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use reexport ::* ;
use rustc ::front ::map ::Node ::NodeBlock ;
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use rustc ::lint ::* ;
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use rustc ::middle ::const_eval ::EvalHint ::ExprTypeChecked ;
use rustc ::middle ::const_eval ::{ ConstVal , eval_const_expr_partial } ;
use rustc ::middle ::def ::Def ;
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use rustc ::middle ::region ::CodeExtent ;
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use rustc ::ty ;
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use rustc_front ::hir ::* ;
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use rustc_front ::intravisit ::{ Visitor , walk_expr , walk_block , walk_decl } ;
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use std ::borrow ::Cow ;
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use std ::collections ::HashMap ;
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use syntax ::ast ;
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use utils ::{ snippet , span_lint , get_parent_expr , match_trait_method , match_type , in_external_macro ,
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span_help_and_lint , is_integer_literal , get_enclosing_block , span_lint_and_then ,
unsugar_range , walk_ptrs_ty } ;
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use utils ::{ BTREEMAP_PATH , HASHMAP_PATH , LL_PATH , OPTION_PATH , RESULT_PATH , VEC_PATH } ;
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use utils ::UnsugaredRange ;
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/// **What it does:** This lint checks for looping over the range of `0..len` of some collection just to get the values by index.
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///
/// **Why is this bad?** Just iterating the collection itself makes the intent more clear and is probably faster.
///
/// **Known problems:** None
///
/// **Example:**
/// ```
/// for i in 0..vec.len() {
/// println!("{}", vec[i]);
/// }
/// ```
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declare_lint! {
pub NEEDLESS_RANGE_LOOP ,
Warn ,
" for-looping over a range of indices where an iterator over items would do "
}
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/// **What it does:** This lint checks for loops on `x.iter()` where `&x` will do, and suggest the latter.
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///
/// **Why is this bad?** Readability.
///
/// **Known problems:** False negatives. We currently only warn on some known types.
///
/// **Example:** `for x in y.iter() { .. }` (where y is a `Vec` or slice)
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declare_lint! {
pub EXPLICIT_ITER_LOOP ,
Warn ,
" for-looping over `_.iter()` or `_.iter_mut()` when `&_` or `&mut _` would do "
}
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/// **What it does:** This lint checks for loops on `x.next()`.
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///
/// **Why is this bad?** `next()` returns either `Some(value)` if there was a value, or `None` otherwise. The insidious thing is that `Option<_>` implements `IntoIterator`, so that possibly one value will be iterated, leading to some hard to find bugs. No one will want to write such code [except to win an Underhanded Rust Contest](https://www.reddit.com/r/rust/comments/3hb0wm/underhanded_rust_contest/cu5yuhr).
///
/// **Known problems:** None
///
/// **Example:** `for x in y.next() { .. }`
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declare_lint! {
pub ITER_NEXT_LOOP ,
Warn ,
" for-looping over `_.next()` which is probably not intended "
}
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/// **What it does:** This lint checks for `for` loops over `Option` values.
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///
/// **Why is this bad?** Readability. This is more clearly expressed as an `if let`.
///
/// **Known problems:** None
///
/// **Example:** `for x in option { .. }`. This should be `if let Some(x) = option { .. }`.
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declare_lint! {
pub FOR_LOOP_OVER_OPTION ,
Warn ,
" for-looping over an `Option`, which is more clearly expressed as an `if let` "
}
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/// **What it does:** This lint checks for `for` loops over `Result` values.
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///
/// **Why is this bad?** Readability. This is more clearly expressed as an `if let`.
///
/// **Known problems:** None
///
/// **Example:** `for x in result { .. }`. This should be `if let Ok(x) = result { .. }`.
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declare_lint! {
pub FOR_LOOP_OVER_RESULT ,
Warn ,
" for-looping over a `Result`, which is more clearly expressed as an `if let` "
}
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/// **What it does:** This lint detects `loop + match` combinations that are easier written as a `while let` loop.
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///
/// **Why is this bad?** The `while let` loop is usually shorter and more readable
///
/// **Known problems:** Sometimes the wrong binding is displayed (#383)
///
/// **Example:**
///
/// ```
/// loop {
/// let x = match y {
/// Some(x) => x,
/// None => break,
/// }
/// // .. do something with x
/// }
/// // is easier written as
/// while let Some(x) = y {
/// // .. do something with x
/// }
/// ```
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declare_lint! {
pub WHILE_LET_LOOP ,
Warn ,
" `loop { if let { ... } else break }` can be written as a `while let` loop "
}
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/// **What it does:** This lint checks for using `collect()` on an iterator without using the result.
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///
/// **Why is this bad?** It is more idiomatic to use a `for` loop over the iterator instead.
