| Author | Tokens | Token Proportion | Commits | Commit Proportion |
|---|---|---|---|---|
| Miguel Ojeda Sandonis | 4195 | 100.00% | 2 | 100.00% |
| Total | 4195 | 2 |
// SPDX-License-Identifier: Apache-2.0 OR MIT
use crate::classify;
use crate::expr::Expr;
#[cfg(feature = "full")]
use crate::expr::{
ExprBreak, ExprRange, ExprRawAddr, ExprReference, ExprReturn, ExprUnary, ExprYield,
};
use crate::precedence::Precedence;
#[cfg(feature = "full")]
use crate::ty::ReturnType;
pub(crate) struct FixupContext {
#[cfg(feature = "full")]
previous_operator: Precedence,
#[cfg(feature = "full")]
next_operator: Precedence,
// Print expression such that it can be parsed back as a statement
// consisting of the original expression.
//
// The effect of this is for binary operators in statement position to set
// `leftmost_subexpression_in_stmt` when printing their left-hand operand.
//
// (match x {}) - 1; // match needs parens when LHS of binary operator
//
// match x {}; // not when its own statement
//
#[cfg(feature = "full")]
stmt: bool,
// This is the difference between:
//
// (match x {}) - 1; // subexpression needs parens
//
// let _ = match x {} - 1; // no parens
//
// There are 3 distinguishable contexts in which `print_expr` might be
// called with the expression `$match` as its argument, where `$match`
// represents an expression of kind `ExprKind::Match`:
//
// - stmt=false leftmost_subexpression_in_stmt=false
//
// Example: `let _ = $match - 1;`
//
// No parentheses required.
//
// - stmt=false leftmost_subexpression_in_stmt=true
//
// Example: `$match - 1;`
//
// Must parenthesize `($match)`, otherwise parsing back the output as a
// statement would terminate the statement after the closing brace of
// the match, parsing `-1;` as a separate statement.
//
// - stmt=true leftmost_subexpression_in_stmt=false
//
// Example: `$match;`
//
// No parentheses required.
#[cfg(feature = "full")]
leftmost_subexpression_in_stmt: bool,
// Print expression such that it can be parsed as a match arm.
//
// This is almost equivalent to `stmt`, but the grammar diverges a tiny bit
// between statements and match arms when it comes to braced macro calls.
// Macro calls with brace delimiter terminate a statement without a
// semicolon, but do not terminate a match-arm without comma.
//
// m! {} - 1; // two statements: a macro call followed by -1 literal
//
// match () {
// _ => m! {} - 1, // binary subtraction operator
// }
//
#[cfg(feature = "full")]
match_arm: bool,
// This is almost equivalent to `leftmost_subexpression_in_stmt`, other than
// for braced macro calls.
//
// If we have `m! {} - 1` as an expression, the leftmost subexpression
// `m! {}` will need to be parenthesized in the statement case but not the
// match-arm case.
//
// (m! {}) - 1; // subexpression needs parens
//
// match () {
// _ => m! {} - 1, // no parens
// }
//
#[cfg(feature = "full")]
leftmost_subexpression_in_match_arm: bool,
// This is the difference between:
//
// if let _ = (Struct {}) {} // needs parens
//
// match () {
// () if let _ = Struct {} => {} // no parens
// }
//
#[cfg(feature = "full")]
condition: bool,
// This is the difference between:
//
// if break Struct {} == (break) {} // needs parens
//
// if break break == Struct {} {} // no parens
//
#[cfg(feature = "full")]
rightmost_subexpression_in_condition: bool,
// This is the difference between:
//
// if break ({ x }).field + 1 {} needs parens
//
// if break 1 + { x }.field {} // no parens
//
#[cfg(feature = "full")]
leftmost_subexpression_in_optional_operand: bool,
// This is the difference between:
//
// let _ = (return) - 1; // without paren, this would return -1
//
// let _ = return + 1; // no paren because '+' cannot begin expr
//
#[cfg(feature = "full")]
next_operator_can_begin_expr: bool,
// This is the difference between:
//
// let _ = 1 + return 1; // no parens if rightmost subexpression
//
// let _ = 1 + (return 1) + 1; // needs parens
//
#[cfg(feature = "full")]
next_operator_can_continue_expr: bool,
// This is the difference between:
//
// let _ = x as u8 + T;
//
// let _ = (x as u8) < T;
//
// Without parens, the latter would want to parse `u8<T...` as a type.
