rust/src/libsyntax/ast_util.rs

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// 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 <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.
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use ast::*;
use ast;
use ast_util;
use codemap::{Span, dummy_sp};
use opt_vec;
use parse::token;
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use visit::Visitor;
use visit;
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use std::hashmap::HashMap;
use std::u32;
use std::local_data;
use std::num;
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use std::option;
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pub fn path_name_i(idents: &[Ident]) -> ~str {
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// FIXME: Bad copies (#2543 -- same for everything else that says "bad")
idents.map(|i| token::interner_get(i.name)).connect("::")
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}
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// totally scary function: ignores all but the last element, should have
// a different name
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pub fn path_to_ident(path: &Path) -> Ident {
path.segments.last().identifier
}
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pub fn local_def(id: NodeId) -> DefId {
ast::DefId { crate: LOCAL_CRATE, node: id }
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}
pub fn is_local(did: ast::DefId) -> bool { did.crate == LOCAL_CRATE }
pub fn stmt_id(s: &Stmt) -> NodeId {
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match s.node {
StmtDecl(_, id) => id,
StmtExpr(_, id) => id,
StmtSemi(_, id) => id,
StmtMac(*) => fail!("attempted to analyze unexpanded stmt")
}
}
pub fn variant_def_ids(d: Def) -> Option<(DefId, DefId)> {
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match d {
DefVariant(enum_id, var_id, _) => {
Some((enum_id, var_id))
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}
_ => None
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}
}
pub fn def_id_of_def(d: Def) -> DefId {
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match d {
DefFn(id, _) | DefStaticMethod(id, _, _) | DefMod(id) |
DefForeignMod(id) | DefStatic(id, _) |
DefVariant(_, id, _) | DefTy(id) | DefTyParam(id, _) |
DefUse(id) | DefStruct(id) | DefTrait(id) | DefMethod(id, _) => {
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id
}
DefArg(id, _) | DefLocal(id, _) | DefSelf(id, _) | DefSelfTy(id)
| DefUpvar(id, _, _, _) | DefBinding(id, _) | DefRegion(id)
| DefTyParamBinder(id) | DefLabel(id) => {
local_def(id)
}
DefPrimTy(_) => fail!()
}
}
pub fn binop_to_str(op: BinOp) -> ~str {
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match op {
BiAdd => return ~"+",
BiSub => return ~"-",
BiMul => return ~"*",
BiDiv => return ~"/",
BiRem => return ~"%",
BiAnd => return ~"&&",
BiOr => return ~"||",
BiBitXor => return ~"^",
BiBitAnd => return ~"&",
BiBitOr => return ~"|",
BiShl => return ~"<<",
BiShr => return ~">>",
BiEq => return ~"==",
BiLt => return ~"<",
BiLe => return ~"<=",
BiNe => return ~"!=",
BiGe => return ~">=",
BiGt => return ~">"
}
}
pub fn binop_to_method_name(op: BinOp) -> Option<~str> {
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match op {
BiAdd => return Some(~"add"),
BiSub => return Some(~"sub"),
BiMul => return Some(~"mul"),
BiDiv => return Some(~"div"),
BiRem => return Some(~"rem"),
BiBitXor => return Some(~"bitxor"),
BiBitAnd => return Some(~"bitand"),
BiBitOr => return Some(~"bitor"),
BiShl => return Some(~"shl"),
BiShr => return Some(~"shr"),
BiLt => return Some(~"lt"),
BiLe => return Some(~"le"),
BiGe => return Some(~"ge"),
BiGt => return Some(~"gt"),
BiEq => return Some(~"eq"),
BiNe => return Some(~"ne"),
BiAnd | BiOr => return None
}
}
pub fn lazy_binop(b: BinOp) -> bool {
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match b {
BiAnd => true,
BiOr => true,
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_ => false
}
}
pub fn is_shift_binop(b: BinOp) -> bool {
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match b {
BiShl => true,
BiShr => true,
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_ => false
}
}
pub fn unop_to_str(op: UnOp) -> ~str {
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match op {
UnBox(mt) => if mt == MutMutable { ~"@mut " } else { ~"@" },
UnUniq => ~"~",
UnDeref => ~"*",
UnNot => ~"!",
UnNeg => ~"-"
}
}
pub fn is_path(e: @Expr) -> bool {
return match e.node { ExprPath(_) => true, _ => false };
}
pub fn int_ty_to_str(t: int_ty) -> ~str {
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match t {
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ty_i => ~"",
ty_i8 => ~"i8",
ty_i16 => ~"i16",
ty_i32 => ~"i32",
ty_i64 => ~"i64"
}
}
pub fn int_ty_max(t: int_ty) -> u64 {
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match t {
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ty_i8 => 0x80u64,
ty_i16 => 0x8000u64,
