compiler/rustc_mir_build/src/build/block.rs - toolchain/rustc - Git at Google

 use crate::build::matches::ArmHasGuard;
 use crate::build::ForGuard::OutsideGuard;
 use crate::build::{BlockAnd, BlockAndExtension, BlockFrame, Builder};
 use rustc_middle::thir::*;
 use rustc_middle::{mir::*, ty};
 use rustc_span::Span;

 impl<'a, 'tcx> Builder<'a, 'tcx> {
     pub(crate) fn ast_block(
         &mut self,
         destination: Place<'tcx>,
         block: BasicBlock,
         ast_block: &Block,
         source_info: SourceInfo,
     ) -> BlockAnd<()> {
         let Block {
             region_scope,
             opt_destruction_scope,
             span,
             ref stmts,
             expr,
             targeted_by_break,
             safety_mode,
         } = *ast_block;
         let expr = expr.map(|expr| &self.thir[expr]);
         self.in_opt_scope(opt_destruction_scope.map(|de| (de, source_info)), move |this| {
             this.in_scope((region_scope, source_info), LintLevel::Inherited, move |this| {
                 if targeted_by_break {
                     this.in_breakable_scope(None, destination, span, |this| {
                         Some(this.ast_block_stmts(
                             destination,
                             block,
                             span,
                             &stmts,
                             expr,
                             safety_mode,
                         ))
                     })
                 } else {
                     this.ast_block_stmts(destination, block, span, &stmts, expr, safety_mode)
                 }
             })
         })
     }

     fn ast_block_stmts(
         &mut self,
         destination: Place<'tcx>,
         mut block: BasicBlock,
         span: Span,
         stmts: &[StmtId],
         expr: Option<&Expr<'tcx>>,
         safety_mode: BlockSafety,
     ) -> BlockAnd<()> {
         let this = self;

         // This convoluted structure is to avoid using recursion as we walk down a list
         // of statements. Basically, the structure we get back is something like:
         //
         //    let x = <init> in {
         //       expr1;
         //       let y = <init> in {
         //           expr2;
         //           expr3;
         //           ...
         //       }
         //    }
         //
         // The let bindings are valid till the end of block so all we have to do is to pop all
         // the let-scopes at the end.
         //
         // First we build all the statements in the block.
         let mut let_scope_stack = Vec::with_capacity(8);
         let outer_source_scope = this.source_scope;
         let outer_in_scope_unsafe = this.in_scope_unsafe;
         this.update_source_scope_for_safety_mode(span, safety_mode);

         let source_info = this.source_info(span);
         for stmt in stmts {
             let Stmt { ref kind, opt_destruction_scope } = this.thir[*stmt];
             match kind {
                 StmtKind::Expr { scope, expr } => {
                     this.block_context.push(BlockFrame::Statement { ignores_expr_result: true });
                     unpack!(
                         block = this.in_opt_scope(
                             opt_destruction_scope.map(|de| (de, source_info)),
                             |this| {
                                 let si = (*scope, source_info);
                                 this.in_scope(si, LintLevel::Inherited, |this| {
                                     this.stmt_expr(block, &this.thir[*expr], Some(*scope))
                                 })
                             }
                         )
                     );
                 }
                 StmtKind::Let {
                     remainder_scope,
                     init_scope,
                     ref pattern,
                     initializer,
                     lint_level,
                 } => {
                     let ignores_expr_result = matches!(*pattern.kind, PatKind::Wild);
                     this.block_context.push(BlockFrame::Statement { ignores_expr_result });

                     // Enter the remainder scope, i.e., the bindings' destruction scope.
                     this.push_scope((*remainder_scope, source_info));
                     let_scope_stack.push(remainder_scope);

                     // Declare the bindings, which may create a source scope.
                     let remainder_span = remainder_scope.span(this.tcx, this.region_scope_tree);

                     let visibility_scope =
                         Some(this.new_source_scope(remainder_span, LintLevel::Inherited, None));

                     // Evaluate the initializer, if present.
                     if let Some(init) = initializer {
                         let init = &this.thir[*init];
                         let initializer_span = init.span;

