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7e77bf1769
rust/src/libsyntax/fold.rs
Patrick Walton 7e77bf1769 librustc: Implement the proc type as sugar for ~once fn and proc 
notation for closures, and disable the feature gate for `once fn` if
used with the `~` sigil.
2013-10-29 10:34:17 -07:00

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// Copyright 2012 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 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
use ast::*;
use ast;
use codemap::{respan, Span, Spanned};
use parse::token;
use opt_vec::OptVec;
// We may eventually want to be able to fold over type parameters, too.
pub trait ast_fold {
fn fold_crate(&self, c: Crate) -> Crate {
noop_fold_crate(c, self)
}
fn fold_meta_items(&self, meta_items: &[@MetaItem]) -> ~[@MetaItem] {
meta_items.map(|x| fold_meta_item_(*x, self))
}
fn fold_view_paths(&self, view_paths: &[@view_path]) -> ~[@view_path] {
view_paths.map(|view_path| {
let inner_view_path = match view_path.node {
view_path_simple(ref ident, ref path, node_id) => {
view_path_simple(ident.clone(),
self.fold_path(path),
self.new_id(node_id))
}
view_path_glob(ref path, node_id) => {
view_path_glob(self.fold_path(path), self.new_id(node_id))
}
view_path_list(ref path, ref path_list_idents, node_id) => {
view_path_list(self.fold_path(path),
path_list_idents.map(|path_list_ident| {
let id = self.new_id(path_list_ident.node
.id);
Spanned {
node: path_list_ident_ {
name: path_list_ident.node
.name
.clone(),
id: id,
},
span: self.new_span(
path_list_ident.span)
}
}),
self.new_id(node_id))
}
};
@Spanned {
node: inner_view_path,
span: self.new_span(view_path.span),
}
})
}
fn fold_view_item(&self, vi: &view_item) -> view_item {
let inner_view_item = match vi.node {
view_item_extern_mod(ref ident,
string,
ref meta_items,
node_id) => {
view_item_extern_mod(ident.clone(),
string,
self.fold_meta_items(*meta_items),
self.new_id(node_id))
}
view_item_use(ref view_paths) => {
view_item_use(self.fold_view_paths(*view_paths))
}
};
view_item {
node: inner_view_item,
attrs: vi.attrs.map(|a| fold_attribute_(*a, self)),
vis: vi.vis,
span: self.new_span(vi.span),
}
}
fn fold_foreign_item(&self, ni: @foreign_item) -> @foreign_item {
let fold_attribute = |x| fold_attribute_(x, self);
@ast::foreign_item {
ident: self.fold_ident(ni.ident),
attrs: ni.attrs.map(|x| fold_attribute(*x)),
node:
match ni.node {
foreign_item_fn(ref fdec, ref generics) => {
foreign_item_fn(
ast::fn_decl {
inputs: fdec.inputs.map(|a| fold_arg_(a,
self)),
output: self.fold_ty(&fdec.output),
cf: fdec.cf,
},
fold_generics(generics, self))
}
foreign_item_static(ref t, m) => {
foreign_item_static(self.fold_ty(t), m)
}
},
id: self.new_id(ni.id),
span: self.new_span(ni.span),
vis: ni.vis,
}
}
fn fold_item(&self, i: @item) -> Option<@item> {