///
/// **Known problems:** None
///
/// **Example:** `vec.iter().map(|x| /* some operation returning () */).collect::<Vec<_>>();`
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declare_lint! {
pub UNUSED_COLLECT ,
Warn ,
" `collect()`ing an iterator without using the result; this is usually better \
written as a for loop "
}
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/// **What it does:** This lint checks for loops over ranges `x..y` where both `x` and `y` are constant and `x` is greater or equal to `y`, unless the range is reversed or has a negative `.step_by(_)`.
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///
/// **Why is it bad?** Such loops will either be skipped or loop until wrap-around (in debug code, this may `panic!()`). Both options are probably not intended.
///
/// **Known problems:** The lint cannot catch loops over dynamically defined ranges. Doing this would require simulating all possible inputs and code paths through the program, which would be complex and error-prone.
///
/// **Examples**: `for x in 5..10-5 { .. }` (oops, stray `-`)
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declare_lint! {
pub REVERSE_RANGE_LOOP ,
Warn ,
" Iterating over an empty range, such as `10..0` or `5..5` "
}
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/// **What it does:** This lint checks `for` loops over slices with an explicit counter and suggests the use of `.enumerate()`.
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///
/// **Why is it bad?** Not only is the version using `.enumerate()` more readable, the compiler is able to remove bounds checks which can lead to faster code in some instances.
///
/// **Known problems:** None.
///
/// **Example:** `for i in 0..v.len() { foo(v[i]); }` or `for i in 0..v.len() { bar(i, v[i]); }`
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declare_lint! {
pub EXPLICIT_COUNTER_LOOP ,
Warn ,
" for-looping with an explicit counter when `_.enumerate()` would do "
}
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/// **What it does:** This lint checks for empty `loop` expressions.
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///
/// **Why is this bad?** Those busy loops burn CPU cycles without doing anything. Think of the environment and either block on something or at least make the thread sleep for some microseconds.
///
/// **Known problems:** None
///
/// **Example:** `loop {}`
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declare_lint! {
pub EMPTY_LOOP ,
Warn ,
" empty `loop {}` detected "
}
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/// **What it does:** This lint checks for `while let` expressions on iterators.
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///
/// **Why is this bad?** Readability. A simple `for` loop is shorter and conveys the intent better.
///
/// **Known problems:** None
///
/// **Example:** `while let Some(val) = iter() { .. }`
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declare_lint! {
pub WHILE_LET_ON_ITERATOR ,
Warn ,
" using a while-let loop instead of a for loop on an iterator "
}
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/// **What it does:** This warns when you iterate on a map (`HashMap` or `BTreeMap`) and ignore
/// either the keys or values.
///
/// **Why is this bad?** Readability. There are `keys` and `values` methods that can be used to
/// express that don't need the values or keys.
///
/// **Known problems:** None
///
/// **Example:**
/// ```rust
/// for (k, _) in &map { .. }
/// ```
/// could be replaced by
/// ```rust
/// for k in map.keys() { .. }
/// ```
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declare_lint! {
pub FOR_KV_MAP ,
Warn ,
" looping on a map using `iter` when `keys` or `values` would do "
}
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#[ derive(Copy, Clone) ]
pub struct LoopsPass ;
impl LintPass for LoopsPass {
fn get_lints ( & self ) -> LintArray {
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lint_array! ( NEEDLESS_RANGE_LOOP ,
EXPLICIT_ITER_LOOP ,
ITER_NEXT_LOOP ,
WHILE_LET_LOOP ,
UNUSED_COLLECT ,
REVERSE_RANGE_LOOP ,
EXPLICIT_COUNTER_LOOP ,
EMPTY_LOOP ,
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WHILE_LET_ON_ITERATOR ,
FOR_KV_MAP )
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}
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}
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impl LateLintPass for LoopsPass {
fn check_expr ( & mut self , cx : & LateContext , expr : & Expr ) {
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if let Some ( ( pat , arg , body ) ) = recover_for_loop ( expr ) {
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check_for_loop ( cx , pat , arg , body , expr ) ;
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}
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// check for `loop { if let {} else break }` that could be `while let`
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// (also matches an explicit "match" instead of "if let")
// (even if the "match" or "if let" is used for declaration)
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if let ExprLoop ( ref block , _ ) = expr . node {
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// also check for empty `loop {}` statements
if block . stmts . is_empty ( ) & & block . expr . is_none ( ) {
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span_lint ( cx ,
EMPTY_LOOP ,
expr . span ,
" empty `loop {}` detected. You may want to either use `panic!()` or add \
` std ::thread ::sleep ( .. ) ; ` to the loop body . " );
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}
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// extract the expression from the first statement (if any) in a block
let inner_stmt_expr = extract_expr_from_first_stmt ( block ) ;
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// or extract the first expression (if any) from the block
if let Some ( inner ) = inner_stmt_expr . or_else ( | | extract_first_expr ( block ) ) {
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if let ExprMatch ( ref matchexpr , ref arms , ref source ) = inner . node {
// ensure "if let" compatible match structure
match * source {
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MatchSource ::Normal | MatchSource ::IfLetDesugar { .. } = > {
if arms . len ( ) = = 2 & & arms [ 0 ] . pats . len ( ) = = 1 & & arms [ 0 ] . guard . is_none ( ) & &
arms [ 1 ] . pats . len ( ) = = 1 & & arms [ 1 ] . guard . is_none ( ) & &
is_break_expr ( & arms [ 1 ] . body ) {
if in_external_macro ( cx , expr . span ) {
return ;
}
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// NOTE: we used to make build a body here instead of using
// ellipsis, this was removed because:
// 1) it was ugly with big bodies;
// 2) it was not indented properly;
// 3) it wasn’ t very smart (see #675).