                         unpack!(
                             block = this.in_opt_scope(
                                 opt_destruction_scope.map(|de| (de, source_info)),
                                 |this| {
                                     let scope = (*init_scope, source_info);
                                     this.in_scope(scope, *lint_level, |this| {
                                         this.declare_bindings(
                                             visibility_scope,
                                             remainder_span,
                                             pattern,
                                             ArmHasGuard(false),
                                             Some((None, initializer_span)),
                                         );
                                         this.expr_into_pattern(block, pattern.clone(), init)
                                     })
                                 }
                             )
                         );
                     } else {
                         let scope = (*init_scope, source_info);
                         unpack!(this.in_scope(scope, *lint_level, |this| {
                             this.declare_bindings(
                                 visibility_scope,
                                 remainder_span,
                                 pattern,
                                 ArmHasGuard(false),
                                 None,
                             );
                             block.unit()
                         }));

                         debug!("ast_block_stmts: pattern={:?}", pattern);
                         this.visit_primary_bindings(
                             pattern,
                             UserTypeProjections::none(),
                             &mut |this, _, _, _, node, span, _, _| {
                                 this.storage_live_binding(block, node, span, OutsideGuard, true);
                                 this.schedule_drop_for_binding(node, span, OutsideGuard);
                             },
                         )
                     }

                     // Enter the visibility scope, after evaluating the initializer.
                     if let Some(source_scope) = visibility_scope {
                         this.source_scope = source_scope;
                     }
                 }
             }

             let popped = this.block_context.pop();
             assert!(popped.map_or(false, |bf| bf.is_statement()));
         }

         // Then, the block may have an optional trailing expression which is a “return” value
         // of the block, which is stored into `destination`.
         let tcx = this.tcx;
         let destination_ty = destination.ty(&this.local_decls, tcx).ty;
         if let Some(expr) = expr {
             let tail_result_is_ignored =
                 destination_ty.is_unit() || this.block_context.currently_ignores_tail_results();
             this.block_context
                 .push(BlockFrame::TailExpr { tail_result_is_ignored, span: expr.span });

             unpack!(block = this.expr_into_dest(destination, block, expr));
             let popped = this.block_context.pop();

             assert!(popped.map_or(false, |bf| bf.is_tail_expr()));
         } else {
             // If a block has no trailing expression, then it is given an implicit return type.
             // This return type is usually `()`, unless the block is diverging, in which case the
             // return type is `!`. For the unit type, we need to actually return the unit, but in
             // the case of `!`, no return value is required, as the block will never return.
             // Opaque types of empty bodies also need this unit assignment, in order to infer that their
             // type is actually unit. Otherwise there will be no defining use found in the MIR.
             if destination_ty.is_unit() || matches!(destination_ty.kind(), ty::Opaque(..)) {
                 // We only want to assign an implicit `()` as the return value of the block if the
                 // block does not diverge. (Otherwise, we may try to assign a unit to a `!`-type.)
                 this.cfg.push_assign_unit(block, source_info, destination, this.tcx);
             }
         }
         // Finally, we pop all the let scopes before exiting out from the scope of block
         // itself.
         for scope in let_scope_stack.into_iter().rev() {
             unpack!(block = this.pop_scope((*scope, source_info), block));
         }
         // Restore the original source scope.
         this.source_scope = outer_source_scope;
         this.in_scope_unsafe = outer_in_scope_unsafe;
         block.unit()
     }