noop_fold_item(i, self)
}
fn fold_struct_field(&self, sf: @struct_field) -> @struct_field {
let fold_attribute = |x| fold_attribute_(x, self);
@Spanned {
node: ast::struct_field_ {
kind: sf.node.kind,
id: self.new_id(sf.node.id),
ty: self.fold_ty(&sf.node.ty),
attrs: sf.node.attrs.map(|e| fold_attribute(*e))
},
span: self.new_span(sf.span)
}
}
fn fold_item_underscore(&self, i: &item_) -> item_ {
noop_fold_item_underscore(i, self)
}
fn fold_type_method(&self, m: &TypeMethod) -> TypeMethod {
noop_fold_type_method(m, self)
}
fn fold_method(&self, m: @method) -> @method {
@ast::method {
ident: self.fold_ident(m.ident),
attrs: m.attrs.map(|a| fold_attribute_(*a, self)),
generics: fold_generics(&m.generics, self),
explicit_self: m.explicit_self,
purity: m.purity,
decl: fold_fn_decl(&m.decl, self),
body: self.fold_block(&m.body),
id: self.new_id(m.id),
span: self.new_span(m.span),
self_id: self.new_id(m.self_id),
vis: m.vis,
}
}
fn fold_block(&self, b: &Block) -> Block {
noop_fold_block(b, self)
}
fn fold_stmt(&self, s: &Stmt) -> Option<@Stmt> {
noop_fold_stmt(s, self)
}
fn fold_arm(&self, a: &Arm) -> Arm {
Arm {
pats: a.pats.map(|x| self.fold_pat(*x)),
guard: a.guard.map(|x| self.fold_expr(x)),
body: self.fold_block(&a.body),
}
}
fn fold_pat(&self, p: @Pat) -> @Pat {
let node = match p.node {
PatWild => PatWild,
PatIdent(binding_mode, ref pth, ref sub) => {
PatIdent(binding_mode,
self.fold_path(pth),
sub.map(|x| self.fold_pat(x)))
}
PatLit(e) => PatLit(self.fold_expr(e)),
PatEnum(ref pth, ref pats) => {
PatEnum(self.fold_path(pth),
pats.as_ref().map(|pats| pats.map(|x| self.fold_pat(*x))))
}
PatStruct(ref pth, ref fields, etc) => {
let pth_ = self.fold_path(pth);
let fs = do fields.map |f| {
ast::FieldPat {
ident: f.ident,
pat: self.fold_pat(f.pat)
}
};
PatStruct(pth_, fs, etc)
}
PatTup(ref elts) => PatTup(elts.map(|x| self.fold_pat(*x))),
PatBox(inner) => PatBox(self.fold_pat(inner)),
PatUniq(inner) => PatUniq(self.fold_pat(inner)),
PatRegion(inner) => PatRegion(self.fold_pat(inner)),
PatRange(e1, e2) => {
PatRange(self.fold_expr(e1), self.fold_expr(e2))
},
PatVec(ref before, ref slice, ref after) => {
PatVec(before.map(|x| self.fold_pat(*x)),
slice.map(|x| self.fold_pat(x)),
after.map(|x| self.fold_pat(*x)))
}
};
@Pat {
id: self.new_id(p.id),
span: self.new_span(p.span),
node: node,
}
}
fn fold_decl(&self, d: @Decl) -> Option<@Decl> {
let node = match d.node {
DeclLocal(ref l) => Some(DeclLocal(self.fold_local(*l))),
DeclItem(it) => {
match self.fold_item(it) {
Some(it_folded) => Some(DeclItem(it_folded)),
None => None,
}
}
};
node.map(|node| {
@Spanned {
node: node,
span: d.span,
}
})
}
fn fold_expr(&self, e: @Expr) -> @Expr {
noop_fold_expr(e, self)
}
fn fold_ty(&self, t: &Ty) -> Ty {
let node = match t.node {
ty_nil | ty_bot | ty_infer => t.node.clone(),