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span_lint_and_then ( cx ,
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WHILE_LET_LOOP ,
expr . span ,
" this loop could be written as a `while let` loop " ,
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| db | {
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let sug = format! ( " while let {} = {} {{ .. }} " ,
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snippet ( cx , arms [ 0 ] . pats [ 0 ] . span , " .. " ) ,
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snippet ( cx , matchexpr . span , " .. " ) ) ;
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db . span_suggestion ( expr . span , " try " , sug ) ;
} ) ;
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}
}
_ = > ( ) ,
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}
}
}
}
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if let ExprMatch ( ref match_expr , ref arms , MatchSource ::WhileLetDesugar ) = expr . node {
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let pat = & arms [ 0 ] . pats [ 0 ] . node ;
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if let ( & PatKind ::TupleStruct ( ref path , Some ( ref pat_args ) ) ,
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& ExprMethodCall ( method_name , _ , ref method_args ) ) = ( pat , & match_expr . node ) {
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let iter_expr = & method_args [ 0 ] ;
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if let Some ( lhs_constructor ) = path . segments . last ( ) {
if method_name . node . as_str ( ) = = " next " & &
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match_trait_method ( cx , match_expr , & [ " core " , " iter " , " Iterator " ] ) & &
lhs_constructor . identifier . name . as_str ( ) = = " Some " & &
! is_iterator_used_after_while_let ( cx , iter_expr ) {
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let iterator = snippet ( cx , method_args [ 0 ] . span , " _ " ) ;
let loop_var = snippet ( cx , pat_args [ 0 ] . span , " _ " ) ;
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span_help_and_lint ( cx ,
WHILE_LET_ON_ITERATOR ,
expr . span ,
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" this loop could be written as a `for` loop " ,
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& format! ( " try \n for {} in {} {{ ... }} " , loop_var , iterator ) ) ;
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}
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}
}
}
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}
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fn check_stmt ( & mut self , cx : & LateContext , stmt : & Stmt ) {
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if let StmtSemi ( ref expr , _ ) = stmt . node {
if let ExprMethodCall ( ref method , _ , ref args ) = expr . node {
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if args . len ( ) = = 1 & & method . node . as_str ( ) = = " collect " & &
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match_trait_method ( cx , expr , & [ " core " , " iter " , " Iterator " ] ) {
span_lint ( cx ,
UNUSED_COLLECT ,
expr . span ,
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" you are collect()ing an iterator and throwing away the result. \
Consider using an explicit for loop to exhaust the iterator " );
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}
}
}
}
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}
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fn check_for_loop ( cx : & LateContext , pat : & Pat , arg : & Expr , body : & Expr , expr : & Expr ) {
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check_for_loop_range ( cx , pat , arg , body , expr ) ;
check_for_loop_reverse_range ( cx , arg , expr ) ;
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check_for_loop_arg ( cx , pat , arg , expr ) ;
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check_for_loop_explicit_counter ( cx , arg , body , expr ) ;
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check_for_loop_over_map_kv ( cx , pat , arg , body , expr ) ;
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}
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/// Check for looping over a range and then indexing a sequence with it.
/// The iteratee must be a range literal.
