// Copyright 2012-2013 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. //! This module contains the "cleaned" pieces of the AST, and the functions //! that clean them. pub use self::ImplMethod::*; pub use self::Type::*; pub use self::PrimitiveType::*; pub use self::TypeKind::*; pub use self::StructField::*; pub use self::VariantKind::*; pub use self::Mutability::*; pub use self::ViewItemInner::*; pub use self::ViewPath::*; pub use self::ItemEnum::*; pub use self::Attribute::*; pub use self::TyParamBound::*; pub use self::SelfTy::*; pub use self::FunctionRetTy::*; pub use self::TraitMethod::*; use syntax; use syntax::ast; use syntax::ast_util; use syntax::ast_util::PostExpansionMethod; use syntax::attr; use syntax::attr::{AttributeMethods, AttrMetaMethods}; use syntax::codemap::{DUMMY_SP, Pos, Spanned}; use syntax::parse::token::InternedString; use syntax::parse::token; use syntax::ptr::P; use rustc_trans::back::link; use rustc::metadata::cstore; use rustc::metadata::csearch; use rustc::metadata::decoder; use rustc::middle::def; use rustc::middle::subst::{mod, ParamSpace, VecPerParamSpace}; use rustc::middle::ty; use rustc::middle::stability; use rustc::session::config; use std::rc::Rc; use std::u32; use std::str::Str as StrTrait; // Conflicts with Str variant use std::char::Char as CharTrait; // Conflicts with Char variant use std::path::Path as FsPath; // Conflicts with Path struct use core::DocContext; use doctree; use visit_ast; /// A stable identifier to the particular version of JSON output. /// Increment this when the `Crate` and related structures change. pub static SCHEMA_VERSION: &'static str = "0.8.3"; mod inline; // extract the stability index for a node from tcx, if possible fn get_stability(cx: &DocContext, def_id: ast::DefId) -> Option { cx.tcx_opt().and_then(|tcx| stability::lookup(tcx, def_id)).clean(cx) } pub trait Clean { fn clean(&self, cx: &DocContext) -> T; } impl, U> Clean> for Vec { fn clean(&self, cx: &DocContext) -> Vec { self.iter().map(|x| x.clean(cx)).collect() } } impl, U> Clean> for VecPerParamSpace { fn clean(&self, cx: &DocContext) -> VecPerParamSpace { self.map(|x| x.clean(cx)) } } impl, U> Clean for P { fn clean(&self, cx: &DocContext) -> U { (**self).clean(cx) } } impl, U> Clean for Rc { fn clean(&self, cx: &DocContext) -> U { (**self).clean(cx) } } impl, U> Clean> for Option { fn clean(&self, cx: &DocContext) -> Option { match self { &None => None, &Some(ref v) => Some(v.clean(cx)) } } } impl, U> Clean> for syntax::owned_slice::OwnedSlice { fn clean(&self, cx: &DocContext) -> Vec { self.iter().map(|x| x.clean(cx)).collect() } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct Crate { pub name: String, pub src: FsPath, pub module: Option, pub externs: Vec<(ast::CrateNum, ExternalCrate)>, pub primitives: Vec, } impl<'a, 'tcx> Clean for visit_ast::RustdocVisitor<'a, 'tcx> { fn clean(&self, cx: &DocContext) -> Crate { let mut externs = Vec::new(); cx.sess().cstore.iter_crate_data(|n, meta| { externs.push((n, meta.clean(cx))); }); externs.sort_by(|&(a, _), &(b, _)| a.cmp(&b)); // Figure out the name of this crate let input = config::Input::File(cx.src.clone()); let name = link::find_crate_name(None, self.attrs.as_slice(), &input); // Clean the crate, translating the entire libsyntax AST to one that is // understood by rustdoc. let mut module = self.module.clean(cx); // Collect all inner modules which are tagged as implementations of // primitives. // // Note that this loop only searches the top-level items of the crate, // and this is intentional. If we were to search the entire crate for an // item tagged with `#[doc(primitive)]` then we we would also have to // search the entirety of external modules for items tagged // `#[doc(primitive)]`, which is a pretty inefficient process (decoding // all that metadata unconditionally). // // In order to keep the metadata load under control, the // `#[doc(primitive)]` feature is explicitly designed to only allow the // primitive tags to show up as the top level items in a crate. // // Also note that this does not attempt to deal with modules tagged // duplicately for the same primitive. This is handled later on when // rendering by delegating everything to a hash map. let mut primitives = Vec::new(); { let m = match module.inner { ModuleItem(ref mut m) => m, _ => unreachable!(), }; let mut tmp = Vec::new(); for child in m.items.iter_mut() { match child.inner { ModuleItem(..) => {} _ => continue, } let prim = match PrimitiveType::find(child.attrs.as_slice()) { Some(prim) => prim, None => continue, }; primitives.push(prim); tmp.push(Item { source: Span::empty(), name: Some(prim.to_url_str().to_string()), attrs: child.attrs.clone(), visibility: Some(ast::Public), stability: None, def_id: ast_util::local_def(prim.to_node_id()), inner: PrimitiveItem(prim), }); } m.items.extend(tmp.into_iter()); } Crate { name: name.to_string(), src: cx.src.clone(), module: Some(module), externs: externs, primitives: primitives, } } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct ExternalCrate { pub name: String, pub attrs: Vec, pub primitives: Vec, } impl Clean for cstore::crate_metadata { fn clean(&self, cx: &DocContext) -> ExternalCrate { let mut primitives = Vec::new(); cx.tcx_opt().map(|tcx| { csearch::each_top_level_item_of_crate(&tcx.sess.cstore, self.cnum, |def, _, _| { let did = match def { decoder::DlDef(def::DefMod(did)) => did, _ => return }; let attrs = inline::load_attrs(cx, tcx, did); PrimitiveType::find(attrs.as_slice()).map(|prim| primitives.push(prim)); }) }); ExternalCrate { name: self.name.to_string(), attrs: decoder::get_crate_attributes(self.data()).clean(cx), primitives: primitives, } } } /// Anything with a source location and set of attributes and, optionally, a /// name. That is, anything that can be documented. This doesn't correspond /// directly to the AST's concept of an item; it's a strict superset. #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct Item { /// Stringified span pub source: Span, /// Not everything has a name. E.g., impls pub name: Option, pub attrs: Vec , pub inner: ItemEnum, pub visibility: Option, pub def_id: ast::DefId, pub stability: Option, } impl Item { /// Finds the `doc` attribute as a List and returns the list of attributes /// nested inside. pub fn doc_list<'a>(&'a self) -> Option<&'a [Attribute]> { for attr in self.attrs.iter() { match *attr { List(ref x, ref list) if "doc" == *x => { return Some(list.as_slice()); } _ => {} } } return None; } /// Finds the `doc` attribute as a NameValue and returns the corresponding /// value found. pub fn doc_value<'a>(&'a self) -> Option<&'a str> { for attr in self.attrs.iter() { match *attr { NameValue(ref x, ref v) if "doc" == *x => { return Some(v.as_slice()); } _ => {} } } return None; } pub fn is_hidden_from_doc(&self) -> bool { match self.doc_list() { Some(ref l) => { for innerattr in l.iter() { match *innerattr { Word(ref s) if "hidden" == *s => { return true } _ => (), } } }, None => () } return false; } pub fn is_mod(&self) -> bool { match self.inner { ModuleItem(..) => true, _ => false } } pub fn is_trait(&self) -> bool { match self.inner { TraitItem(..) => true, _ => false } } pub fn is_struct(&self) -> bool { match self.inner { StructItem(..) => true, _ => false } } pub fn is_enum(&self) -> bool { match self.inner { EnumItem(..) => true, _ => false } } pub fn is_fn(&self) -> bool { match self.inner { FunctionItem(..) => true, _ => false } } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub enum ItemEnum { StructItem(Struct), EnumItem(Enum), FunctionItem(Function), ModuleItem(Module), TypedefItem(Typedef), StaticItem(Static), ConstantItem(Constant), TraitItem(Trait), ImplItem(Impl), /// `use` and `extern crate` ViewItemItem(ViewItem), /// A method signature only. Used for required methods in traits (ie, /// non-default-methods). TyMethodItem(TyMethod), /// A method with a body. MethodItem(Method), StructFieldItem(StructField), VariantItem(Variant), /// `fn`s from an extern block ForeignFunctionItem(Function), /// `static`s from an extern block ForeignStaticItem(Static), MacroItem(Macro), PrimitiveItem(PrimitiveType), AssociatedTypeItem(TyParam), } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct Module { pub items: Vec, pub is_crate: bool, } impl Clean for doctree::Module { fn clean(&self, cx: &DocContext) -> Item { let name = if self.name.is_some() { self.name.unwrap().clean(cx) } else { "".to_string() }; let mut foreigns = Vec::new(); for subforeigns in self.foreigns.clean(cx).into_iter() { for foreign in subforeigns.into_iter() { foreigns.push(foreign) } } let items: Vec > = vec!( self.structs.clean(cx), self.enums.clean(cx), self.fns.clean(cx), foreigns, self.mods.clean(cx), self.typedefs.clean(cx), self.statics.clean(cx), self.constants.clean(cx), self.traits.clean(cx), self.impls.clean(cx), self.view_items.clean(cx).into_iter() .flat_map(|s| s.into_iter()).collect(), self.macros.clean(cx), ); // determine if we should display the inner contents or // the outer `mod` item for the source code. let whence = { let cm = cx.sess().codemap(); let outer = cm.lookup_char_pos(self.where_outer.lo); let inner = cm.lookup_char_pos(self.where_inner.lo); if outer.file.start_pos == inner.file.start_pos { // mod foo { ... } self.where_outer } else { // mod foo; (and a separate FileMap for the contents) self.where_inner } }; Item { name: Some(name), attrs: self.attrs.clean(cx), source: whence.clean(cx), visibility: self.vis.clean(cx), stability: self.stab.clean(cx), def_id: ast_util::local_def(self.id), inner: ModuleItem(Module { is_crate: self.is_crate, items: items.iter() .flat_map(|x| x.iter().map(|x| (*x).clone())) .collect(), }) } } } #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub enum Attribute { Word(String), List(String, Vec ), NameValue(String, String) } impl Clean for ast::MetaItem { fn clean(&self, cx: &DocContext) -> Attribute { match self.node { ast::MetaWord(ref s) => Word(s.get().to_string()), ast::MetaList(ref s, ref l) => { List(s.get().to_string(), l.clean(cx)) } ast::MetaNameValue(ref s, ref v) => { NameValue(s.get().to_string(), lit_to_string(v)) } } } } impl Clean for ast::Attribute { fn clean(&self, cx: &DocContext) -> Attribute { self.with_desugared_doc(|a| a.node.value.clean(cx)) } } // This is a rough approximation that gets us what we want. impl attr::AttrMetaMethods for Attribute { fn name(&self) -> InternedString { match *self { Word(ref n) | List(ref n, _) | NameValue(ref n, _) => { token::intern_and_get_ident(n.as_slice()) } } } fn value_str(&self) -> Option { match *self { NameValue(_, ref v) => { Some(token::intern_and_get_ident(v.as_slice())) } _ => None, } } fn meta_item_list<'a>(&'a self) -> Option<&'a [P]> { None } } impl<'a> attr::AttrMetaMethods for &'a Attribute { fn name(&self) -> InternedString { (**self).name() } fn value_str(&self) -> Option { (**self).value_str() } fn meta_item_list(&self) -> Option<&[P]> { None } } #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub struct TyParam { pub name: String, pub did: ast::DefId, pub bounds: Vec, pub default: Option, /// An optional default bound on the parameter which is unbound, like `Sized?` pub default_unbound: Option } impl Clean for ast::TyParam { fn clean(&self, cx: &DocContext) -> TyParam { TyParam { name: self.ident.clean(cx), did: ast::DefId { krate: ast::LOCAL_CRATE, node: self.id }, bounds: self.bounds.clean(cx), default: self.default.clean(cx), default_unbound: self.unbound.clean(cx) } } } impl<'tcx> Clean for ty::TypeParameterDef<'tcx> { fn clean(&self, cx: &DocContext) -> TyParam { cx.external_typarams.borrow_mut().as_mut().unwrap() .insert(self.def_id, self.name.clean(cx)); let (bounds, default_unbound) = self.bounds.clean(cx); TyParam { name: self.name.clean(cx), did: self.def_id, bounds: bounds, default: self.default.clean(cx), default_unbound: default_unbound } } } #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub enum TyParamBound { RegionBound(Lifetime), TraitBound(PolyTrait) } impl Clean for ast::TyParamBound { fn clean(&self, cx: &DocContext) -> TyParamBound { match *self { ast::RegionTyParamBound(lt) => RegionBound(lt.clean(cx)), ast::TraitTyParamBound(ref t) => TraitBound(t.clean(cx)), } } } impl Clean> for ty::ExistentialBounds { fn clean(&self, cx: &DocContext) -> Vec { let mut vec = vec![]; self.region_bound.clean(cx).map(|b| vec.push(RegionBound(b))); for bb in self.builtin_bounds.iter() { vec.push(bb.clean(cx)); } vec } } fn external_path_params(cx: &DocContext, trait_did: Option, substs: &subst::Substs) -> PathParameters { use rustc::middle::ty::sty; let lifetimes = substs.regions().get_slice(subst::TypeSpace) .iter() .filter_map(|v| v.clean(cx)) .collect(); let types = substs.types.get_slice(subst::TypeSpace).to_vec(); match (trait_did, cx.tcx_opt()) { // Attempt to sugar an external path like Fn<(A, B,), C> to Fn(A, B) -> C (Some(did), Some(ref tcx)) if tcx.lang_items.fn_trait_kind(did).is_some() => { assert_eq!(types.len(), 2); let inputs = match types[0].sty { sty::ty_tup(ref tys) => tys.iter().map(|t| t.clean(cx)).collect(), _ => { return PathParameters::AngleBracketed { lifetimes: lifetimes, types: types.clean(cx) } } }; let output = match types[1].sty { sty::ty_tup(ref v) if v.is_empty() => None, // -> () _ => Some(types[1].clean(cx)) }; PathParameters::Parenthesized { inputs: inputs, output: output } }, (_, _) => { PathParameters::AngleBracketed { lifetimes: lifetimes, types: types.clean(cx), } } } } // trait_did should be set to a trait's DefId if called on a TraitRef, in order to sugar // from Fn<(A, B,), C> to Fn(A, B) -> C fn external_path(cx: &DocContext, name: &str, trait_did: Option, substs: &subst::Substs) -> Path { Path { global: false, segments: vec![PathSegment { name: name.to_string(), params: external_path_params(cx, trait_did, substs) }], } } impl Clean for ty::BuiltinBound { fn clean(&self, cx: &DocContext) -> TyParamBound { let tcx = match cx.tcx_opt() { Some(tcx) => tcx, None => return RegionBound(Lifetime::statik()) }; let empty = subst::Substs::empty(); let (did, path) = match *self { ty::BoundSend => (tcx.lang_items.send_trait().unwrap(), external_path(cx, "Send", None, &empty)), ty::BoundSized => (tcx.lang_items.sized_trait().unwrap(), external_path(cx, "Sized", None, &empty)), ty::BoundCopy => (tcx.lang_items.copy_trait().unwrap(), external_path(cx, "Copy", None, &empty)), ty::BoundSync => (tcx.lang_items.sync_trait().unwrap(), external_path(cx, "Sync", None, &empty)), }; let fqn = csearch::get_item_path(tcx, did); let fqn = fqn.into_iter().map(|i| i.to_string()).collect(); cx.external_paths.borrow_mut().as_mut().unwrap().insert(did, (fqn, TypeTrait)); TraitBound(PolyTrait { trait_: ResolvedPath { path: path, typarams: None, did: did, }, lifetimes: vec![] }) } } impl<'tcx> Clean for ty::PolyTraitRef<'tcx> { fn clean(&self, cx: &DocContext) -> TyParamBound { self.0.clean(cx) } } impl<'tcx> Clean for ty::TraitRef<'tcx> { fn clean(&self, cx: &DocContext) -> TyParamBound { let tcx = match cx.tcx_opt() { Some(tcx) => tcx, None => return RegionBound(Lifetime::statik()) }; let fqn = csearch::get_item_path(tcx, self.def_id); let fqn = fqn.into_iter().map(|i| i.to_string()) .collect::>(); let path = external_path(cx, fqn.last().unwrap().as_slice(), Some(self.def_id), &self.substs); cx.external_paths.borrow_mut().as_mut().unwrap().insert(self.def_id, (fqn, TypeTrait)); debug!