rust/src/libsyntax/visit.rs
2013-08-28 15:30:38 -07:00

816 lines
30 KiB
Rust

// 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 abi::AbiSet;
use ast::*;
use ast;
use codemap::span;
use parse;
use opt_vec;
use opt_vec::OptVec;
// Context-passing AST walker. Each overridden visit method has full control
// over what happens with its node, it can do its own traversal of the node's
// children (potentially passing in different contexts to each), call
// visit::visit_* to apply the default traversal algorithm (again, it can
// override the context), or prevent deeper traversal by doing nothing.
//
// Note: it is an important invariant that the default visitor walks the body
// of a function in "execution order" (more concretely, reverse post-order
// with respect to the CFG implied by the AST), meaning that if AST node A may
// execute before AST node B, then A is visited first. The borrow checker in
// particular relies on this property.
pub enum fn_kind<'self> {
// fn foo() or extern "Abi" fn foo()
fk_item_fn(ident, &'self Generics, purity, AbiSet),
// fn foo(&self)
fk_method(ident, &'self Generics, &'self method),
// @fn(x, y) { ... }
fk_anon(ast::Sigil),
// |x, y| ...
fk_fn_block,
}
pub fn name_of_fn(fk: &fn_kind) -> ident {
match *fk {
fk_item_fn(name, _, _, _) | fk_method(name, _, _) => {
name
}
fk_anon(*) | fk_fn_block(*) => parse::token::special_idents::anon,
}
}
pub fn generics_of_fn(fk: &fn_kind) -> Generics {
match *fk {
fk_item_fn(_, generics, _, _) |
fk_method(_, generics, _) => {
(*generics).clone()
}
fk_anon(*) | fk_fn_block(*) => {
Generics {
lifetimes: opt_vec::Empty,
ty_params: opt_vec::Empty,
}
}
}
}
pub trait Visitor<E:Clone> {
fn visit_mod(&mut self, m:&_mod, _s:span, _n:NodeId, e:E) { walk_mod(self, m, e) }
fn visit_view_item(&mut self, i:&view_item, e:E) { walk_view_item(self, i, e) }
fn visit_foreign_item(&mut self, i:@foreign_item, e:E) { walk_foreign_item(self, i, e) }
fn visit_item(&mut self, i:@item, e:E) { walk_item(self, i, e) }
fn visit_local(&mut self, l:@Local, e:E) { walk_local(self, l, e) }
fn visit_block(&mut self, b:&Block, e:E) { walk_block(self, b, e) }
fn visit_stmt(&mut self, s:@stmt, e:E) { walk_stmt(self, s, e) }
fn visit_arm(&mut self, a:&arm, e:E) { walk_arm(self, a, e) }
fn visit_pat(&mut self, p:@pat, e:E) { walk_pat(self, p, e) }
fn visit_decl(&mut self, d:@decl, e:E) { walk_decl(self, d, e) }
fn visit_expr(&mut self, ex:@expr, e:E) { walk_expr(self, ex, e) }
fn visit_expr_post(&mut self, _ex:@expr, _e:E) { }
fn visit_ty(&mut self, _t:&Ty, _e:E) { }
fn visit_generics(&mut self, g:&Generics, e:E) { walk_generics(self, g, e) }
fn visit_fn(&mut self, fk:&fn_kind, fd:&fn_decl, b:&Block, s:span, n:NodeId, e:E) {
walk_fn(self, fk, fd, b, s, n , e)
}
fn visit_ty_method(&mut self, t:&TypeMethod, e:E) { walk_ty_method(self, t, e) }
fn visit_trait_method(&mut self, t:&trait_method, e:E) { walk_trait_method(self, t, e) }
fn visit_struct_def(&mut self, s:@struct_def, i:ident, g:&Generics, n:NodeId, e:E) {
walk_struct_def(self, s, i, g, n, e)
}
fn visit_struct_field(&mut self, s:@struct_field, e:E) { walk_struct_field(self, s, e) }
}
impl<E:Clone> Visitor<E> for @mut Visitor<E> {
fn visit_mod(&mut self, a:&_mod, b:span, c:NodeId, e:E) {
(*self).visit_mod(a, b, c, e)
}
