// Copyright 2015 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 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. use std::borrow::Cow; use std::cmp::min; use std::iter::repeat; use config::lists::*; use syntax::{ast, ptr}; use syntax::codemap::{BytePos, CodeMap, Span}; use chains::rewrite_chain; use closures; use codemap::{LineRangeUtils, SpanUtils}; use comment::{combine_strs_with_missing_comments, contains_comment, recover_comment_removed, rewrite_comment, rewrite_missing_comment, CharClasses, FindUncommented}; use config::{Config, ControlBraceStyle, IndentStyle}; use lists::{definitive_tactic, itemize_list, shape_for_tactic, struct_lit_formatting, struct_lit_shape, struct_lit_tactic, write_list, ListFormatting, ListItem, Separator}; use macros::{rewrite_macro, MacroArg, MacroPosition}; use patterns::{can_be_overflowed_pat, TuplePatField}; use rewrite::{Rewrite, RewriteContext}; use shape::{Indent, Shape}; use spanned::Spanned; use string::{rewrite_string, StringFormat}; use types::{can_be_overflowed_type, rewrite_path, PathContext}; use utils::{colon_spaces, contains_skip, count_newlines, extra_offset, first_line_width, inner_attributes, last_line_extendable, last_line_width, mk_sp, outer_attributes, paren_overhead, ptr_vec_to_ref_vec, semicolon_for_stmt, trimmed_last_line_width, wrap_str}; use vertical::rewrite_with_alignment; use visitor::FmtVisitor; impl Rewrite for ast::Expr { fn rewrite(&self, context: &RewriteContext, shape: Shape) -> Option { format_expr(self, ExprType::SubExpression, context, shape) } } #[derive(Copy, Clone, PartialEq)] pub enum ExprType { Statement, SubExpression, } pub fn format_expr( expr: &ast::Expr, expr_type: ExprType, context: &RewriteContext, shape: Shape, ) -> Option { skip_out_of_file_lines_range!(context, expr.span); if contains_skip(&*expr.attrs) { return Some(context.snippet(expr.span()).to_owned()); } let expr_rw = match expr.node { ast::ExprKind::Array(ref expr_vec) => rewrite_array( &ptr_vec_to_ref_vec(expr_vec), mk_sp( context.snippet_provider.span_after(expr.span, "["), expr.span.hi(), ), context, shape, false, ), ast::ExprKind::Lit(ref l) => rewrite_literal(context, l, shape), ast::ExprKind::Call(ref callee, ref args) => { let inner_span = mk_sp(callee.span.hi(), expr.span.hi()); let callee_str = callee.rewrite(context, shape)?; rewrite_call(context, &callee_str, args, inner_span, shape) } ast::ExprKind::Paren(ref subexpr) => rewrite_paren(context, subexpr, shape, expr.span), ast::ExprKind::Binary(ref op, ref lhs, ref rhs) => { // FIXME: format comments between operands and operator rewrite_pair( &**lhs, &**rhs, PairParts::new("", &format!(" {} ", context.snippet(op.span)), ""), context, shape, context.config.binop_separator(), ) } ast::ExprKind::Unary(ref op, ref subexpr) => rewrite_unary_op(context, op, subexpr, shape), ast::ExprKind::Struct(ref path, ref fields, ref base) => rewrite_struct_lit( context, path, fields, base.as_ref().map(|e| &**e), expr.span, shape, ), ast::ExprKind::Tup(ref items) => { rewrite_tuple(context, &ptr_vec_to_ref_vec(items), expr.span, shape) } ast::ExprKind::If(..) | ast::ExprKind::IfLet(..) | ast::ExprKind::ForLoop(..) | ast::ExprKind::Loop(..) | ast::ExprKind::While(..) | ast::ExprKind::WhileLet(..) => to_control_flow(expr, expr_type) .and_then(|control_flow| control_flow.rewrite(context, shape)), ast::ExprKind::Block(ref block) => { match expr_type { ExprType::Statement => { if is_unsafe_block(block) { block.rewrite(context, shape) } else if let rw @ Some(_) = rewrite_empty_block(context, block, shape) { // Rewrite block without trying to put it in a single line. rw } else { let prefix = block_prefix(context, block, shape)?; rewrite_block_with_visitor(context, &prefix, block, shape, true) } } ExprType::SubExpression => block.rewrite(context, shape), } } ast::ExprKind::Match(ref cond, ref arms) => { rewrite_match(context, cond, arms, shape, expr.span, &expr.attrs) } ast::ExprKind::Path(ref qself, ref path) => { rewrite_path(context, PathContext::Expr, qself.as_ref(), path, shape) } ast::ExprKind::Assign(ref lhs, ref rhs) => { rewrite_assignment(context, lhs, rhs, None, shape) } ast::ExprKind::AssignOp(ref op, ref lhs, ref rhs) => { rewrite_assignment(context, lhs, rhs, Some(op), shape) } ast::ExprKind::Continue(ref opt_label) => { let id_str = match *opt_label { Some(label) => format!(" {}", label.ident), None => String::new(), }; Some(format!("continue{}", id_str)) } ast::ExprKind::Break(ref opt_label, ref opt_expr) => { let id_str = match *opt_label { Some(label) => format!(" {}", label.ident), None => String::new(), }; if let Some(ref expr) = *opt_expr { rewrite_unary_prefix(context, &format!("break{} ", id_str), &**expr, shape) } else { Some(format!("break{}", id_str)) } } ast::ExprKind::Yield(ref opt_expr) => if let Some(ref expr) = *opt_expr { rewrite_unary_prefix(context, "yield ", &**expr, shape) } else { Some("yield".to_string()) }, ast::ExprKind::Closure(capture, movability, ref fn_decl, ref body, _) => { closures::rewrite_closure( capture, movability, fn_decl, body, expr.span, context, shape, ) } ast::ExprKind::Try(..) | ast::ExprKind::Field(..) | ast::ExprKind::TupField(..) | ast::ExprKind::MethodCall(..) => rewrite_chain(expr, context, shape), ast::ExprKind::Mac(ref mac) => { rewrite_macro(mac, None, context, shape, MacroPosition::Expression).or_else(|| { wrap_str( context.snippet(expr.span).to_owned(), context.config.max_width(), shape, ) }) } ast::ExprKind::Ret(None) => Some("return".to_owned()), ast::ExprKind::Ret(Some(ref expr)) => { rewrite_unary_prefix(context, "return ", &**expr, shape) } ast::ExprKind::Box(ref expr) => rewrite_unary_prefix(context, "box ", &**expr, shape), ast::ExprKind::AddrOf(mutability, ref expr) => { rewrite_expr_addrof(context, mutability, expr, shape) } ast::ExprKind::Cast(ref expr, ref ty) => rewrite_pair( &**expr, &**ty, PairParts::new("", " as ", ""), context, shape, SeparatorPlace::Front, ), ast::ExprKind::Type(ref expr, ref ty) => rewrite_pair( &**expr, &**ty, PairParts::new("", ": ", ""), context, shape, SeparatorPlace::Back, ), ast::ExprKind::Index(ref expr, ref index) => { rewrite_index(&**expr, &**index, context, shape) } ast::ExprKind::Repeat(ref expr, ref repeats) => { let (lbr, rbr) = if context.config.spaces_within_parens_and_brackets() { ("[ ", " ]") } else { ("[", "]") }; rewrite_pair( &**expr, &**repeats, PairParts::new(lbr, "; ", rbr), context, shape, SeparatorPlace::Back, ) } ast::ExprKind::Range(ref lhs, ref rhs, limits) => { let delim = match limits { ast::RangeLimits::HalfOpen => "..", ast::RangeLimits::Closed => "..=", }; fn needs_space_before_range(context: &RewriteContext, lhs: &ast::Expr) -> bool { match lhs.node { ast::ExprKind::Lit(ref lit) => match lit.node { ast::LitKind::FloatUnsuffixed(..) => { context.snippet(lit.span).ends_with('.') } _ => false, }, _ => false, } } match (lhs.as_ref().map(|x| &**x), rhs.as_ref().map(|x| &**x)) { (Some(lhs), Some(rhs)) => { let sp_delim = if context.config.spaces_around_ranges() { format!(" {} ", delim) } else if needs_space_before_range(context, lhs) { format!(" {}", delim) } else { delim.to_owned() }; rewrite_pair( &*lhs, &*rhs, PairParts::new("", &sp_delim, ""), context, shape, context.config.binop_separator(), ) } (None, Some(rhs)) => { let sp_delim = if context.config.spaces_around_ranges() { format!("{} ", delim) } else { delim.to_owned() }; rewrite_unary_prefix(context, &sp_delim, &*rhs, shape) } (Some(lhs), None) => { let sp_delim = if context.config.spaces_around_ranges() { format!(" {}", delim) } else { delim.to_owned() }; rewrite_unary_suffix(context, &sp_delim, &*lhs, shape) } (None, None) => Some(delim.to_owned()), } } // We do not format these expressions yet, but they should still // satisfy our width restrictions. ast::ExprKind::InPlace(..) | ast::ExprKind::InlineAsm(..) => { Some(context.snippet(expr.span).to_owned()) } ast::ExprKind::Catch(ref block) => { if let rw @ Some(_) = rewrite_single_line_block(context, "do catch ", block, shape) { rw } else { // 9 = `do catch ` let budget = shape.width.checked_sub(9).unwrap_or(0); Some(format!( "{}{}", "do catch ", block.rewrite(context, Shape::legacy(budget, shape.indent))? )) } } }; expr_rw .and_then(|expr_str| recover_comment_removed(expr_str, expr.span, context)) .and_then(|expr_str| { let attrs = outer_attributes(&expr.attrs); let attrs_str = attrs.rewrite(context, shape)?; let span = mk_sp( attrs.last().map_or(expr.span.lo(), |attr| attr.span.hi()), expr.span.lo(), ); combine_strs_with_missing_comments(context, &attrs_str, &expr_str, span, shape, false) }) } #[derive(new, Clone, Copy)] pub struct PairParts<'a> { prefix: &'a str, infix: &'a str, suffix: &'a str, } pub fn rewrite_pair( lhs: &LHS, rhs: &RHS, pp: PairParts, context: &RewriteContext, shape: Shape, separator_place: SeparatorPlace, ) -> Option where LHS: Rewrite, RHS: Rewrite, { let lhs_overhead = match separator_place { SeparatorPlace::Back => shape.used_width() + pp.prefix.len() + pp.infix.trim_right().len(), SeparatorPlace::Front => shape.used_width(), }; let lhs_shape = Shape { width: context.budget(lhs_overhead), ..shape }; let lhs_result = lhs.rewrite(context, lhs_shape) .map(|lhs_str| format!("{}{}", pp.prefix, lhs_str))?; // Try to the both lhs and rhs on the same line. let rhs_orig_result = shape .offset_left(last_line_width(&lhs_result) + pp.infix.len()) .and_then(|s| s.sub_width(pp.suffix.len())) .and_then(|rhs_shape| rhs.rewrite(context, rhs_shape)); if let Some(ref rhs_result) = rhs_orig_result { // If the rhs looks like block expression, we allow it to stay on the same line // with the lhs even if it is multi-lined. let allow_same_line = rhs_result .lines() .next() .map(|first_line| first_line.ends_with('{')) .unwrap_or(false); if !rhs_result.contains('\n') || allow_same_line { let one_line_width = last_line_width(&lhs_result) + pp.infix.len() + first_line_width(rhs_result) + pp.suffix.len(); if one_line_width <= shape.width { return Some(format!