("ty::TraitRef\n substs.types(TypeSpace): {}\n", self.substs.types.get_slice(ParamSpace::TypeSpace)); // collect any late bound regions let mut late_bounds = vec![]; for &ty_s in self.substs.types.get_slice(ParamSpace::TypeSpace).iter() { use rustc::middle::ty::{Region, sty}; if let sty::ty_tup(ref ts) = ty_s.sty { for &ty_s in ts.iter() { if let sty::ty_rptr(ref reg, _) = ty_s.sty { if let &Region::ReLateBound(_, _) = reg { debug!(" hit an ReLateBound {}", reg); if let Some(lt) = reg.clean(cx) { late_bounds.push(lt) } } } } } } TraitBound(PolyTrait { trait_: ResolvedPath { path: path, typarams: None, did: self.def_id, }, lifetimes: late_bounds }) } } // Returns (bounds, default_unbound) impl<'tcx> Clean<(Vec, Option)> for ty::ParamBounds<'tcx> { fn clean(&self, cx: &DocContext) -> (Vec, Option) { let mut v = Vec::new(); let mut has_sized_bound = false; for b in self.builtin_bounds.iter() { if b != ty::BoundSized { v.push(b.clean(cx)); } else { has_sized_bound = true; } } for t in self.trait_bounds.iter() { v.push(t.clean(cx)); } for r in self.region_bounds.iter().filter_map(|r| r.clean(cx)) { v.push(RegionBound(r)); } if has_sized_bound { (v, None) } else { let ty = match ty::BoundSized.clean(cx) { TraitBound(polyt) => polyt.trait_, _ => unreachable!() }; (v, Some(ty)) } } } impl<'tcx> Clean>> for subst::Substs<'tcx> { fn clean(&self, cx: &DocContext) -> Option> { let mut v = Vec::new(); v.extend(self.regions().iter().filter_map(|r| r.clean(cx)).map(RegionBound)); v.extend(self.types.iter().map(|t| TraitBound(PolyTrait { trait_: t.clean(cx), lifetimes: vec![] }))); if v.len() > 0 {Some(v)} else {None} } } #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub struct Lifetime(String); impl Lifetime { pub fn get_ref<'a>(&'a self) -> &'a str { let Lifetime(ref s) = *self; let s: &'a str = s.as_slice(); return s; } pub fn statik() -> Lifetime { Lifetime("'static".to_string()) } } impl Clean for ast::Lifetime { fn clean(&self, _: &DocContext) -> Lifetime { Lifetime(token::get_name(self.name).get().to_string()) } } impl Clean for ast::LifetimeDef { fn clean(&self, _: &DocContext) -> Lifetime { Lifetime(token::get_name(self.lifetime.name).get().to_string()) } } impl Clean for ty::RegionParameterDef { fn clean(&self, _: &DocContext) -> Lifetime { Lifetime(token::get_name(self.name).get().to_string()) } } impl Clean> for ty::Region { fn clean(&self, cx: &DocContext) -> Option { match *self { ty::ReStatic => Some(Lifetime::statik()), ty::ReLateBound(_, ty::BrNamed(_, name)) => Some(Lifetime(token::get_name(name).get().to_string())), ty::ReEarlyBound(_, _, _, name) => Some(Lifetime(name.clean(cx))), ty::ReLateBound(..) | ty::ReFree(..) | ty::ReScope(..) | ty::ReInfer(..) | ty::ReEmpty(..) => None } } } #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub enum WherePredicate { BoundPredicate { ty: Type, bounds: Vec }, RegionPredicate { lifetime: Lifetime, bounds: Vec}, // FIXME (#20041) EqPredicate } impl Clean for ast::WherePredicate { fn clean(&self, cx: &DocContext) -> WherePredicate { match *self { ast::WherePredicate::BoundPredicate(ref wbp) => { WherePredicate::BoundPredicate { ty: wbp.bounded_ty.clean(cx), bounds: wbp.bounds.clean(cx) } } ast::WherePredicate::RegionPredicate(ref wrp) => { WherePredicate::RegionPredicate { lifetime: wrp.lifetime.clean(cx), bounds: wrp.bounds.clean(cx) } } ast::WherePredicate::EqPredicate(_) => { WherePredicate::EqPredicate } } } } // maybe use a Generic enum and use ~[Generic]? #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub struct Generics { pub lifetimes: Vec, pub type_params: Vec, pub where_predicates: Vec } impl Clean for ast::Generics { fn clean(&self, cx: &DocContext) -> Generics { Generics { lifetimes: self.lifetimes.clean(cx), type_params: self.ty_params.clean(cx), where_predicates: self.where_clause.predicates.clean(cx) } } } impl<'a, 'tcx> Clean for (&'a ty::Generics<'tcx>, subst::ParamSpace) { fn clean(&self, cx: &DocContext) -> Generics { let (me, space) = *self; Generics { type_params: me.types.get_slice(space).to_vec().clean(cx), lifetimes: me.regions.get_slice(space).to_vec().clean(cx), where_predicates: vec![] } } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct Method { pub generics: Generics, pub self_: SelfTy, pub unsafety: ast::Unsafety, pub decl: FnDecl, } impl Clean for ast::Method { fn clean(&self, cx: &DocContext) -> Item { let all_inputs = &self.pe_fn_decl().inputs; let inputs = match self.pe_explicit_self().node { ast::SelfStatic => all_inputs.as_slice(), _ => all_inputs[1..] }; let decl = FnDecl { inputs: Arguments { values: inputs.iter().map(|x| x.clean(cx)).collect(), }, output: self.pe_fn_decl().output.clean(cx), attrs: Vec::new() }; Item { name: Some(self.pe_ident().clean(cx)), attrs: self.attrs.clean(cx), source: self.span.clean(cx), def_id: ast_util::local_def(self.id), visibility: self.pe_vis().clean(cx), stability: get_stability(cx, ast_util::local_def(self.id)), inner: MethodItem(Method { generics: self.pe_generics().clean(cx), self_: self.pe_explicit_self().node.clean(cx), unsafety: self.pe_unsafety().clone(), decl: decl, }), } } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct TyMethod { pub unsafety: ast::Unsafety, pub decl: FnDecl, pub generics: Generics, pub self_: SelfTy, } impl Clean for ast::TypeMethod { fn clean(&self, cx: &DocContext) -> Item { let inputs = match self.explicit_self.node { ast::SelfStatic => self.decl.inputs.as_slice(), _ => self.decl.inputs[1..] }; let decl = FnDecl { inputs: Arguments { values: inputs.iter().map(|x| x.clean(cx)).collect(), }, output: self.decl.output.clean(cx), attrs: Vec::new() }; Item { name: Some(self.ident.clean(cx)), attrs: self.attrs.clean(cx), source: self.span.clean(cx), def_id: ast_util::local_def(self.id), visibility: None, stability: get_stability(cx, ast_util::local_def(self.id)), inner: TyMethodItem(TyMethod { unsafety: self.unsafety.clone(), decl: decl, self_: self.explicit_self.node.clean(cx), generics: self.generics.clean(cx), }), } } } #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub enum SelfTy { SelfStatic, SelfValue, SelfBorrowed(Option, Mutability), SelfExplicit(Type), } impl Clean for ast::ExplicitSelf_ { fn clean(&self, cx: &DocContext) -> SelfTy { match *self { ast::SelfStatic => SelfStatic, ast::SelfValue(_) => SelfValue, ast::SelfRegion(ref