fn visit_view_item(&mut self, a:&view_item, e:E) {
(*self).visit_view_item(a, e)
}
fn visit_foreign_item(&mut self, a:@foreign_item, e:E) {
(*self).visit_foreign_item(a, e)
}
fn visit_item(&mut self, a:@item, e:E) {
(*self).visit_item(a, e)
}
fn visit_local(&mut self, a:@Local, e:E) {
(*self).visit_local(a, e)
}
fn visit_block(&mut self, a:&Block, e:E) {
(*self).visit_block(a, e)
}
fn visit_stmt(&mut self, a:@stmt, e:E) {
(*self).visit_stmt(a, e)
}
fn visit_arm(&mut self, a:&arm, e:E) {
(*self).visit_arm(a, e)
}
fn visit_pat(&mut self, a:@pat, e:E) {
(*self).visit_pat(a, e)
}
fn visit_decl(&mut self, a:@decl, e:E) {
(*self).visit_decl(a, e)
}
fn visit_expr(&mut self, a:@expr, e:E) {
(*self).visit_expr(a, e)
}
fn visit_expr_post(&mut self, a:@expr, e:E) {
(*self).visit_expr_post(a, e)
}
fn visit_ty(&mut self, a:&Ty, e:E) {
(*self).visit_ty(a, e)
}
fn visit_generics(&mut self, a:&Generics, e:E) {
(*self).visit_generics(a, e)
}
fn visit_fn(&mut self, a:&fn_kind, b:&fn_decl, c:&Block, d:span, f:NodeId, e:E) {
(*self).visit_fn(a, b, c, d, f, e)
}
fn visit_ty_method(&mut self, a:&TypeMethod, e:E) {
(*self).visit_ty_method(a, e)
}
fn visit_trait_method(&mut self, a:&trait_method, e:E) {
(*self).visit_trait_method(a, e)
}
fn visit_struct_def(&mut self, a:@struct_def, b:ident, c:&Generics, d:NodeId, e:E) {
(*self).visit_struct_def(a, b, c, d, e)
}
fn visit_struct_field(&mut self, a:@struct_field, e:E) {
(*self).visit_struct_field(a, e)
}
}
pub fn walk_crate<E:Clone, V:Visitor<E>>(visitor: &mut V, crate: &Crate, env: E) {
visitor.visit_mod(&crate.module, crate.span, CRATE_NODE_ID, env)
}
pub fn walk_mod<E:Clone, V:Visitor<E>>(visitor: &mut V, module: &_mod, env: E) {
for view_item in module.view_items.iter() {
visitor.visit_view_item(view_item, env.clone())
}
for item in module.items.iter() {
visitor.visit_item(*item, env.clone())
}
}
pub fn walk_view_item<E:Clone, V:Visitor<E>>(_: &mut V, _: &view_item, _: E) {
// Empty!
}
pub fn walk_local<E:Clone, V:Visitor<E>>(visitor: &mut V, local: &Local, env: E) {
visitor.visit_pat(local.pat, env.clone());
visitor.visit_ty(&local.ty, env.clone());
match local.init {
None => {}
Some(initializer) => visitor.visit_expr(initializer, env),
}
}
fn walk_trait_ref<E:Clone, V:Visitor<E>>(visitor: &mut V,
trait_ref: &ast::trait_ref,
env: E) {
walk_path(visitor, &trait_ref.path, env)
}
pub fn walk_item<E:Clone, V:Visitor<E>>(visitor: &mut V, item: &item, env: E) {
match item.node {
item_static(ref typ, _, expr) => {
visitor.visit_ty(typ, env.clone());
visitor.visit_expr(expr, env);
}
item_fn(ref declaration, purity, abi, ref generics, ref body) => {
visitor.visit_fn(&fk_item_fn(item.ident, generics, purity, abi),
declaration,
body,
item.span,
item.id,
env)
}
item_mod(ref module) => {
visitor.visit_mod(module, item.span, item.id, env)
}
item_foreign_mod(ref foreign_module) => {
for view_item in foreign_module.view_items.iter() {
visitor.visit_view_item(view_item, env.clone())
}
for foreign_item in foreign_module.items.iter() {
visitor.visit_foreign_item(*foreign_item, env.clone())
}
}
item_ty(ref typ, ref type_parameters) => {
visitor.visit_ty(typ, env.clone());
visitor.visit_generics(type_parameters, env)
}
item_enum(ref enum_definition, ref type_parameters) => {
visitor.visit_generics(type_parameters, env.clone());
