2016-06-29 19:23:21 +00:00
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//! This module contains functions for retrieve the original AST from lowered `hir`.
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use rustc::hir;
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2016-06-30 17:49:34 +00:00
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use rustc::lint::LateContext;
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2016-06-29 19:23:21 +00:00
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use syntax::ast;
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2016-06-30 17:49:34 +00:00
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use syntax::ptr::P;
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use utils::{is_expn_of, match_path, paths};
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2016-06-29 19:23:21 +00:00
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/// Convert a hir binary operator to the corresponding `ast` type.
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pub fn binop(op: hir::BinOp_) -> ast::BinOpKind {
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match op {
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hir::BiEq => ast::BinOpKind::Eq,
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hir::BiGe => ast::BinOpKind::Ge,
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hir::BiGt => ast::BinOpKind::Gt,
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hir::BiLe => ast::BinOpKind::Le,
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hir::BiLt => ast::BinOpKind::Lt,
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hir::BiNe => ast::BinOpKind::Ne,
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hir::BiOr => ast::BinOpKind::Or,
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hir::BiAdd => ast::BinOpKind::Add,
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hir::BiAnd => ast::BinOpKind::And,
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hir::BiBitAnd => ast::BinOpKind::BitAnd,
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hir::BiBitOr => ast::BinOpKind::BitOr,
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hir::BiBitXor => ast::BinOpKind::BitXor,
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hir::BiDiv => ast::BinOpKind::Div,
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hir::BiMul => ast::BinOpKind::Mul,
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hir::BiRem => ast::BinOpKind::Rem,
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hir::BiShl => ast::BinOpKind::Shl,
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hir::BiShr => ast::BinOpKind::Shr,
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hir::BiSub => ast::BinOpKind::Sub,
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}
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}
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2016-06-29 21:16:44 +00:00
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/// Represent a range akin to `ast::ExprKind::Range`.
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#[derive(Debug, Copy, Clone)]
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pub struct Range<'a> {
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pub start: Option<&'a hir::Expr>,
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pub end: Option<&'a hir::Expr>,
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pub limits: ast::RangeLimits,
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}
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/// Higher a `hir` range to something similar to `ast::ExprKind::Range`.
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pub fn range(expr: &hir::Expr) -> Option<Range> {
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// To be removed when ranges get stable.
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fn unwrap_unstable(expr: &hir::Expr) -> &hir::Expr {
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if let hir::ExprBlock(ref block) = expr.node {
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if block.rules == hir::BlockCheckMode::PushUnstableBlock || block.rules == hir::BlockCheckMode::PopUnstableBlock {
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if let Some(ref expr) = block.expr {
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return expr;
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}
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}
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}
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expr
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}
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fn get_field<'a>(name: &str, fields: &'a [hir::Field]) -> Option<&'a hir::Expr> {
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let expr = &fields.iter()
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.find(|field| field.name.node.as_str() == name)
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.unwrap_or_else(|| panic!("missing {} field for range", name))
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.expr;
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Some(unwrap_unstable(expr))
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}
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// The range syntax is expanded to literal paths starting with `core` or `std` depending on
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// `#[no_std]`. Testing both instead of resolving the paths.