ty_i | ty_i32 => 0x80000000u64, // actually ni about ty_i
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ty_i64 => 0x8000000000000000u64
}
}
pub fn uint_ty_to_str(t: uint_ty) -> ~str {
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match t {
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ty_u => ~"u",
ty_u8 => ~"u8",
ty_u16 => ~"u16",
ty_u32 => ~"u32",
ty_u64 => ~"u64"
}
}
pub fn uint_ty_max(t: uint_ty) -> u64 {
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match t {
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ty_u8 => 0xffu64,
ty_u16 => 0xffffu64,
ty_u | ty_u32 => 0xffffffffu64, // actually ni about ty_u
ty_u64 => 0xffffffffffffffffu64
}
}
pub fn float_ty_to_str(t: float_ty) -> ~str {
match t { ty_f32 => ~"f32", ty_f64 => ~"f64" }
}
pub fn is_call_expr(e: @Expr) -> bool {
match e.node { ExprCall(*) => true, _ => false }
}
pub fn block_from_expr(e: @Expr) -> Block {
let mut blk = default_block(~[], option::Some::<@Expr>(e), e.id);
blk.span = e.span;
return blk;
}
pub fn default_block(
stmts1: ~[@Stmt],
expr1: Option<@Expr>,
id1: NodeId
) -> Block {
ast::Block {
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view_items: ~[],
stmts: stmts1,
expr: expr1,
id: id1,
rules: DefaultBlock,
span: dummy_sp(),
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}
}
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pub fn ident_to_path(s: Span, identifier: Ident) -> Path {
ast::Path {
span: s,
global: false,
segments: ~[
ast::PathSegment {
identifier: identifier,
lifetimes: opt_vec::Empty,
types: opt_vec::Empty,
}
],
}
}
pub fn ident_to_pat(id: NodeId, s: Span, i: Ident) -> @Pat {
@ast::Pat { id: id,
node: PatIdent(BindByValue(MutImmutable), ident_to_path(s, i), None),
span: s }
}
pub fn is_unguarded(a: &Arm) -> bool {
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match a.guard {
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None => true,
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_ => false
}
}
pub fn unguarded_pat(a: &Arm) -> Option<~[@Pat]> {
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if is_unguarded(a) {
Some(/* FIXME (#2543) */ a.pats.clone())
} else {
None
}
}
pub fn public_methods(ms: ~[@method]) -> ~[@method] {
ms.move_iter().filter(|m| {
match m.vis {
public => true,
_ => false
}
}).collect()
}
// extract a TypeMethod from a trait_method. if the trait_method is
// a default, pull out the useful fields to make a TypeMethod
pub fn trait_method_to_ty_method(method: &trait_method) -> TypeMethod {
match *method {
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required(ref m) => (*m).clone(),
provided(ref m) => {
TypeMethod {
ident: m.ident,
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attrs: m.attrs.clone(),
purity: m.purity,
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decl: m.decl.clone(),
generics: m.generics.clone(),
explicit_self: m.explicit_self,
id: m.id,
span: m.span,
}
}
}
}
pub fn split_trait_methods(trait_methods: &[trait_method])
-> (~[TypeMethod], ~[@method]) {
let mut reqd = ~[];
let mut provd = ~[];
for trt_method in trait_methods.iter() {
match *trt_method {
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required(ref tm) => reqd.push((*tm).clone()),
provided(m) => provd.push(m)
}
};
(reqd, provd)
}
pub fn struct_field_visibility(field: ast::struct_field) -> visibility {
match field.node.kind {
ast::named_field(_, visibility) => visibility,
ast::unnamed_field => ast::public
}
}
pub trait inlined_item_utils {
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fn ident(&self) -> Ident;
fn id(&self) -> ast::NodeId;
fn accept<E: Clone, V:Visitor<E>>(&self, e: E, v: &mut V);
}
impl inlined_item_utils for inlined_item {
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fn ident(&self) -> Ident {
match *self {
ii_item(i) => i.ident,
ii_foreign(i) => i.ident,
ii_method(_, _, m) => m.ident,
}
}
fn id(&self) -> ast::NodeId {
match *self {
ii_item(i) => i.id,
ii_foreign(i) => i.id,
ii_method(_, _, m) => m.id,
}
}
fn accept<E: Clone, V:Visitor<E>>(&self, e: E, v: &mut V) {
match *self {
ii_item(i) => v.visit_item(i, e),
ii_foreign(i) => v.visit_foreign_item(i, e),
ii_method(_, _, m) => visit::walk_method_helper(v, m, e),
}
}
}
/* True if d is either a def_self, or a chain of def_upvars
referring to a def_self */
pub fn is_self(d: ast::Def) -> bool {
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match d {
DefSelf(*) => true,
DefUpvar(_, d, _, _) => is_self(*d),
_ => false
}
}
/// Maps a binary operator to its precedence
pub fn operator_prec(op: ast::BinOp) -> uint {
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match op {
// 'as' sits here with 12
BiMul | BiDiv | BiRem => 11u,
BiAdd | BiSub => 10u,
BiShl | BiShr => 9u,
BiBitAnd => 8u,
BiBitXor => 7u,
BiBitOr => 6u,
BiLt | BiLe | BiGe | BiGt => 4u,
BiEq | BiNe => 3u,
BiAnd => 2u,
BiOr => 1u
}
}
/// Precedence of the `as` operator, which is a binary operator
/// not appearing in the prior table.
