use std::collections::HashMap; use quote::{quote, ToTokens}; use crate::attrs::ExportScope; use crate::function::ExportedFn; use crate::module::Module; pub(crate) type ExportedConst = (String, syn::Expr); pub(crate) fn generate_body( fns: &mut [ExportedFn], consts: &[ExportedConst], submodules: &mut [Module], parent_scope: &ExportScope, ) -> proc_macro2::TokenStream { let mut set_fn_stmts: Vec = Vec::new(); let mut set_const_stmts: Vec = Vec::new(); let mut add_mod_blocks: Vec = Vec::new(); let mut set_mod_blocks: Vec = Vec::new(); let str_type_path = syn::parse2::(quote! { str }).unwrap(); for (const_name, const_expr) in consts { let const_literal = syn::LitStr::new(&const_name, proc_macro2::Span::call_site()); set_const_stmts.push( syn::parse2::(quote! { m.set_var(#const_literal, #const_expr); }) .unwrap(), ); } for itemmod in submodules { itemmod.update_scope(&parent_scope); if itemmod.skipped() { continue; } let module_name: &syn::Ident = itemmod.module_name().unwrap(); let exported_name: syn::LitStr = if let Some(name) = itemmod.exported_name() { syn::LitStr::new(&name, proc_macro2::Span::call_site()) } else { syn::LitStr::new(&module_name.to_string(), proc_macro2::Span::call_site()) }; let cfg_attrs: Vec<&syn::Attribute> = itemmod .attrs() .unwrap() .iter() .filter(|&a| a.path.get_ident().map(|i| *i == "cfg").unwrap_or(false)) .collect(); add_mod_blocks.push( syn::parse2::(quote! { #(#cfg_attrs)* { m.set_sub_module(#exported_name, self::#module_name::rhai_module_generate()); } }) .unwrap(), ); set_mod_blocks.push( syn::parse2::(quote! { #(#cfg_attrs)* { self::#module_name::rhai_generate_into_module(m); } }) .unwrap(), ); } // NB: these are token streams, because reparsing messes up "> >" vs ">>" let mut gen_fn_tokens: Vec = Vec::new(); for function in fns { function.update_scope(&parent_scope); if function.skipped() { continue; } let fn_token_name = syn::Ident::new( &format!("{}_token", function.name().to_string()), function.name().span(), ); let reg_names = function.exported_names(); let fn_input_types: Vec = function .arg_list() .map(|fnarg| match fnarg { syn::FnArg::Receiver(_) => panic!("internal error: receiver fn outside impl!?"), syn::FnArg::Typed(syn::PatType { ref ty, .. }) => { let arg_type = match ty.as_ref() { syn::Type::Reference(syn::TypeReference { mutability: None, ref elem, .. }) => match elem.as_ref() { syn::Type::Path(ref p) if p.path == str_type_path => { syn::parse2::(quote! { ImmutableString }) .unwrap() } _ => panic!("internal error: non-string shared reference!?"), }, syn::Type::Reference(syn::TypeReference { mutability: Some(_), ref elem, .. }) => match elem.as_ref() { syn::Type::Path(ref p) => syn::parse2::(quote! { #p }) .unwrap(), _ => panic!("internal error: non-string shared reference!?"), }, t => t.clone(), }; syn::parse2::(quote! { core::any::TypeId::of::<#arg_type>()}) .unwrap() } }) .collect(); for fn_literal in reg_names { set_fn_stmts.push( syn::parse2::(quote! { m.set_fn(#fn_literal, FnAccess::Public, &[#(#fn_input_types),*], CallableFunction::from_plugin(#fn_token_name())); }) .unwrap(), ); } gen_fn_tokens.push(quote! { #[allow(non_camel_case_types)] struct #fn_token_name(); }); gen_fn_tokens.push(function.generate_impl(&fn_token_name.to_string())); gen_fn_tokens.push(function.generate_callable(&fn_token_name.to_string())); gen_fn_tokens.push(function.generate_input_types(&fn_token_name.to_string())); } let mut generate_fncall = syn::parse2::(quote! { pub mod generate_info { #[allow(unused_imports)] use super::*; #[allow(unused_mut)] pub fn rhai_module_generate() -> Module { let mut m = Module::new(); #(#set_fn_stmts)* #(#set_const_stmts)* #(#add_mod_blocks)* m } pub fn rhai_generate_into_module(m: &mut Module) { #(#set_fn_stmts)* #(#set_const_stmts)* #(#set_mod_blocks)* } } }) .unwrap(); let (_, generate_call_content) = generate_fncall.content.take().unwrap(); quote! { #(#generate_call_content)* #(#gen_fn_tokens)* } } pub(crate) fn check_rename_collisions(fns: &Vec) -> Result<(), syn::Error> { let mut renames = HashMap::::new(); let mut names = HashMap::::new(); for itemfn in fns.iter() { if let Some(ref names) = itemfn.params().name { for name in names { let current_span = itemfn.params().span.as_ref().unwrap(); let key = itemfn.arg_list().fold(name.clone(), |mut argstr, fnarg| { let type_string: String = match fnarg { syn::FnArg::Receiver(_) => { unimplemented!("receiver rhai_fns not implemented") } syn::FnArg::Typed(syn::PatType { ref ty, .. }) => { ty.as_ref().to_token_stream().to_string() } }; argstr.push('.'); argstr.push_str(&type_string); argstr }); if let Some(other_span) = renames.insert(key, *current_span) { let mut err = syn::Error::new( *current_span, format!("duplicate Rhai signature for '{}'", &name), ); err.combine(syn::Error::new( other_span, format!("duplicated function renamed '{}'", &name), )); return Err(err); } } } else { let ident = itemfn.name(); if let Some(other_span) = names.insert(ident.to_string(), ident.span()) { let mut err = syn::Error::new( ident.span(), format!("duplicate function '{}'", ident.to_string()), ); err.combine(syn::Error::new( other_span, format!("duplicated function '{}'", ident.to_string()), )); return Err(err); } } } for (new_name, attr_span) in renames.drain() { let new_name = new_name.split('.').next().unwrap(); if let Some(fn_span) = names.get(new_name) { let mut err = syn::Error::new( attr_span, format!("duplicate Rhai signature for '{}'", &new_name), ); err.combine(syn::Error::new( *fn_span, format!("duplicated function '{}'", &new_name), )); return Err(err); } } Ok(()) }