lt, ref mt, _) => { SelfBorrowed(lt.clean(cx), mt.clean(cx)) } ast::SelfExplicit(ref typ, _) => SelfExplicit(typ.clean(cx)), } } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct Function { pub decl: FnDecl, pub generics: Generics, pub unsafety: ast::Unsafety, } impl Clean for doctree::Function { fn clean(&self, cx: &DocContext) -> Item { Item { name: Some(self.name.clean(cx)), attrs: self.attrs.clean(cx), source: self.whence.clean(cx), visibility: self.vis.clean(cx), stability: self.stab.clean(cx), def_id: ast_util::local_def(self.id), inner: FunctionItem(Function { decl: self.decl.clean(cx), generics: self.generics.clean(cx), unsafety: self.unsafety, }), } } } #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub struct ClosureDecl { pub lifetimes: Vec, pub decl: FnDecl, pub onceness: ast::Onceness, pub unsafety: ast::Unsafety, pub bounds: Vec, } impl Clean for ast::ClosureTy { fn clean(&self, cx: &DocContext) -> ClosureDecl { ClosureDecl { lifetimes: self.lifetimes.clean(cx), decl: self.decl.clean(cx), onceness: self.onceness, unsafety: self.unsafety, bounds: self.bounds.clean(cx) } } } #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub struct FnDecl { pub inputs: Arguments, pub output: FunctionRetTy, pub attrs: Vec, } #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub struct Arguments { pub values: Vec, } impl Clean for ast::FnDecl { fn clean(&self, cx: &DocContext) -> FnDecl { FnDecl { inputs: Arguments { values: self.inputs.clean(cx), }, output: self.output.clean(cx), attrs: Vec::new() } } } impl<'tcx> Clean for ty::FnOutput<'tcx> { fn clean(&self, cx: &DocContext) -> Type { match *self { ty::FnConverging(ty) => ty.clean(cx), ty::FnDiverging => Bottom } } } impl<'a, 'tcx> Clean for (ast::DefId, &'a ty::PolyFnSig<'tcx>) { fn clean(&self, cx: &DocContext) -> FnDecl { let (did, sig) = *self; let mut names = if did.node != 0 { csearch::get_method_arg_names(&cx.tcx().sess.cstore, did).into_iter() } else { Vec::new().into_iter() }.peekable(); if names.peek().map(|s| s.as_slice()) == Some("self") { let _ = names.next(); } FnDecl { output: Return(sig.0.output.clean(cx)), attrs: Vec::new(), inputs: Arguments { values: sig.0.inputs.iter().map(|t| { Argument { type_: t.clean(cx), id: 0, name: names.next().unwrap_or("".to_string()), } }).collect(), }, } } } #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub struct Argument { pub type_: Type, pub name: String, pub id: ast::NodeId, } impl Clean for ast::Arg { fn clean(&self, cx: &DocContext) -> Argument { Argument { name: name_from_pat(&*self.pat), type_: (self.ty.clean(cx)), id: self.id } } } #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub enum FunctionRetTy { Return(Type), NoReturn } impl Clean for ast::FunctionRetTy { fn clean(&self, cx: &DocContext) -> FunctionRetTy { match *self { ast::Return(ref typ) => Return(typ.clean(cx)), ast::NoReturn(_) => NoReturn } } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct Trait { pub unsafety: ast::Unsafety, pub items: Vec, pub generics: Generics, pub bounds: Vec, /// An optional default bound not required for `Self`, like `Sized?` pub default_unbound: Option } impl Clean for doctree::Trait { fn clean(&self, cx: &DocContext) -> Item { Item { name: Some(self.name.clean(cx)), attrs: self.attrs.clean(cx), source: self.whence.clean(cx), def_id: ast_util::local_def(self.id), visibility: self.vis.clean(cx), stability: self.stab.clean(cx), inner: TraitItem(Trait { unsafety: self.unsafety, items: self.items.clean(cx), generics: self.generics.clean(cx), bounds: self.bounds.clean(cx), default_unbound: self.default_unbound.clean(cx) }), } } } impl Clean for ast::TraitRef { fn clean(&self, cx: &DocContext) -> Type { resolve_type(cx, self.path.clean(cx), self.ref_id) } } impl Clean for ast::PolyTraitRef { fn clean(&self, cx: &DocContext) -> PolyTrait { PolyTrait { trait_: self.trait_ref.clean(cx), lifetimes: self.bound_lifetimes.clean(cx) } } } /// An item belonging to a trait, whether a method or associated. Could be named /// TraitItem except that's already taken by an exported enum variant. #[deriving(Clone, RustcEncodable, RustcDecodable)] pub enum TraitMethod { RequiredMethod(Item), ProvidedMethod(Item), TypeTraitItem(Item), } impl TraitMethod { pub fn is_req(&self) -> bool { match self { &RequiredMethod(..) => true, _ => false, } } pub fn is_def(&self) -> bool { match self { &ProvidedMethod(..) => true, _ => false, } } pub fn is_type(&self) -> bool { match self { &TypeTraitItem(..) => true, _ => false, } } pub fn item<'a>(&'a self) -> &'a Item { match *self { RequiredMethod(ref item) => item, ProvidedMethod(ref item) => item, TypeTraitItem(ref item) => item, } } } impl Clean for ast::TraitItem { fn clean(&self, cx: &DocContext) -> TraitMethod { match self { &ast::RequiredMethod(ref t) => RequiredMethod(t.clean(cx)), &ast::ProvidedMethod(ref t) => ProvidedMethod(t.clean(cx)), &ast::TypeTraitItem(ref t) => TypeTraitItem(t.clean(cx)), } } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub enum ImplMethod { MethodImplItem(Item), TypeImplItem(Item), } impl Clean for ast::ImplItem { fn clean(&self, cx: &DocContext) -> ImplMethod { match self { &ast::MethodImplItem(ref t) => MethodImplItem(t.clean(cx)), &ast::TypeImplItem(ref t) => TypeImplItem(t.clean(cx)), } } } impl<'tcx> Clean for ty::Method<'tcx> { fn clean(&self, cx: &DocContext) -> Item { let (self_, sig) = match self.explicit_self { ty::StaticExplicitSelfCategory => (ast::SelfStatic.clean(cx), self.fty.sig.clone()), s => { let sig = ty::Binder(ty::FnSig { inputs: self.fty.sig.0.inputs[1..].to_vec(), ..self.fty.sig.0.clone() }); let s = match s { ty::ByValueExplicitSelfCategory => SelfValue, ty::ByReferenceExplicitSelfCategory(..) => { match self.fty.sig.0.inputs[0].sty { ty::ty_rptr(r, mt) => { SelfBorrowed(r.clean(cx), mt.mutbl.clean(cx)) } _ => unreachable!(), } } ty::ByBoxExplicitSelfCategory => { SelfExplicit(self.fty.sig.0.inputs[0].clean(cx)) } ty::StaticExplicitSelfCategory => unreachable!(), }; (s, sig) } }; Item { name: Some(self.name.clean(cx)), visibility: Some(ast::Inherited), stability: get_stability(cx, self.def_id), def_id: self.def_id, attrs: inline::load_attrs(cx, cx.tcx(), self.def_id), source: Span::empty(), inner: TyMethodItem(TyMethod { unsafety: self.fty.unsafety, generics: (&self.generics, subst::FnSpace).clean(cx), self_: self_, decl: (self.def_id, &sig).clean(cx), }) } } } impl<'tcx> Clean for ty::ImplOrTraitItem<'tcx> { fn clean(&self, cx: &DocContext) -> Item { match *self { ty::MethodTraitItem(ref mti) => mti.clean(cx), ty::TypeTraitItem(ref tti) => tti.clean(cx), } } } /// A trait reference, which may have higher ranked lifetimes. #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub struct PolyTrait { pub trait_: Type, pub lifetimes: Vec } /// A representation of a Type suitable for hyperlinking purposes. Ideally one can get the original /// type out of the AST/ty::ctxt given one of these, if more information is needed. Most importantly /// it does not preserve mutability or boxes. #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub enum Type { /// structs/enums/traits (anything that'd be an ast::TyPath) ResolvedPath { path: Path, typarams: Option>, did: ast::DefId, }, // I have no idea how to