_map = true;
+ }
+ }
+ if needs_map {
+ write!(w, ".iter().map(|(").unwrap();
+ for i in 0..t.elems.len() {
+ write!(w, "{}{}", if i != 0 { ", " } else { "" }, ('a' as u8 + i as u8) as char).unwrap();
+ }
+ write!(w, ")| (").unwrap();
+ for (idx, e) in t.elems.iter().enumerate() {
+ if let syn::Type::Reference(_) = e {
+ write!(w, "{}{}", if idx != 0 { ", " } else { "" }, (idx as u8 + 'a' as u8) as char).unwrap();
+ } else if let syn::Type::Path(_) = e {
+ write!(w, "{}*{}", if idx != 0 { ", " } else { "" }, (idx as u8 + 'a' as u8) as char).unwrap();
+ } else { unimplemented!(); }
+ }
+ write!(w, ")).collect::<Vec<_>>()[..]").unwrap();
+ }
+ }
} else { unimplemented!(); }
},
syn::Type::Tuple(t) => {
DeclType::EnumIgnored|DeclType::StructImported if !is_ref =>
write!(w, "crate::{} {{ inner: Box::into_raw(Box::new(", decl_path).unwrap(),
DeclType::Trait(_) if is_ref => write!(w, "&").unwrap(),
+ DeclType::Trait(_) if !is_ref => {},
_ => panic!("{:?}", decl_path),
}
});
write!(w, ", is_owned: true }}").unwrap(),
DeclType::EnumIgnored|DeclType::StructImported if !is_ref => write!(w, ")), is_owned: true }}").unwrap(),
DeclType::Trait(_) if is_ref => {},
+ DeclType::Trait(_) => {
+ // This is used when we're converting a concrete Rust type into a C trait
+ // for use when a Rust trait method returns an associated type.
+ // Because all of our C traits implement From<RustTypesImplementingTraits>
+ // we can just call .into() here and be done.
+ write!(w, ".into()").unwrap()
+ },
_ => unimplemented!(),
});
}
}
if let syn::Type::Reference(t) = ty {
if let syn::Type::Path(p) = &*t.elem {
- self.c_type_has_inner_from_path(&self.resolve_path(&p.path))
+ self.c_type_has_inner_from_path(&self.resolve_path(&p.path, generics))
} else { false }
} else if let syn::Type::Path(p) = ty {
- self.c_type_has_inner_from_path(&self.resolve_path(&p.path))
+ self.c_type_has_inner_from_path(&self.resolve_path(&p.path, generics))
} else { false }
} else { true };
}
},
syn::Type::Path(p) => {
- if p.qself.is_some() || p.path.leading_colon.is_some() {
+ if p.qself.is_some() {
unimplemented!();
}
- if let Some(gen_types) = generics {
- if let Some(resolved) = gen_types.maybe_resolve_path(&p.path) {
- assert!(!self.is_known_container(&resolved.0, is_ref) && !self.is_transparent_container(&resolved.0, is_ref));
- if let Some((prefix, suffix)) = path_lookup(&resolved.0, is_ref) {
- write!(w, "let mut local_{} = {}{}{};", ident, prefix, var, suffix).unwrap();
- return true;
- } else { return false; }
- }
+ let resolved_path = self.resolve_path(&p.path, generics);
+ if let Some(aliased_type) = self.crate_types.type_aliases.get(&resolved_path) {
+ return self.write_conversion_new_var_intern(w, ident, var, aliased_type, None, is_ref, ptr_for_ref, to_c, path_lookup, container_lookup, var_prefix, var_suffix);
}
- let resolved_path = self.resolve_path(&p.path);
if self.is_known_container(&resolved_path, is_ref) || self.is_transparent_container(&resolved_path, is_ref) {
if let syn::PathArguments::AngleBracketed(args) = &p.path.segments.iter().next().unwrap().arguments {
convert_container!(resolved_path, args.args.len(), || args.args.iter().map(|arg| {
},
syn::Type::Slice(s) => {
if let syn::Type::Path(p) = &*s.elem {
- let resolved = self.resolve_path(&p.path);
+ let resolved = self.resolve_path(&p.path, generics);
assert!(self.is_primitive(&resolved));
let slice_path = format!("[{}]", resolved);
if let Some((prefix, suffix)) = path_lookup(&slice_path, true) {
is_ref = true;
convert_container!("Slice", 1, || tyref.iter());
unimplemented!("convert_container should return true as container_lookup should succeed for slices");
+ } else if let syn::Type::Tuple(t) = &*s.elem {
+ // When mapping into a temporary new var, we need to own all the underlying objects.