walk_enum_def(visitor, enum_definition, type_parameters, env)
}
item_impl(ref type_parameters,
ref trait_references,
ref typ,
ref methods) => {
visitor.visit_generics(type_parameters, env.clone());
for trait_reference in trait_references.iter() {
walk_trait_ref(visitor, trait_reference, env.clone())
}
visitor.visit_ty(typ, env.clone());
for method in methods.iter() {
walk_method_helper(visitor, *method, env.clone())
}
}
item_struct(struct_definition, ref generics) => {
visitor.visit_generics(generics, env.clone());
visitor.visit_struct_def(struct_definition,
item.ident,
generics,
item.id,
env)
}
item_trait(ref generics, ref trait_paths, ref methods) => {
visitor.visit_generics(generics, env.clone());
for trait_path in trait_paths.iter() {
walk_path(visitor, &trait_path.path, env.clone())
}
for method in methods.iter() {
visitor.visit_trait_method(method, env.clone())
}
}
item_mac(ref macro) => walk_mac(visitor, macro, env),
}
}
pub fn walk_enum_def<E:Clone, V:Visitor<E>>(visitor: &mut V,
enum_definition: &ast::enum_def,
generics: &Generics,
env: E) {
for variant in enum_definition.variants.iter() {
match variant.node.kind {
tuple_variant_kind(ref variant_arguments) => {
for variant_argument in variant_arguments.iter() {
visitor.visit_ty(&variant_argument.ty, env.clone())
}
}
struct_variant_kind(struct_definition) => {
visitor.visit_struct_def(struct_definition,
variant.node.name,
generics,
variant.node.id,
env.clone())
}
}
}
}
pub fn skip_ty<E, V:Visitor<E>>(_: &mut V, _: &Ty, _: E) {
// Empty!
}
pub fn walk_ty<E:Clone, V:Visitor<E>>(visitor: &mut V, typ: &Ty, env: E) {
match typ.node {
ty_box(ref mutable_type) | ty_uniq(ref mutable_type) |
ty_vec(ref mutable_type) | ty_ptr(ref mutable_type) |
ty_rptr(_, ref mutable_type) => {
visitor.visit_ty(mutable_type.ty, env)
}
ty_tup(ref tuple_element_types) => {
for tuple_element_type in tuple_element_types.iter() {
visitor.visit_ty(tuple_element_type, env.clone())
}
}
ty_closure(ref function_declaration) => {
for argument in function_declaration.decl.inputs.iter() {
visitor.visit_ty(&argument.ty, env.clone())
}
visitor.visit_ty(&function_declaration.decl.output, env.clone());
for bounds in function_declaration.bounds.iter() {
walk_ty_param_bounds(visitor, bounds, env.clone())
}
}
ty_bare_fn(ref function_declaration) => {
for argument in function_declaration.decl.inputs.iter() {
visitor.visit_ty(&argument.ty, env.clone())
}
visitor.visit_ty(&function_declaration.decl.output, env.clone())
}
ty_path(ref path, ref bounds, _) => {
walk_path(visitor, path, env.clone());
for bounds in bounds.iter() {
walk_ty_param_bounds(visitor, bounds, env.clone())
}
}
ty_fixed_length_vec(ref mutable_type, expression) => {
visitor.visit_ty(mutable_type.ty, env.clone());
visitor.visit_expr(expression, env)
}
ty_typeof(expression) => {
visitor.visit_expr(expression, env)
}
ty_nil | ty_bot | ty_mac(_) | ty_infer => ()
}
}
pub fn walk_path<E:Clone, V:Visitor<E>>(visitor: &mut V, path: &Path, env: E) {
for segment in path.segments.iter() {
for typ in segment.types.iter() {
visitor.visit_ty(typ, env.clone())
}
}
}
pub fn walk_pat<E:Clone, V:Visitor<E>>(visitor: &mut V, pattern: &pat, env: E) {
match pattern.node {
pat_enum(ref path, ref children) => {
walk_path(visitor, path, env.clone());
