// 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. //! Formatting of chained expressions, i.e. expressions which are chained by //! dots: struct and enum field access, method calls, and try shorthand (?). //! //! Instead of walking these subexpressions one-by-one, as is our usual strategy //! for expression formatting, we collect maximal sequences of these expressions //! and handle them simultaneously. //! //! Whenever possible, the entire chain is put on a single line. If that fails, //! we put each subexpression on a separate, much like the (default) function //! argument function argument strategy. //! //! Depends on config options: `chain_indent` is the indent to use for //! blocks in the parent/root/base of the chain (and the rest of the chain's //! alignment). //! E.g., `let foo = { aaaa; bbb; ccc }.bar.baz();`, we would layout for the //! following values of `chain_indent`: //! Block: //! //! ```ignore //! let foo = { //! aaaa; //! bbb; //! ccc //! }.bar //! .baz(); //! ``` //! //! Visual: //! //! ```ignore //! let foo = { //! aaaa; //! bbb; //! ccc //! } //! .bar //! .baz(); //! ``` //! //! If the first item in the chain is a block expression, we align the dots with //! the braces. //! Block: //! //! ```ignore //! let a = foo.bar //! .baz() //! .qux //! ``` //! //! Visual: //! //! ```ignore //! let a = foo.bar //! .baz() //! .qux //! ``` use config::IndentStyle; use expr::rewrite_call; use macros::convert_try_mac; use rewrite::{Rewrite, RewriteContext}; use shape::Shape; use spanned::Spanned; use utils::{ first_line_width, last_line_extendable, last_line_width, mk_sp, trimmed_last_line_width, wrap_str, }; use std::borrow::Cow; use std::cmp::min; use syntax::codemap::Span; use syntax::{ast, ptr}; pub fn rewrite_chain(expr: &ast::Expr, context: &RewriteContext, shape: Shape) -> Option { debug!("rewrite_chain {:?}", shape); let chain = Chain::from_ast(expr, context); // If this is just an expression with some `?`s, then format it trivially and // return early. if chain.children.is_empty() { let rewrite = chain.parent.expr.rewrite(context, shape.sub_width(chain.parent.tries)?)?; return Some(format!("{}{}", rewrite, "?".repeat(chain.parent.tries))); } match context.config.indent_style() { IndentStyle::Block => rewrite_chain_block(chain, context, shape), IndentStyle::Visual => rewrite_chain_visual(chain, context, shape), } } // An expression plus trailing `?`s to be formatted together. struct ChainItem { expr: ast::Expr, tries: usize, } struct Chain { parent: ChainItem, // TODO do we need to clone the exprs? children: Vec, } impl Chain { fn from_ast(expr: &ast::Expr, context: &RewriteContext) -> Chain { let mut subexpr_list = make_subexpr_list(expr, context); // Un-parse the expression tree into ChainItems let mut children = vec![]; let mut sub_tries = 0; loop { if subexpr_list.is_empty() { break; } let subexpr = subexpr_list.pop().unwrap(); match subexpr.node { ast::ExprKind::Try(_) => sub_tries += 1, _ => { children.push(ChainItem { expr: subexpr.clone(), tries: sub_tries, }); sub_tries = 0; } } } Chain { parent: children.pop().unwrap(), children: children.into_iter().rev().collect(), } } } fn rewrite_chain_block(mut chain: Chain, context: &RewriteContext, shape: Shape) -> Option { let last = chain.children.pop().unwrap(); // Parent is the first item in the chain, e.g., `foo` in `foo.bar.baz()`. let parent_rewrite = chain.parent.expr .rewrite(context, shape) .map(|parent_rw| parent_rw + &"?".repeat(chain.parent.tries))?; let parent_rewrite_contains_newline = parent_rewrite.contains('\n'); let is_small_parent = shape.offset + parent_rewrite.len() <= context.config.tab_spaces(); let