pub static as_prec: uint = 12u;
pub fn empty_generics() -> Generics {
Generics {lifetimes: opt_vec::Empty,
ty_params: opt_vec::Empty}
}
// ______________________________________________________________________
// Enumerating the IDs which appear in an AST
#[deriving(Encodable, Decodable)]
pub struct id_range {
min: NodeId,
max: NodeId,
}
impl id_range {
pub fn max() -> id_range {
id_range {
min: u32::max_value,
max: u32::min_value,
}
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}
pub fn empty(&self) -> bool {
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self.min >= self.max
}
pub fn add(&mut self, id: NodeId) {
self.min = num::min(self.min, id);
self.max = num::max(self.max, id + 1);
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}
}
pub trait IdVisitingOperation {
fn visit_id(&self, node_id: NodeId);
}
pub struct IdVisitor<'self, O> {
operation: &'self O,
pass_through_items: bool,
visited_outermost: bool,
}
impl<'self, O: IdVisitingOperation> IdVisitor<'self, O> {
fn visit_generics_helper(&self, generics: &Generics) {
for type_parameter in generics.ty_params.iter() {
self.operation.visit_id(type_parameter.id)
}
for lifetime in generics.lifetimes.iter() {
self.operation.visit_id(lifetime.id)
}
}
}
impl<'self, O: IdVisitingOperation> Visitor<()> for IdVisitor<'self, O> {
fn visit_mod(&mut self,
module: &_mod,
_: Span,
node_id: NodeId,
env: ()) {
self.operation.visit_id(node_id);
visit::walk_mod(self, module, env)
}
fn visit_view_item(&mut self, view_item: &view_item, env: ()) {
match view_item.node {
view_item_extern_mod(_, _, _, node_id) => {
self.operation.visit_id(node_id)
}
view_item_use(ref view_paths) => {
for view_path in view_paths.iter() {
match view_path.node {
view_path_simple(_, _, node_id) |
view_path_glob(_, node_id) => {
self.operation.visit_id(node_id)
}
view_path_list(_, ref paths, node_id) => {
self.operation.visit_id(node_id);
for path in paths.iter() {
self.operation.visit_id(path.node.id)
}
}
}
}
}
}
visit::walk_view_item(self, view_item, env)
}
fn visit_foreign_item(&mut self, foreign_item: @foreign_item, env: ()) {
self.operation.visit_id(foreign_item.id);
visit::walk_foreign_item(self, foreign_item, env)
}
fn visit_item(&mut self, item: @item, env: ()) {
if !self.pass_through_items {
if self.visited_outermost {
return
} else {
self.visited_outermost = true
}
}
self.operation.visit_id(item.id);
match item.node {
item_enum(ref enum_definition, _) => {
for variant in enum_definition.variants.iter() {
self.operation.visit_id(variant.node.id)
}
}
_ => {}
}
visit::walk_item(self, item, env);
self.visited_outermost = false
}
fn visit_local(&mut self, local: @Local, env: ()) {
self.operation.visit_id(local.id);
visit::walk_local(self, local, env)
}
fn visit_block(&mut self, block: &Block, env: ()) {
self.operation.visit_id(block.id);
visit::walk_block(self, block, env)
}
fn visit_stmt(&mut self, statement: @Stmt, env: ()) {
self.operation.visit_id(ast_util::stmt_id(statement));
visit::walk_stmt(self, statement, env)
}
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fn visit_pat(&mut self, pattern: &Pat, env: ()) {
self.operation.visit_id(pattern.id);
visit::walk_pat(self, pattern, env)
}
fn visit_expr(&mut self, expression: @Expr, env: ()) {
{
let optional_callee_id = expression.get_callee_id();
for callee_id in optional_callee_id.iter() {
self.operation.visit_id(*callee_id)
}
}
self.operation.visit_id(expression.id);
visit::walk_expr(self, expression, env)
}
fn visit_ty(&mut self, typ: &Ty, env: ()) {
self.operation.visit_id(typ.id);
match typ.node {
ty_path(_, _, id) => self.operation.visit_id(id),
_ => {}
}
visit::walk_ty(self, typ, env)
}
fn visit_generics(&mut self, generics: &Generics, env: ()) {
self.visit_generics_helper(generics);
visit::walk_generics(self, generics, env)
}
fn visit_fn(&mut self,
function_kind: &visit::fn_kind,
function_declaration: &fn_decl,
block: &Block,
span: Span,
node_id: NodeId,
env: ()) {
if !self.pass_through_items {
match *function_kind {