for children in children.iter() {
for child in children.iter() {
visitor.visit_pat(*child, env.clone())
}
}
}
pat_struct(ref path, ref fields, _) => {
walk_path(visitor, path, env.clone());
for field in fields.iter() {
visitor.visit_pat(field.pat, env.clone())
}
}
pat_tup(ref tuple_elements) => {
for tuple_element in tuple_elements.iter() {
visitor.visit_pat(*tuple_element, env.clone())
}
}
pat_box(subpattern) |
pat_uniq(subpattern) |
pat_region(subpattern) => {
visitor.visit_pat(subpattern, env)
}
pat_ident(_, ref path, ref optional_subpattern) => {
walk_path(visitor, path, env.clone());
match *optional_subpattern {
None => {}
Some(subpattern) => visitor.visit_pat(subpattern, env),
}
}
pat_lit(expression) => visitor.visit_expr(expression, env),
pat_range(lower_bound, upper_bound) => {
visitor.visit_expr(lower_bound, env.clone());
visitor.visit_expr(upper_bound, env)
}
pat_wild => (),
pat_vec(ref prepattern, ref slice_pattern, ref postpatterns) => {
for prepattern in prepattern.iter() {
visitor.visit_pat(*prepattern, env.clone())
}
for slice_pattern in slice_pattern.iter() {
visitor.visit_pat(*slice_pattern, env.clone())
}
for postpattern in postpatterns.iter() {
visitor.visit_pat(*postpattern, env.clone())
}
}
}
}
pub fn walk_foreign_item<E:Clone, V:Visitor<E>>(visitor: &mut V,
foreign_item: &foreign_item,
env: E) {
match foreign_item.node {
foreign_item_fn(ref function_declaration, ref generics) => {
walk_fn_decl(visitor, function_declaration, env.clone());
visitor.visit_generics(generics, env)
}
foreign_item_static(ref typ, _) => visitor.visit_ty(typ, env),
}
}
pub fn walk_ty_param_bounds<E:Clone, V:Visitor<E>>(visitor: &mut V,
bounds: &OptVec<TyParamBound>,
env: E) {
for bound in bounds.iter() {
match *bound {
TraitTyParamBound(ref typ) => {
walk_trait_ref(visitor, typ, env.clone())
}
RegionTyParamBound => {}
}
}
}
pub fn walk_generics<E:Clone, V:Visitor<E>>(visitor: &mut V,
generics: &Generics,
env: E) {
for type_parameter in generics.ty_params.iter() {
walk_ty_param_bounds(visitor, &type_parameter.bounds, env.clone())
}
}
pub fn walk_fn_decl<E:Clone, V:Visitor<E>>(visitor: &mut V,
function_declaration: &fn_decl,
env: E) {
for argument in function_declaration.inputs.iter() {
visitor.visit_pat(argument.pat, env.clone());
visitor.visit_ty(&argument.ty, env.clone())
}
visitor.visit_ty(&function_declaration.output, env)
}
// Note: there is no visit_method() method in the visitor, instead override
// visit_fn() and check for fk_method(). I named this visit_method_helper()
// because it is not a default impl of any method, though I doubt that really
// clarifies anything. - Niko
pub fn walk_method_helper<E:Clone, V:Visitor<E>>(visitor: &mut V,
method: &method,
env: E) {
visitor.visit_fn(&fk_method(method.ident, &method.generics, method),
&method.decl,
&method.body,
method.span,
method.id,
env)
}
pub fn walk_fn<E:Clone, V:Visitor<E>>(visitor: &mut V,
function_kind: &fn_kind,
function_declaration: &fn_decl,
function_body: &Block,
_: span,
_: NodeId,
env: E) {
walk_fn_decl(visitor, function_declaration, env.clone());
let generics = generics_of_fn(function_kind);
visitor.visit_generics(&generics, env.clone());
visitor.visit_block(function_body, env)
}
pub fn walk_ty_method<E:Clone, V:Visitor<E>>(visitor: &mut V,