ty_box(ref mt) => ty_box(fold_mt(mt, self)),
ty_uniq(ref mt) => ty_uniq(fold_mt(mt, self)),
ty_vec(ref mt) => ty_vec(fold_mt(mt, self)),
ty_ptr(ref mt) => ty_ptr(fold_mt(mt, self)),
ty_rptr(region, ref mt) => ty_rptr(region, fold_mt(mt, self)),
ty_closure(ref f) => {
ty_closure(@TyClosure {
sigil: f.sigil,
purity: f.purity,
region: f.region,
onceness: f.onceness,
bounds: fold_opt_bounds(&f.bounds, self),
decl: fold_fn_decl(&f.decl, self),
lifetimes: f.lifetimes.map(|l| fold_lifetime(l, self)),
})
}
ty_bare_fn(ref f) => {
ty_bare_fn(@TyBareFn {
lifetimes: f.lifetimes.map(|l| fold_lifetime(l, self)),
purity: f.purity,
abis: f.abis,
decl: fold_fn_decl(&f.decl, self)
})
}
ty_tup(ref tys) => ty_tup(tys.map(|ty| self.fold_ty(ty))),
ty_path(ref path, ref bounds, id) => {
ty_path(self.fold_path(path),
fold_opt_bounds(bounds, self),
self.new_id(id))
}
ty_fixed_length_vec(ref mt, e) => {
ty_fixed_length_vec(fold_mt(mt, self), self.fold_expr(e))
}
ty_mac(ref mac) => ty_mac(self.fold_mac(mac)),
ty_typeof(expr) => ty_typeof(self.fold_expr(expr)),
};
Ty {
id: self.new_id(t.id),
span: self.new_span(t.span),
node: node,
}
}
fn fold_mod(&self, m: &_mod) -> _mod {
noop_fold_mod(m, self)
}
fn fold_foreign_mod(&self, nm: &foreign_mod) -> foreign_mod {
ast::foreign_mod {
abis: nm.abis,
view_items: nm.view_items
.iter()
.map(|x| self.fold_view_item(x))
.collect(),
items: nm.items
.iter()
.map(|x| self.fold_foreign_item(*x))
.collect(),
}
}
fn fold_variant(&self, v: &variant) -> variant {
let kind;
match v.node.kind {
tuple_variant_kind(ref variant_args) => {
kind = tuple_variant_kind(variant_args.map(|x|
fold_variant_arg_(x, self)))
}
struct_variant_kind(ref struct_def) => {
kind = struct_variant_kind(@ast::struct_def {
fields: struct_def.fields.iter()
.map(|f| self.fold_struct_field(*f)).collect(),
ctor_id: struct_def.ctor_id.map(|c| self.new_id(c))
})
}
}
let fold_attribute = |x| fold_attribute_(x, self);
let attrs = v.node.attrs.map(|x| fold_attribute(*x));
let de = match v.node.disr_expr {
Some(e) => Some(self.fold_expr(e)),
None => None
};
let node = ast::variant_ {
name: v.node.name,
attrs: attrs,
kind: kind,
id: self.new_id(v.node.id),
disr_expr: de,
vis: v.node.vis,
};
Spanned {
node: node,
span: self.new_span(v.span),
}
}
fn fold_ident(&self, i: Ident) -> Ident {
i
}
fn fold_path(&self, p: &Path) -> Path {
ast::Path {
span: self.new_span(p.span),
global: p.global,
segments: p.segments.map(|segment| ast::PathSegment {
identifier: self.fold_ident(segment.identifier),
lifetime: segment.lifetime,
types: segment.types.map(|typ| self.fold_ty(typ)),
})
}
}
fn fold_local(&self, l: @Local) -> @Local {
@Local {
ty: self.fold_ty(&l.ty),
pat: self.fold_pat(l.pat),
init: l.init.map(|e| self.fold_expr(e)),
id: self.new_id(l.id),
span: self.new_span(l.span),
}
}
fn fold_mac(&self, macro: &mac) -> mac {