visit::fk_method(*) if self.visited_outermost => return,
visit::fk_method(*) => self.visited_outermost = true,
_ => {}
}
}
self.operation.visit_id(node_id);
match *function_kind {
visit::fk_item_fn(_, generics, _, _) => {
self.visit_generics_helper(generics)
}
visit::fk_method(_, generics, method) => {
self.operation.visit_id(method.self_id);
self.visit_generics_helper(generics)
}
visit::fk_anon(_) | visit::fk_fn_block => {}
}
for argument in function_declaration.inputs.iter() {
self.operation.visit_id(argument.id)
}
visit::walk_fn(self,
function_kind,
function_declaration,
block,
span,
node_id,
env);
if !self.pass_through_items {
match *function_kind {
visit::fk_method(*) => self.visited_outermost = false,
_ => {}
}
}
}
fn visit_struct_field(&mut self, struct_field: @struct_field, env: ()) {
self.operation.visit_id(struct_field.node.id);
visit::walk_struct_field(self, struct_field, env)
}
fn visit_struct_def(&mut self,
struct_def: @struct_def,
ident: ast::Ident,
generics: &ast::Generics,
id: NodeId,
_: ()) {
self.operation.visit_id(id);
struct_def.ctor_id.map(|ctor_id| self.operation.visit_id(ctor_id));
visit::walk_struct_def(self, struct_def, ident, generics, id, ());
}
fn visit_trait_method(&mut self, tm: &ast::trait_method, _: ()) {
match *tm {
ast::required(ref m) => self.operation.visit_id(m.id),
ast::provided(ref m) => self.operation.visit_id(m.id),
}
visit::walk_trait_method(self, tm, ());
}
}
pub fn visit_ids_for_inlined_item<O: IdVisitingOperation>(item: &inlined_item,
operation: &O) {
let mut id_visitor = IdVisitor {
operation: operation,
pass_through_items: true,
visited_outermost: false,
};
item.accept((), &mut id_visitor);
}
struct IdRangeComputingVisitor {
result: @mut id_range,
}
impl IdVisitingOperation for IdRangeComputingVisitor {
fn visit_id(&self, id: NodeId) {
self.result.add(id)
}
}
pub fn compute_id_range_for_inlined_item(item: &inlined_item) -> id_range {
let result = @mut id_range::max();
visit_ids_for_inlined_item(item, &IdRangeComputingVisitor {
result: result,
});
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*result
}
pub fn is_item_impl(item: @ast::item) -> bool {
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match item.node {
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item_impl(*) => true,
_ => false
}
}
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pub fn walk_pat(pat: &Pat, it: |&Pat| -> bool) -> bool {
if !it(pat) {
return false;
}
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match pat.node {
PatIdent(_, _, Some(p)) => walk_pat(p, it),
PatStruct(_, ref fields, _) => {
fields.iter().advance(|f| walk_pat(f.pat, |p| it(p)))
}
PatEnum(_, Some(ref s)) | PatTup(ref s) => {
s.iter().advance(|&p| walk_pat(p, |p| it(p)))
}
PatBox(s) | PatUniq(s) | PatRegion(s) => {
walk_pat(s, it)
}
PatVec(ref before, ref slice, ref after) => {
before.iter().advance(|&p| walk_pat(p, |p| it(p))) &&
slice.iter().advance(|&p| walk_pat(p, |p| it(p))) &&
after.iter().advance(|&p| walk_pat(p, |p| it(p)))
}
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PatWild | PatWildMulti | PatLit(_) | PatRange(_, _) | PatIdent(_, _, _) |
PatEnum(_, _) => {
true
}
}
}
pub trait EachViewItem {
fn each_view_item(&self, f: |&ast::view_item| -> bool) -> bool;
}
struct EachViewItemData<'self> {
callback: 'self |&ast::view_item| -> bool,
}
impl<'self> Visitor<()> for EachViewItemData<'self> {
fn visit_view_item(&mut self, view_item: &ast::view_item, _: ()) {
let _ = (self.callback)(view_item);
}
}
impl EachViewItem for ast::Crate {
fn each_view_item(&self, f: |&ast::view_item| -> bool) -> bool {
let mut visit = EachViewItemData {
callback: f,
};
visit::walk_crate(&mut visit, self, ());
true
}
}
pub fn view_path_id(p: &view_path) -> NodeId {
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match p.node {
view_path_simple(_, _, id) |
view_path_glob(_, id) |
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view_path_list(_, _, id) => id
}
}
/// Returns true if the given struct def is tuple-like; i.e. that its fields
/// are unnamed.