parent_is_block = is_block_expr(context, &chain.parent.expr, &parent_rewrite); // Decide how to layout the rest of the chain. `extend` is true if we can // put the first non-parent item on the same line as the parent. let other_child_shape = if parent_is_block { shape } else { shape.block_indent(context.config.tab_spaces()) }.with_max_width(context.config); let extend = parent_is_block || (is_small_parent && !parent_rewrite_contains_newline && is_continuable(&chain.parent.expr)); let first_child_shape = if extend { let offset = trimmed_last_line_width(&parent_rewrite) + chain.parent.tries; other_child_shape.offset_left(offset)? } else { other_child_shape }; debug!( "child_shapes {:?} {:?}", first_child_shape, other_child_shape ); let mut rewrites: Vec = Vec::with_capacity(chain.children.len()); let mut is_block_like = Vec::with_capacity(chain.children.len()); is_block_like.push(true); for (i, item) in chain.children.iter().enumerate() { let shape = if *is_block_like.last().unwrap() && !(extend && i == 0) { first_child_shape } else { other_child_shape }; let rewrite = rewrite_chain_subexpr(&item.expr, context, shape)?; is_block_like.push(is_block_expr(context, &item.expr, &rewrite)); rewrites.push(format!("{}{}", rewrite, "?".repeat(item.tries))); } // Total of all items excluding the last. let extend_last_subexpr = if is_small_parent { rewrites.len() == 1 && last_line_extendable(&rewrites[0]) } else { rewrites.is_empty() && last_line_extendable(&parent_rewrite) }; let almost_total = if extend_last_subexpr { last_line_width(&parent_rewrite) } else { rewrites.iter().fold(0, |a, b| a + b.len()) + parent_rewrite.len() } + last.tries; let one_line_budget = if rewrites.is_empty() { shape.width } else { min(shape.width, context.config.width_heuristics().chain_width) }; let all_in_one_line = !parent_rewrite_contains_newline && rewrites.iter().all(|s| !s.contains('\n')) && almost_total < one_line_budget; let last_shape = if is_block_like[rewrites.len()] { first_child_shape } else { other_child_shape }.sub_width(shape.rhs_overhead(context.config) + last.tries)?; // Rewrite the last child. The last child of a chain requires special treatment. We need to // know whether 'overflowing' the last child make a better formatting: // // A chain with overflowing the last child: // ``` // parent.child1.child2.last_child( // a, // b, // c, // ) // ``` // // A chain without overflowing the last child (in vertical layout): // ``` // parent // .child1 // .child2 // .last_child(a, b, c) // ``` // // In particular, overflowing is effective when the last child is a method with a multi-lined // block-like argument (e.g. closure): // ``` // parent.child1.child2.last_child(|a, b, c| { // let x = foo(a, b, c); // let y = bar(a, b, c); // // // ... // // result // }) // ``` // `rewrite_last` rewrites the last child on its own line. We use a closure here instead of // directly calling `rewrite_chain_subexpr()` to avoid exponential blowup. let (last_subexpr_str, fits_single_line) = if all_in_one_line || extend_last_subexpr { // First we try to 'overflow' the last child and see if it looks better than using // vertical layout. shape.offset_left(almost_total).map(|shape| { if let Some(rw) = rewrite_chain_subexpr(&last.expr, context, shape) { // We allow overflowing here only if both of the following conditions match: // 1. The entire chain fits in a single line except the last child. // 2. `last_child_str.lines().count() >= 5`. let line_count = rw.lines().count(); let fits_single_line = almost_total + first_line_width(&rw) <= one_line_budget; if fits_single_line && line_count >= 5 { (Some(rw), true) } else { // We could not know whether