+ // Thus, we drop any references inside the tuple and convert with non-reference types.
+ let mut elems = syn::punctuated::Punctuated::new();
+ for elem in t.elems.iter() {
+ if let syn::Type::Reference(r) = elem {
+ elems.push((*r.elem).clone());
+ } else {
+ elems.push(elem.clone());
+ }
+ }
+ let ty = [syn::Type::Tuple(syn::TypeTuple {
+ paren_token: t.paren_token, elems
+ })];
+ is_ref = false;
+ ptr_for_ref = true;
+ convert_container!("Slice", 1, || ty.iter());
+ unimplemented!("convert_container should return true as container_lookup should succeed for slices");
} else { unimplemented!() }
},
syn::Type::Tuple(t) => {
// Opaque types with inner pointers shouldn't ever create new stack
// variables, so we don't handle it and just assert that it doesn't
// here.
- assert!(!self.c_type_has_inner_from_path(&self.resolve_path(&p.path)));
+ assert!(!self.c_type_has_inner_from_path(&self.resolve_path(&p.path, generics)));
}
}
}
}
if let syn::Type::Reference(t) = elem {
if let syn::Type::Path(p) = &*t.elem {
- self.c_type_has_inner_from_path(&self.resolve_path(&p.path))
+ self.c_type_has_inner_from_path(&self.resolve_path(&p.path, generics))
} else { false }
} else if let syn::Type::Path(p) = elem {
- self.c_type_has_inner_from_path(&self.resolve_path(&p.path))
+ self.c_type_has_inner_from_path(&self.resolve_path(&p.path, generics))
} else { false }
};
if idx != 0 { write!(w, ", ").unwrap(); }
pub fn write_to_c_conversion_new_var_inner<W: std::io::Write>(&self, w: &mut W, ident: &syn::Ident, var_access: &str, t: &syn::Type, generics: Option<&GenericTypes>, ptr_for_ref: bool) -> bool {
self.write_conversion_new_var_intern(w, ident, var_access, t, generics, false, ptr_for_ref, true,
&|a, b| self.to_c_conversion_new_var_from_path(a, b),
- &|a, b, c, d, e| self.to_c_conversion_container_new_var(a, b, c, d, e),
+ &|a, b, c, d, e| self.to_c_conversion_container_new_var(generics, a, b, c, d, e),
// We force ptr_for_ref here since we can't generate a ref on one line and use it later
&|a, b, c, d, e, f| self.write_to_c_conversion_inline_prefix_inner(a, b, c, d, e, f),
&|a, b, c, d, e, f| self.write_to_c_conversion_inline_suffix_inner(a, b, c, d, e, f))
pub fn write_from_c_conversion_new_var<W: std::io::Write>(&self, w: &mut W, ident: &syn::Ident, t: &syn::Type, generics: Option<&GenericTypes>) -> bool {
self.write_conversion_new_var_intern(w, ident, &format!("{}", ident), t, generics, false, false, false,
&|a, b| self.from_c_conversion_new_var_from_path(a, b),
- &|a, b, c, d, e| self.from_c_conversion_container_new_var(a, b, c, d, e),
+ &|a, b, c, d, e| self.from_c_conversion_container_new_var(generics, a, b, c, d, e),
// We force ptr_for_ref here since we can't generate a ref on one line and use it later
&|a, b, c, d, e, _f| self.write_from_c_conversion_prefix_inner(a, b, c, d, e),
&|a, b, c, d, e, _f| self.write_from_c_conversion_suffix_inner(a, b, c, d, e))
// *** C Container Type Equivalent and alias Printing ***
// ******************************************************
- fn write_template_constructor<W: std::io::Write>(&mut self, w: &mut W, container_type: &str, mangled_container: &str, args: &Vec<&syn::Type>, is_ref: bool) {