pub fn struct_def_is_tuple_like(struct_def: &ast::struct_def) -> bool {
struct_def.ctor_id.is_some()
}
/// Returns true if the given pattern consists solely of an identifier
/// and false otherwise.
pub fn pat_is_ident(pat: @ast::Pat) -> bool {
match pat.node {
ast::PatIdent(*) => true,
_ => false,
}
}
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// HYGIENE FUNCTIONS
/// Extend a syntax context with a given mark
pub fn new_mark(m:Mrk, tail:SyntaxContext) -> SyntaxContext {
new_mark_internal(m,tail,get_sctable())
}
// Extend a syntax context with a given mark and table
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// FIXME #8215 : currently pub to allow testing
pub fn new_mark_internal(m:Mrk, tail:SyntaxContext,table:&mut SCTable)
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-> SyntaxContext {
let key = (tail,m);
// FIXME #5074 : can't use more natural style because we're missing
// flow-sensitivity. Results in two lookups on a hash table hit.
// also applies to new_rename_internal, below.
// let try_lookup = table.mark_memo.find(&key);
match table.mark_memo.contains_key(&key) {
false => {
let new_idx = idx_push(&mut table.table,Mark(m,tail));
table.mark_memo.insert(key,new_idx);
new_idx
}
true => {
match table.mark_memo.find(&key) {
None => fail!("internal error: key disappeared 2013042901"),
Some(idxptr) => {*idxptr}
}
}
}
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}
/// Extend a syntax context with a given rename
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pub fn new_rename(id:Ident, to:Name, tail:SyntaxContext) -> SyntaxContext {
new_rename_internal(id, to, tail, get_sctable())
}
// Extend a syntax context with a given rename and sctable
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// FIXME #8215 : currently pub to allow testing
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pub fn new_rename_internal(id:Ident, to:Name, tail:SyntaxContext, table: &mut SCTable)
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-> SyntaxContext {
let key = (tail,id,to);
// FIXME #5074
//let try_lookup = table.rename_memo.find(&key);
match table.rename_memo.contains_key(&key) {
false => {
let new_idx = idx_push(&mut table.table,Rename(id,to,tail));
table.rename_memo.insert(key,new_idx);
new_idx
}
true => {
match table.rename_memo.find(&key) {
None => fail!("internal error: key disappeared 2013042902"),
Some(idxptr) => {*idxptr}
}
}
}
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}
/// Make a fresh syntax context table with EmptyCtxt in slot zero
/// and IllegalCtxt in slot one.
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// FIXME #8215 : currently pub to allow testing
pub fn new_sctable_internal() -> SCTable {
SCTable {
table: ~[EmptyCtxt,IllegalCtxt],
mark_memo: HashMap::new(),
rename_memo: HashMap::new()
}
}
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// fetch the SCTable from TLS, create one if it doesn't yet exist.
pub fn get_sctable() -> @mut SCTable {
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local_data_key!(sctable_key: @@mut SCTable)
match local_data::get(sctable_key, |k| k.map(|k| *k)) {
None => {
let new_table = @@mut new_sctable_internal();
local_data::set(sctable_key,new_table);
*new_table
},
Some(intr) => *intr
}
}
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/// print out an SCTable for debugging
pub fn display_sctable(table : &SCTable) {
error!("SC table:");
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for (idx,val) in table.table.iter().enumerate() {
error!("{:4u} : {:?}",idx,val);
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}
}
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/// Add a value to the end of a vec, return its index
fn idx_push<T>(vec: &mut ~[T], val: T) -> u32 {
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vec.push(val);
(vec.len() - 1) as u32
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}
/// Resolve a syntax object to a name, per MTWT.
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pub fn mtwt_resolve(id : Ident) -> Name {
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resolve_internal(id, get_sctable(), get_resolve_table())
}
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// FIXME #8215: must be pub for testing
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pub type ResolveTable = HashMap<(Name,SyntaxContext),Name>;
// okay, I admit, putting this in TLS is not so nice:
// fetch the SCTable from TLS, create one if it doesn't yet exist.
pub fn get_resolve_table() -> @mut ResolveTable {
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local_data_key!(resolve_table_key: @@mut ResolveTable)
match local_data::get(resolve_table_key, |k| k.map(|k| *k)) {
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None => {
let new_table = @@mut HashMap::new();
local_data::set(resolve_table_key,new_table);
*new_table
},
Some(intr) => *intr
}
}
// Resolve a syntax object to a name, per MTWT.