fn check_for_loop_range ( cx : & LateContext , pat : & Pat , arg : & Expr , body : & Expr , expr : & Expr ) {
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if let Some ( UnsugaredRange { start : Some ( ref start ) , ref end , .. } ) = unsugar_range ( & arg ) {
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// the var must be a single name
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if let PatKind ::Ident ( _ , ref ident , _ ) = pat . node {
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let mut visitor = VarVisitor {
cx : cx ,
var : ident . node . name ,
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indexed : HashMap ::new ( ) ,
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nonindex : false ,
} ;
walk_expr ( & mut visitor , body ) ;
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// linting condition: we only indexed one variable
if visitor . indexed . len ( ) = = 1 {
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let ( indexed , indexed_extent ) = visitor . indexed
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. into_iter ( )
. next ( )
. unwrap_or_else ( | | unreachable! ( ) /* len == 1 */ ) ;
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// ensure that the indexed variable was declared before the loop, see #601
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if let Some ( indexed_extent ) = indexed_extent {
let pat_extent = cx . tcx . region_maps . var_scope ( pat . id ) ;
if cx . tcx . region_maps . is_subscope_of ( indexed_extent , pat_extent ) {
return ;
}
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}
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let starts_at_zero = is_integer_literal ( start , 0 ) ;
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let skip : Cow < _ > = if starts_at_zero {
" " . into ( )
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} else {
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format! ( " .skip( {} ) " , snippet ( cx , start . span , " .. " ) ) . into ( )
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} ;
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let take : Cow < _ > = if let Some ( ref end ) = * end {
if is_len_call ( & end , & indexed ) {
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" " . into ( )
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} else {
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format! ( " .take( {} ) " , snippet ( cx , end . span , " .. " ) ) . into ( )
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}
} else {
" " . into ( )
} ;
if visitor . nonindex {
span_lint ( cx ,
NEEDLESS_RANGE_LOOP ,
expr . span ,
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& format! ( " the loop variable ` {} ` is used to index ` {} `. Consider using `for ( {} , \
item ) in { } . iter ( ) . enumerate ( ) { } { } ` or similar iterators " ,
ident . node . name ,
indexed ,
ident . node . name ,
indexed ,
take ,
skip ) ) ;
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} else {
let repl = if starts_at_zero & & take . is_empty ( ) {
format! ( " & {} " , indexed )
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} else {
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format! ( " {} .iter() {} {} " , indexed , take , skip )
} ;
span_lint ( cx ,
NEEDLESS_RANGE_LOOP ,
expr . span ,
& format! ( " the loop variable ` {} ` is only used to index ` {} `. \
Consider using ` for item in { } ` or similar iterators " ,
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ident . node . name ,
indexed ,
repl ) ) ;
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}
}
}
}
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}
fn is_len_call ( expr : & Expr , var : & Name ) -> bool {
if_let_chain! { [
let ExprMethodCall ( method , _ , ref len_args ) = expr . node ,
len_args . len ( ) = = 1 ,
method . node . as_str ( ) = = " len " ,
let ExprPath ( _ , ref path ) = len_args [ 0 ] . node ,
path . segments . len ( ) = = 1 ,
& path . segments [ 0 ] . identifier . name = = var
] , {
return true ;
} }
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false
}
fn check_for_loop_reverse_range ( cx : & LateContext , arg : & Expr , expr : & Expr ) {
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// if this for loop is iterating over a two-sided range...
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if let Some ( UnsugaredRange { start : Some ( ref start ) , end : Some ( ref end ) , limits } ) = unsugar_range ( & arg ) {
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// ...and both sides are compile-time constant integers...
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if let Ok ( start_idx ) = eval_const_expr_partial ( & cx . tcx , start , ExprTypeChecked , None ) {
if let Ok ( end_idx ) = eval_const_expr_partial ( & cx . tcx , end , ExprTypeChecked , None ) {
// ...and the start index is greater than the end index,
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// this loop will never run. This is often confusing for developers
// who think that this will iterate from the larger value to the
// smaller value.
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let ( sup , eq ) = match ( start_idx , end_idx ) {
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( ConstVal ::Integral ( start_idx ) , ConstVal ::Integral ( end_idx ) ) = > {
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( start_idx > end_idx , start_idx = = end_idx )
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}
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_ = > ( false , false ) ,
} ;
if sup {
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let start_snippet = snippet ( cx , start . span , " _ " ) ;
let end_snippet = snippet ( cx , end . span , " _ " ) ;
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span_lint_and_then ( cx ,
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REVERSE_RANGE_LOOP ,
expr . span ,
" this range is empty so this for loop will never run " ,
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| db | {
db . span_suggestion ( expr . span ,
" consider using the following if \
you are attempting to iterate \
over this range in reverse " ,
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format! ( " ( {} .. {} ).rev()` " , end_snippet , start_snippet ) ) ;
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} ) ;
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} else if eq & & limits ! = ast ::RangeLimits ::Closed {
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// if they are equal, it's also problematic - this loop
// will never run.