usefully use this. TyParamBinder(ast::NodeId), /// For parameterized types, so the consumer of the JSON don't go looking /// for types which don't exist anywhere. Generic(ast::DefId), /// For references to self Self(ast::DefId), /// Primitives are just the fixed-size numeric types (plus int/uint/float), and char. Primitive(PrimitiveType), Closure(Box), Proc(Box), /// extern "ABI" fn BareFunction(Box), Tuple(Vec), Vector(Box), FixedVector(Box, String), /// aka TyBot Bottom, Unique(Box), RawPointer(Mutability, Box), BorrowedRef { lifetime: Option, mutability: Mutability, type_: Box, }, // ::Name QPath { name: String, self_type: Box, trait_: Box }, // _ Infer, // for<'a> Foo(&'a) PolyTraitRef(Vec), } #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq, Eq, Hash, Copy)] pub enum PrimitiveType { Int, I8, I16, I32, I64, Uint, U8, U16, U32, U64, F32, F64, Char, Bool, Str, Slice, PrimitiveTuple, } #[deriving(Clone, RustcEncodable, RustcDecodable, Copy)] pub enum TypeKind { TypeEnum, TypeFunction, TypeModule, TypeConst, TypeStatic, TypeStruct, TypeTrait, TypeVariant, TypeTypedef, } impl PrimitiveType { fn from_str(s: &str) -> Option { match s.as_slice() { "int" => Some(Int), "i8" => Some(I8), "i16" => Some(I16), "i32" => Some(I32), "i64" => Some(I64), "uint" => Some(Uint), "u8" => Some(U8), "u16" => Some(U16), "u32" => Some(U32), "u64" => Some(U64), "bool" => Some(Bool), "char" => Some(Char), "str" => Some(Str), "f32" => Some(F32), "f64" => Some(F64), "slice" => Some(Slice), "tuple" => Some(PrimitiveTuple), _ => None, } } fn find(attrs: &[Attribute]) -> Option { for attr in attrs.iter() { let list = match *attr { List(ref k, ref l) if *k == "doc" => l, _ => continue, }; for sub_attr in list.iter() { let value = match *sub_attr { NameValue(ref k, ref v) if *k == "primitive" => v.as_slice(), _ => continue, }; match PrimitiveType::from_str(value) { Some(p) => return Some(p), None => {} } } } return None } pub fn to_string(&self) -> &'static str { match *self { Int => "int", I8 => "i8", I16 => "i16", I32 => "i32", I64 => "i64", Uint => "uint", U8 => "u8", U16 => "u16", U32 => "u32", U64 => "u64", F32 => "f32", F64 => "f64", Str => "str", Bool => "bool", Char => "char", Slice => "slice", PrimitiveTuple => "tuple", } } pub fn to_url_str(&self) -> &'static str { self.to_string() } /// Creates a rustdoc-specific node id for primitive types. /// /// These node ids are generally never used by the AST itself. pub fn to_node_id(&self) -> ast::NodeId { u32::MAX - 1 - (*self as u32) } } impl Clean for ast::Ty { fn clean(&self, cx: &DocContext) -> Type { use syntax::ast::*; match self.node { TyPtr(ref m) => RawPointer(m.mutbl.clean(cx), box m.ty.clean(cx)), TyRptr(ref l, ref m) => BorrowedRef {lifetime: l.clean(cx), mutability: m.mutbl.clean(cx), type_: box m.ty.clean(cx)}, TyVec(ref ty) => Vector(box ty.clean(cx)), TyFixedLengthVec(ref ty, ref e) => FixedVector(box ty.clean(cx), e.span.to_src(cx)), TyTup(ref tys) => Tuple(tys.clean(cx)), TyPath(ref p, id) => { resolve_type(cx, p.clean(cx), id) } TyObjectSum(ref lhs, ref bounds) => { let lhs_ty = lhs.clean(cx); match lhs_ty { ResolvedPath { path, typarams: None, did } => { ResolvedPath { path: path, typarams: Some(bounds.clean(cx)), did: did} } _ => { lhs_ty // shouldn't happen } } } TyClosure(ref c) => Closure(box c.clean(cx)), TyBareFn(ref barefn) => BareFunction(box barefn.clean(cx)), TyParen(ref ty) => ty.clean(cx), TyQPath(ref qp) => qp.clean(cx), TyPolyTraitRef(ref bounds) => { PolyTraitRef(bounds.clean(cx)) }, TyInfer(..) => { Infer }, TyTypeof(..) => { panic!("Unimplemented type {}", self.node) }, } } } impl<'tcx> Clean for ty::Ty<'tcx> { fn clean(&self, cx: &DocContext) -> Type { match self.sty { ty::ty_bool => Primitive(Bool), ty::ty_char => Primitive(Char), ty::ty_int(ast::TyI) => Primitive(Int), ty::ty_int(ast::TyI8) => Primitive(I8), ty::ty_int(ast::TyI16) => Primitive(I16), ty::ty_int(ast::TyI32) => Primitive(I32), ty::ty_int(ast::TyI64) => Primitive(I64), ty::ty_uint(ast::TyU) => Primitive(Uint), ty::ty_uint(ast::TyU8) => Primitive(U8), ty::ty_uint(ast::TyU16) => Primitive(U16), ty::ty_uint(ast::TyU32) => Primitive(U32), ty::ty_uint(ast::TyU64) => Primitive(U64), ty::ty_float(ast::TyF32) => Primitive(F32), ty::ty_float(ast::TyF64) => Primitive(F64), ty::ty_str => Primitive(Str), ty::ty_uniq(t) => { let box_did = cx.tcx_opt().and_then(|tcx| { tcx.lang_items.owned_box() }); lang_struct(cx, box_did, t, "Box", Unique) } ty::ty_vec(ty, None) => Vector(box ty.clean(cx)), ty::ty_vec(ty, Some(i)) => FixedVector(box ty.clean(cx), format!("{}", i)), ty::ty_ptr(mt) => RawPointer(mt.mutbl.clean(cx), box mt.ty.clean(cx)), ty::ty_rptr(r, mt) => BorrowedRef { lifetime: r.clean(cx), mutability: mt.mutbl.clean(cx), type_: box mt.ty.clean(cx), }, ty::ty_bare_fn(_, ref fty) => BareFunction(box BareFunctionDecl { unsafety: fty.unsafety, generics: Generics { lifetimes: Vec::new(), type_params: Vec::new(), where_predicates: Vec::new() }, decl: (ast_util::local_def(0), &fty.sig).clean(cx), abi: fty.abi.to_string(), }), ty::ty_closure(ref fty) => { let decl = box ClosureDecl { lifetimes: Vec::new(), // FIXME: this looks wrong... decl: (ast_util::local_def(0), &fty.sig).clean(cx), onceness: fty.onceness, unsafety: fty.unsafety, bounds: fty.bounds.clean(cx), }; match fty.store { ty::UniqTraitStore => Proc(decl), ty::RegionTraitStore(..) => Closure(decl), } } ty::ty_struct(did, ref substs) | ty::ty_enum(did, ref substs) | ty::ty_trait(box ty::TyTrait { principal: ty::Binder(ty::TraitRef { def_id: did, ref substs }), .. }) => { let fqn = csearch::get_item_path(cx.tcx(), did); let fqn: Vec = fqn.into_iter().map(|i| { i.to_string() }).collect(); let kind = match self.sty { ty::ty_struct(..) => TypeStruct, ty::ty_trait(..) => TypeTrait, _ => TypeEnum, }; let path = external_path(cx, fqn.last().unwrap().to_string().as_slice(), None, substs); cx.external_paths.borrow_mut().as_mut().unwrap().insert(did, (fqn, kind)); ResolvedPath { path: path, typarams: None, did: did, } } ty::ty_tup(ref t) => Tuple(t.clean(cx)), ty::ty_param(ref p) => { if p.space == subst::SelfSpace { Self(p.def_id) } else { Generic(p.def_id) } } ty::ty_unboxed_closure(..) => Tuple(vec![]), // FIXME(pcwalton) ty::ty_infer(..) => panic!("ty_infer"), ty::ty_open(..) => panic!("ty_open"), ty::ty_err => panic!