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//! This file declares the `ScopeTree` type, which describes
//! the parent links in the region hierarchy.
//!
//! For more information about how MIR-based region-checking works,
//! see the [rustc dev guide].
//!
//! [rustc dev guide]: https://rustc-dev-guide.rust-lang.org/borrow_check.html
use crate::ty::TyCtxt;
use rustc_data_structures::fx::FxIndexMap;
use rustc_data_structures::unord::UnordMap;
use rustc_hir as hir;
use rustc_hir::{HirId, HirIdMap, Node};
use rustc_macros::{HashStable, TyDecodable, TyEncodable};
use rustc_span::{Span, DUMMY_SP};
use tracing::debug;
use std::fmt;
use std::ops::Deref;
/// Represents a statically-describable scope that can be used to
/// bound the lifetime/region for values.
///
/// `Node(node_id)`: Any AST node that has any scope at all has the
/// `Node(node_id)` scope. Other variants represent special cases not
/// immediately derivable from the abstract syntax tree structure.
///
/// `DestructionScope(node_id)` represents the scope of destructors
/// implicitly-attached to `node_id` that run immediately after the
/// expression for `node_id` itself. Not every AST node carries a
/// `DestructionScope`, but those that are `terminating_scopes` do;
/// see discussion with `ScopeTree`.
///
/// `Remainder { block, statement_index }` represents
/// the scope of user code running immediately after the initializer
/// expression for the indexed statement, until the end of the block.
///
/// So: the following code can be broken down into the scopes beneath:
///
/// ```text
/// let a = f().g( 'b: { let x = d(); let y = d(); x.h(y) } ) ;
///
/// +-+ (D12.)
/// +-+ (D11.)
/// +---------+ (R10.)
/// +-+ (D9.)
/// +----------+ (M8.)
/// +----------------------+ (R7.)
/// +-+ (D6.)
/// +----------+ (M5.)
/// +-----------------------------------+ (M4.)
/// +--------------------------------------------------+ (M3.)
/// +--+ (M2.)
/// +-----------------------------------------------------------+ (M1.)
///
/// (M1.): Node scope of the whole `let a = ...;` statement.
/// (M2.): Node scope of the `f()` expression.
/// (M3.): Node scope of the `f().g(..)` expression.
/// (M4.): Node scope of the block labeled `'b:`.
/// (M5.): Node scope of the `let x = d();` statement
/// (D6.): DestructionScope for temporaries created during M5.
/// (R7.): Remainder scope for block `'b:`, stmt 0 (let x = ...).
/// (M8.): Node scope of the `let y = d();` statement.
/// (D9.): DestructionScope for temporaries created during M8.
/// (R10.): Remainder scope for block `'b:`, stmt 1 (let y = ...).
/// (D11.): DestructionScope for temporaries and bindings from block `'b:`.
/// (D12.): DestructionScope for temporaries created during M1 (e.g., f()).
/// ```
///
/// Note that while the above picture shows the destruction scopes
/// as following their corresponding node scopes, in the internal
/// data structures of the compiler the destruction scopes are
/// represented as enclosing parents. This is sound because we use the
/// enclosing parent relationship just to ensure that referenced
/// values live long enough; phrased another way, the starting point
/// of each range is not really the important thing in the above
/// picture, but rather the ending point.
//
// FIXME(pnkfelix): this currently derives `PartialOrd` and `Ord` to
// placate the same deriving in `ty::LateParamRegion`, but we may want to
// actually attach a more meaningful ordering to scopes than the one
// generated via deriving here.
#[derive(Clone, PartialEq, PartialOrd, Eq, Ord, Hash, Copy, TyEncodable, TyDecodable)]
#[derive(HashStable)]
pub struct Scope {
pub id: hir::ItemLocalId,
pub data: ScopeData,
}
impl fmt::Debug for Scope {
fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result {
match self.data {
ScopeData::Node => write!(fmt, "Node({:?})", self.id),
ScopeData::CallSite => write!(fmt, "CallSite({:?})", self.id),
ScopeData::Arguments => write!(fmt, "Arguments({:?})", self.id),
ScopeData::Destruction => write!(fmt, "Destruction({:?})", self.id),
ScopeData::IfThen => write!(fmt, "IfThen({:?})", self.id),
ScopeData::Remainder(fsi) => write!(
fmt,
"Remainder {{ block: {:?}, first_statement_index: {}}}",
self.id,
fsi.as_u32(),
),
}
}
}
#[derive(Clone, PartialEq, PartialOrd, Eq, Ord, Hash, Debug, Copy, TyEncodable, TyDecodable)]
#[derive(HashStable)]
pub enum ScopeData {
Node,
/// Scope of the call-site for a function or closure
/// (outlives the arguments as well as the body).
CallSite,
/// Scope of arguments passed to a function or closure
/// (they outlive its body).
Arguments,
/// Scope of destructors for temporaries of node-id.
Destruction,
/// Scope of the condition and then block of an if expression
/// Used for variables introduced in an if-let expression.
IfThen,
/// Scope following a `let id = expr;` binding in a block.