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span_lint ( cx ,
REVERSE_RANGE_LOOP ,
expr . span ,
" this range is empty so this for loop will never run " ) ;
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}
}
}
}
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}
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fn check_for_loop_arg ( cx : & LateContext , pat : & Pat , arg : & Expr , expr : & Expr ) {
let mut next_loop_linted = false ; // whether or not ITER_NEXT_LOOP lint was used
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if let ExprMethodCall ( ref method , _ , ref args ) = arg . node {
// just the receiver, no arguments
if args . len ( ) = = 1 {
let method_name = method . node ;
// check for looping over x.iter() or x.iter_mut(), could use &x or &mut x
if method_name . as_str ( ) = = " iter " | | method_name . as_str ( ) = = " iter_mut " {
if is_ref_iterable_type ( cx , & args [ 0 ] ) {
let object = snippet ( cx , args [ 0 ] . span , " _ " ) ;
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span_lint ( cx ,
EXPLICIT_ITER_LOOP ,
expr . span ,
& format! ( " it is more idiomatic to loop over `& {} {} ` instead of ` {} . {} ()` " ,
if method_name . as_str ( ) = = " iter_mut " {
" mut "
} else {
" "
} ,
object ,
object ,
method_name ) ) ;
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}
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} else if method_name . as_str ( ) = = " next " & & match_trait_method ( cx , arg , & [ " core " , " iter " , " Iterator " ] ) {
span_lint ( cx ,
ITER_NEXT_LOOP ,
expr . span ,
" you are iterating over `Iterator::next()` which is an Option; this will compile but is \
probably not what you want " );
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next_loop_linted = true ;
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}
}
}
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if ! next_loop_linted {
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check_arg_type ( cx , pat , arg ) ;
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}
}
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/// Check for `for` loops over `Option`s and `Results`
fn check_arg_type ( cx : & LateContext , pat : & Pat , arg : & Expr ) {
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let ty = cx . tcx . expr_ty ( arg ) ;
if match_type ( cx , ty , & OPTION_PATH ) {
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span_help_and_lint ( cx ,
FOR_LOOP_OVER_OPTION ,
arg . span ,
& format! ( " for loop over ` {0} `, which is an `Option`. This is more readably written as an \
` if let ` statement . " ,
snippet ( cx , arg . span , " _ " ) ) ,
& format! ( " consider replacing `for {0} in {1} ` with `if let Some( {0} ) = {1} ` " ,
snippet ( cx , pat . span , " _ " ) ,
snippet ( cx , arg . span , " _ " ) ) ) ;
} else if match_type ( cx , ty , & RESULT_PATH ) {
span_help_and_lint ( cx ,
FOR_LOOP_OVER_RESULT ,
arg . span ,
& format! ( " for loop over ` {0} `, which is a `Result`. This is more readably written as an \
` if let ` statement . " ,
snippet ( cx , arg . span , " _ " ) ) ,
& format! ( " consider replacing `for {0} in {1} ` with `if let Ok( {0} ) = {1} ` " ,
snippet ( cx , pat . span , " _ " ) ,
snippet ( cx , arg . span , " _ " ) ) ) ;
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}
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}
fn check_for_loop_explicit_counter ( cx : & LateContext , arg : & Expr , body : & Expr , expr : & Expr ) {
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// Look for variables that are incremented once per loop iteration.
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let mut visitor = IncrementVisitor {
cx : cx ,
states : HashMap ::new ( ) ,
depth : 0 ,
done : false ,
} ;
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walk_expr ( & mut visitor , body ) ;
// For each candidate, check the parent block to see if
// it's initialized to zero at the start of the loop.
let map = & cx . tcx . map ;
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let parent_scope = map . get_enclosing_scope ( expr . id ) . and_then ( | id | map . get_enclosing_scope ( id ) ) ;
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if let Some ( parent_id ) = parent_scope {
if let NodeBlock ( block ) = map . get ( parent_id ) {
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for ( id , _ ) in visitor . states . iter ( ) . filter ( | & ( _ , v ) | * v = = VarState ::IncrOnce ) {
let mut visitor2 = InitializeVisitor {
cx : cx ,
end_expr : expr ,
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var_id : * id ,
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state : VarState ::IncrOnce ,
name : None ,
depth : 0 ,
past_loop : false ,
} ;
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walk_block ( & mut visitor2 , block ) ;
if visitor2 . state = = VarState ::Warn {
if let Some ( name ) = visitor2 . name {
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span_lint ( cx ,
EXPLICIT_COUNTER_LOOP ,
expr . span ,
& format! ( " the variable ` {0} ` is used as a loop counter. Consider using `for ( {0} , \
item ) in { 1 } . enumerate ( ) ` or similar iterators " ,
name ,
snippet ( cx , arg . span , " _ " ) ) ) ;
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}
}
}
}
}
}
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/// Check for the FOR_KV_MAP lint.
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fn check_for_loop_over_map_kv ( cx : & LateContext , pat : & Pat , arg : & Expr , body : & Expr , expr : & Expr ) {
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if let PatKind ::Tup ( ref pat ) = pat . node {
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if pat . len ( ) = = 2 {
let ( pat_span , kind ) = match ( & pat [ 0 ] . node , & pat [ 1 ] . node ) {
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( key , _ ) if pat_is_wild ( key , body ) = > ( & pat [ 1 ] . span , " values " ) ,
( _ , value ) if pat_is_wild ( value , body ) = > ( & pat [ 0 ] . span , " keys " ) ,
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_ = > return ,
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} ;
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let arg_span = match arg . node {
ExprAddrOf ( MutImmutable , ref expr ) = > expr . span ,
ExprAddrOf ( MutMutable , _ ) = > return , // for _ in &mut _, there is no {values,keys}_mut method
_ = > arg . span ,
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} ;
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let ty = walk_ptrs_ty ( cx . tcx . expr_ty ( arg ) ) ;
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if match_type ( cx , ty , & HASHMAP_PATH ) | | match_type ( cx , ty , & BTREEMAP_PATH ) {
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span_lint_and_then ( cx ,
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FOR_KV_MAP ,
expr . span ,
& format! ( " you seem to want to iterate on a map's {} " , kind ) ,
| db | {
db . span_suggestion ( expr . span ,
" use the corresponding method " ,
format! ( " for {} in {} . {} () {{ ... }} " ,
snippet ( cx , * pat_span , " .. " ) ,
snippet ( cx , arg_span , " .. " ) ,
kind ) ) ;
} ) ;
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}
}
}
}
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/// Return true if the pattern is a `PatWild` or an ident prefixed with '_'.