overflowing is better than using vertical layout, // just by looking at the overflowed rewrite. Now we rewrite the last child // on its own line, and compare two rewrites to choose which is better. match rewrite_chain_subexpr(&last.expr, context, last_shape) { Some(ref new_rw) if !fits_single_line => (Some(new_rw.clone()), false), Some(ref new_rw) if new_rw.lines().count() >= line_count => { (Some(rw), fits_single_line) } new_rw @ Some(..) => (new_rw, false), _ => (Some(rw), fits_single_line), } } } else { (rewrite_chain_subexpr(&last.expr, context, last_shape), false) } })? } else { (rewrite_chain_subexpr(&last.expr, context, last_shape), false) }; rewrites.push(last_subexpr_str?); // We should never look at this, since we only look at the block-ness of the // previous item in the chain. is_block_like.push(false); let connector = if fits_single_line && !parent_rewrite_contains_newline { // Yay, we can put everything on one line. Cow::from("") } else { // Use new lines. if *context.force_one_line_chain.borrow() { return None; } other_child_shape.indent.to_string_with_newline(context.config) }; let first_connector = if is_small_parent || fits_single_line || last_line_extendable(&parent_rewrite) { "" } else { &connector }; let result = if is_small_parent && rewrites.len() > 1 { let second_connector = if fits_single_line || rewrites[1] == "?" || last_line_extendable(&rewrites[0]) { "" } else { &connector }; format!( "{}{}{}{}{}", parent_rewrite, first_connector, rewrites[0], second_connector, join_rewrites(&rewrites[1..], &is_block_like[2..], &connector), ) } else { format!( "{}{}{}", parent_rewrite, first_connector, join_rewrites(&rewrites, &is_block_like[1..], &connector), ) }; let result = format!("{}{}", result, "?".repeat(last.tries)); Some(result) } fn rewrite_chain_visual(mut chain: Chain, context: &RewriteContext, shape: Shape) -> Option { let last = chain.children.pop().unwrap(); // Parent is the first item in the chain, e.g., `foo` in `foo.bar.baz()`. let parent_shape = if is_block_expr(context, &chain.parent.expr, "\n") { shape.visual_indent(0) } else { shape }; let parent_rewrite = chain.parent.expr .rewrite(context, parent_shape) .map(|parent_rw| parent_rw + &"?".repeat(chain.parent.tries))?; let parent_rewrite_contains_newline = parent_rewrite.contains('\n'); let other_child_shape = shape.visual_indent(0).with_max_width(context.config); // Decide how to layout the rest of the chain. `extend` is true if we can // put the first non-parent item on the same line as the parent. let extend = !parent_rewrite_contains_newline && is_continuable(&chain.parent.expr); let first_child_shape = if extend { let overhead = last_line_width(&parent_rewrite); parent_shape.offset_left(overhead)? } else { other_child_shape }; debug!( "child_shapes {:?} {:?}", first_child_shape, other_child_shape ); let mut rewrites: Vec = Vec::with_capacity(chain.children.len()); for (i, item) in chain.children.iter().enumerate() { let shape = if i == 0 { first_child_shape } else { other_child_shape }; let rewrite = rewrite_chain_subexpr(&item.expr, context, shape)?; rewrites.push(format!