+ fn write_template_constructor<W: std::io::Write>(&mut self, w: &mut W, container_type: &str, mangled_container: &str, args: &Vec<&syn::Type>, generics: Option<&GenericTypes>, is_ref: bool) {
if container_type == "Result" {
assert_eq!(args.len(), 2);
macro_rules! write_fn {
($call: expr, $item: expr) => { {
write!(w, "#[no_mangle]\npub static {}_{}: extern \"C\" fn (", mangled_container, $call).unwrap();
if let syn::Type::Path(syn::TypePath { path, .. }) = $item {
- let resolved = self.resolve_path(path);
+ let resolved = self.resolve_path(path, generics);
if self.is_known_container(&resolved, is_ref) || self.is_transparent_container(&resolved, is_ref) {
- self.write_c_mangled_container_path_intern(w, Self::path_to_generic_args(path),
+ self.write_c_mangled_container_path_intern(w, Self::path_to_generic_args(path), generics,
&format!("{}", single_ident_generic_path_to_ident(path).unwrap()), is_ref, false, false, false);
} else {
- self.write_template_generics(w, &mut [$item].iter().map(|t| *t), is_ref, true);
+ self.write_template_generics(w, &mut [$item].iter().map(|t| *t), generics, is_ref, true);
}
} else if let syn::Type::Tuple(syn::TypeTuple { elems, .. }) = $item {
- self.write_c_mangled_container_path_intern(w, elems.iter().collect(),
+ self.write_c_mangled_container_path_intern(w, elems.iter().collect(), generics,
&format!("{}Tuple", elems.len()), is_ref, false, false, false);
} else { unimplemented!(); }
write!(w, ") -> {} =\n\t{}::CResultTempl::<", mangled_container, Self::container_templ_path()).unwrap();
- self.write_template_generics(w, &mut args.iter().map(|t| *t), is_ref, true);
+ self.write_template_generics(w, &mut args.iter().map(|t| *t), generics, is_ref, true);
writeln!(w, ">::{};\n", $call).unwrap();
} }
}
write!(w, "#[no_mangle]\npub extern \"C\" fn {}_new(", mangled_container).unwrap();
for (idx, gen) in args.iter().enumerate() {
write!(w, "{}{}: ", if idx != 0 { ", " } else { "" }, ('a' as u8 + idx as u8) as char).unwrap();
- self.write_c_type_intern(None, w, gen, false, false, false);
+ assert!(self.write_c_type_intern(w, gen, None, false, false, false));
}
writeln!(w, ") -> {} {{", mangled_container).unwrap();
- writeln!(w, "\t{} {{", mangled_container).unwrap();
+ write!(w, "\t{} {{ ", mangled_container).unwrap();
for idx in 0..args.len() {
- writeln!(w, "\t\t{}: Box::into_raw(Box::new({})),", ('a' as u8 + idx as u8) as char, ('a' as u8 + idx as u8) as char).unwrap();
+ write!(w, "{}, ", ('a' as u8 + idx as u8) as char).unwrap();
}
- writeln!(w, "\t}}\n}}\n").unwrap();
+ writeln!(w, "}}\n}}\n").unwrap();
} else {
writeln!(w, "").unwrap();
}
}
- fn write_template_generics<'b, W: std::io::Write>(&self, w: &mut W, args: &mut dyn Iterator<Item=&'b syn::Type>, is_ref: bool, in_crate: bool) {
+ fn write_template_generics<'b, W: std::io::Write>(&self, w: &mut W, args: &mut dyn Iterator<Item=&'b syn::Type>, generics: Option<&GenericTypes>, is_ref: bool, in_crate: bool) {
for (idx, t) in args.enumerate() {
if idx != 0 {
write!(w, ", ").unwrap();
write!(w, "u8").unwrap();
} else {
write!(w, "{}::C{}TupleTempl<", Self::container_templ_path(), tup.elems.len()).unwrap();