( "{}{}{}{}", lhs_result, pp.infix, rhs_result, pp.suffix )); } } } // We have to use multiple lines. // Re-evaluate the rhs because we have more space now: let mut rhs_shape = match context.config.indent_style() { IndentStyle::Visual => shape .sub_width(pp.suffix.len() + pp.prefix.len())? .visual_indent(pp.prefix.len()), IndentStyle::Block => { // Try to calculate the initial constraint on the right hand side. let rhs_overhead = shape.rhs_overhead(context.config); Shape::indented(shape.indent.block_indent(context.config), context.config) .sub_width(rhs_overhead)? } }; let infix = match separator_place { SeparatorPlace::Back => pp.infix.trim_right(), SeparatorPlace::Front => pp.infix.trim_left(), }; if separator_place == SeparatorPlace::Front { rhs_shape = rhs_shape.offset_left(infix.len())?; } let rhs_result = rhs.rewrite(context, rhs_shape)?; let indent_str = rhs_shape.indent.to_string_with_newline(context.config); let infix_with_sep = match separator_place { SeparatorPlace::Back => format!("{}{}", infix, indent_str), SeparatorPlace::Front => format!("{}{}", indent_str, infix), }; Some(format!( "{}{}{}{}", lhs_result, infix_with_sep, rhs_result, pp.suffix )) } pub fn rewrite_array( exprs: &[&T], span: Span, context: &RewriteContext, shape: Shape, trailing_comma: bool, ) -> Option { let bracket_size = if context.config.spaces_within_parens_and_brackets() { 2 // "[ " } else { 1 // "[" }; let nested_shape = match context.config.indent_style() { IndentStyle::Block => shape .block() .block_indent(context.config.tab_spaces()) .with_max_width(context.config) .sub_width(1)?, IndentStyle::Visual => shape .visual_indent(bracket_size) .sub_width(bracket_size * 2)?, }; let items = itemize_list( context.snippet_provider, exprs.iter(), "]", ",", |item| item.span().lo(), |item| item.span().hi(), |item| item.rewrite(context, nested_shape), span.lo(), span.hi(), false, ).collect::>(); if items.is_empty() { if context.config.spaces_within_parens_and_brackets() { return Some("[ ]".to_string()); } else { return Some("[]".to_string()); } } let tactic = array_tactic(context, shape, nested_shape, exprs, &items, bracket_size); let ends_with_newline = tactic.ends_with_newline(context.config.indent_style()); let fmt = ListFormatting { tactic, separator: ",", trailing_separator: if trailing_comma { SeparatorTactic::Always } else if context.inside_macro && !exprs.is_empty() { let ends_with_bracket = context.snippet(span).ends_with(']'); let bracket_offset = if ends_with_bracket { 1 } else { 0 }; let snippet = context.snippet(mk_sp(span.lo(), span.hi() - BytePos(bracket_offset))); let last_char_index = snippet.rfind(|c: char| !c.is_whitespace())?; if &snippet[last_char_index..last_char_index + 1] == "," { SeparatorTactic::Always } else { SeparatorTactic::Never } } else if context.config.indent_style() == IndentStyle::Visual { SeparatorTactic::Never } else { SeparatorTactic::Vertical }, separator_place: SeparatorPlace::Back, shape: nested_shape, ends_with_newline, preserve_newline: false, config: context.config, }; let list_str = write_list(&items, &fmt)?; let result = if context.config.indent_style() == IndentStyle::Visual || tactic == DefinitiveListTactic::Horizontal { if context.config.spaces_within_parens_and_brackets() && !list_str.is_empty() { format!("[ {} ]", list_str) } else { format!("[{}]", list_str) } } else { format!( "[{}{}{}]", nested_shape.indent.to_string_with_newline(context.config), list_str, shape.block().indent.to_string_with_newline(context.config) ) }; Some(result) } fn array_tactic( context: &RewriteContext, shape: Shape, nested_shape: Shape, exprs: &[&T], items: &[ListItem], bracket_size: usize, ) -> DefinitiveListTactic { let has_long_item = items .iter() .any(|li| li.item.as_ref().map(|s| s.len() > 10).unwrap_or(false)); match context.config.indent_style() { IndentStyle::Block => { let tactic = match shape.width.checked_sub(2 * bracket_size) { Some(width) => { let tactic = ListTactic::LimitedHorizontalVertical( context.config.width_heuristics().array_width, ); definitive_tactic(items, tactic, Separator::Comma, width) } None => DefinitiveListTactic::Vertical, }; if tactic == DefinitiveListTactic::Vertical && !has_long_item && is_every_args_simple(exprs) { DefinitiveListTactic::Mixed } else { tactic } } IndentStyle::Visual => { if has_long_item || items.iter().any(ListItem::is_multiline) { definitive_tactic( items, ListTactic::LimitedHorizontalVertical( context.config.width_heuristics().array_width, ), Separator::Comma, nested_shape.width, ) } else { DefinitiveListTactic::Mixed } } } } fn nop_block_collapse(block_str: Option, budget: usize) -> Option { debug!("nop_block_collapse {:?} {}", block_str, budget); block_str.map(|block_str| { if block_str.starts_with('{') && budget >= 2 && (block_str[1..].find(|c: char| !c.is_whitespace()).unwrap() == block_str.len() - 2) { "{}".to_owned() } else { block_str.to_owned() } }) } fn rewrite_empty_block( context: &RewriteContext, block: &ast::Block, shape: Shape, ) -> Option { if block.stmts.is_empty() && !block_contains_comment(block, context.codemap) && shape.width >= 2 { return Some("{}".to_owned()); } // If a block contains only a single-line comment, then leave it on one line. let user_str = context.snippet(block.span); let user_str = user_str.trim(); if user_str.starts_with('{') && user_str.ends_with('}') { let comment_str = user_str[1..user_str.len() - 1].trim(); if block.stmts.is_empty() && !comment_str.contains('\n') && !comment_str.starts_with("//") && comment_str.len() + 4 <= shape.width { return Some(format!("{{ {} }}", comment_str)); } } None } fn block_prefix(context: &RewriteContext, block: &ast::Block, shape: Shape) -> Option { Some(match block.rules { ast::BlockCheckMode::Unsafe(..) => { let snippet = context.snippet(block.span); let open_pos = snippet.find_uncommented("{")?; // Extract comment between unsafe and block start. let trimmed = &snippet[6..open_pos].trim(); if !trimmed.is_empty() { // 9 = "unsafe {".len(), 7 = "unsafe ".len() let budget = shape.width.checked_sub(9)?; format!( "unsafe {} ", rewrite_comment( trimmed, true, Shape::legacy(budget, shape.indent + 7), context.config, )? ) } else { "unsafe ".to_owned() } } ast::BlockCheckMode::Default => String::new(), }) } fn rewrite_single_line_block( context: &RewriteContext, prefix: &str, block: &ast::Block, shape: Shape, ) -> Option { if is_simple_block(block, context.codemap) { let expr_shape = shape.offset_left(last_line_width(prefix))?; let expr_str = block.stmts[0].rewrite(context, expr_shape)?; let result = format!("{}{{ {} }}", prefix, expr_str); if result.len() <= shape.width && !result.contains('\n') { return Some(result); } } None } pub fn rewrite_block_with_visitor( context: &RewriteContext, prefix: &str, block: &ast::Block, shape: Shape, has_braces: bool, ) -> Option { if let rw @ Some(_) = rewrite_empty_block(context, block, shape) { return rw; } let mut visitor = FmtVisitor::from_context(context); visitor.block_indent = shape.indent; visitor.is_if_else_block = context.is_if_else_block; match block.rules { ast::BlockCheckMode::Unsafe(..) => { let snippet = context.snippet(block.span); let open_pos = snippet.find_uncommented("{")?; visitor.last_pos = block.span.lo() + BytePos(open_pos as u32) } ast::BlockCheckMode::Default => visitor.last_pos = block.span.lo(), } visitor.visit_block(block, None, has_braces); Some(format!("{}{}", prefix, visitor.buffer)) } impl Rewrite for ast::Block { fn rewrite(&self, context: &RewriteContext, shape: Shape) -> Option { // shape.width is used only for the single line case: either the empty block `{}`, // or an unsafe expression `unsafe { e }`. if let rw @ Some(_) = rewrite_empty_block(context, self, shape) { return rw; } let prefix = block_prefix(context, self, shape)?; let result = rewrite_block_with_visitor(context, &prefix, self, shape, true); if let Some(ref result_str) = result { if result_str.lines().count() <= 3 { if let rw @ Some(_) = rewrite_single_line_block(context, &prefix, self, shape) { return rw; } } } result } } impl Rewrite for ast::Stmt { fn rewrite(&self, context: &RewriteContext, shape: Shape) -> Option { skip_out_of_file_lines_range!