//! This module contains functions for retrieve the original AST from lowered //! `hir`. #![deny(missing_docs_in_private_items)] use rustc::{hir, ty}; use rustc::lint::LateContext; use syntax::ast; use utils::{is_expn_of, match_def_path, match_qpath, opt_def_id, paths, resolve_node}; /// Convert a hir binary operator to the corresponding `ast` type. pub fn binop(op: hir::BinOp_) -> ast::BinOpKind { match op { hir::BiEq => ast::BinOpKind::Eq, hir::BiGe => ast::BinOpKind::Ge, hir::BiGt => ast::BinOpKind::Gt, hir::BiLe => ast::BinOpKind::Le, hir::BiLt => ast::BinOpKind::Lt, hir::BiNe => ast::BinOpKind::Ne, hir::BiOr => ast::BinOpKind::Or, hir::BiAdd => ast::BinOpKind::Add, hir::BiAnd => ast::BinOpKind::And, hir::BiBitAnd => ast::BinOpKind::BitAnd, hir::BiBitOr => ast::BinOpKind::BitOr, hir::BiBitXor => ast::BinOpKind::BitXor, hir::BiDiv => ast::BinOpKind::Div, hir::BiMul => ast::BinOpKind::Mul, hir::BiRem => ast::BinOpKind::Rem, hir::BiShl => ast::BinOpKind::Shl, hir::BiShr => ast::BinOpKind::Shr, hir::BiSub => ast::BinOpKind::Sub, } } /// Represent a range akin to `ast::ExprKind::Range`. #[derive(Debug, Copy, Clone)] pub struct Range<'a> { /// The lower bound of the range, or `None` for ranges such as `..X`. pub start: Option<&'a hir::Expr>, /// The upper bound of the range, or `None` for ranges such as `X..`. pub end: Option<&'a hir::Expr>, /// Whether the interval is open or closed. pub limits: ast::RangeLimits, } /// Higher a `hir` range to something similar to `ast::ExprKind::Range`. pub fn range<'a, 'b, 'tcx>(cx: &LateContext<'a, 'tcx>, expr: &'b hir::Expr) -> Option> { let def_path = match cx.tables.expr_ty(expr).sty { ty::TyAdt(def, _) => cx.tcx.def_path(def.did), _ => return None, }; // sanity checks for std::ops::RangeXXXX if def_path.data.len() != 3 { return None; } if def_path.data.get(0)?.data.as_interned_str() != "ops" { return None; } if def_path.data.get(1)?.data.as_interned_str() != "range" { return None; } let type_name = def_path.data.get(2)?.data.as_interned_str(); let range_types = [ "RangeFrom", "RangeFull", "RangeInclusive", "Range", "RangeTo", "RangeToInclusive", ]; if !range_types.contains(&&*type_name.as_str()) { return None; } /// Find the field named `name` in the field. Always return `Some` for /// convenience. fn get_field<'a>(name: &str, fields: &'a [hir::Field]) -> Option<&'a hir::Expr> { let expr = &fields.iter().find(|field| field.name.node == name)?.expr; Some(expr) } // The range syntax is expanded to literal paths starting with `core` or `std` // depending on // `#[no_std]`. Testing both instead of resolving the paths. match expr.node { hir::ExprPath(ref path) => { if match_qpath(path, &paths::RANGE_FULL_STD) || match_qpath(path, &paths::RANGE_FULL) { Some(Range { start: None, end: None, limits: ast::RangeLimits::HalfOpen, }) } else { None } }, hir::ExprCall(ref path, ref args) => if let hir::ExprPath(ref path) = path.node { if match_qpath(path, &paths::RANGE_INCLUSIVE_STD_NEW) || match_qpath(path, &paths::RANGE_INCLUSIVE_NEW) { Some(Range { start: Some(&args[0]), end: Some(&args[1]), limits: ast::RangeLimits::Closed, }) } else { None } } else { None }, hir::ExprStruct(ref path, ref fields, None) => if match_qpath(path, &paths::RANGE_FROM_STD) || match_qpath(path, &paths::RANGE_FROM) { Some(Range { start: Some(get_field("start", fields)?), end: None, limits: ast::RangeLimits::HalfOpen, }) } else if match_qpath(path, &paths::RANGE_STD) || match_qpath(path, &paths::RANGE) { Some(Range { start: Some(get_field("start", fields)?), end: Some(get_field("end", fields)?), limits: ast::RangeLimits::HalfOpen, }) } else if match_qpath(path, &paths::RANGE_TO_INCLUSIVE_STD) || match_qpath(path, &paths::RANGE_TO_INCLUSIVE) { Some(Range { start: None, end: Some(get_field("end", fields)?), limits: ast::RangeLimits::Closed, }) } else if match_qpath(path, &paths::RANGE_TO_STD) || match_qpath(path, &paths::RANGE_TO) { Some(Range { start: None, end: Some(get_field("end", fields)?), limits: ast::RangeLimits::HalfOpen, }) } else { None }, _ => None, } } /// Checks if a `let` decl is from a `for` loop desugaring. pub fn is_from_for_desugar(decl: &hir::Decl) -> bool { // This will detect plain for-loops without an actual variable binding: // // ``` // for x in some_vec { // // do stuff // } // ``` if_chain! { if let hir::DeclLocal(ref loc) = decl.node; if let Some(ref expr) = loc.init; if let hir::ExprMatch(_, _, hir::MatchSource::ForLoopDesugar) = expr.node; then { return true; } } // This detects a variable binding in for loop to avoid `let_unit_value` // lint (see issue #1964). // // ``` // for _ in vec![()] { // // anything // } // ``` if_chain! { if let hir::DeclLocal(ref loc) = decl.node; if let hir::LocalSource::ForLoopDesugar = loc.source; then { return true; } } false } /// Recover the essential nodes of a desugared for loop: /// `for pat in arg { body }` becomes `(pat, arg, body)`. pub fn for_loop(expr: &hir::Expr) -> Option<(&hir::Pat, &hir::Expr, &hir::Expr)> { if_chain! { if let hir::ExprMatch(ref iterexpr, ref arms, hir::MatchSource::ForLoopDesugar) = expr.node; if let hir::ExprCall(_, ref iterargs) = iterexpr.node; if iterargs.len() == 1 && arms.len() == 1 && arms[0].guard.is_none(); if let hir::ExprLoop(ref block, _, _) = arms[0].body.node; if block.expr.is_none(); if let [ _, _, ref let_stmt, ref body ] = *block.stmts; if let hir::StmtDecl(ref decl, _) = let_stmt.node; if let hir::DeclLocal(ref decl) = decl.node; if let hir::StmtExpr(ref expr, _) = body.node; then { return Some((&*decl.pat, &iterargs[0], expr)); } } None } /// Represent the pre-expansion arguments of a `vec!` invocation. pub enum VecArgs<'a> { /// `vec![elem; len]` Repeat(&'a hir::Expr, &'a hir::Expr), /// `vec![a, b, c]` Vec(&'a [hir::Expr]), } /// Returns the arguments of the `vec!` macro if this expression was expanded /// from `vec!`. pub fn vec_macro<'e>(cx: &LateContext, expr: &'e hir::Expr) -> Option> { if_chain! { if let hir::ExprCall(ref fun, ref args) = expr.node; if let hir::ExprPath(ref path) = fun.node; if is_expn_of(fun.span, "vec").is_some(); if let Some(fun_def_id) = opt_def_id(resolve_node(cx, path, fun.hir_id)); then { return if match_def_path(cx.tcx, fun_def_id, &paths::VEC_FROM_ELEM) && args.len() == 2 { // `vec![elem; size]` case Some(VecArgs::Repeat(&args[0], &args[1])) } else if match_def_path(cx.tcx, fun_def_id, &paths::SLICE_INTO_VEC) && args.len() == 1 { // `vec![a, b, c]` case if_chain! { if let hir::ExprBox(ref boxed) = args[0].node; if let hir::ExprArray(ref args) = boxed.node; then { return Some(VecArgs::Vec(&*args)); } } None } else { None }; } } None }