     /// If we are entering an unsafe block, create a new source scope
     fn update_source_scope_for_safety_mode(&mut self, span: Span, safety_mode: BlockSafety) {
         debug!("update_source_scope_for({:?}, {:?})", span, safety_mode);
         let new_unsafety = match safety_mode {
             BlockSafety::Safe => return,
             BlockSafety::BuiltinUnsafe => Safety::BuiltinUnsafe,
             BlockSafety::ExplicitUnsafe(hir_id) => {
                 self.in_scope_unsafe = Safety::ExplicitUnsafe(hir_id);
                 Safety::ExplicitUnsafe(hir_id)
             }
         };

         self.source_scope = self.new_source_scope(span, LintLevel::Inherited, Some(new_unsafety));
     }
 }
	use crate::build::matches::ArmHasGuard;
	use crate::build::ForGuard::OutsideGuard;
	use crate::build::{BlockAnd, BlockAndExtension, BlockFrame, Builder};
	use rustc_middle::thir::*;
	use rustc_middle::{mir::*, ty};
	use rustc_span::Span;

	impl<'a, 'tcx> Builder<'a, 'tcx> {
	pub(crate) fn ast_block(
	&mut self,
	destination: Place<'tcx>,
	block: BasicBlock,
	ast_block: &Block,
	source_info: SourceInfo,
	) -> BlockAnd<()> {
	let Block {
	region_scope,
	opt_destruction_scope,
	span,
	ref stmts,
	expr,
	targeted_by_break,
	safety_mode,
	} = *ast_block;
	let expr = expr.map(\|expr\| &self.thir[expr]);
	self.in_opt_scope(opt_destruction_scope.map(\|de\| (de, source_info)), move \|this\| {
	this.in_scope((region_scope, source_info), LintLevel::Inherited, move \|this\| {
	if targeted_by_break {
	this.in_breakable_scope(None, destination, span, \|this\| {
	Some(this.ast_block_stmts(
	destination,
	block,
	span,
	&stmts,
	expr,
	safety_mode,
	))
	})
	} else {
	this.ast_block_stmts(destination, block, span, &stmts, expr, safety_mode)
	}
	})
	})
	}

	fn ast_block_stmts(
	&mut self,
	destination: Place<'tcx>,
	mut block: BasicBlock,
	span: Span,
	stmts: &[StmtId],
	expr: Option<&Expr<'tcx>>,
	safety_mode: BlockSafety,
	) -> BlockAnd<()> {
	let this = self;

	// This convoluted structure is to avoid using recursion as we walk down a list
	// of statements. Basically, the structure we get back is something like:
	//
	// let x = <init> in {
	// expr1;
	// let y = <init> in {
	// expr2;
	// expr3;
	// ...
	// }
	// }
	//
	// The let bindings are valid till the end of block so all we have to do is to pop all
	// the let-scopes at the end.
	//
	// First we build all the statements in the block.
	let mut let_scope_stack = Vec::with_capacity(8);
	let outer_source_scope = this.source_scope;
	let outer_in_scope_unsafe = this.in_scope_unsafe;
	this.update_source_scope_for_safety_mode(span, safety_mode);

	let source_info = this.source_info(span);
	for stmt in stmts {
	let Stmt { ref kind, opt_destruction_scope } = this.thir[*stmt];
	match kind {
	StmtKind::Expr { scope, expr } => {
	this.block_context.push(BlockFrame::Statement { ignores_expr_result: true });
	unpack!(
	block = this.in_opt_scope(
	opt_destruction_scope.map(\|de\| (de, source_info)),
	\|this\| {
	let si = (*scope, source_info);
	this.in_scope(si, LintLevel::Inherited, \|this\| {
	this.stmt_expr(block, &this.thir[expr], Some(scope))
	})
	}
	)
	);
	}
	StmtKind::Let {
	remainder_scope,
	init_scope,
	ref pattern,
	initializer,
	lint_level,
	} => {
	let ignores_expr_result = matches!(*pattern.kind, PatKind::Wild);
	this.block_context.push(BlockFrame::Statement { ignores_expr_result });

	// Enter the remainder scope, i.e., the bindings' destruction scope.
	this.push_scope((*remainder_scope, source_info));
	let_scope_stack.push(remainder_scope);

	// Declare the bindings, which may create a source scope.
	let remainder_span = remainder_scope.span(this.tcx, this.region_scope_tree);

	let visibility_scope =
	Some(this.new_source_scope(remainder_span, LintLevel::Inherited, None));