method_type: &TypeMethod,
env: E) {
for argument_type in method_type.decl.inputs.iter() {
visitor.visit_ty(&argument_type.ty, env.clone())
}
visitor.visit_generics(&method_type.generics, env.clone());
visitor.visit_ty(&method_type.decl.output, env.clone())
}
pub fn walk_trait_method<E:Clone, V:Visitor<E>>(visitor: &mut V,
trait_method: &trait_method,
env: E) {
match *trait_method {
required(ref method_type) => {
visitor.visit_ty_method(method_type, env)
}
provided(method) => walk_method_helper(visitor, method, env),
}
}
pub fn walk_struct_def<E:Clone, V:Visitor<E>>(visitor: &mut V,
struct_definition: @struct_def,
_: ast::ident,
_: &Generics,
_: NodeId,
env: E) {
for field in struct_definition.fields.iter() {
visitor.visit_struct_field(*field, env.clone())
}
}
pub fn walk_struct_field<E:Clone, V:Visitor<E>>(visitor: &mut V,
struct_field: &struct_field,
env: E) {
visitor.visit_ty(&struct_field.node.ty, env)
}
pub fn walk_block<E:Clone, V:Visitor<E>>(visitor: &mut V, block: &Block, env: E) {
for view_item in block.view_items.iter() {
visitor.visit_view_item(view_item, env.clone())
}
for statement in block.stmts.iter() {
visitor.visit_stmt(*statement, env.clone())
}
walk_expr_opt(visitor, block.expr, env)
}
pub fn walk_stmt<E:Clone, V:Visitor<E>>(visitor: &mut V, statement: &stmt, env: E) {
match statement.node {
stmt_decl(declaration, _) => visitor.visit_decl(declaration, env),
stmt_expr(expression, _) | stmt_semi(expression, _) => {
visitor.visit_expr(expression, env)
}
stmt_mac(ref macro, _) => walk_mac(visitor, macro, env),
}
}
pub fn walk_decl<E:Clone, V:Visitor<E>>(visitor: &mut V, declaration: &decl, env: E) {
match declaration.node {
decl_local(ref local) => visitor.visit_local(*local, env),
decl_item(item) => visitor.visit_item(item, env),
}
}
pub fn walk_expr_opt<E:Clone, V:Visitor<E>>(visitor: &mut V,
optional_expression: Option<@expr>,
env: E) {
match optional_expression {
None => {}
Some(expression) => visitor.visit_expr(expression, env),
}
}
pub fn walk_exprs<E:Clone, V:Visitor<E>>(visitor: &mut V,
expressions: &[@expr],
env: E) {
for expression in expressions.iter() {
visitor.visit_expr(*expression, env.clone())
}
}
pub fn walk_mac<E, V:Visitor<E>>(_: &mut V, _: &mac, _: E) {
// Empty!
}
pub fn walk_expr<E:Clone, V:Visitor<E>>(visitor: &mut V, expression: @expr, env: E) {
match expression.node {
expr_vstore(subexpression, _) => {
visitor.visit_expr(subexpression, env.clone())
}
expr_vec(ref subexpressions, _) => {
walk_exprs(visitor, *subexpressions, env.clone())
}
expr_repeat(element, count, _) => {
visitor.visit_expr(element, env.clone());
visitor.visit_expr(count, env.clone())
}
expr_struct(ref path, ref fields, optional_base) => {
walk_path(visitor, path, env.clone());
for field in fields.iter() {
visitor.visit_expr(field.expr, env.clone())
}
walk_expr_opt(visitor, optional_base, env.clone())
}
expr_tup(ref subexpressions) => {
for subexpression in subexpressions.iter() {
visitor.visit_expr(*subexpression, env.clone())
}
}
expr_call(callee_expression, ref arguments, _) => {
for argument in arguments.iter() {
visitor.visit_expr(*argument, env.clone())
}
visitor.visit_expr(callee_expression, env.clone())
}
expr_method_call(_, callee, _, ref types, ref arguments, _) => {
walk_exprs(visitor, *arguments, env.clone());