("ty_err"), } } } impl Clean for ast::QPath { fn clean(&self, cx: &DocContext) -> Type { Type::QPath { name: self.item_name.clean(cx), self_type: box self.self_type.clean(cx), trait_: box self.trait_ref.clean(cx) } } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub enum StructField { HiddenStructField, // inserted later by strip passes TypedStructField(Type), } impl Clean for ast::StructField { fn clean(&self, cx: &DocContext) -> Item { let (name, vis) = match self.node.kind { ast::NamedField(id, vis) => (Some(id), vis), ast::UnnamedField(vis) => (None, vis) }; Item { name: name.clean(cx), attrs: self.node.attrs.clean(cx), source: self.span.clean(cx), visibility: Some(vis), stability: get_stability(cx, ast_util::local_def(self.node.id)), def_id: ast_util::local_def(self.node.id), inner: StructFieldItem(TypedStructField(self.node.ty.clean(cx))), } } } impl Clean for ty::field_ty { fn clean(&self, cx: &DocContext) -> Item { use syntax::parse::token::special_idents::unnamed_field; use rustc::metadata::csearch; let attr_map = csearch::get_struct_field_attrs(&cx.tcx().sess.cstore, self.id); let (name, attrs) = if self.name == unnamed_field.name { (None, None) } else { (Some(self.name), Some(attr_map.get(&self.id.node).unwrap())) }; let ty = ty::lookup_item_type(cx.tcx(), self.id); Item { name: name.clean(cx), attrs: attrs.unwrap_or(&Vec::new()).clean(cx), source: Span::empty(), visibility: Some(self.vis), stability: get_stability(cx, self.id), def_id: self.id, inner: StructFieldItem(TypedStructField(ty.ty.clean(cx))), } } } pub type Visibility = ast::Visibility; impl Clean> for ast::Visibility { fn clean(&self, _: &DocContext) -> Option { Some(*self) } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct Struct { pub struct_type: doctree::StructType, pub generics: Generics, pub fields: Vec, pub fields_stripped: bool, } impl Clean for doctree::Struct { fn clean(&self, cx: &DocContext) -> Item { Item { name: Some(self.name.clean(cx)), attrs: self.attrs.clean(cx), source: self.whence.clean(cx), def_id: ast_util::local_def(self.id), visibility: self.vis.clean(cx), stability: self.stab.clean(cx), inner: StructItem(Struct { struct_type: self.struct_type, generics: self.generics.clean(cx), fields: self.fields.clean(cx), fields_stripped: false, }), } } } /// This is a more limited form of the standard Struct, different in that /// it lacks the things most items have (name, id, parameterization). Found /// only as a variant in an enum. #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct VariantStruct { pub struct_type: doctree::StructType, pub fields: Vec, pub fields_stripped: bool, } impl Clean for syntax::ast::StructDef { fn clean(&self, cx: &DocContext) -> VariantStruct { VariantStruct { struct_type: doctree::struct_type_from_def(self), fields: self.fields.clean(cx), fields_stripped: false, } } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct Enum { pub variants: Vec, pub generics: Generics, pub variants_stripped: bool, } impl Clean for doctree::Enum { fn clean(&self, cx: &DocContext) -> Item { Item { name: Some(self.name.clean(cx)), attrs: self.attrs.clean(cx), source: self.whence.clean(cx), def_id: ast_util::local_def(self.id), visibility: self.vis.clean(cx), stability: self.stab.clean(cx), inner: EnumItem(Enum { variants: self.variants.clean(cx), generics: self.generics.clean(cx), variants_stripped: false, }), } } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct Variant { pub kind: VariantKind, } impl Clean for doctree::Variant { fn clean(&self, cx: &DocContext) -> Item { Item { name: Some(self.name.clean(cx)), attrs: self.attrs.clean(cx), source: self.whence.clean(cx), visibility: self.vis.clean(cx), stability: self.stab.clean(cx), def_id: ast_util::local_def(self.id), inner: VariantItem(Variant { kind: self.kind.clean(cx), }), } } } impl<'tcx> Clean for ty::VariantInfo<'tcx> { fn clean(&self, cx: &DocContext) -> Item { // use syntax::parse::token::special_idents::unnamed_field; let kind = match self.arg_names.as_ref().map(|s| s.as_slice()) { None | Some([]) if self.args.len() == 0 => CLikeVariant, None | Some([]) => { TupleVariant(self.args.clean(cx)) } Some(s) => { StructVariant(VariantStruct { struct_type: doctree::Plain, fields_stripped: false, fields: s.iter().zip(self.args.iter()).map(|(name, ty)| { Item { source: Span::empty(), name: Some(name.clean(cx)), attrs: Vec::new(), visibility: Some(ast::Public), // FIXME: this is not accurate, we need an id for // the specific field but we're using the id // for the whole variant. Thus we read the // stability from the whole variant as well. // Struct variants are experimental and need // more infrastructure work before we can get // at the needed information here. def_id: self.id, stability: get_stability(cx, self.id), inner: StructFieldItem( TypedStructField(ty.clean(cx)) ) } }).collect() }) } }; Item { name: Some(self.name.clean(cx)), attrs: inline::load_attrs(cx, cx.tcx(), self.id), source: Span::empty(), visibility: Some(ast::Public), def_id: self.id, inner: VariantItem(Variant { kind: kind }), stability: get_stability(cx, self.id), } } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub enum VariantKind { CLikeVariant, TupleVariant(Vec), StructVariant(VariantStruct), } impl Clean for ast::VariantKind { fn clean(&self, cx: &DocContext) -> VariantKind { match self { &ast::TupleVariantKind(ref args) => { if args.len() == 0 { CLikeVariant } else { TupleVariant(args.iter().map(|x| x.ty.clean(cx)).collect()) } }, &ast::StructVariantKind(ref sd) => StructVariant(sd.clean(cx)), } } } #[deriving(Clone, RustcEncodable, RustcDecodable, Show)] pub struct Span { pub filename: String, pub loline: uint, pub locol: uint, pub hiline: uint, pub hicol: uint, } impl Span { fn empty() -> Span { Span { filename: "".to_string(), loline: 0, locol: 0, hiline: 0, hicol: 0, } } } impl Clean for syntax::codemap::Span { fn clean(&self, cx: &DocContext) -> Span { let cm = cx.sess().codemap(); let filename = cm.span_to_filename(*self); let lo = cm.lookup_char_pos(self.lo); let hi = cm.lookup_char_pos(self.hi); Span { filename: filename.to_string(), loline: lo.line, locol: lo.col.to_uint(), hiline: hi.line, hicol: hi.col.to_uint(), } } } #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub struct Path { pub global: bool, pub segments: Vec, } impl Clean for ast::Path { fn clean(&self, cx: &DocContext) -> Path { Path { global: self.global, segments: self.segments.clean(cx), } } } #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub enum PathParameters { AngleBracketed { lifetimes: Vec, types: Vec, }, Parenthesized { inputs: Vec, output: Option } } impl Clean for ast::PathParameters { fn clean(&self, cx: &DocContext) -> PathParameters { match *self { ast::AngleBracketedParameters(ref data) => { PathParameters::AngleBracketed { lifetimes: data.lifetimes.clean(cx), types: data.types.clean(cx) } } ast::ParenthesizedParameters(ref data) => { PathParameters::Parenthesized { inputs: data.inputs.clean(cx), output: data.output.clean(cx) } } } } } #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub struct PathSegment { pub name: String, pub params: PathParameters } impl Clean for ast::PathSegment { fn clean(&self, cx: &DocContext) -> PathSegment { PathSegment { name: self.identifier.clean(cx), params: self.parameters.clean(cx) } } } fn path_to_string(p: &ast::Path) -> String { let mut s = String::new(); let mut first = true; for i in p.segments.iter().map(|x| token::get_ident(x.identifier)) { if !first || p.global { s.push_str("::"); } else { first = false; } s.push_str(i.get()); } s } impl Clean for ast::Ident { fn clean(&self, _: &DocContext) -> String { token::get_ident(*self).get().to_string() } } impl Clean for ast::Name { fn clean(&self, _: &DocContext) -> String { token::get_name(*self).get().to_string() } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct Typedef { pub type_: Type, pub generics: Generics, } impl Clean for doctree::Typedef { fn clean(&self, cx: &DocContext) -> Item { Item { name: Some(self.name.clean(cx)), attrs: self.attrs.clean(cx), source: self.whence.clean(cx), def_id: ast_util::local_def(self.id.clone()), visibility: self.vis.clean(cx), stability: self.stab.clean(cx), inner: TypedefItem(Typedef { type_: self.ty.clean(cx), generics: self.gen.clean(cx), }), } } } #[deriving(Clone, RustcEncodable, RustcDecodable, PartialEq)] pub struct BareFunctionDecl { pub unsafety: ast::Unsafety, pub generics: Generics, pub decl: FnDecl, pub abi: String, } impl Clean for ast::BareFnTy { fn clean(&self, cx: &DocContext) -> BareFunctionDecl { BareFunctionDecl { unsafety: self.unsafety, generics: Generics { lifetimes: self.lifetimes.clean(cx), type_params: Vec::new(), where_predicates: Vec::new() }, decl: self.decl.clean(cx), abi: self.abi.to_string(), } } } #[deriving(Clone, RustcEncodable, RustcDecodable, Show)] pub struct Static { pub type_: Type, pub mutability: Mutability, /// It's useful to have the value of a static documented, but I have no /// desire to represent expressions (that'd basically be all of the AST, /// which is huge!). So, have a string. pub expr: String, } impl Clean for doctree::Static { fn clean(&self, cx: &DocContext) -> Item { debug!