Spanned {
node: match macro.node {
mac_invoc_tt(ref p, ref tts, ctxt) => {
mac_invoc_tt(self.fold_path(p),
fold_tts(*tts, self),
ctxt)
}
},
span: self.new_span(macro.span)
}
}
fn map_exprs(&self, f: &fn(@Expr) -> @Expr, es: &[@Expr]) -> ~[@Expr] {
es.map(|x| f(*x))
}
fn new_id(&self, i: NodeId) -> NodeId {
i
}
fn new_span(&self, sp: Span) -> Span {
sp
}
}
/* some little folds that probably aren't useful to have in ast_fold itself*/
//used in noop_fold_item and noop_fold_crate and noop_fold_crate_directive
fn fold_meta_item_<T:ast_fold>(mi: @MetaItem, fld: &T) -> @MetaItem {
@Spanned {
node:
match mi.node {
MetaWord(id) => MetaWord(id),
MetaList(id, ref mis) => {
let fold_meta_item = |x| fold_meta_item_(x, fld);
MetaList(
id,
mis.map(|e| fold_meta_item(*e))
)
}
MetaNameValue(id, s) => MetaNameValue(id, s)
},
span: fld.new_span(mi.span) }
}
//used in noop_fold_item and noop_fold_crate
fn fold_attribute_<T:ast_fold>(at: Attribute, fld: &T) -> Attribute {
Spanned {
span: fld.new_span(at.span),
node: ast::Attribute_ {
style: at.node.style,
value: fold_meta_item_(at.node.value, fld),
is_sugared_doc: at.node.is_sugared_doc
}
}
}
//used in noop_fold_foreign_item and noop_fold_fn_decl
fn fold_arg_<T:ast_fold>(a: &arg, fld: &T) -> arg {
ast::arg {
ty: fld.fold_ty(&a.ty),
pat: fld.fold_pat(a.pat),
id: fld.new_id(a.id),
}
}
// build a new vector of tts by appling the ast_fold's fold_ident to
// all of the identifiers in the token trees.
pub fn fold_tts<T:ast_fold>(tts: &[token_tree], fld: &T) -> ~[token_tree] {
do tts.map |tt| {
match *tt {
tt_tok(span, ref tok) =>
tt_tok(span,maybe_fold_ident(tok,fld)),
tt_delim(ref tts) => tt_delim(@mut fold_tts(**tts, fld)),
tt_seq(span, ref pattern, ref sep, is_optional) =>
tt_seq(span,
@mut fold_tts(**pattern, fld),
sep.as_ref().map(|tok|maybe_fold_ident(tok,fld)),
is_optional),
tt_nonterminal(sp,ref ident) =>
tt_nonterminal(sp,fld.fold_ident(*ident))
}
}
}
// apply ident folder if it's an ident, otherwise leave it alone
fn maybe_fold_ident<T:ast_fold>(t: &token::Token, fld: &T) -> token::Token {
match *t {
token::IDENT(id, followed_by_colons) => {
token::IDENT(fld.fold_ident(id), followed_by_colons)
}
_ => (*t).clone()
}
}
pub fn fold_fn_decl<T:ast_fold>(decl: &ast::fn_decl, fld: &T)
-> ast::fn_decl {
ast::fn_decl {
inputs: decl.inputs.map(|x| fold_arg_(x, fld)), // bad copy
output: fld.fold_ty(&decl.output),
cf: decl.cf,
}
}
fn fold_ty_param_bound<T:ast_fold>(tpb: &TyParamBound, fld: &T)
-> TyParamBound {
match *tpb {
TraitTyParamBound(ref ty) => TraitTyParamBound(fold_trait_ref(ty, fld)),
RegionTyParamBound => RegionTyParamBound
}
}
pub fn fold_ty_param<T:ast_fold>(tp: &TyParam, fld: &T) -> TyParam {
TyParam {
ident: tp.ident,
id: fld.new_id(tp.id),
bounds: tp.bounds.map(|x| fold_ty_param_bound(x, fld)),
}
}