(context, self.span()); let result = match self.node { ast::StmtKind::Local(ref local) => local.rewrite(context, shape), ast::StmtKind::Expr(ref ex) | ast::StmtKind::Semi(ref ex) => { let suffix = if semicolon_for_stmt(context, self) { ";" } else { "" }; let shape = shape.sub_width(suffix.len())?; format_expr(ex, ExprType::Statement, context, shape).map(|s| s + suffix) } ast::StmtKind::Mac(..) | ast::StmtKind::Item(..) => None, }; result.and_then(|res| recover_comment_removed(res, self.span(), context)) } } // Rewrite condition if the given expression has one. pub fn rewrite_cond(context: &RewriteContext, expr: &ast::Expr, shape: Shape) -> Option { match expr.node { ast::ExprKind::Match(ref cond, _) => { // `match `cond` {` let cond_shape = match context.config.indent_style() { IndentStyle::Visual => shape.shrink_left(6).and_then(|s| s.sub_width(2))?, IndentStyle::Block => shape.offset_left(8)?, }; cond.rewrite(context, cond_shape) } _ => to_control_flow(expr, ExprType::SubExpression).and_then(|control_flow| { let alt_block_sep = String::from("\n") + &shape.indent.block_only().to_string(context.config); control_flow .rewrite_cond(context, shape, &alt_block_sep) .and_then(|rw| Some(rw.0)) }), } } // Abstraction over control flow expressions #[derive(Debug)] struct ControlFlow<'a> { cond: Option<&'a ast::Expr>, block: &'a ast::Block, else_block: Option<&'a ast::Expr>, label: Option, pats: Vec<&'a ast::Pat>, keyword: &'a str, matcher: &'a str, connector: &'a str, allow_single_line: bool, // True if this is an `if` expression in an `else if` :-( hacky nested_if: bool, span: Span, } fn to_control_flow(expr: &ast::Expr, expr_type: ExprType) -> Option { match expr.node { ast::ExprKind::If(ref cond, ref if_block, ref else_block) => Some(ControlFlow::new_if( cond, vec![], if_block, else_block.as_ref().map(|e| &**e), expr_type == ExprType::SubExpression, false, expr.span, )), ast::ExprKind::IfLet(ref pat, ref cond, ref if_block, ref else_block) => { Some(ControlFlow::new_if( cond, ptr_vec_to_ref_vec(pat), if_block, else_block.as_ref().map(|e| &**e), expr_type == ExprType::SubExpression, false, expr.span, )) } ast::ExprKind::ForLoop(ref pat, ref cond, ref block, label) => { Some(ControlFlow::new_for(pat, cond, block, label, expr.span)) } ast::ExprKind::Loop(ref block, label) => { Some(ControlFlow::new_loop(block, label, expr.span)) } ast::ExprKind::While(ref cond, ref block, label) => Some(ControlFlow::new_while( vec![], cond, block, label, expr.span, )), ast::ExprKind::WhileLet(ref pat, ref cond, ref block, label) => Some( ControlFlow::new_while(ptr_vec_to_ref_vec(pat), cond, block, label, expr.span), ), _ => None, } } fn choose_matcher(pats: &[&ast::Pat]) -> &'static str { if pats.is_empty() { "" } else { "let" } } impl<'a> ControlFlow<'a> { fn new_if( cond: &'a ast::Expr, pats: Vec<&'a ast::Pat>, block: &'a ast::Block, else_block: Option<&'a ast::Expr>, allow_single_line: bool, nested_if: bool, span: Span, ) -> ControlFlow<'a> { let matcher = choose_matcher(&pats); ControlFlow { cond: Some(cond), block, else_block, label: None, pats, keyword: "if", matcher, connector: " =", allow_single_line, nested_if, span, } } fn new_loop(block: &'a ast::Block, label: Option, span: Span) -> ControlFlow<'a> { ControlFlow { cond: None, block, else_block: None, label, pats: vec![], keyword: "loop", matcher: "", connector: "", allow_single_line: false, nested_if: false, span, } } fn new_while( pats: Vec<&'a ast::Pat>, cond: &'a ast::Expr, block: &'a ast::Block, label: Option, span: Span, ) -> ControlFlow<'a> { let matcher = choose_matcher(&pats); ControlFlow { cond: Some(cond), block, else_block: None, label, pats, keyword: "while", matcher, connector: " =", allow_single_line: false, nested_if: false, span, } } fn new_for( pat: &'a ast::Pat, cond: &'a ast::Expr, block: &'a ast::Block, label: Option, span: Span, ) -> ControlFlow<'a> { ControlFlow { cond: Some(cond), block, else_block: None, label, pats: vec![pat], keyword: "for", matcher: "", connector: " in", allow_single_line: false, nested_if: false, span, } } fn rewrite_single_line( &self, pat_expr_str: &str, context: &RewriteContext, width: usize, ) -> Option { assert!(self.allow_single_line); let else_block = self.else_block?; let fixed_cost = self.keyword.len() + " { } else { }".len(); if let ast::ExprKind::Block(ref else_node) = else_block.node { if !is_simple_block(self.block, context.codemap) || !is_simple_block(else_node, context.codemap) || pat_expr_str.contains('\n') { return None; } let new_width = width.checked_sub(pat_expr_str.len() + fixed_cost)?; let expr = &self.block.stmts[0]; let if_str = expr.rewrite(context, Shape::legacy(new_width, Indent::empty()))?; let new_width = new_width.checked_sub(if_str.len())?; let else_expr = &else_node.stmts[0]; let else_str = else_expr.rewrite(context, Shape::legacy(new_width, Indent::empty()))?; if if_str.contains('\n') || else_str.contains('\n') { return None; } let result = format!( "{} {} {{ {} }} else {{ {} }}", self.keyword, pat_expr_str, if_str, else_str ); if result.len() <= width { return Some(result); } } None } } impl<'a> ControlFlow<'a> { fn rewrite_pat_expr( &self, context: &RewriteContext, expr: &ast::Expr, shape: Shape, offset: usize, ) -> Option { debug!("rewrite_pat_expr {:?} {:?} {:?}", shape, self.pats, expr); let cond_shape = shape.offset_left(offset)?; if !self.pats.is_empty() { let matcher = if self.matcher.is_empty() { self.matcher.to_owned() } else { format!("{} ", self.matcher) }; let pat_shape = cond_shape .offset_left(matcher.len())? .sub_width(self.connector.len())?; let pat_string = rewrite_multiple_patterns(context, &self.pats, pat_shape)?; let result = format!("{}{}{}", matcher, pat_string, self.connector); return rewrite_assign_rhs(context, result, expr, cond_shape); } let expr_rw = expr.rewrite(context, cond_shape); // The expression may (partially) fit on the current line. // We do not allow splitting between `if` and condition. if self.keyword == "if" || expr_rw.is_some() { return expr_rw; } // The expression won't fit on the current line, jump to next. let nested_shape = shape .block_indent(context.config.tab_spaces()) .with_max_width(context.config); let nested_indent_str = nested_shape.indent.to_string_with_newline(context.config); expr.rewrite(context, nested_shape) .map(|expr_rw| format!("{}{}", nested_indent_str, expr_rw)) } fn rewrite_cond( &self, context: &RewriteContext, shape: Shape, alt_block_sep: &str, ) -> Option<(String, usize)> { // Do not take the rhs overhead from the upper expressions into account // when rewriting pattern. let new_width = context.budget(shape.used_width()); let fresh_shape = Shape { width: new_width, ..shape }; let constr_shape = if self.nested_if { // We are part of an if-elseif-else chain. Our constraints are tightened. // 7 = "} else " .len() fresh_shape.offset_left(7)? } else { fresh_shape }; let label_string = rewrite_label(self.label); // 1 = space after keyword. let offset = self.keyword.len() + label_string.len() + 1; let pat_expr_string = match self.cond { Some(cond) => self.rewrite_pat_expr(context, cond, constr_shape, offset)?, None => String::new(), }; let brace_overhead = if context.config.control_brace_style() != ControlBraceStyle::AlwaysNextLine { // 2 = ` {` 2 } else { 0 }; let one_line_budget = context .config .max_width() .checked_sub(constr_shape.used_width() + offset + brace_overhead) .unwrap_or(0); let force_newline_brace = (pat_expr_string.contains('\n') || pat_expr_string.len() > one_line_budget) && !last_line_extendable(&pat_expr_string); // Try to format if-else on single line. if self.allow_single_line && context .config .width_heuristics() .single_line_if_else_max_width > 0 { let trial = self.rewrite_single_line(&pat_expr_string, context, shape.width); if let Some(cond_str) = trial { if cond_str.len() <= context .config .width_heuristics() .single_line_if_else_max_width { return Some((cond_str, 0)); } } } let cond_span = if let Some(cond) = self.cond { cond.span } else { mk_sp(self.block.span.lo(), self.block.span.lo()) }; // `for event in event` // Do not include label in the span. let lo = self.label.map_or(self.span.lo(), |label| label.span.hi()); let between_kwd_cond = mk_sp( context .snippet_provider .span_after(mk_sp(lo, self.span.hi()), self.keyword.trim()), if self.pats.is_empty() { cond_span.lo() } else if self.matcher.is_empty() { self.pats[0].span.lo() } else { context .snippet_provider .span_before(self.span, self.matcher.trim()) }, ); let between_kwd_cond_comment = extract_comment(between_kwd_cond, context, shape); let after_cond_comment = extract_comment(mk_sp(cond_span.hi(), self.block.span.lo()), context, shape); let block_sep = if self.cond.is_none() && between_kwd_cond_comment.is_some() { "" } else if context.config.control_brace_style() == ControlBraceStyle::AlwaysNextLine || force_newline_brace { alt_block_sep } else { " " }; let used_width = if pat_expr_string.contains('\n') { last_line_width(&pat_expr_string) } else { // 2 = spaces after keyword and condition. label_string.len() + self.keyword.len() + pat_expr_string.len() + 2 }; Some(( format!( "{}{}{}{}{}", label_string, self.keyword, between_kwd_cond_comment.as_ref().map_or( if pat_expr_string.is_empty() || pat_expr_string.starts_with('\n') { "" } else { " " }, |s| &**s, ), pat_expr_string, after_cond_comment.as_ref().map_or(block_sep, |s| &**s) ), used_width, )) } } impl<'a> Rewrite for ControlFlow<'a> { fn rewrite(&self, context: &RewriteContext, shape: Shape) -> Option { debug!("ControlFlow::rewrite {:?} {:?}", self, shape); let alt_block_sep = &shape.indent.to_string_with_newline(context.config); let (cond_str, used_width) = self.rewrite_cond(context, shape, alt_block_sep)?; // If `used_width` is 0, it indicates that whole control flow is written in a single line. if used_width == 0 { return Some(cond_str); } let block_width = shape.width.checked_sub(used_width).unwrap_or(0); // This is used only for the empty block case: `{}`. So, we use 1 if we know // we should avoid the single line case. let block_width = if self.else_block.is_some() || self.nested_if { min(1, block_width) } else { block_width }; let block_shape = Shape { width: block_width, ..shape }; let mut block_context = context.clone(); block_context.is_if_else_block = self.else_block.is_some(); let block_str = rewrite_block_with_visitor(&block_context, "", self.block, block_shape, true)?; let mut result = format!