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// adding memoization to possibly resolve 500+ seconds in resolve for librustc (!)
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// FIXME #8215 : currently pub to allow testing
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pub fn resolve_internal(id : Ident,
table : &mut SCTable,
resolve_table : &mut ResolveTable) -> Name {
let key = (id.name,id.ctxt);
match resolve_table.contains_key(&key) {
false => {
let resolved = {
match table.table[id.ctxt] {
EmptyCtxt => id.name,
// ignore marks here:
Mark(_,subctxt) =>
resolve_internal(Ident{name:id.name, ctxt: subctxt},table,resolve_table),
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// do the rename if necessary:
Rename(Ident{name,ctxt},toname,subctxt) => {
let resolvedfrom =
resolve_internal(Ident{name:name,ctxt:ctxt},table,resolve_table);
let resolvedthis =
resolve_internal(Ident{name:id.name,ctxt:subctxt},table,resolve_table);
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if ((resolvedthis == resolvedfrom)
&& (marksof(ctxt,resolvedthis,table)
== marksof(subctxt,resolvedthis,table))) {
toname
} else {
resolvedthis
}
}
IllegalCtxt() => fail!("expected resolvable context, got IllegalCtxt")
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}
};
resolve_table.insert(key,resolved);
resolved
}
true => {
// it's guaranteed to be there, because we just checked that it was
// there and we never remove anything from the table:
*(resolve_table.find(&key).unwrap())
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}
}
}
/// Compute the marks associated with a syntax context.
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pub fn mtwt_marksof(ctxt: SyntaxContext, stopname: Name) -> ~[Mrk] {
marksof(ctxt, stopname, get_sctable())
}
// the internal function for computing marks
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// it's not clear to me whether it's better to use a [] mutable
// vector or a cons-list for this.
pub fn marksof(ctxt: SyntaxContext, stopname: Name, table: &SCTable) -> ~[Mrk] {
let mut result = ~[];
let mut loopvar = ctxt;
loop {
match table.table[loopvar] {
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EmptyCtxt => {return result;},
Mark(mark,tl) => {
xorPush(&mut result,mark);
loopvar = tl;
},
Rename(_,name,tl) => {
// see MTWT for details on the purpose of the stopname.
// short version: it prevents duplication of effort.
if (name == stopname) {
return result;
} else {
loopvar = tl;
}
}
IllegalCtxt => fail!("expected resolvable context, got IllegalCtxt")
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}
}
}
/// Return the outer mark for a context with a mark at the outside.
/// FAILS when outside is not a mark.
pub fn mtwt_outer_mark(ctxt: SyntaxContext) -> Mrk {
let sctable = get_sctable();
match sctable.table[ctxt] {
ast::Mark(mrk,_) => mrk,
_ => fail!("can't retrieve outer mark when outside is not a mark")
}
}
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/// Push a name... unless it matches the one on top, in which
/// case pop and discard (so two of the same marks cancel)
pub fn xorPush(marks: &mut ~[Mrk], mark: Mrk) {
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if ((marks.len() > 0) && (getLast(marks) == mark)) {
marks.pop();
} else {
marks.push(mark);
}
}
// get the last element of a mutable array.
// FIXME #4903: , must be a separate procedure for now.
pub fn getLast(arr: &~[Mrk]) -> Mrk {
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*arr.last()
}
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// are two paths equal when compared unhygienically?
// since I'm using this to replace ==, it seems appropriate
// to compare the span, global, etc. fields as well.
pub fn path_name_eq(a : &ast::Path, b : &ast::Path) -> bool {
(a.span == b.span)
&& (a.global == b.global)
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&& (segments_name_eq(a.segments, b.segments))
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}
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// are two arrays of segments equal when compared unhygienically?
pub fn segments_name_eq(a : &[ast::PathSegment], b : &[ast::PathSegment]) -> bool {
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if (a.len() != b.len()) {
false
} else {
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for (idx,seg) in a.iter().enumerate() {
if (seg.identifier.name != b[idx].identifier.name)
// FIXME #7743: ident -> name problems in lifetime comparison?
|| (seg.lifetimes != b[idx].lifetimes)
// can types contain idents?