pub fn fold_ty_params<T:ast_fold>(tps: &OptVec<TyParam>, fld: &T)
-> OptVec<TyParam> {
tps.map(|tp| fold_ty_param(tp, fld))
}
pub fn fold_lifetime<T:ast_fold>(l: &Lifetime, fld: &T) -> Lifetime {
Lifetime {
id: fld.new_id(l.id),
span: fld.new_span(l.span),
ident: l.ident
}
}
pub fn fold_lifetimes<T:ast_fold>(lts: &OptVec<Lifetime>, fld: &T)
-> OptVec<Lifetime> {
lts.map(|l| fold_lifetime(l, fld))
}
pub fn fold_generics<T:ast_fold>(generics: &Generics, fld: &T) -> Generics {
Generics {ty_params: fold_ty_params(&generics.ty_params, fld),
lifetimes: fold_lifetimes(&generics.lifetimes, fld)}
}
fn fold_struct_def<T:ast_fold>(struct_def: @ast::struct_def, fld: &T)
-> @ast::struct_def {
@ast::struct_def {
fields: struct_def.fields.map(|f| fold_struct_field(*f, fld)),
ctor_id: struct_def.ctor_id.map(|cid| fld.new_id(cid)),
}
}
fn noop_fold_view_item(vi: &view_item_, fld: @ast_fold) -> view_item_ {
match *vi {
view_item_extern_mod(ident, name, ref meta_items, node_id) => {
view_item_extern_mod(ident,
name,
fld.fold_meta_items(*meta_items),
fld.new_id(node_id))
}
view_item_use(ref view_paths) => {
view_item_use(fld.fold_view_paths(*view_paths))
}
}
}
fn fold_trait_ref<T:ast_fold>(p: &trait_ref, fld: &T) -> trait_ref {
ast::trait_ref {
path: fld.fold_path(&p.path),
ref_id: fld.new_id(p.ref_id),
}
}
fn fold_struct_field<T:ast_fold>(f: @struct_field, fld: &T) -> @struct_field {
@Spanned {
node: ast::struct_field_ {
kind: f.node.kind,
id: fld.new_id(f.node.id),
ty: fld.fold_ty(&f.node.ty),
attrs: f.node.attrs.map(|a| fold_attribute_(*a, fld)),
},
span: fld.new_span(f.span),
}
}
fn fold_field_<T:ast_fold>(field: Field, folder: &T) -> Field {
ast::Field {
ident: respan(field.ident.span, folder.fold_ident(field.ident.node)),
expr: folder.fold_expr(field.expr),
span: folder.new_span(field.span),
}
}
fn fold_mt<T:ast_fold>(mt: &mt, folder: &T) -> mt {
mt {
ty: ~folder.fold_ty(mt.ty),
mutbl: mt.mutbl,
}
}
fn fold_field<T:ast_fold>(f: TypeField, folder: &T) -> TypeField {
ast::TypeField {
ident: folder.fold_ident(f.ident),
mt: fold_mt(&f.mt, folder),
span: folder.new_span(f.span),
}
}
fn fold_opt_bounds<T:ast_fold>(b: &Option<OptVec<TyParamBound>>, folder: &T)
-> Option<OptVec<TyParamBound>> {
do b.as_ref().map |bounds| {
do bounds.map |bound| {
fold_ty_param_bound(bound, folder)
}
}
}
fn fold_variant_arg_<T:ast_fold>(va: &variant_arg, folder: &T)
-> variant_arg {
ast::variant_arg {
ty: folder.fold_ty(&va.ty),
id: folder.new_id(va.id)
}
}
pub fn noop_fold_block<T:ast_fold>(b: &Block, folder: &T) -> Block {
let view_items = b.view_items.map(|x| folder.fold_view_item(x));
let mut stmts = ~[];
for stmt in b.stmts.iter() {
match folder.fold_stmt(*stmt) {
None => {}
Some(stmt) => stmts.push(stmt)
}
}
ast::Block {
view_items: view_items,
stmts: stmts,
expr: b.expr.map(|x| folder.fold_expr(x)),
id: folder.new_id(b.id),