("{}{}", cond_str, block_str); if let Some(else_block) = self.else_block { let shape = Shape::indented(shape.indent, context.config); let mut last_in_chain = false; let rewrite = match else_block.node { // If the else expression is another if-else expression, prevent it // from being formatted on a single line. // Note how we're passing the original shape, as the // cost of "else" should not cascade. ast::ExprKind::IfLet(ref pat, ref cond, ref if_block, ref next_else_block) => { ControlFlow::new_if( cond, ptr_vec_to_ref_vec(pat), if_block, next_else_block.as_ref().map(|e| &**e), false, true, mk_sp(else_block.span.lo(), self.span.hi()), ).rewrite(context, shape) } ast::ExprKind::If(ref cond, ref if_block, ref next_else_block) => { ControlFlow::new_if( cond, vec![], if_block, next_else_block.as_ref().map(|e| &**e), false, true, mk_sp(else_block.span.lo(), self.span.hi()), ).rewrite(context, shape) } _ => { last_in_chain = true; // When rewriting a block, the width is only used for single line // blocks, passing 1 lets us avoid that. let else_shape = Shape { width: min(1, shape.width), ..shape }; format_expr(else_block, ExprType::Statement, context, else_shape) } }; let between_kwd_else_block = mk_sp( self.block.span.hi(), context .snippet_provider .span_before(mk_sp(self.block.span.hi(), else_block.span.lo()), "else"), ); let between_kwd_else_block_comment = extract_comment(between_kwd_else_block, context, shape); let after_else = mk_sp( context .snippet_provider .span_after(mk_sp(self.block.span.hi(), else_block.span.lo()), "else"), else_block.span.lo(), ); let after_else_comment = extract_comment(after_else, context, shape); let between_sep = match context.config.control_brace_style() { ControlBraceStyle::AlwaysNextLine | ControlBraceStyle::ClosingNextLine => { &*alt_block_sep } ControlBraceStyle::AlwaysSameLine => " ", }; let after_sep = match context.config.control_brace_style() { ControlBraceStyle::AlwaysNextLine if last_in_chain => &*alt_block_sep, _ => " ", }; result.push_str(&format!( "{}else{}", between_kwd_else_block_comment .as_ref() .map_or(between_sep, |s| &**s), after_else_comment.as_ref().map_or(after_sep, |s| &**s), )); result.push_str(&rewrite?); } Some(result) } } fn rewrite_label(opt_label: Option) -> Cow<'static, str> { match opt_label { Some(label) => Cow::from(format!("{}: ", label.ident)), None => Cow::from(""), } } fn extract_comment(span: Span, context: &RewriteContext, shape: Shape) -> Option { match rewrite_missing_comment(span, shape, context) { Some(ref comment) if !comment.is_empty() => Some(format!( "{indent}{}{indent}", comment, indent = shape.indent.to_string_with_newline(context.config) )), _ => None, } } pub fn block_contains_comment(block: &ast::Block, codemap: &CodeMap) -> bool { let snippet = codemap.span_to_snippet(block.span).unwrap(); contains_comment(&snippet) } // Checks that a block contains no statements, an expression and no comments. // FIXME: incorrectly returns false when comment is contained completely within // the expression. pub fn is_simple_block(block: &ast::Block, codemap: &CodeMap) -> bool { (block.stmts.len() == 1 && stmt_is_expr(&block.stmts[0]) && !block_contains_comment(block, codemap)) } /// Checks whether a block contains at most one statement or expression, and no comments. pub fn is_simple_block_stmt(block: &ast::Block, codemap: &CodeMap) -> bool { block.stmts.len() <= 1 && !block_contains_comment(block, codemap) } /// Checks whether a block contains no statements, expressions, or comments. pub fn is_empty_block(block: &ast::Block, codemap: &CodeMap) -> bool { block.stmts.is_empty() && !block_contains_comment(block, codemap) } pub fn stmt_is_expr(stmt: &ast::Stmt) -> bool { match stmt.node { ast::StmtKind::Expr(..) => true, _ => false, } } pub fn is_unsafe_block(block: &ast::Block) -> bool { if let ast::BlockCheckMode::Unsafe(..) = block.rules { true } else { false } } /// A simple wrapper type against `ast::Arm`. Used inside `write_list()`. struct ArmWrapper<'a> { pub arm: &'a ast::Arm, /// True if the arm is the last one in match expression. Used to decide on whether we should add /// trailing comma to the match arm when `config.trailing_comma() == Never`. pub is_last: bool, /// Holds a byte position of `|` at the beginning of the arm pattern, if available. pub beginning_vert: Option, } impl<'a> ArmWrapper<'a> { pub fn new( arm: &'a ast::Arm, is_last: bool, beginning_vert: Option, ) -> ArmWrapper<'a> { ArmWrapper { arm, is_last, beginning_vert, } } } impl<'a> Spanned for ArmWrapper<'a> { fn span(&self) -> Span { if let Some(lo) = self.beginning_vert { mk_sp(lo, self.arm.span().hi()) } else { self.arm.span() } } } impl<'a> Rewrite for ArmWrapper<'a> { fn rewrite(&self, context: &RewriteContext, shape: Shape) -> Option { rewrite_match_arm(context, self.arm, shape, self.is_last, self.beginning_vert) } } fn rewrite_match( context: &RewriteContext, cond: &ast::Expr, arms: &[ast::Arm], shape: Shape, span: Span, attrs: &[ast::Attribute], ) -> Option { // Do not take the rhs overhead from the upper expressions into account // when rewriting match condition. let cond_shape = Shape { width: context.budget(shape.used_width()), ..shape }; // 6 = `match ` let cond_shape = match context.config.indent_style() { IndentStyle::Visual => cond_shape.shrink_left(6)?, IndentStyle::Block => cond_shape.offset_left(6)?, }; let cond_str = cond.rewrite(context, cond_shape)?; let alt_block_sep = &shape.indent.to_string_with_newline(context.config); let block_sep = match context.config.control_brace_style() { ControlBraceStyle::AlwaysNextLine => alt_block_sep, _ if last_line_extendable(&cond_str) => " ", // 2 = ` {` _ if cond_str.contains('\n') || cond_str.len() + 2 > cond_shape.width => alt_block_sep, _ => " ", }; let nested_indent_str = shape .indent .block_indent(context.config) .to_string(context.config); // Inner attributes. let inner_attrs = &inner_attributes(attrs); let inner_attrs_str = if inner_attrs.is_empty() { String::new() } else { inner_attrs .rewrite(context, shape) .map(|s| format!("{}{}\n", nested_indent_str, s))? }; let open_brace_pos = if inner_attrs.is_empty() { let hi = if arms.is_empty() { span.hi() } else { arms[0].span().lo() }; context .snippet_provider .span_after(mk_sp(cond.span.hi(), hi), "{") } else { inner_attrs[inner_attrs.len() - 1].span().hi() }; if arms.is_empty() { let snippet = context.snippet(mk_sp(open_brace_pos, span.hi() - BytePos(1))); if snippet.trim().is_empty() { Some(format!("match {} {{}}", cond_str)) } else { // Empty match with comments or inner attributes? We are not going to bother, sorry ;) Some(context.snippet(span).to_owned()) } } else { Some(format!( "match {}{}{{\n{}{}{}\n{}}}", cond_str, block_sep, inner_attrs_str, nested_indent_str, rewrite_match_arms(context, arms, shape, span, open_brace_pos)?, shape.indent.to_string(context.config), )) } } fn arm_comma(config: &Config, body: &ast::Expr, is_last: bool) -> &'static str { if is_last && config.trailing_comma() == SeparatorTactic::Never { "" } else if config.match_block_trailing_comma() { "," } else if let ast::ExprKind::Block(ref block) = body.node { if let ast::BlockCheckMode::Default = block.rules { "" } else { "," } } else { "," } } /// Collect a byte position of the beginning `|` for each arm, if available. fn collect_beginning_verts( context: &RewriteContext, arms: &[ast::Arm], span: Span, ) -> Vec> { let mut beginning_verts = Vec::with_capacity(arms.len()); let mut lo = context.snippet_provider.span_after(span, "{"); for arm in arms { let hi = arm.pats[0].span.lo(); let missing_span = mk_sp(lo, hi); beginning_verts.push(context.snippet_provider.opt_span_before(missing_span, "|")); lo = arm.span().hi(); } beginning_verts } fn rewrite_match_arms( context: &RewriteContext, arms: &[ast::Arm], shape: Shape, span: Span, open_brace_pos: BytePos, ) -> Option { let arm_shape = shape .block_indent(context.config.tab_spaces()) .with_max_width(context.config); let arm_len = arms.len(); let is_last_iter = repeat(false) .take(arm_len.checked_sub(1).unwrap_or(0)) .chain(repeat(true)); let beginning_verts = collect_beginning_verts(context, arms, span); let items = itemize_list( context.snippet_provider, arms.iter() .zip(is_last_iter) .zip(beginning_verts.into_iter()) .map(|((arm, is_last), beginning_vert)| ArmWrapper::new(arm, is_last, beginning_vert)), "}", "|", |arm| arm.span().lo(), |arm| arm.span().hi(), |arm| arm.rewrite(context, arm_shape), open_brace_pos, span.hi(), false, ); let arms_vec: Vec<_> = items.collect(); let fmt = ListFormatting { tactic: DefinitiveListTactic::Vertical, // We will add/remove commas inside `arm.rewrite()`, and hence no separator here. separator: "", trailing_separator: SeparatorTactic::Never, separator_place: SeparatorPlace::Back, shape: arm_shape, ends_with_newline: true, preserve_newline: true, config: context.config, }; write_list(&arms_vec, &fmt) } fn rewrite_match_arm( context: &RewriteContext, arm: &ast::Arm, shape: Shape, is_last: bool, beginning_vert: Option, ) -> Option { let (missing_span, attrs_str) = if !arm.attrs.is_empty() { if contains_skip(&arm.attrs) { let (_, body) = flatten_arm_body(context, &arm.body); // `arm.span()` does not include trailing comma, add it manually. return Some(format!