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|| (seg.types != b[idx].types) {
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return false;
}
}
true
}
}
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#[cfg(test)]
mod test {
use ast::*;
use super::*;
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use opt_vec;
use std::hashmap::HashMap;
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fn ident_to_segment(id : &Ident) -> PathSegment {
PathSegment {identifier:id.clone(),
lifetimes: opt_vec::Empty,
types: opt_vec::Empty}
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}
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#[test] fn idents_name_eq_test() {
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assert!(segments_name_eq([Ident{name:3,ctxt:4},
Ident{name:78,ctxt:82}].map(ident_to_segment),
[Ident{name:3,ctxt:104},
Ident{name:78,ctxt:182}].map(ident_to_segment)));
assert!(!segments_name_eq([Ident{name:3,ctxt:4},
Ident{name:78,ctxt:82}].map(ident_to_segment),
[Ident{name:3,ctxt:104},
Ident{name:77,ctxt:182}].map(ident_to_segment)));
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}
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#[test] fn xorpush_test () {
let mut s = ~[];
xorPush(&mut s,14);
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assert_eq!(s.clone(),~[14]);
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xorPush(&mut s,14);
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assert_eq!(s.clone(),~[]);
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xorPush(&mut s,14);
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assert_eq!(s.clone(),~[14]);
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xorPush(&mut s,15);
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assert_eq!(s.clone(),~[14,15]);
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xorPush (&mut s,16);
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assert_eq!(s.clone(),~[14,15,16]);
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xorPush (&mut s,16);
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assert_eq!(s.clone(),~[14,15]);
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xorPush (&mut s,15);
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assert_eq!(s.clone(),~[14]);
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}
fn id(n: Name, s: SyntaxContext) -> Ident {
Ident {name: n, ctxt: s}
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}
// because of the SCTable, I now need a tidy way of
// creating syntax objects. Sigh.
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#[deriving(Clone, Eq)]
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enum TestSC {
M(Mrk),
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R(Ident,Name)
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}
// unfold a vector of TestSC values into a SCTable,
// returning the resulting index
fn unfold_test_sc(tscs : ~[TestSC], tail: SyntaxContext, table : &mut SCTable)
-> SyntaxContext {
tscs.rev_iter().fold(tail, |tail : SyntaxContext, tsc : &TestSC|
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{match *tsc {
M(mrk) => new_mark_internal(mrk,tail,table),
R(ident,name) => new_rename_internal(ident,name,tail,table)}})
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}
// gather a SyntaxContext back into a vector of TestSCs
fn refold_test_sc(mut sc: SyntaxContext, table : &SCTable) -> ~[TestSC] {
let mut result = ~[];
loop {
match table.table[sc] {
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EmptyCtxt => {return result;},
Mark(mrk,tail) => {
result.push(M(mrk));
sc = tail;
continue;
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},
Rename(id,name,tail) => {
result.push(R(id,name));
sc = tail;
continue;
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}
IllegalCtxt => fail!("expected resolvable context, got IllegalCtxt")
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}
}
}
#[test] fn test_unfold_refold(){
let mut t = new_sctable_internal();
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let test_sc = ~[M(3),R(id(101,0),14),M(9)];
assert_eq!(unfold_test_sc(test_sc.clone(),EMPTY_CTXT,&mut t),4);
assert_eq!(t.table[2],Mark(9,0));
assert_eq!(t.table[3],Rename(id(101,0),14,2));
assert_eq!(t.table[4],Mark(3,3));
assert_eq!(refold_test_sc(4,&t),test_sc);
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}
// extend a syntax context with a sequence of marks given
// in a vector. v[0] will be the outermost mark.
fn unfold_marks(mrks:~[Mrk],tail:SyntaxContext,table: &mut SCTable) -> SyntaxContext {
mrks.rev_iter().fold(tail, |tail:SyntaxContext, mrk:&Mrk|
{new_mark_internal(*mrk,tail,table)})
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}
#[test] fn unfold_marks_test() {
let mut t = new_sctable_internal();
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assert_eq!(unfold_marks(~[3,7],EMPTY_CTXT,&mut t),3);
assert_eq!(t.table[2],Mark(7,0));
assert_eq!(t.table[3],Mark(3,2));
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}
#[test] fn test_marksof () {
let stopname = 242;
let name1 = 243;
let mut t = new_sctable_internal();
assert_eq!(marksof (EMPTY_CTXT,stopname,&t),~[]);
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// FIXME #5074: ANF'd to dodge nested calls
{ let ans = unfold_marks(~[4,98],EMPTY_CTXT,&mut t);
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assert_eq! (marksof (ans,stopname,&t),~[4,98]);}
// does xoring work?
{ let ans = unfold_marks(~[5,5,16],EMPTY_CTXT,&mut t);
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assert_eq! (marksof (ans,stopname,&t), ~[16]);}
// does nested xoring work?