rules: b.rules,
span: folder.new_span(b.span),
}
}
pub fn noop_fold_item_underscore<T:ast_fold>(i: &item_, folder: &T) -> item_ {
match *i {
item_static(ref t, m, e) => {
item_static(folder.fold_ty(t), m, folder.fold_expr(e))
}
item_fn(ref decl, purity, abi, ref generics, ref body) => {
item_fn(
fold_fn_decl(decl, folder),
purity,
abi,
fold_generics(generics, folder),
folder.fold_block(body)
)
}
item_mod(ref m) => item_mod(folder.fold_mod(m)),
item_foreign_mod(ref nm) => {
item_foreign_mod(folder.fold_foreign_mod(nm))
}
item_ty(ref t, ref generics) => {
item_ty(folder.fold_ty(t),
fold_generics(generics, folder))
}
item_enum(ref enum_definition, ref generics) => {
item_enum(
ast::enum_def {
variants: do enum_definition.variants.map |x| {
folder.fold_variant(x)
},
},
fold_generics(generics, folder))
}
item_struct(ref struct_def, ref generics) => {
let struct_def = fold_struct_def(*struct_def, folder);
item_struct(struct_def, fold_generics(generics, folder))
}
item_impl(ref generics, ref ifce, ref ty, ref methods) => {
item_impl(fold_generics(generics, folder),
ifce.as_ref().map(|p| fold_trait_ref(p, folder)),
folder.fold_ty(ty),
methods.map(|x| folder.fold_method(*x))
)
}
item_trait(ref generics, ref traits, ref methods) => {
let methods = do methods.map |method| {
match *method {
required(ref m) => required(folder.fold_type_method(m)),
provided(method) => provided(folder.fold_method(method))
}
};
item_trait(fold_generics(generics, folder),
traits.map(|p| fold_trait_ref(p, folder)),
methods)
}
item_mac(ref m) => item_mac(folder.fold_mac(m)),
}
}
pub fn noop_fold_type_method<T:ast_fold>(m: &TypeMethod, fld: &T)
-> TypeMethod {
TypeMethod {
ident: fld.fold_ident(m.ident),
attrs: m.attrs.map(|a| fold_attribute_(*a, fld)),
purity: m.purity,
decl: fold_fn_decl(&m.decl, fld),
generics: fold_generics(&m.generics, fld),
explicit_self: m.explicit_self,
id: fld.new_id(m.id),
span: fld.new_span(m.span),
}
}
pub fn noop_fold_mod<T:ast_fold>(m: &_mod, folder: &T) -> _mod {
ast::_mod {
view_items: m.view_items
.iter()
.map(|x| folder.fold_view_item(x)).collect(),
items: m.items.iter().filter_map(|x| folder.fold_item(*x)).collect(),
}
}
pub fn noop_fold_crate<T:ast_fold>(c: Crate, folder: &T) -> Crate {
let fold_meta_item = |x| fold_meta_item_(x, folder);
let fold_attribute = |x| fold_attribute_(x, folder);
Crate {
module: folder.fold_mod(&c.module),
attrs: c.attrs.map(|x| fold_attribute(*x)),
config: c.config.map(|x| fold_meta_item(*x)),
span: folder.new_span(c.span),
}
}
pub fn noop_fold_item<T:ast_fold>(i: @ast::item, folder: &T)
-> Option<@ast::item> {
let fold_attribute = |x| fold_attribute_(x, folder);
Some(@ast::item {
ident: folder.fold_ident(i.ident),
attrs: i.attrs.map(|e| fold_attribute(*e)),
id: folder.new_id(i.id),
node: folder.fold_item_underscore(&i.node),
vis: i.vis,