next_operator_can_begin_generics: bool,
}
impl FixupContext {
/// The default amount of fixing is minimal fixing. Fixups should be turned
/// on in a targeted fashion where needed.
pub const NONE: Self = FixupContext {
#[cfg(feature = "full")]
previous_operator: Precedence::MIN,
#[cfg(feature = "full")]
next_operator: Precedence::MIN,
#[cfg(feature = "full")]
stmt: false,
#[cfg(feature = "full")]
leftmost_subexpression_in_stmt: false,
#[cfg(feature = "full")]
match_arm: false,
#[cfg(feature = "full")]
leftmost_subexpression_in_match_arm: false,
#[cfg(feature = "full")]
condition: false,
#[cfg(feature = "full")]
rightmost_subexpression_in_condition: false,
#[cfg(feature = "full")]
leftmost_subexpression_in_optional_operand: false,
#[cfg(feature = "full")]
next_operator_can_begin_expr: false,
#[cfg(feature = "full")]
next_operator_can_continue_expr: false,
next_operator_can_begin_generics: false,
};
/// Create the initial fixup for printing an expression in statement
/// position.
#[cfg(feature = "full")]
pub fn new_stmt() -> Self {
FixupContext {
stmt: true,
..FixupContext::NONE
}
}
/// Create the initial fixup for printing an expression as the right-hand
/// side of a match arm.
#[cfg(feature = "full")]
pub fn new_match_arm() -> Self {
FixupContext {
match_arm: true,
..FixupContext::NONE
}
}
/// Create the initial fixup for printing an expression as the "condition"
/// of an `if` or `while`. There are a few other positions which are
/// grammatically equivalent and also use this, such as the iterator
/// expression in `for` and the scrutinee in `match`.
#[cfg(feature = "full")]
pub fn new_condition() -> Self {
FixupContext {
condition: true,
rightmost_subexpression_in_condition: true,
..FixupContext::NONE
}
}
/// Transform this fixup into the one that should apply when printing the
/// leftmost subexpression of the current expression.
///
/// The leftmost subexpression is any subexpression that has the same first
/// token as the current expression, but has a different last token.
///
/// For example in `$a + $b` and `$a.method()`, the subexpression `$a` is a
/// leftmost subexpression.
///
/// Not every expression has a leftmost subexpression. For example neither
/// `-$a` nor `[$a]` have one.
pub fn leftmost_subexpression_with_operator(
self,
expr: &Expr,
#[cfg(feature = "full")] next_operator_can_begin_expr: bool,
next_operator_can_begin_generics: bool,
#[cfg(feature = "full")] precedence: Precedence,
) -> (Precedence, Self) {
let fixup = FixupContext {
#[cfg(feature = "full")]
next_operator: precedence,
#[cfg(feature = "full")]
stmt: false,
#[cfg(feature = "full")]
leftmost_subexpression_in_stmt: self.stmt || self.leftmost_subexpression_in_stmt,
#[cfg(feature = "full")]
match_arm: false,
#[cfg(feature = "full")]
leftmost_subexpression_in_match_arm: self.match_arm
|| self.leftmost_subexpression_in_match_arm,
#[cfg(feature = "full")]
rightmost_subexpression_in_condition: false,
#[cfg(feature = "full")]
next_operator_can_begin_expr,
#[cfg(feature = "full")]
next_operator_can_continue_expr: true,
next_operator_can_begin_generics,
..self
};
(fixup.leftmost_subexpression_precedence(expr), fixup)
}
/// Transform this fixup into the one that should apply when printing a
/// leftmost subexpression followed by a `.` or `?` token, which confer
/// different statement boundary rules compared to other leftmost
/// subexpressions.