for typ in types.iter() {
visitor.visit_ty(typ, env.clone())
}
visitor.visit_expr(callee, env.clone())
}
expr_binary(_, _, left_expression, right_expression) => {
visitor.visit_expr(left_expression, env.clone());
visitor.visit_expr(right_expression, env.clone())
}
expr_addr_of(_, subexpression) |
expr_unary(_, _, subexpression) |
expr_do_body(subexpression) => {
visitor.visit_expr(subexpression, env.clone())
}
expr_lit(_) => {}
expr_cast(subexpression, ref typ) => {
visitor.visit_expr(subexpression, env.clone());
visitor.visit_ty(typ, env.clone())
}
expr_if(head_expression, ref if_block, optional_else) => {
visitor.visit_expr(head_expression, env.clone());
visitor.visit_block(if_block, env.clone());
walk_expr_opt(visitor, optional_else, env.clone())
}
expr_while(subexpression, ref block) => {
visitor.visit_expr(subexpression, env.clone());
visitor.visit_block(block, env.clone())
}
expr_for_loop(pattern, subexpression, ref block) => {
visitor.visit_pat(pattern, env.clone());
visitor.visit_expr(subexpression, env.clone());
visitor.visit_block(block, env.clone())
}
expr_loop(ref block, _) => visitor.visit_block(block, env.clone()),
expr_match(subexpression, ref arms) => {
visitor.visit_expr(subexpression, env.clone());
for arm in arms.iter() {
visitor.visit_arm(arm, env.clone())
}
}
expr_fn_block(ref function_declaration, ref body) => {
visitor.visit_fn(&fk_fn_block,
function_declaration,
body,
expression.span,
expression.id,
env.clone())
}
expr_block(ref block) => visitor.visit_block(block, env.clone()),
expr_assign(left_hand_expression, right_hand_expression) => {
visitor.visit_expr(right_hand_expression, env.clone());
visitor.visit_expr(left_hand_expression, env.clone())
}
expr_assign_op(_, _, left_expression, right_expression) => {
visitor.visit_expr(right_expression, env.clone());
visitor.visit_expr(left_expression, env.clone())
}
expr_field(subexpression, _, ref types) => {
visitor.visit_expr(subexpression, env.clone());
for typ in types.iter() {
visitor.visit_ty(typ, env.clone())
}
}
expr_index(_, main_expression, index_expression) => {
visitor.visit_expr(main_expression, env.clone());
visitor.visit_expr(index_expression, env.clone())
}
expr_path(ref path) => walk_path(visitor, path, env.clone()),
expr_self | expr_break(_) | expr_again(_) => {}
expr_ret(optional_expression) => {
walk_expr_opt(visitor, optional_expression, env.clone())
}
expr_log(level, subexpression) => {
visitor.visit_expr(level, env.clone());
visitor.visit_expr(subexpression, env.clone());
}
expr_mac(ref macro) => walk_mac(visitor, macro, env.clone()),
expr_paren(subexpression) => {
visitor.visit_expr(subexpression, env.clone())
}
expr_inline_asm(ref assembler) => {
for &(_, input) in assembler.inputs.iter() {
visitor.visit_expr(input, env.clone())
}
for &(_, output) in assembler.outputs.iter() {
visitor.visit_expr(output, env.clone())
}
}
}
visitor.visit_expr_post(expression, env.clone())
}
pub fn walk_arm<E:Clone, V:Visitor<E>>(visitor: &mut V, arm: &arm, env: E) {
for pattern in arm.pats.iter() {
visitor.visit_pat(*pattern, env.clone())
}
walk_expr_opt(visitor, arm.guard, env.clone());
visitor.visit_block(&arm.body, env)
}
// Simpler, non-context passing interface. Always walks the whole tree, simply
// calls the given functions on the nodes.