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fn pat_is_wild ( pat : & PatKind , body : & Expr ) -> bool {
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match * pat {
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PatKind ::Wild = > true ,
PatKind ::Ident ( _ , ident , None ) if ident . node . name . as_str ( ) . starts_with ( '_' ) = > {
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let mut visitor = UsedVisitor {
var : ident . node ,
used : false ,
} ;
walk_expr ( & mut visitor , body ) ;
! visitor . used
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}
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_ = > false ,
}
}
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struct UsedVisitor {
var : Ident , // var to look for
used : bool , // has the var been used otherwise?
}
impl < ' a > Visitor < ' a > for UsedVisitor {
fn visit_expr ( & mut self , expr : & Expr ) {
if let ExprPath ( None , ref path ) = expr . node {
if path . segments . len ( ) = = 1 & & path . segments [ 0 ] . identifier = = self . var {
self . used = true ;
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return ;
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}
}
walk_expr ( self , expr ) ;
}
}
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/// Recover the essential nodes of a desugared for loop:
/// `for pat in arg { body }` becomes `(pat, arg, body)`.
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fn recover_for_loop ( expr : & Expr ) -> Option < ( & Pat , & Expr , & Expr ) > {
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if_let_chain! {
[
let ExprMatch ( ref iterexpr , ref arms , _ ) = expr . node ,
let 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 ExprLoop ( ref block , _ ) = arms [ 0 ] . body . node ,
block . stmts . is_empty ( ) ,
let Some ( ref loopexpr ) = block . expr ,
let ExprMatch ( _ , ref innerarms , MatchSource ::ForLoopDesugar ) = loopexpr . node ,
innerarms . len ( ) = = 2 & & innerarms [ 0 ] . pats . len ( ) = = 1 ,
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let PatKind ::TupleStruct ( _ , Some ( ref somepats ) ) = innerarms [ 0 ] . pats [ 0 ] . node ,
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somepats . len ( ) = = 1
] , {
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return Some ( ( & somepats [ 0 ] ,
& iterargs [ 0 ] ,
& innerarms [ 0 ] . body ) ) ;
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}
}
None
}
struct VarVisitor < ' v , ' t : ' v > {
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cx : & ' v LateContext < ' v , ' t > , // context reference
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var : Name , // var name to look for as index
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indexed : HashMap < Name , Option < CodeExtent > > , // indexed variables, the extent is None for global
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nonindex : bool , // has the var been used otherwise?
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}
impl < ' v , ' t > Visitor < ' v > for VarVisitor < ' v , ' t > {
fn visit_expr ( & mut self , expr : & ' v Expr ) {
if let ExprPath ( None , ref path ) = expr . node {
if path . segments . len ( ) = = 1 & & path . segments [ 0 ] . identifier . name = = self . var {
// we are referencing our variable! now check if it's as an index
if_let_chain! {
[
let Some ( parexpr ) = get_parent_expr ( self . cx , expr ) ,
let ExprIndex ( ref seqexpr , _ ) = parexpr . node ,
let ExprPath ( None , ref seqvar ) = seqexpr . node ,
seqvar . segments . len ( ) = = 1
] , {
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let def_map = self . cx . tcx . def_map . borrow ( ) ;
if let Some ( def ) = def_map . get ( & seqexpr . id ) {
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match def . base_def {
Def ::Local ( .. ) | Def ::Upvar ( .. ) = > {
let extent = self . cx . tcx . region_maps . var_scope ( def . base_def . var_id ( ) ) ;
self . indexed . insert ( seqvar . segments [ 0 ] . identifier . name , Some ( extent ) ) ;
return ; // no need to walk further
}
Def ::Static ( .. ) | Def ::Const ( .. ) = > {
self . indexed . insert ( seqvar . segments [ 0 ] . identifier . name , None ) ;
return ; // no need to walk further
}
_ = > ( ) ,
}
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}
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}
}
// we are not indexing anything, record that
self . nonindex = true ;
return ;
}
}
walk_expr ( self , expr ) ;
}
}
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fn is_iterator_used_after_while_let ( cx : & LateContext , iter_expr : & Expr ) -> bool {
let def_id = match var_def_id ( cx , iter_expr ) {
Some ( id ) = > id ,
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None = > return false ,
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} ;
let mut visitor = VarUsedAfterLoopVisitor {
cx : cx ,
def_id : def_id ,
iter_expr_id : iter_expr . id ,
past_while_let : false ,
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var_used_after_while_let : false ,
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} ;
if let Some ( enclosing_block ) = get_enclosing_block ( cx , def_id ) {
walk_block ( & mut visitor , enclosing_block ) ;
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}
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visitor . var_used_after_while_let
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}
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struct VarUsedAfterLoopVisitor < ' v , ' t : ' v > {
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cx : & ' v LateContext < ' v , ' t > ,
def_id : NodeId ,
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iter_expr_id : NodeId ,
past_while_let : bool ,
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var_used_after_while_let : bool ,
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}
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impl < ' v , ' t > Visitor < ' v > for VarUsedAfterLoopVisitor < ' v , ' t > {
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fn visit_expr ( & mut self , expr : & ' v Expr ) {
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if self . past_while_let {
if Some ( self . def_id ) = = var_def_id ( self . cx , expr ) {
self . var_used_after_while_let = true ;
}
} else if self . iter_expr_id = = expr . id {
self . past_while_let = true ;
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}
walk_expr ( self , expr ) ;
}
}
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/// Return true if the type of expr is one that provides IntoIterator impls
/// for &T and &mut T, such as Vec.