pub fn leftmost_subexpression_with_dot(self, expr: &Expr) -> (Precedence, Self) {
let fixup = FixupContext {
#[cfg(feature = "full")]
next_operator: Precedence::Unambiguous,
#[cfg(feature = "full")]
stmt: self.stmt || self.leftmost_subexpression_in_stmt,
#[cfg(feature = "full")]
leftmost_subexpression_in_stmt: false,
#[cfg(feature = "full")]
match_arm: self.match_arm || self.leftmost_subexpression_in_match_arm,
#[cfg(feature = "full")]
leftmost_subexpression_in_match_arm: false,
#[cfg(feature = "full")]
rightmost_subexpression_in_condition: false,
#[cfg(feature = "full")]
next_operator_can_begin_expr: false,
#[cfg(feature = "full")]
next_operator_can_continue_expr: true,
next_operator_can_begin_generics: false,
..self
};
(fixup.leftmost_subexpression_precedence(expr), fixup)
}
fn leftmost_subexpression_precedence(self, expr: &Expr) -> Precedence {
#[cfg(feature = "full")]
if !self.next_operator_can_begin_expr || self.next_operator == Precedence::Range {
if let Scan::Bailout = scan_right(expr, self, Precedence::MIN, 0, 0) {
if scan_left(expr, self) {
return Precedence::Unambiguous;
}
}
}
self.precedence(expr)
}
/// Transform this fixup into the one that should apply when printing the
/// rightmost subexpression of the current expression.
///
/// The rightmost subexpression is any subexpression that has a different
/// first token than the current expression, but has the same last token.
///
/// For example in `$a + $b` and `-$b`, the subexpression `$b` is a
/// rightmost subexpression.
///
/// Not every expression has a rightmost subexpression. For example neither
/// `[$b]` nor `$a.f($b)` have one.
pub fn rightmost_subexpression(
self,
expr: &Expr,
#[cfg(feature = "full")] precedence: Precedence,
) -> (Precedence, Self) {
let fixup = self.rightmost_subexpression_fixup(
#[cfg(feature = "full")]
false,
#[cfg(feature = "full")]
false,
#[cfg(feature = "full")]
precedence,
);
(fixup.rightmost_subexpression_precedence(expr), fixup)
}
pub fn rightmost_subexpression_fixup(
self,
#[cfg(feature = "full")] reset_allow_struct: bool,
#[cfg(feature = "full")] optional_operand: bool,
#[cfg(feature = "full")] precedence: Precedence,
) -> Self {
FixupContext {
#[cfg(feature = "full")]
previous_operator: precedence,
#[cfg(feature = "full")]
stmt: false,
#[cfg(feature = "full")]
leftmost_subexpression_in_stmt: false,
#[cfg(feature = "full")]
match_arm: false,
#[cfg(feature = "full")]
leftmost_subexpression_in_match_arm: false,
#[cfg(feature = "full")]
condition: self.condition && !reset_allow_struct,
#[cfg(feature = "full")]
leftmost_subexpression_in_optional_operand: self.condition && optional_operand,
..self
}
}
pub fn rightmost_subexpression_precedence(self, expr: &Expr) -> Precedence {
let default_prec = self.precedence(expr);
#[cfg(feature = "full")]
if match self.previous_operator {
Precedence::Assign | Precedence::Let | Precedence::Prefix => {
default_prec < self.previous_operator
}
_ => default_prec <= self.previous_operator,
} && match self.next_operator {
Precedence::Range | Precedence::Or | Precedence::And => true,
_ => !self.next_operator_can_begin_expr,
} {
if let Scan::Bailout | Scan::Fail = scan_right(expr, self, self.previous_operator, 1, 0)
{
if scan_left(expr, self) {
return Precedence::Prefix;
}
}
}
default_prec
}
/// Determine whether parentheses are needed around the given expression to
/// head off the early termination of a statement or condition.