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match unwrap_unstable(expr).node {
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hir::ExprPath(None, ref path) => {
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if match_path(path, &paths::RANGE_FULL_STD) || match_path(path, &paths::RANGE_FULL) {
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Some(Range {
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start: None,
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end: None,
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limits: ast::RangeLimits::HalfOpen,
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})
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} else {
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None
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}
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}
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hir::ExprStruct(ref path, ref fields, None) => {
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if match_path(path, &paths::RANGE_FROM_STD) || match_path(path, &paths::RANGE_FROM) {
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Some(Range {
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start: get_field("start", fields),
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end: None,
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limits: ast::RangeLimits::HalfOpen,
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})
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} else if match_path(path, &paths::RANGE_INCLUSIVE_NON_EMPTY_STD) ||
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match_path(path, &paths::RANGE_INCLUSIVE_NON_EMPTY) {
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Some(Range {
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start: get_field("start", fields),
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end: get_field("end", fields),
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limits: ast::RangeLimits::Closed,
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})
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} else if match_path(path, &paths::RANGE_STD) || match_path(path, &paths::RANGE) {
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Some(Range {
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start: get_field("start", fields),
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end: get_field("end", fields),
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limits: ast::RangeLimits::HalfOpen,
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})
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} else if match_path(path, &paths::RANGE_TO_INCLUSIVE_STD) || match_path(path, &paths::RANGE_TO_INCLUSIVE) {
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Some(Range {
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start: None,
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end: get_field("end", fields),
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limits: ast::RangeLimits::Closed,
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})
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} else if match_path(path, &paths::RANGE_TO_STD) || match_path(path, &paths::RANGE_TO) {
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Some(Range {
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start: None,
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end: get_field("end", fields),
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limits: ast::RangeLimits::HalfOpen,
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})
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} else {
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None
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}
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}
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_ => None,
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}
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}
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2016-06-29 22:08:43 +00:00
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/// Checks if a `let` decl is from a `for` loop desugaring.
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pub fn is_from_for_desugar(decl: &hir::Decl) -> bool {
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if_let_chain! {[
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let hir::DeclLocal(ref loc) = decl.node,
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let Some(ref expr) = loc.init,
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let hir::ExprMatch(_, _, hir::MatchSource::ForLoopDesugar) = expr.node,
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], {
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return true;
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}}
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false
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}
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/// Recover the essential nodes of a desugared for loop:
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/// `for pat in arg { body }` becomes `(pat, arg, body)`.
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pub fn for_loop(expr: &hir::Expr) -> Option<(&hir::Pat, &hir::Expr, &hir::Expr)> {
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if_let_chain! {[
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let hir::ExprMatch(ref iterexpr, ref arms, _) = expr.node,
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let hir::ExprCall(_, ref iterargs) = iterexpr.node,
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iterargs.len() == 1 && arms.len() == 1 && arms[0].guard.is_none(),
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let hir::ExprLoop(ref block, _) = arms[0].body.node,
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block.stmts.is_empty(),
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let Some(ref loopexpr) = block.expr,
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let hir::ExprMatch(_, ref innerarms, hir::MatchSource::ForLoopDesugar) = loopexpr.node,
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innerarms.len() == 2 && innerarms[0].pats.len() == 1,
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let hir::PatKind::TupleStruct(_, ref somepats, _) = innerarms[0].pats[0].node,
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somepats.len() == 1
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], {
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return Some((&somepats[0],
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&iterargs[0],
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&innerarms[0].body));
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}}
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None
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}
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2016-06-30 17:49:34 +00:00
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/// Represent the pre-expansion arguments of a `vec!` invocation.
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pub enum VecArgs<'a> {
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/// `vec![elem; len]`
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Repeat(&'a P<hir::Expr>, &'a P<hir::Expr>),
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/// `vec![a, b, c]`
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Vec(&'a [P<hir::Expr>]),
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}
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/// Returns the arguments of the `vec!` macro if this expression was expanded from `vec!`.
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pub fn vec_macro<'e>(cx: &LateContext, expr: &'e hir::Expr) -> Option<VecArgs<'e>> {
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if_let_chain!{[
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let hir::ExprCall(ref fun, ref args) = expr.node,
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let hir::ExprPath(_, ref path) = fun.node,
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is_expn_of(cx, fun.span, "vec").is_some()
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], {
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return if match_path(path, &paths::VEC_FROM_ELEM) && args.len() == 2 {
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// `vec![elem; size]` case
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Some(VecArgs::Repeat(&args[0], &args[1]))
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}
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else if match_path(path, &["into_vec"]) && args.len() == 1 {
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// `vec![a, b, c]` case
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if_let_chain!{[
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let hir::ExprBox(ref boxed) = args[0].node,
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let hir::ExprVec(ref args) = boxed.node
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], {
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return Some(VecArgs::Vec(&*args));
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}}
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None
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}
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else {
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None
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};
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}}
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None
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}
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