( "{}{}", context.snippet(arm.span()), arm_comma(context.config, body, is_last), )); } let missing_span = mk_sp( arm.attrs[arm.attrs.len() - 1].span.hi(), arm.pats[0].span.lo(), ); (missing_span, arm.attrs.rewrite(context, shape)?) } else { (mk_sp(arm.span().lo(), arm.span().lo()), String::new()) }; let pats_str = rewrite_match_pattern( context, &ptr_vec_to_ref_vec(&arm.pats), &arm.guard, beginning_vert.is_some(), shape, ).and_then(|pats_str| { combine_strs_with_missing_comments( context, &attrs_str, &pats_str, missing_span, shape, false, ) })?; rewrite_match_body( context, &arm.body, &pats_str, shape, arm.guard.is_some(), is_last, ) } /// Returns true if the given pattern is short. A short pattern is defined by the following grammer: /// /// [small, ntp]: /// - single token /// - `&[single-line, ntp]` /// /// [small]: /// - `[small, ntp]` /// - unary tuple constructor `([small, ntp])` /// - `&[small]` fn is_short_pattern(pat: &ast::Pat, pat_str: &str) -> bool { // We also require that the pattern is reasonably 'small' with its literal width. pat_str.len() <= 20 && !pat_str.contains('\n') && is_short_pattern_inner(pat) } fn is_short_pattern_inner(pat: &ast::Pat) -> bool { match pat.node { ast::PatKind::Wild | ast::PatKind::Lit(_) => true, ast::PatKind::Ident(_, _, ref pat) => pat.is_none(), ast::PatKind::Struct(..) | ast::PatKind::Mac(..) | ast::PatKind::Slice(..) | ast::PatKind::Path(..) | ast::PatKind::Range(..) => false, ast::PatKind::Tuple(ref subpats, _) => subpats.len() <= 1, ast::PatKind::TupleStruct(ref path, ref subpats, _) => { path.segments.len() <= 1 && subpats.len() <= 1 } ast::PatKind::Box(ref p) | ast::PatKind::Ref(ref p, _) | ast::PatKind::Paren(ref p) => { is_short_pattern_inner(&*p) } } } fn rewrite_match_pattern( context: &RewriteContext, pats: &[&ast::Pat], guard: &Option>, has_beginning_vert: bool, shape: Shape, ) -> Option { // Patterns // 5 = ` => {` // 2 = `| ` let pat_shape = shape .sub_width(5)? .offset_left(if has_beginning_vert { 2 } else { 0 })?; let pats_str = rewrite_multiple_patterns(context, pats, pat_shape)?; let beginning_vert = if has_beginning_vert { "| " } else { "" }; // Guard let guard_str = rewrite_guard(context, guard, shape, trimmed_last_line_width(&pats_str))?; Some(format!("{}{}{}", beginning_vert, pats_str, guard_str)) } // (extend, body) // @extend: true if the arm body can be put next to `=>` // @body: flattened body, if the body is block with a single expression fn flatten_arm_body<'a>(context: &'a RewriteContext, body: &'a ast::Expr) -> (bool, &'a ast::Expr) { match body.node { ast::ExprKind::Block(ref block) if !is_unsafe_block(block) && is_simple_block(block, context.codemap) => { if let ast::StmtKind::Expr(ref expr) = block.stmts[0].node { ( !context.config.force_multiline_blocks() && can_extend_match_arm_body(expr), &*expr, ) } else { (false, &*body) } } _ => ( !context.config.force_multiline_blocks() && body.can_be_overflowed(context, 1), &*body, ), } } fn rewrite_match_body( context: &RewriteContext, body: &ptr::P, pats_str: &str, shape: Shape, has_guard: bool, is_last: bool, ) -> Option { let (extend, body) = flatten_arm_body(context, body); let (is_block, is_empty_block) = if let ast::ExprKind::Block(ref block) = body.node { (true, is_empty_block(block, context.codemap)) } else { (false, false) }; let comma = arm_comma(context.config, body, is_last); let alt_block_sep = &shape.indent.to_string_with_newline(context.config); let combine_orig_body = |body_str: &str| { let block_sep = match context.config.control_brace_style() { ControlBraceStyle::AlwaysNextLine if is_block => alt_block_sep, _ => " ", }; Some(format!("{} =>{}{}{}", pats_str, block_sep, body_str, comma)) }; let forbid_same_line = has_guard && pats_str.contains('\n') && !is_empty_block; let next_line_indent = if !is_block || is_empty_block { shape.indent.block_indent(context.config) } else { shape.indent }; let combine_next_line_body = |body_str: &str| { if is_block { return Some(format!( "{} =>{}{}", pats_str, next_line_indent.to_string_with_newline(context.config), body_str )); } let indent_str = shape.indent.to_string_with_newline(context.config); let nested_indent_str = next_line_indent.to_string_with_newline(context.config); let (body_prefix, body_suffix) = if context.config.match_arm_blocks() { let comma = if context.config.match_block_trailing_comma() { "," } else { "" }; ("{", format!("{}}}{}", indent_str, comma)) } else { ("", String::from(",")) }; let block_sep = match context.config.control_brace_style() { ControlBraceStyle::AlwaysNextLine => format!("{}{}", alt_block_sep, body_prefix), _ if body_prefix.is_empty() => "".to_owned(), _ if forbid_same_line => format!("{}{}", alt_block_sep, body_prefix), _ => format!(" {}", body_prefix), } + &nested_indent_str; Some(format!( "{} =>{}{}{}", pats_str, block_sep, body_str, body_suffix )) }; // Let's try and get the arm body on the same line as the condition. // 4 = ` => `.len() let orig_body_shape = shape .offset_left(extra_offset(pats_str, shape) + 4) .and_then(|shape| shape.sub_width(comma.len())); let orig_body = if let Some(body_shape) = orig_body_shape { let rewrite = nop_block_collapse( format_expr(body, ExprType::Statement, context, body_shape), body_shape.width, ); match rewrite { Some(ref body_str) if !forbid_same_line && (is_block || (!body_str.contains('\n') && body_str.len() <= body_shape.width)) => { return combine_orig_body(body_str); } _ => rewrite, } } else { None }; let orig_budget = orig_body_shape.map_or(0, |shape| shape.width); // Try putting body on the next line and see if it looks better. let next_line_body_shape = Shape::indented(next_line_indent, context.config); let next_line_body = nop_block_collapse( format_expr(body, ExprType::Statement, context, next_line_body_shape), next_line_body_shape.width, ); match (orig_body, next_line_body) { (Some(ref orig_str), Some(ref next_line_str)) if forbid_same_line || prefer_next_line(orig_str, next_line_str) => { combine_next_line_body(next_line_str) } (Some(ref orig_str), _) if extend && first_line_width(orig_str) <= orig_budget => { combine_orig_body(orig_str) } (Some(ref orig_str), Some(ref next_line_str)) if orig_str.contains('\n') => { combine_next_line_body(next_line_str) } (None, Some(ref next_line_str)) => combine_next_line_body(next_line_str), (None, None) => None, (Some(ref orig_str), _) => combine_orig_body(orig_str), } } // The `if ...` guard on a match arm. fn rewrite_guard( context: &RewriteContext, guard: &Option>, shape: Shape, // The amount of space used up on this line for the pattern in // the arm (excludes offset). pattern_width: usize, ) -> Option { if let Some(ref guard) = *guard { // First try to fit the guard string on the same line as the pattern. // 4 = ` if `, 5 = ` => {` let cond_shape = shape .offset_left(pattern_width + 4) .and_then(|s| s.sub_width(5)); if let Some(cond_shape) = cond_shape { if let Some(cond_str) = guard.rewrite(context, cond_shape) { if !cond_str.contains('\n') || pattern_width <= context.config.tab_spaces() { return Some(format!(" if {}", cond_str)); } } } // Not enough space to put the guard after the pattern, try a newline. // 3 = `if `, 5 = ` => {` let cond_shape = Shape::indented(shape.indent.block_indent(context.config), context.config) .offset_left(3) .and_then(|s| s.sub_width(5)); if let Some(cond_shape) = cond_shape { if let Some(cond_str) = guard.rewrite(context, cond_shape) { return Some(format!( "{}if {}", cond_shape.indent.to_string_with_newline(context.config), cond_str )); } } None } else { Some(String::new()) } } fn rewrite_multiple_patterns( context: &RewriteContext, pats: &[&ast::Pat], shape: Shape, ) -> Option { let pat_strs = pats.iter() .map(|p| p.rewrite(context, shape)) .collect::>>()?; let use_mixed_layout = pats.iter() .zip(pat_strs.iter()) .all(|(pat, pat_str)| is_short_pattern(pat, pat_str)); let items: Vec<_> = pat_strs.into_iter().map(ListItem::from_str).collect(); let tactic = if use_mixed_layout { DefinitiveListTactic::Mixed } else { definitive_tactic( &items, ListTactic::HorizontalVertical, Separator::VerticalBar, shape.width, ) }; let fmt = ListFormatting { tactic, separator: " |", trailing_separator: SeparatorTactic::Never, separator_place: context.config.binop_separator(), shape, ends_with_newline: false, preserve_newline: false, config: context.config, }; write_list(&items, &fmt) } fn can_extend_match_arm_body(body: &ast::Expr) -> bool { match body.node { // We do not allow `if` to stay on the same line, since we could easily mistake // `pat => if cond { ... }` and `pat if cond => { ... }`. ast::ExprKind::If(..) | ast::ExprKind::IfLet(..) => false, ast::ExprKind::ForLoop(..) | ast::ExprKind::Loop(..) | ast::ExprKind::While(..) | ast::ExprKind::WhileLet(..) | ast::ExprKind::Match(..) | ast::ExprKind::Block(..) | ast::ExprKind::Closure(..) | ast::ExprKind::Array(..) | ast::ExprKind::Call(..) | ast::ExprKind::MethodCall(..) | ast::ExprKind::Mac(..) | ast::ExprKind::Struct(..) | ast::ExprKind::Tup(..) => true, ast::ExprKind::AddrOf(_, ref expr) | ast::ExprKind::Box(ref expr) | ast::ExprKind::Try(ref expr) | ast::ExprKind::Unary(_, ref expr) | ast::ExprKind::Cast(ref expr, _) => can_extend_match_arm_body(expr), _ => false, } } pub fn rewrite_literal(context: &RewriteContext, l: &ast::Lit, shape: Shape) -> Option { match l.node { ast::LitKind::Str(_, ast::StrStyle::Cooked) => rewrite_string_lit(context, l.span, shape), _ => wrap_str( context.snippet(l.span).to_owned(), context.config.max_width(), shape, ), } } fn rewrite_string_lit(context: &RewriteContext, span: Span, shape: Shape) -> Option { let string_lit = context.snippet(span); if !context.config.format_strings() { if string_lit .lines() .rev() .skip(1) .all(|line| line.ends_with('\\')) { let new_indent = shape.visual_indent(1).indent; let indented_string_lit = String::from( string_lit .lines() .map(|line| { format!( "{}{}", new_indent.to_string(context.config), line.trim_left() ) }) .collect::>() .join("\n") .trim_left(), ); return wrap_str(indented_string_lit, context.config.max_width(), shape); } else { return wrap_str(string_lit.to_owned(), context.config.max_width(), shape); } } // Remove the quote characters. let str_lit = &string_lit[1..string_lit.len() - 1]; rewrite_string( str_lit, &StringFormat::new(shape.visual_indent(0), context.config), None, ) } /// A list of `format!`-like macros, that take a long format string and a list of arguments to /// format. /// /// Organized as a list of `(&str, usize)` tuples, giving the name of the macro and the number of /// arguments before the format string (none for `format!("format", ...)`, one for `assert!(result, /// "format", ...)`, two for `assert_eq!(left, right, "format", ...)