span: folder.new_span(i.span)
})
}
pub fn noop_fold_expr<T:ast_fold>(e: @ast::Expr, folder: &T) -> @ast::Expr {
let fold_field = |x| fold_field_(x, folder);
let node = match e.node {
ExprVstore(e, v) => {
ExprVstore(folder.fold_expr(e), v)
}
ExprVec(ref exprs, mutt) => {
ExprVec(folder.map_exprs(|x| folder.fold_expr(x), *exprs), mutt)
}
ExprRepeat(expr, count, mutt) => {
ExprRepeat(folder.fold_expr(expr), folder.fold_expr(count), mutt)
}
ExprTup(ref elts) => ExprTup(elts.map(|x| folder.fold_expr(*x))),
ExprCall(f, ref args, blk) => {
ExprCall(folder.fold_expr(f),
folder.map_exprs(|x| folder.fold_expr(x), *args),
blk)
}
ExprMethodCall(callee_id, f, i, ref tps, ref args, blk) => {
ExprMethodCall(
folder.new_id(callee_id),
folder.fold_expr(f),
folder.fold_ident(i),
tps.map(|x| folder.fold_ty(x)),
folder.map_exprs(|x| folder.fold_expr(x), *args),
blk
)
}
ExprBinary(callee_id, binop, lhs, rhs) => {
ExprBinary(folder.new_id(callee_id),
binop,
folder.fold_expr(lhs),
folder.fold_expr(rhs))
}
ExprUnary(callee_id, binop, ohs) => {
ExprUnary(folder.new_id(callee_id), binop, folder.fold_expr(ohs))
}
ExprDoBody(f) => ExprDoBody(folder.fold_expr(f)),
ExprLit(_) => e.node.clone(),
ExprCast(expr, ref ty) => {
ExprCast(folder.fold_expr(expr), folder.fold_ty(ty))
}
ExprAddrOf(m, ohs) => ExprAddrOf(m, folder.fold_expr(ohs)),
ExprIf(cond, ref tr, fl) => {
ExprIf(folder.fold_expr(cond),
folder.fold_block(tr),
fl.map(|x| folder.fold_expr(x)))
}
ExprWhile(cond, ref body) => {
ExprWhile(folder.fold_expr(cond), folder.fold_block(body))
}
ExprForLoop(pat, iter, ref body, ref maybe_ident) => {
ExprForLoop(folder.fold_pat(pat),
folder.fold_expr(iter),
folder.fold_block(body),
maybe_ident.map(|i| folder.fold_ident(i)))
}
ExprLoop(ref body, opt_ident) => {
ExprLoop(folder.fold_block(body),
opt_ident.map(|x| folder.fold_ident(x)))
}
ExprMatch(expr, ref arms) => {
ExprMatch(folder.fold_expr(expr),
arms.map(|x| folder.fold_arm(x)))
}
ExprFnBlock(ref decl, ref body) => {
ExprFnBlock(
fold_fn_decl(decl, folder),
folder.fold_block(body)
)
}
ExprProc(ref decl, ref body) => {
ExprProc(fold_fn_decl(decl, folder), folder.fold_block(body))
}
ExprBlock(ref blk) => ExprBlock(folder.fold_block(blk)),
ExprAssign(el, er) => {
ExprAssign(folder.fold_expr(el), folder.fold_expr(er))
}
ExprAssignOp(callee_id, op, el, er) => {
ExprAssignOp(folder.new_id(callee_id),
op,
folder.fold_expr(el),
folder.fold_expr(er))
}
ExprField(el, id, ref tys) => {
ExprField(folder.fold_expr(el),
folder.fold_ident(id),
tys.map(|x| folder.fold_ty(x)))
}
ExprIndex(callee_id, el, er) => {
ExprIndex(folder.new_id(callee_id),
folder.fold_expr(el),
folder.fold_expr(er))
}
ExprPath(ref pth) => ExprPath(folder.fold_path(pth)),
ExprSelf => ExprSelf,
ExprLogLevel => ExprLogLevel,
ExprBreak(opt_ident) => ExprBreak(opt_ident),