#[cfg(feature = "full")]
pub fn parenthesize(self, expr: &Expr) -> bool {
(self.leftmost_subexpression_in_stmt && !classify::requires_semi_to_be_stmt(expr))
|| ((self.stmt || self.leftmost_subexpression_in_stmt) && matches!(expr, Expr::Let(_)))
|| (self.leftmost_subexpression_in_match_arm
&& !classify::requires_comma_to_be_match_arm(expr))
|| (self.condition && matches!(expr, Expr::Struct(_)))
|| (self.rightmost_subexpression_in_condition
&& matches!(
expr,
Expr::Return(ExprReturn { expr: None, .. })
| Expr::Yield(ExprYield { expr: None, .. })
))
|| (self.rightmost_subexpression_in_condition
&& !self.condition
&& matches!(
expr,
Expr::Break(ExprBreak { expr: None, .. })
| Expr::Path(_)
| Expr::Range(ExprRange { end: None, .. })
))
|| (self.leftmost_subexpression_in_optional_operand
&& matches!(expr, Expr::Block(expr) if expr.attrs.is_empty() && expr.label.is_none()))
}
/// Determines the effective precedence of a subexpression. Some expressions
/// have higher or lower precedence when adjacent to particular operators.
fn precedence(self, expr: &Expr) -> Precedence {
#[cfg(feature = "full")]
if self.next_operator_can_begin_expr {
// Decrease precedence of value-less jumps when followed by an
// operator that would otherwise get interpreted as beginning a
// value for the jump.
if let Expr::Break(ExprBreak { expr: None, .. })
| Expr::Return(ExprReturn { expr: None, .. })
| Expr::Yield(ExprYield { expr: None, .. }) = expr
{
return Precedence::Jump;
}
}
#[cfg(feature = "full")]
if !self.next_operator_can_continue_expr {
match expr {
// Increase precedence of expressions that extend to the end of
// current statement or group.
Expr::Break(_)
| Expr::Closure(_)
| Expr::Let(_)
| Expr::Return(_)
| Expr::Yield(_) => {
return Precedence::Prefix;
}
Expr::Range(e) if e.start.is_none() => return Precedence::Prefix,
_ => {}
}
}
if self.next_operator_can_begin_generics {
if let Expr::Cast(cast) = expr {
if classify::trailing_unparameterized_path(&cast.ty) {
return Precedence::MIN;
}
}
}
Precedence::of(expr)
}
}
impl Copy for FixupContext {}
impl Clone for FixupContext {
fn clone(&self) -> Self {
*self
}
}
#[cfg(feature = "full")]
enum Scan {
Fail,
Bailout,
Consume,
}
#[cfg(feature = "full")]
impl Copy for Scan {}
#[cfg(feature = "full")]
impl Clone for Scan {
fn clone(&self) -> Self {
*self
}
}
#[cfg(feature = "full")]
impl PartialEq for Scan {
fn eq(&self, other: &Self) -> bool {
*self as u8 == *other as u8
}
}
#[cfg(feature = "full")]
fn scan_left(expr: &Expr, fixup: FixupContext) -> bool {
match expr {
Expr::Assign(_) => fixup.previous_operator <= Precedence::Assign,
Expr::Binary(e) => match Precedence::of_binop(&e.op) {
Precedence::Assign => fixup.previous_operator <= Precedence::Assign,
binop_prec => fixup.previous_operator < binop_prec,
},
Expr::Cast(_) => fixup.previous_operator < Precedence::Cast,
Expr::Range(e) => e.start.is_none() || fixup.previous_operator < Precedence::Assign,
_ => true,
}
}
#[cfg(feature = "full")]
fn scan_right(
expr: &Expr,
fixup: FixupContext,
precedence: Precedence,
fail_offset: u8,
bailout_offset: u8,
) -> Scan {
let consume_by_precedence = if match precedence {
Precedence::Assign | Precedence::Compare => precedence <= fixup.next_operator,
_ => precedence < fixup.next_operator,
} || fixup.next_operator == Precedence::MIN