`). const SPECIAL_MACRO_WHITELIST: &[(&str, usize)] = &[ // format! like macros // From the Rust Standard Library. ("eprint!", 0), ("eprintln!", 0), ("format!", 0), ("format_args!", 0), ("print!", 0), ("println!", 0), ("panic!", 0), ("unreachable!", 0), // From the `log` crate. ("debug!", 0), ("error!", 0), ("info!", 0), ("warn!", 0), // write! like macros ("assert!", 1), ("debug_assert!", 1), ("write!", 1), ("writeln!", 1), // assert_eq! like macros ("assert_eq!", 2), ("assert_ne!", 2), ("debug_assert_eq!", 2), ("debug_assert_ne!", 2), ]; pub fn rewrite_call( context: &RewriteContext, callee: &str, args: &[ptr::P], span: Span, shape: Shape, ) -> Option { let force_trailing_comma = if context.inside_macro { span_ends_with_comma(context, span) } else { false }; rewrite_call_inner( context, callee, &ptr_vec_to_ref_vec(args), span, shape, context.config.width_heuristics().fn_call_width, force_trailing_comma, ) } pub fn rewrite_call_inner<'a, T>( context: &RewriteContext, callee_str: &str, args: &[&T], span: Span, shape: Shape, args_max_width: usize, force_trailing_comma: bool, ) -> Option where T: Rewrite + Spanned + ToExpr + 'a, { // 2 = `( `, 1 = `(` let paren_overhead = if context.config.spaces_within_parens_and_brackets() { 2 } else { 1 }; let used_width = extra_offset(callee_str, shape); let one_line_width = shape .width .checked_sub(used_width + 2 * paren_overhead) .unwrap_or(0); // 1 = "(" or ")" let one_line_shape = shape .offset_left(last_line_width(callee_str) + 1) .and_then(|shape| shape.sub_width(1)) .unwrap_or(Shape { width: 0, ..shape }); let nested_shape = shape_from_indent_style( context, shape, used_width + 2 * paren_overhead, used_width + paren_overhead, )?; let span_lo = context.snippet_provider.span_after(span, "("); let args_span = mk_sp(span_lo, span.hi()); let (extendable, list_str) = rewrite_call_args( context, args, args_span, one_line_shape, nested_shape, one_line_width, args_max_width, force_trailing_comma, callee_str, )?; if !context.use_block_indent() && need_block_indent(&list_str, nested_shape) && !extendable { let mut new_context = context.clone(); new_context.use_block = true; return rewrite_call_inner( &new_context, callee_str, args, span, shape, args_max_width, force_trailing_comma, ); } let args_shape = Shape { width: shape .width .checked_sub(last_line_width(callee_str)) .unwrap_or(0), ..shape }; Some(format!( "{}{}", callee_str, wrap_args_with_parens(context, &list_str, extendable, args_shape, nested_shape) )) } fn need_block_indent(s: &str, shape: Shape) -> bool { s.lines().skip(1).any(|s| { s.find(|c| !char::is_whitespace(c)) .map_or(false, |w| w + 1 < shape.indent.width()) }) } fn rewrite_call_args<'a, T>( context: &RewriteContext, args: &[&T], span: Span, one_line_shape: Shape, nested_shape: Shape, one_line_width: usize, args_max_width: usize, force_trailing_comma: bool, callee_str: &str, ) -> Option<(bool, String)> where T: Rewrite + Spanned + ToExpr + 'a, { let items = itemize_list( context.snippet_provider, args.iter(), ")", ",", |item| item.span().lo(), |item| item.span().hi(), |item| item.rewrite(context, nested_shape), span.lo(), span.hi(), true, ); let mut item_vec: Vec<_> = items.collect(); // Try letting the last argument overflow to the next line with block // indentation. If its first line fits on one line with the other arguments, // we format the function arguments horizontally. let tactic = try_overflow_last_arg( context, &mut item_vec, &args[..], one_line_shape, nested_shape, one_line_width, args_max_width, callee_str, ); let fmt = ListFormatting { tactic, separator: ",", trailing_separator: if force_trailing_comma { SeparatorTactic::Always } else if context.inside_macro || !context.use_block_indent() { SeparatorTactic::Never } else { context.config.trailing_comma() }, separator_place: SeparatorPlace::Back, shape: nested_shape, ends_with_newline: context.use_block_indent() && tactic == DefinitiveListTactic::Vertical, preserve_newline: false, config: context.config, }; write_list(&item_vec, &fmt) .map(|args_str| (tactic == DefinitiveListTactic::Horizontal, args_str)) } fn try_overflow_last_arg<'a, T>( context: &RewriteContext, item_vec: &mut Vec, args: &[&T], one_line_shape: Shape, nested_shape: Shape, one_line_width: usize, args_max_width: usize, callee_str: &str, ) -> DefinitiveListTactic where T: Rewrite + Spanned + ToExpr + 'a, { // 1 = "(" let combine_arg_with_callee = callee_str.len() + 1 <= context.config.tab_spaces() && args.len() == 1; let overflow_last = combine_arg_with_callee || can_be_overflowed(context, args); // Replace the last item with its first line to see if it fits with // first arguments. let placeholder = if overflow_last { let mut context = context.clone(); if !combine_arg_with_callee { if let Some(expr) = args[args.len() - 1].to_expr() { if let ast::ExprKind::MethodCall(..) = expr.node { context.force_one_line_chain = true; } } } last_arg_shape(args, item_vec, one_line_shape, args_max_width).and_then(|arg_shape| { rewrite_last_arg_with_overflow(&context, args, &mut item_vec[args.len() - 1], arg_shape) }) } else { None }; let mut tactic = definitive_tactic( &*item_vec, ListTactic::LimitedHorizontalVertical(args_max_width), Separator::Comma, one_line_width, ); // Replace the stub with the full overflowing last argument if the rewrite // succeeded and its first line fits with the other arguments. match (overflow_last, tactic, placeholder) { (true, DefinitiveListTactic::Horizontal, Some(ref overflowed)) if args.len() == 1 => { // When we are rewriting a nested function call, we restrict the // bugdet for the inner function to avoid them being deeply nested. // However, when the inner function has a prefix or a suffix // (e.g. `foo() as u32`), this budget reduction may produce poorly // formatted code, where a prefix or a suffix being left on its own // line. Here we explicitlly check those cases. if count_newlines(overflowed) == 1 { let rw = args.last() .and_then(|last_arg| last_arg.rewrite(context, nested_shape)); let no_newline = rw.as_ref().map_or(false, |s| !s.contains('\n')); if no_newline { item_vec[args.len() - 1].item = rw; } else { item_vec[args.len() - 1].item = Some(overflowed.to_owned()); } } else { item_vec[args.len() - 1].item = Some(overflowed.to_owned()); } } (true, DefinitiveListTactic::Horizontal, placeholder @ Some(..)) => { item_vec[args.len() - 1].item = placeholder; } _ if args.len() >= 1 => { item_vec[args.len() - 1].item = args.last() .and_then(|last_arg| last_arg.rewrite(context, nested_shape)); let default_tactic = || { definitive_tactic( &*item_vec, ListTactic::LimitedHorizontalVertical(args_max_width), Separator::Comma, one_line_width, ) }; // Use horizontal layout for a function with a single argument as long as // everything fits in a single line. if args.len() == 1 && args_max_width != 0 // Vertical layout is forced. && !item_vec[0].has_comment() && !item_vec[0].inner_as_ref().contains('\n') && ::lists::total_item_width(&item_vec[0]) <= one_line_width { tactic = DefinitiveListTactic::Horizontal; } else { tactic = default_tactic(); if tactic == DefinitiveListTactic::Vertical { if let Some((all_simple, num_args_before)) = maybe_get_args_offset(callee_str, args) { let one_line = all_simple && definitive_tactic( &item_vec[..num_args_before], ListTactic::HorizontalVertical, Separator::Comma, nested_shape.width, ) == DefinitiveListTactic::Horizontal && definitive_tactic( &item_vec[num_args_before + 1..], ListTactic::HorizontalVertical, Separator::Comma, nested_shape.width, ) == DefinitiveListTactic::Horizontal; if one_line { tactic = DefinitiveListTactic::SpecialMacro(num_args_before); }; } } } } _ => (), } tactic } fn is_simple_arg(expr: &ast::Expr) -> bool { match expr.node { ast::ExprKind::Lit(..) => true, ast::ExprKind::Path(ref qself, ref path) => qself.is_none() && path.segments.len() <= 1, ast::ExprKind::AddrOf(_, ref expr) | ast::ExprKind::Box(ref expr) | ast::ExprKind::Cast(ref expr, _) | ast::ExprKind::Field(ref expr, _) | ast::ExprKind::Try(ref expr) | ast::ExprKind::TupField(ref expr, _) | ast::ExprKind::Unary(_, ref expr) => is_simple_arg(expr), ast::ExprKind::Index(ref lhs, ref rhs) | ast::ExprKind::Repeat(ref lhs, ref rhs) => { is_simple_arg(lhs) && is_simple_arg(rhs) } _ => false, } } fn is_every_args_simple(lists: &[&T]) -> bool { lists .iter() .all(|arg| arg.to_expr().map_or(false, is_simple_arg)) } /// In case special-case style is required, returns an offset from which we start horizontal layout. fn maybe_get_args_offset(callee_str: &str, args: &[&T]) -> Option<(bool, usize)> { if let Some(&(_, num_args_before)) = SPECIAL_MACRO_WHITELIST .iter() .find(|&&(s, _)| s == callee_str) { let all_simple = args.len() > num_args_before && is_every_args_simple(args); Some((all_simple, num_args_before)) } else { None } } /// Returns a shape for the last argument which is going to be overflowed. fn last_arg_shape( lists: &[&T], items: &[ListItem], shape: Shape, args_max_width: usize, ) -> Option where T: Rewrite + Spanned + ToExpr, { let is_nested_call = lists .iter() .next() .and_then(|item| item.to_expr()) .map_or(false, is_nested_call); if items.len() == 1 && !is_nested_call { return Some(shape); } let offset = items.iter().rev().skip(1).fold(0, |acc, i| { // 2 = ", " acc + 2 + i.inner_as_ref().len() }); Shape { width: min(args_max_width, shape.width), ..shape }.offset_left(offset) } fn rewrite_last_arg_with_overflow<'a, T>( context: &RewriteContext, args: &[&T], last_item: &mut ListItem, shape: Shape, ) -> Option where T: Rewrite + Spanned + ToExpr + 'a, { let last_arg = args[args.len() - 1]; let rewrite = if let Some(expr) = last_arg.to_expr() { match expr.node { // When overflowing the closure which consists of a single control flow expression, // force to use block if