- self.write_template_generics(w, &mut tup.elems.iter(), is_ref, in_crate);
+ self.write_template_generics(w, &mut tup.elems.iter(), generics, is_ref, in_crate);
write!(w, ">").unwrap();
}
} else if let syn::Type::Path(p_arg) = t {
- let resolved_generic = self.resolve_path(&p_arg.path);
+ let resolved_generic = self.resolve_path(&p_arg.path, generics);
if self.is_primitive(&resolved_generic) {
write!(w, "{}", resolved_generic).unwrap();
} else if let Some(c_type) = self.c_type_from_path(&resolved_generic, is_ref, false) {
if let syn::PathArguments::AngleBracketed(args) = &p_arg.path.segments.iter().next().unwrap().arguments {
self.write_template_generics(w, &mut args.args.iter().map(|gen|
if let syn::GenericArgument::Type(t) = gen { t } else { unimplemented!() }),
- is_ref, in_crate);
+ generics, is_ref, in_crate);
} else { unimplemented!(); }
write!(w, ">").unwrap();
} else if resolved_generic == "Option" {
if let syn::PathArguments::AngleBracketed(args) = &p_arg.path.segments.iter().next().unwrap().arguments {
self.write_template_generics(w, &mut args.args.iter().map(|gen|
if let syn::GenericArgument::Type(t) = gen { t } else { unimplemented!() }),
- is_ref, in_crate);
+ generics, is_ref, in_crate);
} else { unimplemented!(); }
} else if in_crate {
write!(w, "{}", c_type).unwrap();
} else {
- self.write_rust_type(w, &t);
+ self.write_rust_type(w, generics, &t);
}
} else {
// If we just write out resolved_generic, it may mostly work, however for
}
} else if let syn::Type::Reference(r_arg) = t {
if let syn::Type::Path(p_arg) = &*r_arg.elem {
- let resolved = self.resolve_path(&p_arg.path);
- if single_ident_generic_path_to_ident(&p_arg.path).is_some() {
- if self.crate_types.opaques.get(&resolved).is_some() {
- write!(w, "crate::{}", resolved).unwrap();
- } else { unimplemented!(); }
- } else { unimplemented!(); }
+ let resolved = self.resolve_path(&p_arg.path, generics);
+ if self.crate_types.opaques.get(&resolved).is_some() {
+ write!(w, "crate::{}", resolved).unwrap();
+ } else {
+ let cty = self.c_type_from_path(&resolved, true, true).expect("Template generics should be opaque or have a predefined mapping");
+ w.write(cty.as_bytes()).unwrap();
+ }
} else { unimplemented!(); }
} else if let syn::Type::Array(a_arg) = t {
if let syn::Type::Path(p_arg) = &*a_arg.elem {
- let resolved = self.resolve_path(&p_arg.path);
+ let resolved = self.resolve_path(&p_arg.path, generics);
assert!(self.is_primitive(&resolved));
if let syn::Expr::Lit(syn::ExprLit { lit: syn::Lit::Int(len), .. }) = &a_arg.len {
write!(w, "{}",
}
}
}
- fn check_create_container(&mut self, mangled_container: String, container_type: &str, args: Vec<&syn::Type>, is_ref: bool) {
+ fn check_create_container(&mut self, mangled_container: String, container_type: &str, args: Vec<&syn::Type>, generics: Option<&GenericTypes>, is_ref: bool) {
if !self.crate_types.templates_defined.get(&mangled_container).is_some() {
self.crate_types.templates_defined.insert(mangled_container.clone(), true);
let mut created_container: Vec<u8> = Vec::new();
write!(&mut created_container, "#[no_mangle]\npub type {} = ", mangled_container).unwrap();