	// Evaluate the initializer, if present.
	if let Some(init) = initializer {
	let init = &this.thir[*init];
	let initializer_span = init.span;

	unpack!(
	block = this.in_opt_scope(
	opt_destruction_scope.map(\|de\| (de, source_info)),
	\|this\| {
	let scope = (*init_scope, source_info);
	this.in_scope(scope, *lint_level, \|this\| {
	this.declare_bindings(
	visibility_scope,
	remainder_span,
	pattern,
	ArmHasGuard(false),
	Some((None, initializer_span)),
	);
	this.expr_into_pattern(block, pattern.clone(), init)
	})
	}
	)
	);
	} else {
	let scope = (*init_scope, source_info);
	unpack!(this.in_scope(scope, *lint_level, \|this\| {
	this.declare_bindings(
	visibility_scope,
	remainder_span,
	pattern,
	ArmHasGuard(false),
	None,
	);
	block.unit()
	}));

	debug!("ast_block_stmts: pattern={:?}", pattern);
	this.visit_primary_bindings(
	pattern,
	UserTypeProjections::none(),
	&mut \|this, _, _, _, node, span, _, _\| {
	this.storage_live_binding(block, node, span, OutsideGuard, true);
	this.schedule_drop_for_binding(node, span, OutsideGuard);
	},
	)
	}

	// Enter the visibility scope, after evaluating the initializer.
	if let Some(source_scope) = visibility_scope {
	this.source_scope = source_scope;
	}
	}
	}

	let popped = this.block_context.pop();
	assert!(popped.map_or(false, \|bf\| bf.is_statement()));
	}

	// Then, the block may have an optional trailing expression which is a “return” value
	// of the block, which is stored into `destination`.
	let tcx = this.tcx;
	let destination_ty = destination.ty(&this.local_decls, tcx).ty;
	if let Some(expr) = expr {
	let tail_result_is_ignored =
	destination_ty.is_unit() \|\| this.block_context.currently_ignores_tail_results();
	this.block_context
	.push(BlockFrame::TailExpr { tail_result_is_ignored, span: expr.span });

	unpack!(block = this.expr_into_dest(destination, block, expr));
	let popped = this.block_context.pop();

	assert!(popped.map_or(false, \|bf\| bf.is_tail_expr()));
	} else {
	// If a block has no trailing expression, then it is given an implicit return type.
	// This return type is usually `()`, unless the block is diverging, in which case the
	// return type is `!`. For the unit type, we need to actually return the unit, but in
	// the case of `!`, no return value is required, as the block will never return.
	// Opaque types of empty bodies also need this unit assignment, in order to infer that their
	// type is actually unit. Otherwise there will be no defining use found in the MIR.
	if destination_ty.is_unit() \|\| matches!(destination_ty.kind(), ty::Opaque(..)) {
	// We only want to assign an implicit `()` as the return value of the block if the
	// block does not diverge. (Otherwise, we may try to assign a unit to a `!`-type.)
	this.cfg.push_assign_unit(block, source_info, destination, this.tcx);
	}
	}
	// Finally, we pop all the let scopes before exiting out from the scope of block
	// itself.
	for scope in let_scope_stack.into_iter().rev() {
	unpack!(block = this.pop_scope((*scope, source_info), block));
	}
	// Restore the original source scope.
	this.source_scope = outer_source_scope;
	this.in_scope_unsafe = outer_in_scope_unsafe;
	block.unit()
	}

	/// If we are entering an unsafe block, create a new source scope
	fn update_source_scope_for_safety_mode(&mut self, span: Span, safety_mode: BlockSafety) {
	debug!("update_source_scope_for({:?}, {:?})", span, safety_mode);
	let new_unsafety = match safety_mode {
	BlockSafety::Safe => return,
	BlockSafety::BuiltinUnsafe => Safety::BuiltinUnsafe,
	BlockSafety::ExplicitUnsafe(hir_id) => {
	self.in_scope_unsafe = Safety::ExplicitUnsafe(hir_id);
	Safety::ExplicitUnsafe(hir_id)
	}
	};

	self.source_scope = self.new_source_scope(span, LintLevel::Inherited, Some(new_unsafety));
	}
	}