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#[ cfg_attr(rustfmt, rustfmt_skip) ]
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fn is_ref_iterable_type ( cx : & LateContext , e : & Expr ) -> bool {
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// no walk_ptrs_ty: calling iter() on a reference can make sense because it
// will allow further borrows afterwards
let ty = cx . tcx . expr_ty ( e ) ;
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is_iterable_array ( ty ) | |
match_type ( cx , ty , & VEC_PATH ) | |
match_type ( cx , ty , & LL_PATH ) | |
match_type ( cx , ty , & HASHMAP_PATH ) | |
match_type ( cx , ty , & [ " std " , " collections " , " hash " , " set " , " HashSet " ] ) | |
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match_type ( cx , ty , & [ " collections " , " vec_deque " , " VecDeque " ] ) | |
match_type ( cx , ty , & [ " collections " , " binary_heap " , " BinaryHeap " ] ) | |
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match_type ( cx , ty , & BTREEMAP_PATH ) | |
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match_type ( cx , ty , & [ " collections " , " btree " , " set " , " BTreeSet " ] )
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}
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fn is_iterable_array ( ty : ty ::Ty ) -> bool {
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// IntoIterator is currently only implemented for array sizes <= 32 in rustc
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match ty . sty {
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ty ::TyArray ( _ , 0 .. . 32 ) = > true ,
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_ = > false ,
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}
}
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/// If a block begins with a statement (possibly a `let` binding) and has an expression, return it.
fn extract_expr_from_first_stmt ( block : & Block ) -> Option < & Expr > {
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if block . stmts . is_empty ( ) {
return None ;
}
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if let StmtDecl ( ref decl , _ ) = block . stmts [ 0 ] . node {
if let DeclLocal ( ref local ) = decl . node {
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if let Some ( ref expr ) = local . init {
Some ( expr )
} else {
None
}
} else {
None
}
} else {
None
}
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}
/// If a block begins with an expression (with or without semicolon), return it.
fn extract_first_expr ( block : & Block ) -> Option < & Expr > {
match block . expr {
Some ( ref expr ) = > Some ( expr ) ,
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None if ! block . stmts . is_empty ( ) = > {
match block . stmts [ 0 ] . node {
StmtExpr ( ref expr , _ ) | StmtSemi ( ref expr , _ ) = > Some ( expr ) ,
_ = > None ,
}
}
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_ = > None ,
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}
}
/// Return true if expr contains a single break expr (maybe within a block).
fn is_break_expr ( expr : & Expr ) -> bool {
match expr . node {
ExprBreak ( None ) = > true ,
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// there won't be a `let <pat> = break` and so we can safely ignore the StmtDecl case
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ExprBlock ( ref b ) = > {
match extract_first_expr ( b ) {
Some ( ref subexpr ) = > is_break_expr ( subexpr ) ,
None = > false ,
}
}
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_ = > false ,
}
}
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// To trigger the EXPLICIT_COUNTER_LOOP lint, a variable must be
// incremented exactly once in the loop body, and initialized to zero
// at the start of the loop.
#[ derive(PartialEq) ]
enum VarState {
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Initial , // Not examined yet
IncrOnce , // Incremented exactly once, may be a loop counter
Declared , // Declared but not (yet) initialized to zero
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Warn ,
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DontWarn ,
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}
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/// Scan a for loop for variables that are incremented exactly once.