write!(&mut created_container, "{}::C{}Templ<", Self::container_templ_path(), container_type).unwrap();
- self.write_template_generics(&mut created_container, &mut args.iter().map(|t| *t), is_ref, true);
+ self.write_template_generics(&mut created_container, &mut args.iter().map(|t| *t), generics, is_ref, true);
writeln!(&mut created_container, ">;").unwrap();
write!(&mut created_container, "#[no_mangle]\npub static {}_free: extern \"C\" fn({}) = ", mangled_container, mangled_container).unwrap();
write!(&mut created_container, "{}::C{}Templ_free::<", Self::container_templ_path(), container_type).unwrap();
- self.write_template_generics(&mut created_container, &mut args.iter().map(|t| *t), is_ref, true);
+ self.write_template_generics(&mut created_container, &mut args.iter().map(|t| *t), generics, is_ref, true);
writeln!(&mut created_container, ">;").unwrap();
- self.write_template_constructor(&mut created_container, container_type, &mangled_container, &args, is_ref);
+ self.write_template_constructor(&mut created_container, container_type, &mangled_container, &args, generics, is_ref);
self.crate_types.template_file.write(&created_container).unwrap();
}
} else { unimplemented!(); }
}
fn write_c_mangled_container_path_intern<W: std::io::Write>
- (&mut self, w: &mut W, args: Vec<&syn::Type>, ident: &str, is_ref: bool, is_mut: bool, ptr_for_ref: bool, in_type: bool) -> bool {
+ (&mut self, w: &mut W, args: Vec<&syn::Type>, generics: Option<&GenericTypes>, ident: &str, is_ref: bool, is_mut: bool, ptr_for_ref: bool, in_type: bool) -> bool {
let mut mangled_type: Vec<u8> = Vec::new();
if !self.is_transparent_container(ident, is_ref) {
write!(w, "C{}_", ident).unwrap();
for arg in args.iter() {
macro_rules! write_path {
($p_arg: expr, $extra_write: expr) => {
- let subtype = self.resolve_path(&$p_arg.path);
+ let subtype = self.resolve_path(&$p_arg.path, generics);
if self.is_transparent_container(ident, is_ref) {
// We dont (yet) support primitives or containers inside transparent
// containers, so check for that first:
if self.is_known_container(&subtype, is_ref) { return false; }
if !in_type {
if self.c_type_has_inner_from_path(&subtype) {
- if !self.write_c_path_intern(w, &$p_arg.path, is_ref, is_mut, ptr_for_ref) { return false; }
+ if !self.write_c_path_intern(w, &$p_arg.path, generics, is_ref, is_mut, ptr_for_ref) { return false; }
} else {
- if !self.write_c_path_intern(w, &$p_arg.path, true, is_mut, true) { return false; }
+ // Option<T> needs to be converted to a *mut T, ie mut ptr-for-ref
+ if !self.write_c_path_intern(w, &$p_arg.path, generics, true, true, true) { return false; }
}
} else {
if $p_arg.path.segments.len() == 1 {
}
}
} else if self.is_known_container(&subtype, is_ref) || self.is_transparent_container(&subtype, is_ref) {
- if !self.write_c_mangled_container_path_intern(w, Self::path_to_generic_args(&$p_arg.path),
+ if !self.write_c_mangled_container_path_intern(w, Self::path_to_generic_args(&$p_arg.path), generics,
&subtype, is_ref, is_mut, ptr_for_ref, true) {
return false;
}
self.write_c_mangled_container_path_intern(&mut mangled_type, Self::path_to_generic_args(&$p_arg.path),
- &subtype, is_ref, is_mut, ptr_for_ref, true);