ExprAgain(opt_ident) => ExprAgain(opt_ident),
ExprRet(ref e) => {
ExprRet(e.map(|x| folder.fold_expr(x)))
}
ExprInlineAsm(ref a) => {
ExprInlineAsm(inline_asm {
inputs: a.inputs.map(|&(c, input)| (c, folder.fold_expr(input))),
outputs: a.outputs.map(|&(c, out)| (c, folder.fold_expr(out))),
.. (*a).clone()
})
}
ExprMac(ref mac) => ExprMac(folder.fold_mac(mac)),
ExprStruct(ref path, ref fields, maybe_expr) => {
ExprStruct(folder.fold_path(path),
fields.map(|x| fold_field(*x)),
maybe_expr.map(|x| folder.fold_expr(x)))
},
ExprParen(ex) => ExprParen(folder.fold_expr(ex))
};
@Expr {
id: folder.new_id(e.id),
node: node,
span: folder.new_span(e.span),
}
}
pub fn noop_fold_stmt<T:ast_fold>(s: &Stmt, folder: &T) -> Option<@Stmt> {
let node = match s.node {
StmtDecl(d, nid) => {
match folder.fold_decl(d) {
Some(d) => Some(StmtDecl(d, folder.new_id(nid))),
None => None,
}
}
StmtExpr(e, nid) => {
Some(StmtExpr(folder.fold_expr(e), folder.new_id(nid)))
}
StmtSemi(e, nid) => {
Some(StmtSemi(folder.fold_expr(e), folder.new_id(nid)))
}
StmtMac(ref mac, semi) => Some(StmtMac(folder.fold_mac(mac), semi))
};
node.map(|node| @Spanned {
node: node,
span: folder.new_span(s.span),
})
}
#[cfg(test)]
mod test {
use ast;
use util::parser_testing::{string_to_crate, matches_codepattern};
use parse::token;
use print::pprust;
use super::*;
// this version doesn't care about getting comments or docstrings in.
fn fake_print_crate(s: @pprust::ps, crate: &ast::Crate) {
pprust::print_mod(s, &crate.module, crate.attrs);
}
// change every identifier to "zz"
struct ToZzIdentFolder;
impl ast_fold for ToZzIdentFolder {
fn fold_ident(&self, _: ast::Ident) -> ast::Ident {
token::str_to_ident("zz")
}
}
// maybe add to expand.rs...
macro_rules! assert_pred (
($pred:expr, $predname:expr, $a:expr , $b:expr) => (
{
let pred_val = $pred;
let a_val = $a;
let b_val = $b;
if !(pred_val(a_val,b_val)) {
fail!("expected args satisfying {}, got {:?} and {:?}",
$predname, a_val, b_val);
}
}
)
)
// make sure idents get transformed everywhere
#[test] fn ident_transformation () {
let zz_fold = ToZzIdentFolder;
let ast = string_to_crate(@"#[a] mod b {fn c (d : e, f : g) {h!(i,j,k);l;m}}");
assert_pred!(matches_codepattern,
"matches_codepattern",
pprust::to_str(&zz_fold.fold_crate(ast),fake_print_crate,
token::get_ident_interner()),
~"#[a]mod zz{fn zz(zz:zz,zz:zz){zz!(zz,zz,zz);zz;zz}}");
}
// even inside macro defs....
#[test] fn ident_transformation_in_defs () {
let zz_fold = ToZzIdentFolder;
let ast = string_to_crate(@"macro_rules! a {(b $c:expr $(d $e:token)f+
=> (g $(d $d $e)+))} ");
assert_pred!(matches_codepattern,
"matches_codepattern",
pprust::to_str(&zz_fold.fold_crate(ast),fake_print_crate,
token::get_ident_interner()),
~"zz!zz((zz$zz:zz$(zz $zz:zz)zz+=>(zz$(zz$zz$zz)+)))");
}
}
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