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struct IncrementVisitor < ' v , ' t : ' v > {
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cx : & ' v LateContext < ' v , ' t > , // context reference
states : HashMap < NodeId , VarState > , // incremented variables
depth : u32 , // depth of conditional expressions
done : bool ,
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}
impl < ' v , ' t > Visitor < ' v > for IncrementVisitor < ' v , ' t > {
fn visit_expr ( & mut self , expr : & ' v Expr ) {
if self . done {
return ;
}
// If node is a variable
if let Some ( def_id ) = var_def_id ( self . cx , expr ) {
if let Some ( parent ) = get_parent_expr ( self . cx , expr ) {
let state = self . states . entry ( def_id ) . or_insert ( VarState ::Initial ) ;
match parent . node {
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ExprAssignOp ( op , ref lhs , ref rhs ) = > {
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if lhs . id = = expr . id {
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if op . node = = BiAdd & & is_integer_literal ( rhs , 1 ) {
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* state = match * state {
VarState ::Initial if self . depth = = 0 = > VarState ::IncrOnce ,
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_ = > VarState ::DontWarn ,
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} ;
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} else {
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// Assigned some other value
* state = VarState ::DontWarn ;
}
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}
}
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ExprAssign ( ref lhs , _ ) if lhs . id = = expr . id = > * state = VarState ::DontWarn ,
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ExprAddrOf ( mutability , _ ) if mutability = = MutMutable = > * state = VarState ::DontWarn ,
_ = > ( ) ,
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}
}
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} else if is_loop ( expr ) {
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self . states . clear ( ) ;
self . done = true ;
return ;
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} else if is_conditional ( expr ) {
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self . depth + = 1 ;
walk_expr ( self , expr ) ;
self . depth - = 1 ;
return ;
}
walk_expr ( self , expr ) ;
}
}
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/// Check whether a variable is initialized to zero at the start of a loop.
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struct InitializeVisitor < ' v , ' t : ' v > {
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cx : & ' v LateContext < ' v , ' t > , // context reference
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end_expr : & ' v Expr , // the for loop. Stop scanning here.
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var_id : NodeId ,
state : VarState ,
name : Option < Name > ,
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depth : u32 , // depth of conditional expressions
past_loop : bool ,
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}
impl < ' v , ' t > Visitor < ' v > for InitializeVisitor < ' v , ' t > {
fn visit_decl ( & mut self , decl : & ' v Decl ) {
// Look for declarations of the variable
if let DeclLocal ( ref local ) = decl . node {
if local . pat . id = = self . var_id {
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if let PatKind ::Ident ( _ , ref ident , _ ) = local . pat . node {
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self . name = Some ( ident . node . name ) ;
self . state = if let Some ( ref init ) = local . init {
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if is_integer_literal ( init , 0 ) {
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VarState ::Warn
} else {
VarState ::Declared
}
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} else {
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VarState ::Declared
}
}
}
}
walk_decl ( self , decl ) ;
}
fn visit_expr ( & mut self , expr : & ' v Expr ) {
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if self . state = = VarState ::DontWarn {
return ;
}
if expr = = self . end_expr {
self . past_loop = true ;
return ;
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}
// No need to visit expressions before the variable is
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// declared
if self . state = = VarState ::IncrOnce {
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return ;
}
// If node is the desired variable, see how it's used
if var_def_id ( self . cx , expr ) = = Some ( self . var_id ) {
if let Some ( parent ) = get_parent_expr ( self . cx , expr ) {
match parent . node {
ExprAssignOp ( _ , ref lhs , _ ) if lhs . id = = expr . id = > {
self . state = VarState ::DontWarn ;
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}
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ExprAssign ( ref lhs , ref rhs ) if lhs . id = = expr . id = > {
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self . state = if is_integer_literal ( rhs , 0 ) & & self . depth = = 0 {
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VarState ::Warn
} else {
VarState ::DontWarn
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}
}
ExprAddrOf ( mutability , _ ) if mutability = = MutMutable = > self . state = VarState ::DontWarn ,
_ = > ( ) ,
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}
}
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if self . past_loop {
self . state = VarState ::DontWarn ;
return ;
}
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} else if ! self . past_loop & & is_loop ( expr ) {
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self . state = VarState ::DontWarn ;
return ;
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} else if is_conditional ( expr ) {
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self . depth + = 1 ;
walk_expr ( self , expr ) ;
self . depth - = 1 ;
return ;
}
walk_expr ( self , expr ) ;
}
}
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fn var_def_id ( cx : & LateContext , expr : & Expr ) -> Option < NodeId > {
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if let Some ( path_res ) = cx . tcx . def_map . borrow ( ) . get ( & expr . id ) {
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if let Def ::Local ( _ , node_id ) = path_res . base_def {
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return Some ( node_id ) ;
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}
}
None
}
fn is_loop ( expr : & Expr ) -> bool {
match expr . node {
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ExprLoop ( .. ) | ExprWhile ( .. ) = > true ,
_ = > false ,
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}
}
fn is_conditional ( expr : & Expr ) -> bool {
match expr . node {
ExprIf ( .. ) | ExprMatch ( .. ) = > true ,
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_ = > false ,
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}
}