+ generics, &subtype, is_ref, is_mut, ptr_for_ref, true);
if let Some(w2) = $extra_write as Option<&mut Vec<u8>> {
self.write_c_mangled_container_path_intern(w2, Self::path_to_generic_args(&$p_arg.path),
- &subtype, is_ref, is_mut, ptr_for_ref, true);
+ generics, &subtype, is_ref, is_mut, ptr_for_ref, true);
}
- } else if let Some(id) = single_ident_generic_path_to_ident(&$p_arg.path) {
+ } else {
+ let id = &&$p_arg.path.segments.iter().rev().next().unwrap().ident;
write!(w, "{}", id).unwrap();
write!(mangled_type, "{}", id).unwrap();
if let Some(w2) = $extra_write as Option<&mut Vec<u8>> {
write!(w2, "{}", id).unwrap();
}
- } else { return false; }
+ }
}
}
if let syn::Type::Tuple(tuple) = arg {
for elem in tuple.elems.iter() {
if let syn::Type::Path(p) = elem {
write_path!(p, Some(&mut mangled_tuple_type));
+ } else if let syn::Type::Reference(refelem) = elem {
+ if let syn::Type::Path(p) = &*refelem.elem {
+ write_path!(p, Some(&mut mangled_tuple_type));
+ } else { return false; }
} else { return false; }
}
write!(w, "Z").unwrap();
write!(mangled_type, "Z").unwrap();
write!(mangled_tuple_type, "Z").unwrap();
self.check_create_container(String::from_utf8(mangled_tuple_type).unwrap(),
- &format!("{}Tuple", tuple.elems.len()), tuple.elems.iter().collect(), is_ref);
+ &format!("{}Tuple", tuple.elems.len()), tuple.elems.iter().collect(), generics, is_ref);
}
} else if let syn::Type::Path(p_arg) = arg {
write_path!(p_arg, None);
} else { return false; }
} else if let syn::Type::Array(a) = arg {
if let syn::Type::Path(p_arg) = &*a.elem {
- let resolved = self.resolve_path(&p_arg.path);
+ let resolved = self.resolve_path(&p_arg.path, generics);
if !self.is_primitive(&resolved) { return false; }
if let syn::Expr::Lit(syn::ExprLit { lit: syn::Lit::Int(len), .. }) = &a.len {
if self.c_type_from_path(&format!("[{}; {}]", resolved, len.base10_digits()), is_ref, ptr_for_ref).is_none() { return false; }
write!(mangled_type, "Z").unwrap();
// Make sure the type is actually defined:
- self.check_create_container(String::from_utf8(mangled_type).unwrap(), ident, args, is_ref);
+ self.check_create_container(String::from_utf8(mangled_type).unwrap(), ident, args, generics, is_ref);
true
}
- fn write_c_mangled_container_path<W: std::io::Write>(&mut self, w: &mut W, args: Vec<&syn::Type>, ident: &str, is_ref: bool, is_mut: bool, ptr_for_ref: bool) -> bool {
+ fn write_c_mangled_container_path<W: std::io::Write>(&mut self, w: &mut W, args: Vec<&syn::Type>, generics: Option<&GenericTypes>, ident: &str, is_ref: bool, is_mut: bool, ptr_for_ref: bool) -> bool {
if !self.is_transparent_container(ident, is_ref) {
write!(w, "{}::", Self::generated_container_path()).unwrap();
}
- self.write_c_mangled_container_path_intern(w, args, ident, is_ref, is_mut, ptr_for_ref, false)
+ self.write_c_mangled_container_path_intern(w, args, generics, ident, is_ref, is_mut, ptr_for_ref, false)
}
// **********************************
// *** C Type Equivalent Printing ***
// **********************************
- fn write_c_path_intern<W: std::io::Write>(&self, w: &mut W, path: &syn::Path, is_ref: bool, is_mut: bool, ptr_for_ref: bool) -> bool {