pub trait SimpleVisitor {
fn visit_mod(&mut self, &_mod, span, NodeId);
fn visit_view_item(&mut self, &view_item);
fn visit_foreign_item(&mut self, @foreign_item);
fn visit_item(&mut self, @item);
fn visit_local(&mut self, @Local);
fn visit_block(&mut self, &Block);
fn visit_stmt(&mut self, @stmt);
fn visit_arm(&mut self, &arm);
fn visit_pat(&mut self, @pat);
fn visit_decl(&mut self, @decl);
fn visit_expr(&mut self, @expr);
fn visit_expr_post(&mut self, @expr);
fn visit_ty(&mut self, &Ty);
fn visit_generics(&mut self, &Generics);
fn visit_fn(&mut self, &fn_kind, &fn_decl, &Block, span, NodeId);
fn visit_ty_method(&mut self, &TypeMethod);
fn visit_trait_method(&mut self, &trait_method);
fn visit_struct_def(&mut self, @struct_def, ident, &Generics, NodeId);
fn visit_struct_field(&mut self, @struct_field);
fn visit_struct_method(&mut self, @method);
}
pub struct SimpleVisitorVisitor {
simple_visitor: @mut SimpleVisitor,
}
impl Visitor<()> for SimpleVisitorVisitor {
fn visit_mod(&mut self,
module: &_mod,
span: span,
node_id: NodeId,
env: ()) {
self.simple_visitor.visit_mod(module, span, node_id);
walk_mod(self, module, env)
}
fn visit_view_item(&mut self, view_item: &view_item, env: ()) {
self.simple_visitor.visit_view_item(view_item);
walk_view_item(self, view_item, env)
}
fn visit_foreign_item(&mut self, foreign_item: @foreign_item, env: ()) {
self.simple_visitor.visit_foreign_item(foreign_item);
walk_foreign_item(self, foreign_item, env)
}
fn visit_item(&mut self, item: @item, env: ()) {
self.simple_visitor.visit_item(item);
walk_item(self, item, env)
}
fn visit_local(&mut self, local: @Local, env: ()) {
self.simple_visitor.visit_local(local);
walk_local(self, local, env)
}
fn visit_block(&mut self, block: &Block, env: ()) {
self.simple_visitor.visit_block(block);
walk_block(self, block, env)
}
fn visit_stmt(&mut self, statement: @stmt, env: ()) {
self.simple_visitor.visit_stmt(statement);
walk_stmt(self, statement, env)
}
fn visit_arm(&mut self, arm: &arm, env: ()) {
self.simple_visitor.visit_arm(arm);
walk_arm(self, arm, env)
}
fn visit_pat(&mut self, pattern: @pat, env: ()) {
self.simple_visitor.visit_pat(pattern);
walk_pat(self, pattern, env)
}
fn visit_decl(&mut self, declaration: @decl, env: ()) {
self.simple_visitor.visit_decl(declaration);
walk_decl(self, declaration, env)
}
fn visit_expr(&mut self, expression: @expr, env: ()) {
self.simple_visitor.visit_expr(expression);
walk_expr(self, expression, env)
}
fn visit_expr_post(&mut self, expression: @expr, _: ()) {
self.simple_visitor.visit_expr_post(expression)
}
fn visit_ty(&mut self, typ: &Ty, env: ()) {
self.simple_visitor.visit_ty(typ);
walk_ty(self, typ, env)
}
fn visit_generics(&mut self, generics: &Generics, env: ()) {
self.simple_visitor.visit_generics(generics);
walk_generics(self, generics, env)
}
fn visit_fn(&mut self,
function_kind: &fn_kind,
function_declaration: &fn_decl,
block: &Block,
span: span,
node_id: NodeId,
env: ()) {
self.simple_visitor.visit_fn(function_kind,
function_declaration,
block,
span,
node_id);
walk_fn(self,
function_kind,
function_declaration,
block,
span,
node_id,
env)
}
fn visit_ty_method(&mut self, method_type: &TypeMethod, env: ()) {
self.simple_visitor.visit_ty_method(method_type);
walk_ty_method(self, method_type, env)
}
fn visit_trait_method(&mut self, trait_method: &trait_method, env: ()) {
self.simple_visitor.visit_trait_method(trait_method);
walk_trait_method(self, trait_method, env)
}
fn visit_struct_def(&mut self,
struct_definition: @struct_def,
identifier: ident,
generics: &Generics,
node_id: NodeId,
env: ()) {
self.simple_visitor.visit_struct_def(struct_definition,
identifier,
generics,
node_id);
walk_struct_def(self,
struct_definition,
identifier,
generics,
node_id,
env)
}
fn visit_struct_field(&mut self, struct_field: @struct_field, env: ()) {
self.simple_visitor.visit_struct_field(struct_field);
walk_struct_field(self, struct_field, env)
}
}