Remainder(FirstStatementIndex),
}
rustc_index::newtype_index! {
/// Represents a subscope of `block` for a binding that is introduced
/// by `block.stmts[first_statement_index]`. Such subscopes represent
/// a suffix of the block. Note that each subscope does not include
/// the initializer expression, if any, for the statement indexed by
/// `first_statement_index`.
///
/// For example, given `{ let (a, b) = EXPR_1; let c = EXPR_2; ... }`:
///
/// * The subscope with `first_statement_index == 0` is scope of both
/// `a` and `b`; it does not include EXPR_1, but does include
/// everything after that first `let`. (If you want a scope that
/// includes EXPR_1 as well, then do not use `Scope::Remainder`,
/// but instead another `Scope` that encompasses the whole block,
/// e.g., `Scope::Node`.
///
/// * The subscope with `first_statement_index == 1` is scope of `c`,
/// and thus does not include EXPR_2, but covers the `...`.
#[derive(HashStable)]
#[encodable]
#[orderable]
pub struct FirstStatementIndex {}
}
// compilation error if size of `ScopeData` is not the same as a `u32`
rustc_data_structures::static_assert_size!(ScopeData, 4);
impl Scope {
/// Returns an item-local ID associated with this scope.
///
/// N.B., likely to be replaced as API is refined; e.g., pnkfelix
/// anticipates `fn entry_node_id` and `fn each_exit_node_id`.
pub fn item_local_id(&self) -> hir::ItemLocalId {
self.id
}
pub fn hir_id(&self, scope_tree: &ScopeTree) -> Option<HirId> {
scope_tree
.root_body
.map(|hir_id| HirId { owner: hir_id.owner, local_id: self.item_local_id() })
}
/// Returns the span of this `Scope`. Note that in general the
/// returned span may not correspond to the span of any `NodeId` in
/// the AST.
pub fn span(&self, tcx: TyCtxt<'_>, scope_tree: &ScopeTree) -> Span {
let Some(hir_id) = self.hir_id(scope_tree) else {
return DUMMY_SP;
};
let span = tcx.hir().span(hir_id);
if let ScopeData::Remainder(first_statement_index) = self.data {
if let Node::Block(blk) = tcx.hir_node(hir_id) {
// Want span for scope starting after the
// indexed statement and ending at end of
// `blk`; reuse span of `blk` and shift `lo`
// forward to end of indexed statement.
//
// (This is the special case alluded to in the
// doc-comment for this method)
let stmt_span = blk.stmts[first_statement_index.index()].span;
// To avoid issues with macro-generated spans, the span
// of the statement must be nested in that of the block.
if span.lo() <= stmt_span.lo() && stmt_span.lo() <= span.hi() {
return span.with_lo(stmt_span.lo());
}
}
}
span
}
}
pub type ScopeDepth = u32;
/// The region scope tree encodes information about region relationships.
#[derive(Default, Debug, HashStable)]
pub struct ScopeTree {
/// If not empty, this body is the root of this region hierarchy.
pub root_body: Option<HirId>,
/// Maps from a scope ID to the enclosing scope id;
/// this is usually corresponding to the lexical nesting, though
/// in the case of closures the parent scope is the innermost
/// conditional expression or repeating block. (Note that the
/// enclosing scope ID for the block associated with a closure is
/// the closure itself.)
pub parent_map: FxIndexMap<Scope, (Scope, ScopeDepth)>,
/// Maps from a variable or binding ID to the block in which that
/// variable is declared.
var_map: FxIndexMap<hir::ItemLocalId, Scope>,
/// Identifies expressions which, if captured into a temporary, ought to
/// have a temporary whose lifetime extends to the end of the enclosing *block*,
/// and not the enclosing *statement*. Expressions that are not present in this
/// table are not rvalue candidates. The set of rvalue candidates is computed
/// during type check based on a traversal of the AST.
pub rvalue_candidates: HirIdMap<RvalueCandidateType>,
/// If there are any `yield` nested within a scope, this map
/// stores the `Span` of the last one and its index in the
/// postorder of the Visitor traversal on the HIR.
///
/// HIR Visitor postorder indexes might seem like a peculiar
/// thing to care about. but it turns out that HIR bindings
/// and the temporary results of HIR expressions are never
/// storage-live at the end of HIR nodes with postorder indexes
/// lower than theirs, and therefore don't need to be suspended
/// at yield-points at these indexes.
///
/// For an example, suppose we have some code such as:
/// ```rust,ignore (example)
/// foo(f(), yield y, bar(g()))
/// ```
///
/// With the HIR tree (calls numbered for expository purposes)
///
/// ```text
/// Call#0(foo, [Call#1(f), Yield(y), Call#2(bar, Call#3(g))])
/// ```
///
/// Obviously, the result of `f()` was created before the yield
/// (and therefore needs to be kept valid over the yield) while
/// the result of `g()` occurs after the yield (and therefore
/// doesn't). If we want to infer that, we can look at the
/// postorder traversal:
/// ```plain,ignore
/// `foo` `f` Call#1 `y` Yield `bar` `g` Call#3 Call#2 Call#0
/// ```
///
/// In which we can easily see that `Call#1` occurs before the yield,
/// and `Call#3` after it.