-//eprintln!("pcpi ({} {} {}): {:?}", is_ref, is_mut, ptr_for_ref, path);
- let full_path = match self.maybe_resolve_path(&path) {
+ fn write_c_path_intern<W: std::io::Write>(&self, w: &mut W, path: &syn::Path, generics: Option<&GenericTypes>, is_ref: bool, is_mut: bool, ptr_for_ref: bool) -> bool {
+ let full_path = match self.maybe_resolve_path(&path, generics) {
Some(path) => path, None => return false };
if let Some(c_type) = self.c_type_from_path(&full_path, is_ref, ptr_for_ref) {
write!(w, "{}", c_type).unwrap();
false
}
}
- fn write_c_type_intern<W: std::io::Write>(&mut self, generics: Option<&GenericTypes>, w: &mut W, t: &syn::Type, is_ref: bool, is_mut: bool, ptr_for_ref: bool) -> bool {
+ fn write_c_type_intern<W: std::io::Write>(&mut self, w: &mut W, t: &syn::Type, generics: Option<&GenericTypes>, is_ref: bool, is_mut: bool, ptr_for_ref: bool) -> bool {
match t {
syn::Type::Path(p) => {
- if p.qself.is_some() || p.path.leading_colon.is_some() {
+ if p.qself.is_some() {
return false;
}
- if let Some(gen_types) = generics {
- if let Some(resolved) = gen_types.maybe_resolve_path(&p.path) {
- if self.is_known_container(&resolved.0, is_ref) { return false; }
- if self.is_transparent_container(&resolved.0, is_ref) { return false; }
- return self.write_c_path_intern(w, &resolved.1, is_ref, is_mut, ptr_for_ref);
- }
- }
- if let Some(full_path) = self.maybe_resolve_path(&p.path) {
+ if let Some(full_path) = self.maybe_resolve_path(&p.path, generics) {
if self.is_known_container(&full_path, is_ref) || self.is_transparent_container(&full_path, is_ref) {
- return self.write_c_mangled_container_path(w, Self::path_to_generic_args(&p.path), &full_path, is_ref, is_mut, ptr_for_ref);
+ return self.write_c_mangled_container_path(w, Self::path_to_generic_args(&p.path), generics, &full_path, is_ref, is_mut, ptr_for_ref);
+ }
+ if let Some(aliased_type) = self.crate_types.type_aliases.get(&full_path).cloned() {
+ return self.write_c_type_intern(w, &aliased_type, None, is_ref, is_mut, ptr_for_ref);
}
}
- if p.path.leading_colon.is_some() { return false; }
- self.write_c_path_intern(w, &p.path, is_ref, is_mut, ptr_for_ref)
+ self.write_c_path_intern(w, &p.path, generics, is_ref, is_mut, ptr_for_ref)
},
syn::Type::Reference(r) => {
- if let Some(lft) = &r.lifetime {
- if format!("{}", lft.ident) != "static" { return false; }
- }
- self.write_c_type_intern(generics, w, &*r.elem, true, r.mutability.is_some(), ptr_for_ref)
+ self.write_c_type_intern(w, &*r.elem, generics, true, r.mutability.is_some(), ptr_for_ref)
},
syn::Type::Array(a) => {
if is_ref && is_mut {
write!(w, "*mut [").unwrap();
- if !self.write_c_type_intern(generics, w, &a.elem, false, false, ptr_for_ref) { return false; }
+ if !self.write_c_type_intern(w, &a.elem, generics, false, false, ptr_for_ref) { return false; }
} else if is_ref {
write!(w, "*const [").unwrap();
- if !self.write_c_type_intern(generics, w, &a.elem, false, false, ptr_for_ref) { return false; }
+ if !self.write_c_type_intern(w, &a.elem, generics, false, false, ptr_for_ref) { return false; }
} else {
let mut typecheck = Vec::new();
- if !self.write_c_type_intern(generics, &mut typecheck, &a.elem, false, false, ptr_for_ref) { return false; }