("{}{}", rewrite, "?".repeat(item.tries))); } // Total of all items excluding the last. let almost_total = rewrites.iter().fold(0, |a, b| a + b.len()) + parent_rewrite.len() + last.tries; let one_line_budget = if rewrites.is_empty() { shape.width } else { min(shape.width, context.config.width_heuristics().chain_width) }; let all_in_one_line = !parent_rewrite_contains_newline && rewrites.iter().all(|s| !s.contains('\n')) && almost_total < one_line_budget; let last_shape = other_child_shape.sub_width(shape.rhs_overhead(context.config) + last.tries)?; // Rewrite the last child. The last child of a chain requires special treatment. We need to // know whether 'overflowing' the last child make a better formatting: // // A chain with overflowing the last child: // ``` // parent.child1.child2.last_child( // a, // b, // c, // ) // ``` // // A chain without overflowing the last child (in vertical layout): // ``` // parent // .child1 // .child2 // .last_child(a, b, c) // ``` // // In particular, overflowing is effective when the last child is a method with a multi-lined // block-like argument (e.g. closure): // ``` // parent.child1.child2.last_child(|a, b, c| { // let x = foo(a, b, c); // let y = bar(a, b, c); // // // ... // // result // }) // ``` let mut last_subexpr_str = None; let mut fits_single_line = false; if all_in_one_line { // First we try to 'overflow' the last child and see if it looks better than using // vertical layout. if let Some(shape) = parent_shape.offset_left(almost_total) { if let Some(rw) = rewrite_chain_subexpr(&last.expr, context, shape) { // We allow overflowing here only if both of the following conditions match: // 1. The entire chain fits in a single line except the last child. // 2. `last_child_str.lines().count() >= 5`. let line_count = rw.lines().count(); let could_fit_single_line = almost_total + first_line_width(&rw) <= one_line_budget; if could_fit_single_line && line_count >= 5 { last_subexpr_str = Some(rw); fits_single_line = true; } else { // We could not know whether overflowing is better than using vertical layout, // just by looking at the overflowed rewrite. Now we rewrite the last child // on its own line, and compare two rewrites to choose which is better. match rewrite_chain_subexpr(&last.expr, context, last_shape) { Some(ref new_rw) if !could_fit_single_line => { last_subexpr_str = Some(new_rw.clone()); } Some(ref new_rw) if new_rw.lines().count() >= line_count => { last_subexpr_str = Some(rw); fits_single_line = could_fit_single_line; } new_rw @ Some(..) => { last_subexpr_str = new_rw; } _ => { last_subexpr_str = Some(rw); fits_single_line = could_fit_single_line; } } } } } } last_subexpr_str = last_subexpr_str.or_else(|| rewrite_chain_subexpr(&last.expr, context, last_shape)); rewrites.push(last_subexpr_str?); let connector = if fits_single_line && !parent_rewrite_contains_newline { // Yay, we can put everything on one line. Cow::from("") } else { // Use new lines. if *context.force_one_line_chain.borrow() { return None; } other_child_shape.indent.to_string_with_newline(context.config) }; let result = format!("{}{}{}", parent_rewrite, join_rewrites_vis(&rewrites, &connector), "?".repeat(last.tries), ); wrap_str(result, context.config.max_width(), shape) } fn join_rewrites(rewrites: &[String], is_block_like: &[bool], connector: &str) -> String { let mut rewrite_iter = rewrites.iter(); let mut result = rewrite_iter.next().unwrap().clone(); for (rewrite, prev_is_block_like) in rewrite_iter.zip(is_block_like.iter()) { if rewrite != "?" && !prev_is_block_like { result.push_str(connector); } result.push_str(&rewrite); } result } fn join_rewrites_vis(rewrites: &[String], connector: &str) -> String { let mut rewrite_iter = rewrites.iter(); let mut result = rewrite_iter.next().unwrap().clone(); for rewrite in rewrite_iter { if rewrite != "?" { result.push_str(connector); } result.push_str(&rewrite); } result } // States whether an expression's last line exclusively consists of closing // parens, braces, and brackets in its idiomatic formatting. fn is_block_expr(context: &RewriteContext, expr: &ast::Expr, repr: &str) -> bool { match expr.node { ast::ExprKind::Mac(..) | ast::ExprKind::Call(..) => { context.use_block_indent() && repr.contains('\n') } ast::ExprKind::Struct(..) | ast::ExprKind::While(..) | ast::ExprKind::WhileLet(..) | ast::ExprKind::If(..) | ast::ExprKind::IfLet(..) | ast::ExprKind::Block(..) | ast::ExprKind::Loop(..) | ast::ExprKind::ForLoop(..) | ast::ExprKind::Match(..) => repr.contains('\n'), ast::ExprKind::Paren(ref expr) | ast::ExprKind::Binary(_, _, ref expr) | ast::ExprKind::Index(_, ref expr) | ast::ExprKind::Unary(_, ref expr) | ast::ExprKind::Closure(_, _, _, _, ref expr, _) => is_block_expr(context, expr, repr), ast::ExprKind::MethodCall(_, ref exprs) => { // TODO maybe should be like Call is_block_expr(context, exprs.last().unwrap(), repr) } _ => false, } } // Returns a Vec of the prefixes of the chain. // E.g., for input `a.b.c` we return [`a.b.c`, `a.b`, 'a'] fn make_subexpr_list(expr: &ast::Expr, context: &RewriteContext) -> Vec { let mut subexpr_list = vec![expr.clone()]; while let Some(subexpr) = pop_expr_chain(subexpr_list.last().unwrap(), context) { subexpr_list.push(subexpr.clone()); } subexpr_list } // Returns the expression's subexpression, if it exists. When the subexpr // is a try! macro, we'll convert it to shorthand when the option is set. fn pop_expr_chain(expr: &ast::Expr, context: &RewriteContext) -> Option { match expr.node { ast::ExprKind::MethodCall(_, ref expressions) => { Some(convert_try(&expressions[0], context)) } ast::ExprKind::Field(ref subexpr, _) | ast::ExprKind::Try(ref subexpr) => { Some(convert_try(subexpr, context)) } _ => None, } } fn convert_try(expr: &ast::Expr, context: &RewriteContext) -> ast::Expr { match expr.node { ast::ExprKind::Mac(ref mac) if context.config.use_try_shorthand() => { if let Some(subexpr) = convert_try_mac(mac, context) { subexpr } else { expr.clone() } } _ => expr.clone(), } } // Rewrite the last element in the chain `expr`. E.g., given `a.b.c` we rewrite // `.c`. fn rewrite_chain_subexpr( expr: &ast::Expr, context: &RewriteContext, shape: Shape, ) -> Option { let rewrite_element = |expr_str: String| { if expr_str.len() <= shape.width { Some(expr_str) } else { None } }; match expr.node { ast::ExprKind::MethodCall(ref segment, ref expressions) => { let types = match segment.args { Some(ref params) => match **params { ast::GenericArgs::AngleBracketed(ref data) => &data.args[..], _ => &[], }, _ => &[], }; rewrite_method_call(segment.ident, types, expressions, expr.span, context, shape) } ast::ExprKind::Field(ref nested, ref field) => { let space = if is_tup_field_access(expr) && is_tup_field_access(nested) { " " } else { "" }; rewrite_element(format!("{}.{}", space, field.name)) } ast::ExprKind::Try(_) => rewrite_element(String::from("?")), _ => unreachable!(), } } fn is_tup_field_access(expr: &ast::Expr) -> bool { match expr.node { ast::ExprKind::Field(_, ref field) => { field.name.to_string().chars().all(|c| c.is_digit(10)) } _ => false, } } // Determines if we can continue formatting a given expression on the same line. fn is_continuable(expr: &ast::Expr) -> bool { match expr.node { ast::ExprKind::Path(..) => true, _ => false, } } fn rewrite_method_call( method_name: ast::Ident, types: &[ast::GenericArg], args: &[ptr::P], span: Span, context: &RewriteContext, shape: Shape, ) -> Option { let (lo, type_str) = if types.is_empty() { (args[0].span.hi(), String::new()) } else { let type_list = types .iter() .map(|ty| ty.rewrite(context, shape)) .collect::>>()?; let type_str = format!("::<{}>", type_list.join(", ")); (types.last().unwrap().span().hi(), type_str) }; let callee_str = format!(".{}{}", method_name, type_str); let span = mk_sp(lo, span.hi()); rewrite_call(context, &callee_str, &args[1..], span, shape) }