its condition uses multi line. ast::ExprKind::Closure(..) => { // If the argument consists of multiple closures, we do not overflow // the last closure. if closures::args_have_many_closure(args) { None } else { closures::rewrite_last_closure(context, expr, shape) } } _ => expr.rewrite(context, shape), } } else { last_arg.rewrite(context, shape) }; if let Some(rewrite) = rewrite { let rewrite_first_line = Some(rewrite[..first_line_width(&rewrite)].to_owned()); last_item.item = rewrite_first_line; Some(rewrite) } else { None } } fn can_be_overflowed<'a, T>(context: &RewriteContext, args: &[&T]) -> bool where T: Rewrite + Spanned + ToExpr + 'a, { args.last() .map_or(false, |x| x.can_be_overflowed(context, args.len())) } pub fn can_be_overflowed_expr(context: &RewriteContext, expr: &ast::Expr, args_len: usize) -> bool { match expr.node { ast::ExprKind::Match(..) => { (context.use_block_indent() && args_len == 1) || (context.config.indent_style() == IndentStyle::Visual && args_len > 1) } ast::ExprKind::If(..) | ast::ExprKind::IfLet(..) | ast::ExprKind::ForLoop(..) | ast::ExprKind::Loop(..) | ast::ExprKind::While(..) | ast::ExprKind::WhileLet(..) => { context.config.combine_control_expr() && context.use_block_indent() && args_len == 1 } ast::ExprKind::Block(..) | ast::ExprKind::Closure(..) => { context.use_block_indent() || context.config.indent_style() == IndentStyle::Visual && args_len > 1 } ast::ExprKind::Array(..) | ast::ExprKind::Call(..) | ast::ExprKind::Mac(..) | ast::ExprKind::MethodCall(..) | ast::ExprKind::Struct(..) | ast::ExprKind::Tup(..) => context.use_block_indent() && args_len == 1, ast::ExprKind::AddrOf(_, ref expr) | ast::ExprKind::Box(ref expr) | ast::ExprKind::Try(ref expr) | ast::ExprKind::Unary(_, ref expr) | ast::ExprKind::Cast(ref expr, _) => can_be_overflowed_expr(context, expr, args_len), _ => false, } } fn is_nested_call(expr: &ast::Expr) -> bool { match expr.node { ast::ExprKind::Call(..) | ast::ExprKind::Mac(..) => true, ast::ExprKind::AddrOf(_, ref expr) | ast::ExprKind::Box(ref expr) | ast::ExprKind::Try(ref expr) | ast::ExprKind::Unary(_, ref expr) | ast::ExprKind::Cast(ref expr, _) => is_nested_call(expr), _ => false, } } pub fn wrap_args_with_parens( context: &RewriteContext, args_str: &str, is_extendable: bool, shape: Shape, nested_shape: Shape, ) -> String { let paren_overhead = paren_overhead(context); let fits_one_line = args_str.len() + paren_overhead <= shape.width; let extend_width = if args_str.is_empty() { paren_overhead } else { paren_overhead / 2 }; if !context.use_block_indent() || (context.inside_macro && !args_str.contains('\n') && fits_one_line) || (is_extendable && extend_width <= shape.width) { let mut result = String::with_capacity(args_str.len() + 4); if context.config.spaces_within_parens_and_brackets() && !args_str.is_empty() { result.push_str("( "); result.push_str(args_str); result.push_str(" )"); } else { result.push_str("("); result.push_str(args_str); result.push_str(")"); } result } else { let nested_indent_str = nested_shape.indent.to_string_with_newline(context.config); let indent_str = shape.block().indent.to_string_with_newline(context.config); let mut result = String::with_capacity(args_str.len() + 2 + indent_str.len() + nested_indent_str.len()); result.push_str("("); if !args_str.is_empty() { result.push_str(&nested_indent_str); result.push_str(args_str); } result.push_str(&indent_str); result.push_str(")"); result } } /// Return true if a function call or a method call represented by the given span ends with a /// trailing comma. This function is used when rewriting macro, as adding or removing a trailing /// comma from macro can potentially break the code. fn span_ends_with_comma(context: &RewriteContext, span: Span) -> bool { let mut result: bool = Default::default(); let mut prev_char: char = Default::default(); for (kind, c) in CharClasses::new(context.snippet(span).chars()) { match c { _ if kind.is_comment() || c.is_whitespace() => continue, ')' | '}' => result = result && prev_char != c, ',' => result = true, _ => result = false, } prev_char = c; } result } fn rewrite_paren( context: &RewriteContext, mut subexpr: &ast::Expr, shape: Shape, mut span: Span, ) -> Option { debug!("rewrite_paren, shape: {:?}", shape); // Extract comments within parens. let mut pre_comment; let mut post_comment; loop { // 1 = "(" or ")" let pre_span = mk_sp(span.lo() + BytePos(1), subexpr.span.lo()); let post_span = mk_sp(subexpr.span.hi(), span.hi() - BytePos(1)); pre_comment = rewrite_missing_comment(pre_span, shape, context)?; post_comment = rewrite_missing_comment(post_span, shape, context)?; // Remove nested parens if there are no comments. if let ast::ExprKind::Paren(ref subsubexpr) = subexpr.node { if pre_comment.is_empty() && post_comment.is_empty() { span = subexpr.span; subexpr = subsubexpr; continue; } } break; } let total_paren_overhead = paren_overhead(context); let paren_overhead = total_paren_overhead / 2; let sub_shape = shape .offset_left(paren_overhead) .and_then(|s| s.sub_width(paren_overhead))?; let paren_wrapper = |s: &str| { if context.config.spaces_within_parens_and_brackets() && !s.is_empty() { format!("( {}{}{} )", pre_comment, s, post_comment) } else { format!("({}{}{})", pre_comment, s, post_comment) } }; let subexpr_str = subexpr.rewrite(context, sub_shape)?; debug!("rewrite_paren, subexpr_str: `{:?}`", subexpr_str); if subexpr_str.contains('\n') || first_line_width(&subexpr_str) + total_paren_overhead <= shape.width { Some(paren_wrapper(&subexpr_str)) } else { None } } fn rewrite_index( expr: &ast::Expr, index: &ast::Expr, context: &RewriteContext, shape: Shape, ) -> Option { let expr_str = expr.rewrite(context, shape)?; let (lbr, rbr) = if context.config.spaces_within_parens_and_brackets() { ("[ ", " ]") } else { ("[", "]") }; let offset = last_line_width(&expr_str) + lbr.len(); let rhs_overhead = shape.rhs_overhead(context.config); let index_shape = if expr_str.contains('\n') { Shape::legacy(context.config.max_width(), shape.indent) .offset_left(offset) .and_then(|shape| shape.sub_width(rbr.len() + rhs_overhead)) } else { shape.visual_indent(offset).sub_width(offset + rbr.len()) }; let orig_index_rw = index_shape.and_then(|s| index.rewrite(context, s)); // Return if index fits in a single line. match orig_index_rw { Some(ref index_str) if !index_str.contains('\n') => { return Some(format!("{}{}{}{}", expr_str, lbr, index_str, rbr)); } _ => (), } // Try putting index on the next line and see if it fits in a single line. let indent = shape.indent.block_indent(context.config); let index_shape = Shape::indented(indent, context.config).offset_left(lbr.len())?; let index_shape = index_shape.sub_width(rbr.len() + rhs_overhead)?; let new_index_rw = index.rewrite(context, index_shape); match (orig_index_rw, new_index_rw) { (_, Some(ref new_index_str)) if !new_index_str.contains('\n') => Some(format!( "{}{}{}{}{}", expr_str, indent.to_string_with_newline(context.config), lbr, new_index_str, rbr )), (None, Some(ref new_index_str)) => Some(format!( "{}{}{}{}{}", expr_str, indent.to_string_with_newline(context.config), lbr, new_index_str, rbr )), (Some(ref index_str), _) => Some(format!("{}{}{}{}", expr_str, lbr, index_str, rbr)), _ => None, } } fn struct_lit_can_be_aligned(fields: &[ast::Field], base: &Option<&ast::Expr>) -> bool { if base.is_some() { return false; } fields.iter().all(|field| !field.is_shorthand) } fn rewrite_struct_lit<'a>( context: &RewriteContext, path: &ast::Path, fields: &'a [ast::Field], base: Option<&'a ast::Expr>, span: Span, shape: Shape, ) -> Option { debug!("rewrite_struct_lit: shape {:?}", shape); enum StructLitField<'a> { Regular(&'a ast::Field), Base(&'a ast::Expr), } // 2 = " {".len() let path_shape = shape.sub_width(2)?; let path_str = rewrite_path(context, PathContext::Expr, None, path, path_shape)?; if fields.is_empty() && base.is_none() { return Some(format!("{} {{}}", path_str)); } // Foo { a: Foo } - indent is +3, width is -5. let (h_shape, v_shape) = struct_lit_shape(shape, context, path_str.len() + 3, 2)?; let one_line_width = h_shape.map_or(0, |shape| shape.width); let body_lo = context.snippet_provider.span_after(span, "{"); let fields_str = if struct_lit_can_be_aligned(fields, &base) && context.config.struct_field_align_threshold() > 0 { rewrite_with_alignment( fields, context, shape, mk_sp(body_lo, span.hi()), one_line_width, )? } else { let field_iter = fields .into_iter() .map(StructLitField::Regular) .chain(base.into_iter().map(StructLitField::Base)); let span_lo = |item: &StructLitField| match *item { StructLitField::Regular(field) => field.span().lo(), StructLitField::Base(expr) => { let last_field_hi = fields.last().map_or(span.lo(), |field| field.span.hi()); let snippet = context.snippet(mk_sp(last_field_hi, expr.span.lo())); let pos = snippet.find_uncommented("..").unwrap(); last_field_hi + BytePos(pos as u32) } }; let span_hi = |item: &StructLitField| match *item { StructLitField::Regular(field) => field.span().hi(), StructLitField::Base(expr) => expr.span.hi(), }; let rewrite = |item: &StructLitField| match *item { StructLitField::Regular(field) => { // The 1 taken from the v_budget is for the comma. rewrite_field(context, field, v_shape.sub_width(1)?, 0) } StructLitField::Base(expr) => { // 2 = .. expr.rewrite(context, v_shape.offset_left(2)?) .map(|s| format!("..{}", s)) } }; let items = itemize_list( context.snippet_provider, field_iter, "}", ",", span_lo, span_hi, rewrite, body_lo, span.hi(), false, ); let item_vec = items.collect::>(); let tactic = struct_lit_tactic(h_shape, context, &item_vec); let nested_shape = shape_for_tactic(tactic, h_shape, v_shape); let ends_with_comma = span_ends_with_comma(context, span); let force_no_trailing_comma = if context.inside_macro && !ends_with_comma { true } else { false }; let fmt = struct_lit_formatting( nested_shape, tactic, context, force_no_trailing_comma || base.is_some(), ); write_list(&item_vec, &fmt)? }; let fields_str = wrap_struct_field(context, &fields_str, shape, v_shape, one_line_width); Some(format!