("claning static {}: {}", self.name.clean(cx), self); Item { name: Some(self.name.clean(cx)), attrs: self.attrs.clean(cx), source: self.whence.clean(cx), def_id: ast_util::local_def(self.id), visibility: self.vis.clean(cx), stability: self.stab.clean(cx), inner: StaticItem(Static { type_: self.type_.clean(cx), mutability: self.mutability.clean(cx), expr: self.expr.span.to_src(cx), }), } } } #[deriving(Clone, RustcEncodable, RustcDecodable, Show)] pub struct Constant { pub type_: Type, pub expr: String, } impl Clean for doctree::Constant { fn clean(&self, cx: &DocContext) -> Item { Item { name: Some(self.name.clean(cx)), attrs: self.attrs.clean(cx), source: self.whence.clean(cx), def_id: ast_util::local_def(self.id), visibility: self.vis.clean(cx), stability: self.stab.clean(cx), inner: ConstantItem(Constant { type_: self.type_.clean(cx), expr: self.expr.span.to_src(cx), }), } } } #[deriving(Show, Clone, RustcEncodable, RustcDecodable, PartialEq, Copy)] pub enum Mutability { Mutable, Immutable, } impl Clean for ast::Mutability { fn clean(&self, _: &DocContext) -> Mutability { match self { &ast::MutMutable => Mutable, &ast::MutImmutable => Immutable, } } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct Impl { pub generics: Generics, pub trait_: Option, pub for_: Type, pub items: Vec, pub derived: bool, } fn detect_derived(attrs: &[M]) -> bool { attr::contains_name(attrs, "automatically_derived") } impl Clean for doctree::Impl { fn clean(&self, cx: &DocContext) -> Item { Item { name: None, attrs: self.attrs.clean(cx), source: self.whence.clean(cx), def_id: ast_util::local_def(self.id), visibility: self.vis.clean(cx), stability: self.stab.clean(cx), inner: ImplItem(Impl { generics: self.generics.clean(cx), trait_: self.trait_.clean(cx), for_: self.for_.clean(cx), items: self.items.clean(cx).into_iter().map(|ti| { match ti { MethodImplItem(i) => i, TypeImplItem(i) => i, } }).collect(), derived: detect_derived(self.attrs.as_slice()), }), } } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct ViewItem { pub inner: ViewItemInner, } impl Clean> for ast::ViewItem { fn clean(&self, cx: &DocContext) -> Vec { // We consider inlining the documentation of `pub use` statements, but we // forcefully don't inline if this is not public or if the // #[doc(no_inline)] attribute is present. let denied = self.vis != ast::Public || self.attrs.iter().any(|a| { a.name().get() == "doc" && match a.meta_item_list() { Some(l) => attr::contains_name(l, "no_inline"), None => false, } }); let convert = |node: &ast::ViewItem_| { Item { name: None, attrs: self.attrs.clean(cx), source: self.span.clean(cx), def_id: ast_util::local_def(0), visibility: self.vis.clean(cx), stability: None, inner: ViewItemItem(ViewItem { inner: node.clean(cx) }), } }; let mut ret = Vec::new(); match self.node { ast::ViewItemUse(ref path) if !denied => { match path.node { ast::ViewPathGlob(..) => ret.push(convert(&self.node)), ast::ViewPathList(ref a, ref list, ref b) => { // Attempt to inline all reexported items, but be sure // to keep any non-inlineable reexports so they can be // listed in the documentation. let remaining = list.iter().filter(|path| { match inline::try_inline(cx, path.node.id(), None) { Some(items) => { ret.extend(items.into_iter()); false } None => true, } }).map(|a| a.clone()).collect::>(); if remaining.len() > 0 { let path = ast::ViewPathList(a.clone(), remaining, b.clone()); let path = syntax::codemap::dummy_spanned(path); ret.push(convert(&ast::ViewItemUse(P(path)))); } } ast::ViewPathSimple(ident, _, id) => { match inline::try_inline(cx, id, Some(ident)) { Some(items) => ret.extend(items.into_iter()), None => ret.push(convert(&self.node)), } } } } ref n => ret.push(convert(n)), } return ret; } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub enum ViewItemInner { ExternCrate(String, Option, ast::NodeId), Import(ViewPath) } impl Clean for ast::ViewItem_ { fn clean(&self, cx: &DocContext) -> ViewItemInner { match self { &ast::ViewItemExternCrate(ref i, ref p, ref id) => { let string = match *p { None => None, Some((ref x, _)) => Some(x.get().to_string()), }; ExternCrate(i.clean(cx), string, *id) } &ast::ViewItemUse(ref vp) => { Import(vp.clean(cx)) } } } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub enum ViewPath { // use source as str; SimpleImport(String, ImportSource), // use source::*; GlobImport(ImportSource), // use source::{a, b, c}; ImportList(ImportSource, Vec), } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct ImportSource { pub path: Path, pub did: Option, } impl Clean for ast::ViewPath { fn clean(&self, cx: &DocContext) -> ViewPath { match self.node { ast::ViewPathSimple(ref i, ref p, id) => SimpleImport(i.clean(cx), resolve_use_source(cx, p.clean(cx), id)), ast::ViewPathGlob(ref p, id) => GlobImport(resolve_use_source(cx, p.clean(cx), id)), ast::ViewPathList(ref p, ref pl, id) => { ImportList(resolve_use_source(cx, p.clean(cx), id), pl.clean(cx)) } } } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct ViewListIdent { pub name: String, pub source: Option, } impl Clean for ast::PathListItem { fn clean(&self, cx: &DocContext) -> ViewListIdent { match self.node { ast::PathListIdent { id, name } => ViewListIdent { name: name.clean(cx), source: resolve_def(cx, id) }, ast::PathListMod { id } => ViewListIdent { name: "mod".to_string(), source: resolve_def(cx, id) } } } } impl Clean> for ast::ForeignMod { fn clean(&self, cx: &DocContext) -> Vec { self.items.clean(cx) } } impl Clean for ast::ForeignItem { fn clean(&self, cx: &DocContext) -> Item { let inner = match self.node { ast::ForeignItemFn(ref decl, ref generics) => { ForeignFunctionItem(Function { decl: decl.clean(cx), generics: generics.clean(cx), unsafety: ast::Unsafety::Unsafe, }) } ast::ForeignItemStatic(ref ty, mutbl) => { ForeignStaticItem(Static { type_: ty.clean(cx), mutability: if mutbl {Mutable} else {Immutable}, expr: "".to_string(), }) } }; Item { name: Some(self.ident.clean(cx)), attrs: self.attrs.clean(cx), source: self.span.clean(cx), def_id: ast_util::local_def(self.id), visibility: self.vis.clean(cx), stability: get_stability(cx, ast_util::local_def(self.id)), inner: inner, } } } // Utilities trait ToSource { fn to_src(&self, cx: &DocContext) -> String; } impl ToSource for syntax::codemap::Span { fn to_src(&self, cx: &DocContext) -> String { debug!