use proc_macro::TokenStream; use quote::{format_ident, quote}; use std::mem; use syn::{ parse_macro_input, parse_quote, spanned::Spanned as _, AttributeArgs, FnArg, ItemFn, Lit, Meta, NestedMeta, Type, }; #[proc_macro_attribute] pub fn test(args: TokenStream, function: TokenStream) -> TokenStream { let mut namespace = format_ident!("gpui"); let args = syn::parse_macro_input!(args as AttributeArgs); let mut max_retries = 0; let mut num_iterations = 1; let mut starting_seed = 0; let mut detect_nondeterminism = false; for arg in args { match arg { NestedMeta::Meta(Meta::Path(name)) if name.get_ident().map_or(false, |n| n == "self") => { namespace = format_ident!("crate"); } NestedMeta::Meta(Meta::NameValue(meta)) => { let key_name = meta.path.get_ident().map(|i| i.to_string()); let result = (|| { match key_name.as_deref() { Some("detect_nondeterminism") => { detect_nondeterminism = parse_bool(&meta.lit)? } Some("retries") => max_retries = parse_int(&meta.lit)?, Some("iterations") => num_iterations = parse_int(&meta.lit)?, Some("seed") => starting_seed = parse_int(&meta.lit)?, _ => { return Err(TokenStream::from( syn::Error::new(meta.path.span(), "invalid argument") .into_compile_error(), )) } } Ok(()) })(); if let Err(tokens) = result { return tokens; } } other => { return TokenStream::from( syn::Error::new_spanned(other, "invalid argument").into_compile_error(), ) } } } let mut inner_fn = parse_macro_input!(function as ItemFn); if max_retries > 0 && num_iterations > 1 { return TokenStream::from( syn::Error::new_spanned(inner_fn, "retries and randomized iterations can't be mixed") .into_compile_error(), ); } let inner_fn_attributes = mem::take(&mut inner_fn.attrs); let inner_fn_name = format_ident!("_{}", inner_fn.sig.ident); let outer_fn_name = mem::replace(&mut inner_fn.sig.ident, inner_fn_name.clone()); let mut outer_fn: ItemFn = if inner_fn.sig.asyncness.is_some() { // Pass to the test function the number of app contexts that it needs, // based on its parameter list. let mut cx_vars = proc_macro2::TokenStream::new(); let mut cx_teardowns = proc_macro2::TokenStream::new(); let mut inner_fn_args = proc_macro2::TokenStream::new(); for (ix, arg) in inner_fn.sig.inputs.iter().enumerate() { if let FnArg::Typed(arg) = arg { if let Type::Path(ty) = &*arg.ty { let last_segment = ty.path.segments.last(); match last_segment.map(|s| s.ident.to_string()).as_deref() { Some("StdRng") => { inner_fn_args.extend(quote!(rand::SeedableRng::seed_from_u64(seed),)); continue; } Some("Arc") => { if let syn::PathArguments::AngleBracketed(args) = &last_segment.unwrap().arguments { if let Some(syn::GenericArgument::Type(syn::Type::Path(ty))) = args.args.last() { let last_segment = ty.path.segments.last(); if let Some("Deterministic") = last_segment.map(|s| s.ident.to_string()).as_deref() { inner_fn_args.extend(quote!(deterministic.clone(),)); continue; } } } } _ => {} } } else if let Type::Reference(ty) = &*arg.ty { if let Type::Path(ty) = &*ty.elem { let last_segment = ty.path.segments.last(); if let Some("TestAppContext") = last_segment.map(|s| s.ident.to_string()).as_deref() { let first_entity_id = ix * 100_000; let cx_varname = format_ident!("cx_{}", ix); cx_vars.extend(quote!( let mut #cx_varname = #namespace::TestAppContext::new( foreground_platform.clone(), cx.platform().clone(), deterministic.build_foreground(#ix), deterministic.build_background(), cx.font_cache().clone(), cx.leak_detector(), #first_entity_id, stringify!(#outer_fn_name).to_string(), ); )); cx_teardowns.extend(quote!( #cx_varname.update(|cx| cx.remove_all_windows()); deterministic.run_until_parked(); #cx_varname.update(|cx| cx.clear_globals()); )); inner_fn_args.extend(quote!(&mut #cx_varname,)); continue; } } } } return TokenStream::from( syn::Error::new_spanned(arg, "invalid argument").into_compile_error(), ); } parse_quote! { #[test] fn #outer_fn_name() { #inner_fn #namespace::test::run_test( #num_iterations as u64, #starting_seed as u64, #max_retries, #detect_nondeterminism, &mut |cx, foreground_platform, deterministic, seed| { #cx_vars cx.foreground().run(#inner_fn_name(#inner_fn_args)); #cx_teardowns }, stringify!(#outer_fn_name).to_string(), ); } } } else { let mut inner_fn_args = proc_macro2::TokenStream::new(); for arg in inner_fn.sig.inputs.iter() { if let FnArg::Typed(arg) = arg { if let Type::Path(ty) = &*arg.ty { let last_segment = ty.path.segments.last(); if let Some("StdRng") = last_segment.map(|s| s.ident.to_string()).as_deref() { inner_fn_args.extend(quote!(rand::SeedableRng::seed_from_u64(seed),)); } } else { inner_fn_args.extend(quote!(cx,)); } } else { return TokenStream::from( syn::Error::new_spanned(arg, "invalid argument").into_compile_error(), ); } } parse_quote! { #[test] fn #outer_fn_name() { #inner_fn #namespace::test::run_test( #num_iterations as u64, #starting_seed as u64, #max_retries, #detect_nondeterminism, &mut |cx, _, _, seed| #inner_fn_name(#inner_fn_args), stringify!(#outer_fn_name).to_string(), ); } } }; outer_fn.attrs.extend(inner_fn_attributes); TokenStream::from(quote!(#outer_fn)) } fn parse_int(literal: &Lit) -> Result { let result = if let Lit::Int(int) = &literal { int.base10_parse() } else { Err(syn::Error::new(literal.span(), "must be an integer")) }; result.map_err(|err| TokenStream::from(err.into_compile_error())) } fn parse_bool(literal: &Lit) -> Result { let result = if let Lit::Bool(result) = &literal { Ok(result.value) } else { Err(syn::Error::new(literal.span(), "must be a boolean")) }; result.map_err(|err| TokenStream::from(err.into_compile_error())) }