{
Scan::Consume
} else {
Scan::Bailout
};
if fixup.parenthesize(expr) {
return consume_by_precedence;
}
match expr {
Expr::Assign(e) if e.attrs.is_empty() => {
if match fixup.next_operator {
Precedence::Unambiguous => fail_offset >= 2,
_ => bailout_offset >= 1,
} {
return Scan::Consume;
}
let right_fixup = fixup.rightmost_subexpression_fixup(false, false, Precedence::Assign);
let scan = scan_right(
&e.right,
right_fixup,
Precedence::Assign,
match fixup.next_operator {
Precedence::Unambiguous => fail_offset,
_ => 1,
},
1,
);
if let Scan::Bailout | Scan::Consume = scan {
Scan::Consume
} else if let Precedence::Unambiguous = fixup.next_operator {
Scan::Fail
} else {
Scan::Bailout
}
}
Expr::Binary(e) if e.attrs.is_empty() => {
if match fixup.next_operator {
Precedence::Unambiguous => {
fail_offset >= 2
&& (consume_by_precedence == Scan::Consume || bailout_offset >= 1)
}
_ => bailout_offset >= 1,
} {
return Scan::Consume;
}
let binop_prec = Precedence::of_binop(&e.op);
if binop_prec == Precedence::Compare && fixup.next_operator == Precedence::Compare {
return Scan::Consume;
}
let right_fixup = fixup.rightmost_subexpression_fixup(false, false, binop_prec);
let scan = scan_right(
&e.right,
right_fixup,
binop_prec,
match fixup.next_operator {
Precedence::Unambiguous => fail_offset,
_ => 1,
},
consume_by_precedence as u8 - Scan::Bailout as u8,
);
match scan {
Scan::Fail => {}
Scan::Bailout => return consume_by_precedence,
Scan::Consume => return Scan::Consume,
}
let right_needs_group = binop_prec != Precedence::Assign
&& right_fixup.rightmost_subexpression_precedence(&e.right) <= binop_prec;
if right_needs_group {
consume_by_precedence
} else if let (Scan::Fail, Precedence::Unambiguous) = (scan, fixup.next_operator) {
Scan::Fail
} else {
Scan::Bailout
}
}
Expr::RawAddr(ExprRawAddr { expr, .. })
| Expr::Reference(ExprReference { expr, .. })
| Expr::Unary(ExprUnary { expr, .. }) => {
if match fixup.next_operator {
Precedence::Unambiguous => {
fail_offset >= 2
&& (consume_by_precedence == Scan::Consume || bailout_offset >= 1)
}
_ => bailout_offset >= 1,
} {
return Scan::Consume;
}
let right_fixup = fixup.rightmost_subexpression_fixup(false, false, Precedence::Prefix);
let scan = scan_right(
expr,
right_fixup,
precedence,
match fixup.next_operator {
Precedence::Unambiguous => fail_offset,
_ => 1,
},
consume_by_precedence as u8 - Scan::Bailout as u8,
);
match scan {
Scan::Fail => {}
Scan::Bailout => return consume_by_precedence,
Scan::Consume => return Scan::Consume,
}
if right_fixup.rightmost_subexpression_precedence(expr) < Precedence::Prefix {
consume_by_precedence
} else if let (Scan::Fail, Precedence::Unambiguous) = (scan, fixup.next_operator) {
Scan::Fail
} else {
Scan::Bailout
}
}
Expr::Range(e) if e.attrs.is_empty() => match &e.end {
Some(end) => {
if fail_offset >= 2 {
return Scan::Consume;
}
let right_fixup =
fixup.rightmost_subexpression_fixup(false, true, Precedence::Range);
let scan = scan_right(
end,
right_fixup,
Precedence::Range,
fail_offset,
match fixup.next_operator {
Precedence::Assign | Precedence::Range => 0,
_ => 1,
},
);
if match (scan, fixup.next_operator) {
(Scan::Fail, _) => false,
(Scan::Bailout, Precedence::Assign | Precedence::Range) => false,
(Scan::Bailout | Scan::Consume, _) => true,
} {
return Scan::Consume;
}