{ let ans = unfold_marks(~[5,10,10,5,16],EMPTY_CTXT,&mut t);
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assert_eq! (marksof (ans, stopname,&t), ~[16]);}
// rename where stop doesn't match:
{ let chain = ~[M(9),
R(id(name1,
new_mark_internal (4, EMPTY_CTXT,&mut t)),
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100101102),
M(14)];
let ans = unfold_test_sc(chain,EMPTY_CTXT,&mut t);
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assert_eq! (marksof (ans, stopname, &t), ~[9,14]);}
// rename where stop does match
{ let name1sc = new_mark_internal(4, EMPTY_CTXT, &mut t);
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let chain = ~[M(9),
R(id(name1, name1sc),
stopname),
M(14)];
let ans = unfold_test_sc(chain,EMPTY_CTXT,&mut t);
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assert_eq! (marksof (ans, stopname, &t), ~[9]); }
}
#[test] fn resolve_tests () {
let a = 40;
let mut t = new_sctable_internal();
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let mut rt = HashMap::new();
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// - ctxt is MT
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assert_eq!(resolve_internal(id(a,EMPTY_CTXT),&mut t, &mut rt),a);
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// - simple ignored marks
{ let sc = unfold_marks(~[1,2,3],EMPTY_CTXT,&mut t);
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assert_eq!(resolve_internal(id(a,sc),&mut t, &mut rt),a);}
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// - orthogonal rename where names don't match
{ let sc = unfold_test_sc(~[R(id(50,EMPTY_CTXT),51),M(12)],EMPTY_CTXT,&mut t);
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assert_eq!(resolve_internal(id(a,sc),&mut t, &mut rt),a);}
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// - rename where names do match, but marks don't
{ let sc1 = new_mark_internal(1,EMPTY_CTXT,&mut t);
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let sc = unfold_test_sc(~[R(id(a,sc1),50),
M(1),
M(2)],
EMPTY_CTXT,&mut t);
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assert_eq!(resolve_internal(id(a,sc),&mut t, &mut rt), a);}
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// - rename where names and marks match
{ let sc1 = unfold_test_sc(~[M(1),M(2)],EMPTY_CTXT,&mut t);
let sc = unfold_test_sc(~[R(id(a,sc1),50),M(1),M(2)],EMPTY_CTXT,&mut t);
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assert_eq!(resolve_internal(id(a,sc),&mut t, &mut rt), 50); }
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// - rename where names and marks match by literal sharing
{ let sc1 = unfold_test_sc(~[M(1),M(2)],EMPTY_CTXT,&mut t);
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let sc = unfold_test_sc(~[R(id(a,sc1),50)],sc1,&mut t);
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assert_eq!(resolve_internal(id(a,sc),&mut t, &mut rt), 50); }
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// - two renames of the same var.. can only happen if you use
// local-expand to prevent the inner binding from being renamed
// during the rename-pass caused by the first:
println("about to run bad test");
{ let sc = unfold_test_sc(~[R(id(a,EMPTY_CTXT),50),
R(id(a,EMPTY_CTXT),51)],
EMPTY_CTXT,&mut t);
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assert_eq!(resolve_internal(id(a,sc),&mut t, &mut rt), 51); }
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// the simplest double-rename:
{ let a_to_a50 = new_rename_internal(id(a,EMPTY_CTXT),50,EMPTY_CTXT,&mut t);
let a50_to_a51 = new_rename_internal(id(a,a_to_a50),51,a_to_a50,&mut t);
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assert_eq!(resolve_internal(id(a,a50_to_a51),&mut t, &mut rt),51);
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// mark on the outside doesn't stop rename:
let sc = new_mark_internal(9,a50_to_a51,&mut t);
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assert_eq!(resolve_internal(id(a,sc),&mut t, &mut rt),51);
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// but mark on the inside does:
let a50_to_a51_b = unfold_test_sc(~[R(id(a,a_to_a50),51),
M(9)],
a_to_a50,
&mut t);
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assert_eq!(resolve_internal(id(a,a50_to_a51_b),&mut t, &mut rt),50);}
}
#[test] fn mtwt_resolve_test(){
let a = 40;
assert_eq!(mtwt_resolve(id(a,EMPTY_CTXT)),a);
}
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#[test] fn hashing_tests () {
let mut t = new_sctable_internal();
assert_eq!(new_mark_internal(12,EMPTY_CTXT,&mut t),2);
assert_eq!(new_mark_internal(13,EMPTY_CTXT,&mut t),3);
// using the same one again should result in the same index:
assert_eq!(new_mark_internal(12,EMPTY_CTXT,&mut t),2);
// I'm assuming that the rename table will behave the same....
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}
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#[test] fn resolve_table_hashing_tests() {
let mut t = new_sctable_internal();
let mut rt = HashMap::new();
assert_eq!(rt.len(),0);
resolve_internal(id(30,EMPTY_CTXT),&mut t, &mut rt);
assert_eq!(rt.len(),1);
resolve_internal(id(39,EMPTY_CTXT),&mut t, &mut rt);
assert_eq!(rt.len(),2);
resolve_internal(id(30,EMPTY_CTXT),&mut t, &mut rt);
assert_eq!(rt.len(),2);
}
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}