("{} {{{}}}", path_str, fields_str)) // FIXME if context.config.indent_style() == Visual, but we run out // of space, we should fall back to BlockIndent. } pub fn wrap_struct_field( context: &RewriteContext, fields_str: &str, shape: Shape, nested_shape: Shape, one_line_width: usize, ) -> String { if context.config.indent_style() == IndentStyle::Block && (fields_str.contains('\n') || !context.config.struct_lit_single_line() || fields_str.len() > one_line_width) { format!( "{}{}{}", nested_shape.indent.to_string_with_newline(context.config), fields_str, shape.indent.to_string_with_newline(context.config) ) } else { // One liner or visual indent. format!(" {} ", fields_str) } } pub fn struct_lit_field_separator(config: &Config) -> &str { colon_spaces(config.space_before_colon(), config.space_after_colon()) } pub fn rewrite_field( context: &RewriteContext, field: &ast::Field, shape: Shape, prefix_max_width: usize, ) -> Option { if contains_skip(&field.attrs) { return Some(context.snippet(field.span()).to_owned()); } let mut attrs_str = field.attrs.rewrite(context, shape)?; if !attrs_str.is_empty() { attrs_str.push_str(&shape.indent.to_string_with_newline(context.config)); }; let name = field.ident.node.to_string(); if field.is_shorthand { Some(attrs_str + &name) } else { let mut separator = String::from(struct_lit_field_separator(context.config)); for _ in 0..prefix_max_width.checked_sub(name.len()).unwrap_or(0) { separator.push(' '); } let overhead = name.len() + separator.len(); let expr_shape = shape.offset_left(overhead)?; let expr = field.expr.rewrite(context, expr_shape); match expr { Some(ref e) if e.as_str() == name && context.config.use_field_init_shorthand() => { Some(attrs_str + &name) } Some(e) => Some(format!("{}{}{}{}", attrs_str, name, separator, e)), None => { let expr_offset = shape.indent.block_indent(context.config); let expr = field .expr .rewrite(context, Shape::indented(expr_offset, context.config)); expr.map(|s| { format!( "{}{}:\n{}{}", attrs_str, name, expr_offset.to_string(context.config), s ) }) } } } } fn shape_from_indent_style( context: &RewriteContext, shape: Shape, overhead: usize, offset: usize, ) -> Option { if context.use_block_indent() { // 1 = "," shape .block() .block_indent(context.config.tab_spaces()) .with_max_width(context.config) .sub_width(1) } else { shape.visual_indent(offset).sub_width(overhead) } } fn rewrite_tuple_in_visual_indent_style<'a, T>( context: &RewriteContext, items: &[&T], span: Span, shape: Shape, ) -> Option where T: Rewrite + Spanned + ToExpr + 'a, { let mut items = items.iter(); // In case of length 1, need a trailing comma debug!("rewrite_tuple_in_visual_indent_style {:?}", shape); if items.len() == 1 { // 3 = "(" + ",)" let nested_shape = shape.sub_width(3)?.visual_indent(1); return items .next() .unwrap() .rewrite(context, nested_shape) .map(|s| { if context.config.spaces_within_parens_and_brackets() { format!("( {}, )", s) } else { format!("({},)", s) } }); } let list_lo = context.snippet_provider.span_after(span, "("); let nested_shape = shape.sub_width(2)?.visual_indent(1); let items = itemize_list( context.snippet_provider, items, ")", ",", |item| item.span().lo(), |item| item.span().hi(), |item| item.rewrite(context, nested_shape), list_lo, span.hi() - BytePos(1), false, ); let item_vec: Vec<_> = items.collect(); let tactic = definitive_tactic( &item_vec, ListTactic::HorizontalVertical, Separator::Comma, nested_shape.width, ); let fmt = ListFormatting { tactic, separator: ",", trailing_separator: SeparatorTactic::Never, separator_place: SeparatorPlace::Back, shape, ends_with_newline: false, preserve_newline: false, config: context.config, }; let list_str = write_list(&item_vec, &fmt)?; if context.config.spaces_within_parens_and_brackets() && !list_str.is_empty() { Some(format!("( {} )", list_str)) } else { Some(format!("({})", list_str)) } } pub fn rewrite_tuple<'a, T>( context: &RewriteContext, items: &[&T], span: Span, shape: Shape, ) -> Option where T: Rewrite + Spanned + ToExpr + 'a, { debug!("rewrite_tuple {:?}", shape); if context.use_block_indent() { // We use the same rule as function calls for rewriting tuples. let force_trailing_comma = if context.inside_macro { span_ends_with_comma(context, span) } else { items.len() == 1 }; rewrite_call_inner( context, &String::new(), items, span, shape, context.config.width_heuristics().fn_call_width, force_trailing_comma, ) } else { rewrite_tuple_in_visual_indent_style(context, items, span, shape) } } pub fn rewrite_unary_prefix( context: &RewriteContext, prefix: &str, rewrite: &R, shape: Shape, ) -> Option { rewrite .rewrite(context, shape.offset_left(prefix.len())?) .map(|r| format!("{}{}", prefix, r)) } // FIXME: this is probably not correct for multi-line Rewrites. we should // subtract suffix.len() from the last line budget, not the first! pub fn rewrite_unary_suffix( context: &RewriteContext, suffix: &str, rewrite: &R, shape: Shape, ) -> Option { rewrite .rewrite(context, shape.sub_width(suffix.len())?) .map(|mut r| { r.push_str(suffix); r }) } fn rewrite_unary_op( context: &RewriteContext, op: &ast::UnOp, expr: &ast::Expr, shape: Shape, ) -> Option { // For some reason, an UnOp is not spanned like BinOp! let operator_str = match *op { ast::UnOp::Deref => "*", ast::UnOp::Not => "!", ast::UnOp::Neg => "-", }; rewrite_unary_prefix(context, operator_str, expr, shape) } fn rewrite_assignment( context: &RewriteContext, lhs: &ast::Expr, rhs: &ast::Expr, op: Option<&ast::BinOp>, shape: Shape, ) -> Option { let operator_str = match op { Some(op) => context.snippet(op.span), None => "=", }; // 1 = space between lhs and operator. let lhs_shape = shape.sub_width(operator_str.len() + 1)?; let lhs_str = format!("{} {}", lhs.rewrite(context, lhs_shape)?, operator_str); rewrite_assign_rhs(context, lhs_str, rhs, shape) } // The left hand side must contain everything up to, and including, the // assignment operator. pub fn rewrite_assign_rhs, R: Rewrite>( context: &RewriteContext, lhs: S, ex: &R, shape: Shape, ) -> Option { let lhs = lhs.into(); let last_line_width = last_line_width(&lhs) .checked_sub(if lhs.contains('\n') { shape.indent.width() } else { 0 }) .unwrap_or(0); // 1 = space between operator and rhs. let orig_shape = shape.offset_left(last_line_width + 1).unwrap_or(Shape { width: 0, offset: shape.offset + last_line_width + 1, ..shape }); let rhs = choose_rhs(context, ex, orig_shape, ex.rewrite(context, orig_shape))?; Some(lhs + &rhs) } pub fn choose_rhs( context: &RewriteContext, expr: &R, shape: Shape, orig_rhs: Option, ) -> Option { match orig_rhs { Some(ref new_str) if !new_str.contains('\n') && new_str.len() <= shape.width => { Some(format!(" {}", new_str)) } _ => { // Expression did not fit on the same line as the identifier. // Try splitting the line and see if that works better. let new_shape = Shape::indented(shape.indent.block_indent(context.config), context.config) .sub_width(shape.rhs_overhead(context.config))?; let new_rhs = expr.rewrite(context, new_shape); let new_indent_str = &new_shape.indent.to_string_with_newline(context.config); match (orig_rhs, new_rhs) { (Some(ref orig_rhs), Some(ref new_rhs)) if wrap_str(new_rhs.clone(), context.config.max_width(), new_shape) .is_none() => { Some(format!(" {}", orig_rhs)) } (Some(ref orig_rhs), Some(ref new_rhs)) if prefer_next_line(orig_rhs, new_rhs) => { Some(format!("{}{}", new_indent_str, new_rhs)) } (None, Some(ref new_rhs)) => Some(format!("{}{}", new_indent_str, new_rhs)), (None, None) => None, (Some(ref orig_rhs), _) => Some(format!(" {}", orig_rhs)), } } } } fn prefer_next_line(orig_rhs: &str, next_line_rhs: &str) -> bool { !next_line_rhs.contains('\n') || count_newlines(orig_rhs) > count_newlines(next_line_rhs) + 1 } fn rewrite_expr_addrof( context: &RewriteContext, mutability: ast::Mutability, expr: &ast::Expr, shape: Shape, ) -> Option { let operator_str = match mutability { ast::Mutability::Immutable => "&", ast::Mutability::Mutable => "&mut ", }; rewrite_unary_prefix(context, operator_str, expr, shape) } pub trait ToExpr { fn to_expr(&self) -> Option<&ast::Expr>; fn can_be_overflowed(&self, context: &RewriteContext, len: usize) -> bool; } impl ToExpr for ast::Expr { fn to_expr(&self) -> Option<&ast::Expr> { Some(self) } fn can_be_overflowed(&self, context: &RewriteContext, len: usize) -> bool { can_be_overflowed_expr(context, self, len) } } impl ToExpr for ast::Ty { fn to_expr(&self) -> Option<&ast::Expr> { None } fn can_be_overflowed(&self, context: &RewriteContext, len: usize) -> bool { can_be_overflowed_type(context, self, len) } } impl<'a> ToExpr for TuplePatField<'a> { fn to_expr(&self) -> Option<&ast::Expr> { None } fn can_be_overflowed(&self, context: &RewriteContext, len: usize) -> bool { can_be_overflowed_pat(context, self, len) } } impl<'a> ToExpr for ast::StructField { fn to_expr(&self) -> Option<&ast::Expr> { None } fn can_be_overflowed(&self, _: &RewriteContext, _: usize) -> bool { false } } impl<'a> ToExpr for MacroArg { fn to_expr(&self) -> Option<&ast::Expr> { match *self { MacroArg::Expr(ref expr) => Some(expr), _ => None, } } fn can_be_overflowed(&self, context: &RewriteContext, len: usize) -> bool { match *self { MacroArg::Expr(ref expr) => can_be_overflowed_expr(context, expr, len), MacroArg::Ty(ref ty) => can_be_overflowed_type(context, ty, len), MacroArg::Pat(..) => false, } } }