if right_fixup.rightmost_subexpression_precedence(end) <= Precedence::Range {
Scan::Consume
} else {
Scan::Fail
}
}
None => {
if fixup.next_operator_can_begin_expr {
Scan::Consume
} else {
Scan::Fail
}
}
},
Expr::Break(e) => match &e.expr {
Some(value) => {
if bailout_offset >= 1 || e.label.is_none() && classify::expr_leading_label(value) {
return Scan::Consume;
}
let right_fixup = fixup.rightmost_subexpression_fixup(true, true, Precedence::Jump);
match scan_right(value, right_fixup, Precedence::Jump, 1, 1) {
Scan::Fail => Scan::Bailout,
Scan::Bailout | Scan::Consume => Scan::Consume,
}
}
None => match fixup.next_operator {
Precedence::Assign if precedence > Precedence::Assign => Scan::Fail,
_ => Scan::Consume,
},
},
Expr::Return(ExprReturn { expr, .. }) | Expr::Yield(ExprYield { expr, .. }) => match expr {
Some(e) => {
if bailout_offset >= 1 {
return Scan::Consume;
}
let right_fixup =
fixup.rightmost_subexpression_fixup(true, false, Precedence::Jump);
match scan_right(e, right_fixup, Precedence::Jump, 1, 1) {
Scan::Fail => Scan::Bailout,
Scan::Bailout | Scan::Consume => Scan::Consume,
}
}
None => match fixup.next_operator {
Precedence::Assign if precedence > Precedence::Assign => Scan::Fail,
_ => Scan::Consume,
},
},
Expr::Closure(e) => {
if matches!(e.output, ReturnType::Default)
|| matches!(&*e.body, Expr::Block(body) if body.attrs.is_empty() && body.label.is_none())
{
if bailout_offset >= 1 {
return Scan::Consume;
}
let right_fixup =
fixup.rightmost_subexpression_fixup(false, false, Precedence::Jump);
match scan_right(&e.body, right_fixup, Precedence::Jump, 1, 1) {
Scan::Fail => Scan::Bailout,
Scan::Bailout | Scan::Consume => Scan::Consume,
}
} else {
Scan::Consume
}
}
Expr::Let(e) => {
if bailout_offset >= 1 {
return Scan::Consume;
}
let right_fixup = fixup.rightmost_subexpression_fixup(false, false, Precedence::Let);
let scan = scan_right(
&e.expr,
right_fixup,
Precedence::Let,
1,
if fixup.next_operator < Precedence::Let {
0
} else {
1
},
);
match scan {
Scan::Fail | Scan::Bailout if fixup.next_operator < Precedence::Let => {
return Scan::Bailout;
}
Scan::Consume => return Scan::Consume,
_ => {}
}
if right_fixup.rightmost_subexpression_precedence(&e.expr) < Precedence::Let {
Scan::Consume
} else if let Scan::Fail = scan {
Scan::Bailout
} else {
Scan::Consume
}
}
Expr::Array(_)
| Expr::Assign(_)
| Expr::Async(_)
| Expr::Await(_)
| Expr::Binary(_)
| Expr::Block(_)
| Expr::Call(_)
| Expr::Cast(_)
| Expr::Const(_)
| Expr::Continue(_)
| Expr::Field(_)
| Expr::ForLoop(_)
| Expr::Group(_)
| Expr::If(_)
| Expr::Index(_)
| Expr::Infer(_)
| Expr::Lit(_)
| Expr::Loop(_)
| Expr::Macro(_)
| Expr::Match(_)
| Expr::MethodCall(_)
| Expr::Paren(_)
| Expr::Path(_)
| Expr::Range(_)
| Expr::Repeat(_)
| Expr::Struct(_)
| Expr::Try(_)
| Expr::TryBlock(_)
| Expr::Tuple(_)
| Expr::Unsafe(_)
| Expr::Verbatim(_)
| Expr::While(_) => match fixup.next_operator {
Precedence::Assign | Precedence::Range if precedence == Precedence::Range => Scan::Fail,
_ if precedence == Precedence::Let && fixup.next_operator < Precedence::Let => {
Scan::Fail
}
_ => consume_by_precedence,
},
}
}
Information contained on this website is for historical information purposes only and does not indicate or represent copyright ownership.
Created with Cregit http://github.com/cregit/cregit
Version 2.0-RC1