///
/// To see that this method works, consider:
///
/// Let `D` be our binding/temporary and `U` be our other HIR node, with
/// `HIR-postorder(U) < HIR-postorder(D)`. Suppose, as in our example,
/// U is the yield and D is one of the calls.
/// Let's show that `D` is storage-dead at `U`.
///
/// Remember that storage-live/storage-dead refers to the state of
/// the *storage*, and does not consider moves/drop flags.
///
/// Then:
///
/// 1. From the ordering guarantee of HIR visitors (see
/// `rustc_hir::intravisit`), `D` does not dominate `U`.
///
/// 2. Therefore, `D` is *potentially* storage-dead at `U` (because
/// we might visit `U` without ever getting to `D`).
///
/// 3. However, we guarantee that at each HIR point, each
/// binding/temporary is always either always storage-live
/// or always storage-dead. This is what is being guaranteed
/// by `terminating_scopes` including all blocks where the
/// count of executions is not guaranteed.
///
/// 4. By `2.` and `3.`, `D` is *statically* storage-dead at `U`,
/// QED.
///
/// This property ought to not on (3) in an essential way -- it
/// is probably still correct even if we have "unrestricted" terminating
/// scopes. However, why use the complicated proof when a simple one
/// works?
///
/// A subtle thing: `box` expressions, such as `box (&x, yield 2, &y)`. It
/// might seem that a `box` expression creates a `Box<T>` temporary
/// when it *starts* executing, at `HIR-preorder(BOX-EXPR)`. That might
/// be true in the MIR desugaring, but it is not important in the semantics.
///
/// The reason is that semantically, until the `box` expression returns,
/// the values are still owned by their containing expressions. So
/// we'll see that `&x`.
pub yield_in_scope: UnordMap<Scope, Vec<YieldData>>,
}
/// Identifies the reason that a given expression is an rvalue candidate
/// (see the `rvalue_candidates` field for more information what rvalue
/// candidates in general). In constants, the `lifetime` field is None
/// to indicate that certain expressions escape into 'static and
/// should have no local cleanup scope.
#[derive(Debug, Copy, Clone, HashStable)]
pub enum RvalueCandidateType {
Borrow { target: hir::ItemLocalId, lifetime: Option<Scope> },
Pattern { target: hir::ItemLocalId, lifetime: Option<Scope> },
}
#[derive(Debug, Copy, Clone, HashStable)]
pub struct YieldData {
/// The `Span` of the yield.
pub span: Span,
/// The number of expressions and patterns appearing before the `yield` in the body, plus one.
pub expr_and_pat_count: usize,
pub source: hir::YieldSource,
}
impl ScopeTree {
pub fn record_scope_parent(&mut self, child: Scope, parent: Option<(Scope, ScopeDepth)>) {
debug!("{:?}.parent = {:?}", child, parent);
if let Some(p) = parent {
let prev = self.parent_map.insert(child, p);
assert!(prev.is_none());
}
}
pub fn record_var_scope(&mut self, var: hir::ItemLocalId, lifetime: Scope) {
debug!("record_var_scope(sub={:?}, sup={:?})", var, lifetime);
assert!(var != lifetime.item_local_id());
self.var_map.insert(var, lifetime);
}
pub fn record_rvalue_candidate(&mut self, var: HirId, candidate_type: RvalueCandidateType) {
debug!("record_rvalue_candidate(var={var:?}, type={candidate_type:?})");
match &candidate_type {
RvalueCandidateType::Borrow { lifetime: Some(lifetime), .. }
| RvalueCandidateType::Pattern { lifetime: Some(lifetime), .. } => {
assert!(var.local_id != lifetime.item_local_id())
}
_ => {}
}
self.rvalue_candidates.insert(var, candidate_type);
}
/// Returns the narrowest scope that encloses `id`, if any.
pub fn opt_encl_scope(&self, id: Scope) -> Option<Scope> {
self.parent_map.get(&id).cloned().map(|(p, _)| p)
}
/// Returns the lifetime of the local variable `var_id`, if any.
pub fn var_scope(&self, var_id: hir::ItemLocalId) -> Option<Scope> {
self.var_map.get(&var_id).cloned()
}
/// Returns `true` if `subscope` is equal to or is lexically nested inside `superscope`, and
/// `false` otherwise.
///
/// Used by clippy.
pub fn is_subscope_of(&self, subscope: Scope, superscope: Scope) -> bool {
let mut s = subscope;
debug!("is_subscope_of({:?}, {:?})", subscope, superscope);
while superscope != s {
match self.opt_encl_scope(s) {
None => {
debug!("is_subscope_of({:?}, {:?}, s={:?})=false", subscope, superscope, s);
return false;
}
Some(scope) => s = scope,
}
}
debug!("is_subscope_of({:?}, {:?})=true", subscope, superscope);
true
}
/// Checks whether the given scope contains a `yield`. If so,
/// returns `Some(YieldData)`. If not, returns `None`.
pub fn yield_in_scope(&self, scope: Scope) -> Option<&[YieldData]> {
self.yield_in_scope.get(&scope).map(Deref::deref)
}
}