+ if !self.write_c_type_intern(&mut typecheck, &a.elem, generics, false, false, ptr_for_ref) { return false; }
if typecheck[..] != ['u' as u8, '8' as u8] { return false; }
}
if let syn::Expr::Lit(l) = &a.len {
syn::Type::Slice(s) => {
if !is_ref || is_mut { return false; }
if let syn::Type::Path(p) = &*s.elem {
- let resolved = self.resolve_path(&p.path);
+ let resolved = self.resolve_path(&p.path, generics);
if self.is_primitive(&resolved) {
write!(w, "{}::{}slice", Self::container_templ_path(), resolved).unwrap();
true
} else if let syn::Type::Reference(r) = &*s.elem {
if let syn::Type::Path(p) = &*r.elem {
// Slices with "real types" inside are mapped as the equivalent non-ref Vec
- let resolved = self.resolve_path(&p.path);
+ let resolved = self.resolve_path(&p.path, generics);
let mangled_container = if let Some(ident) = self.crate_types.opaques.get(&resolved) {
format!("CVec_{}Z", ident)
} else if let Some(en) = self.crate_types.mirrored_enums.get(&resolved) {
format!("CVec_{}Z", id)
} else { return false; };
write!(w, "{}::{}", Self::generated_container_path(), mangled_container).unwrap();
- self.check_create_container(mangled_container, "Vec", vec![&*r.elem], false);
+ self.check_create_container(mangled_container, "Vec", vec![&*r.elem], generics, false);
true
} else { false }
+ } else if let syn::Type::Tuple(_) = &*s.elem {
+ let mut args = syn::punctuated::Punctuated::new();
+ args.push(syn::GenericArgument::Type((*s.elem).clone()));
+ let mut segments = syn::punctuated::Punctuated::new();
+ segments.push(syn::PathSegment {
+ ident: syn::Ident::new("Vec", Span::call_site()),
+ arguments: syn::PathArguments::AngleBracketed(syn::AngleBracketedGenericArguments {
+ colon2_token: None, lt_token: syn::Token![<](Span::call_site()), args, gt_token: syn::Token![>](Span::call_site()),
+ })
+ });
+ self.write_c_type_intern(w, &syn::Type::Path(syn::TypePath { qself: None, path: syn::Path { leading_colon: None, segments } }), generics, false, is_mut, ptr_for_ref)
} else { false }
},
syn::Type::Tuple(t) => {
if t.elems.len() == 0 {
true
} else {
- self.write_c_mangled_container_path(w, t.elems.iter().collect(),
+ self.write_c_mangled_container_path(w, t.elems.iter().collect(), generics,
&format!("{}Tuple", t.elems.len()), is_ref, is_mut, ptr_for_ref)
}
},
}
}
pub fn write_c_type<W: std::io::Write>(&mut self, w: &mut W, t: &syn::Type, generics: Option<&GenericTypes>, ptr_for_ref: bool) {
- assert!(self.write_c_type_intern(generics, w, t, false, false, ptr_for_ref));
+ assert!(self.write_c_type_intern(w, t, generics, false, false, ptr_for_ref));
}
pub fn understood_c_path(&mut self, p: &syn::Path) -> bool {
if p.leading_colon.is_some() { return false; }
- self.write_c_path_intern(&mut std::io::sink(), p, false, false, false)
+ self.write_c_path_intern(&mut std::io::sink(), p, None, false, false, false)
}
pub fn understood_c_type(&mut self, t: &syn::Type, generics: Option<&GenericTypes>) -> bool {
- self.write_c_type_intern(generics, &mut std::io::sink(), t, false, false, false)
+ self.write_c_type_intern(&mut std::io::sink(), t, generics, false, false, false)
}
}