("converting span {} to snippet", self.clean(cx)); let sn = match cx.sess().codemap().span_to_snippet(*self) { Some(x) => x.to_string(), None => "".to_string() }; debug!("got snippet {}", sn); sn } } fn lit_to_string(lit: &ast::Lit) -> String { match lit.node { ast::LitStr(ref st, _) => st.get().to_string(), ast::LitBinary(ref data) => format!("{}", data), ast::LitByte(b) => { let mut res = String::from_str("b'"); for c in (b as char).escape_default() { res.push(c); } res.push('\''); res }, ast::LitChar(c) => format!("'{}'", c), ast::LitInt(i, _t) => i.to_string(), ast::LitFloat(ref f, _t) => f.get().to_string(), ast::LitFloatUnsuffixed(ref f) => f.get().to_string(), ast::LitBool(b) => b.to_string(), } } fn name_from_pat(p: &ast::Pat) -> String { use syntax::ast::*; debug!("Trying to get a name from pattern: {}", p); match p.node { PatWild(PatWildSingle) => "_".to_string(), PatWild(PatWildMulti) => "..".to_string(), PatIdent(_, ref p, _) => token::get_ident(p.node).get().to_string(), PatEnum(ref p, _) => path_to_string(p), PatStruct(ref name, ref fields, etc) => { format!("{} {{ {}{} }}", path_to_string(name), fields.iter().map(|&Spanned { node: ref fp, .. }| format!("{}: {}", fp.ident.as_str(), name_from_pat(&*fp.pat))) .collect::>().connect(", "), if etc { ", ..." } else { "" } ) }, PatTup(ref elts) => format!("({})", elts.iter().map(|p| name_from_pat(&**p)) .collect::>().connect(", ")), PatBox(ref p) => name_from_pat(&**p), PatRegion(ref p) => name_from_pat(&**p), PatLit(..) => { warn!("tried to get argument name from PatLit, \ which is silly in function arguments"); "()".to_string() }, PatRange(..) => panic!("tried to get argument name from PatRange, \ which is not allowed in function arguments"), PatVec(..) => panic!("tried to get argument name from pat_vec, \ which is not allowed in function arguments"), PatMac(..) => { warn!("can't document the name of a function argument \ produced by a pattern macro"); "(argument produced by macro)".to_string() } } } /// Given a Type, resolve it using the def_map fn resolve_type(cx: &DocContext, path: Path, id: ast::NodeId) -> Type { let tcx = match cx.tcx_opt() { Some(tcx) => tcx, // If we're extracting tests, this return value doesn't matter. None => return Primitive(Bool), }; debug!("searching for {} in defmap", id); let def = match tcx.def_map.borrow().get(&id) { Some(&k) => k, None => panic!("unresolved id not in defmap") }; match def { def::DefSelfTy(i) => return Self(ast_util::local_def(i)), def::DefPrimTy(p) => match p { ast::TyStr => return Primitive(Str), ast::TyBool => return Primitive(Bool), ast::TyChar => return Primitive(Char), ast::TyInt(ast::TyI) => return Primitive(Int), ast::TyInt(ast::TyI8) => return Primitive(I8), ast::TyInt(ast::TyI16) => return Primitive(I16), ast::TyInt(ast::TyI32) => return Primitive(I32), ast::TyInt(ast::TyI64) => return Primitive(I64), ast::TyUint(ast::TyU) => return Primitive(Uint), ast::TyUint(ast::TyU8) => return Primitive(U8), ast::TyUint(ast::TyU16) => return Primitive(U16), ast::TyUint(ast::TyU32) => return Primitive(U32), ast::TyUint(ast::TyU64) => return Primitive(U64), ast::TyFloat(ast::TyF32) => return Primitive(F32), ast::TyFloat(ast::TyF64) => return Primitive(F64), }, def::DefTyParam(_, i, _) => return Generic(i), def::DefTyParamBinder(i) => return TyParamBinder(i), _ => {} }; let did = register_def(&*cx, def); ResolvedPath { path: path, typarams: None, did: did } } fn register_def(cx: &DocContext, def: def::Def) -> ast::DefId { let (did, kind) = match def { def::DefFn(i, _) => (i, TypeFunction), def::DefTy(i, false) => (i, TypeTypedef), def::DefTy(i, true) => (i, TypeEnum), def::DefTrait(i) => (i, TypeTrait), def::DefStruct(i) => (i, TypeStruct), def::DefMod(i) => (i, TypeModule), def::DefStatic(i, _) => (i, TypeStatic), def::DefVariant(i, _, _) => (i, TypeEnum), _ => return def.def_id() }; if ast_util::is_local(did) { return did } let tcx = match cx.tcx_opt() { Some(tcx) => tcx, None => return did }; inline::record_extern_fqn(cx, did, kind); if let TypeTrait = kind { let t = inline::build_external_trait(cx, tcx, did); cx.external_traits.borrow_mut().as_mut().unwrap().insert(did, t); } return did; } fn resolve_use_source(cx: &DocContext, path: Path, id: ast::NodeId) -> ImportSource { ImportSource { path: path, did: resolve_def(cx, id), } } fn resolve_def(cx: &DocContext, id: ast::NodeId) -> Option { cx.tcx_opt().and_then(|tcx| { tcx.def_map.borrow().get(&id).map(|&def| register_def(cx, def)) }) } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct Macro { pub source: String, } impl Clean for doctree::Macro { fn clean(&self, cx: &DocContext) -> Item { Item { name: Some(format!("{}!", self.name.clean(cx))), attrs: self.attrs.clean(cx), source: self.whence.clean(cx), visibility: ast::Public.clean(cx), stability: self.stab.clean(cx), def_id: ast_util::local_def(self.id), inner: MacroItem(Macro { source: self.whence.to_src(cx), }), } } } #[deriving(Clone, RustcEncodable, RustcDecodable)] pub struct Stability { pub level: attr::StabilityLevel, pub text: String } impl Clean for attr::Stability { fn clean(&self, _: &DocContext) -> Stability { Stability { level: self.level, text: self.text.as_ref().map_or("".to_string(), |interned| interned.get().to_string()), } } } impl Clean for ast::AssociatedType { fn clean(&self, cx: &DocContext) -> Item { Item { source: self.ty_param.span.clean(cx), name: Some(self.ty_param.ident.clean(cx)), attrs: self.attrs.clean(cx), inner: AssociatedTypeItem(self.ty_param.clean(cx)), visibility: None, def_id: ast_util::local_def(self.ty_param.id), stability: None, } } } impl Clean for ty::AssociatedType { fn clean(&self, cx: &DocContext) -> Item { Item { source: DUMMY_SP.clean(cx), name: Some(self.name.clean(cx)), attrs: Vec::new(), // FIXME(#18048): this is wrong, but cross-crate associated types are broken // anyway, for the time being. inner: AssociatedTypeItem(TyParam { name: self.name.clean(cx), did: ast::DefId { krate: 0, node: ast::DUMMY_NODE_ID }, bounds: vec![], default: None, default_unbound: None }), visibility: None, def_id: self.def_id, stability: None, } } } impl Clean for ast::Typedef { fn clean(&self, cx: &DocContext) -> Item { Item { source: self.span.clean(cx), name: Some(self.ident.clean(cx)), attrs: self.attrs.clean(cx), inner: TypedefItem(Typedef { type_: self.typ.clean(cx), generics: Generics { lifetimes: Vec::new(), type_params: Vec::new(), where_predicates: Vec::new() }, }), visibility: None, def_id: ast_util::local_def(self.id), stability: None, } } } fn lang_struct(cx: &DocContext, did: Option, t: ty::Ty, name: &str, fallback: fn(Box) -> Type) -> Type { let did = match did { Some(did) => did, None => return fallback(box t.clean(cx)), }; let fqn = csearch::get_item_path(cx.tcx(), did); let fqn: Vec = fqn.into_iter().map(|i| { i.to_string() }).collect(); cx.external_paths.borrow_mut().as_mut().unwrap().insert(did, (fqn, TypeStruct)); ResolvedPath { typarams: None, did: did, path: Path { global: false, segments: vec![PathSegment { name: name.to_string(), params: PathParameters::AngleBracketed { lifetimes: vec![], types: vec![t.clean(cx)], } }], }, } }