src/closure.md - rust-lang/rustc-dev-guide - Git at Google

 # Closure Capture Inference

 This section describes how rustc handles closures. Closures in Rust are
 effectively "desugared" into structs that contain the values they use (or
 references to the values they use) from their creator's stack frame. rustc has
 the job of figuring out which values a closure uses and how, so it can decide
 whether to capture a given variable by shared reference, mutable reference, or
 by move. rustc also has to figure out which of the closure traits ([`Fn`][fn],
 [`FnMut`][fn_mut], or [`FnOnce`][fn_once]) a closure is capable of
 implementing.

 [fn]: https://doc.rust-lang.org/std/ops/trait.Fn.html
 [fn_mut]:https://doc.rust-lang.org/std/ops/trait.FnMut.html
 [fn_once]: https://doc.rust-lang.org/std/ops/trait.FnOnce.html

 Let's start with a few examples:

 ### Example 1

 To start, let's take a look at how the closure in the following example is desugared:

 ```rust
 fn closure(f: impl Fn()) {
     f();
 }

 fn main() {
     let x: i32 = 10;
     closure(|| println!("Hi {}", x));  // The closure just reads x.
     println!("Value of x after return {}", x);
 }
 ```

 Let's say the above is the content of a file called `immut.rs`. If we compile
 `immut.rs` using the following command. The [`-Z dump-mir=all`][dump-mir] flag will cause
 `rustc` to generate and dump the [MIR][mir] to a directory called `mir_dump`.
 ```console
 > rustc +stage1 immut.rs -Z dump-mir=all
 ```

 [mir]: ./mir/index.md
 [dump-mir]: ./mir/passes.md

 After we run this command, we will see a newly generated directory in our
 current working directory called `mir_dump`, which will contain several files.
 If we look at file `rustc.main.-------.mir_map.0.mir`, we will find, among
 other things, it also contains this line:

 ```rust,ignore
 _4 = &_1;
 _3 = [closure@immut.rs:7:13: 7:36] { x: move _4 };
 ```

 Note that in the MIR examples in this chapter, `_1` is `x`.

 Here in first line `_4 = &_1;`, the `mir_dump` tells us that `x` was borrowed
 as an immutable reference.  This is what we would hope as our closure just
 reads `x`.

 ### Example 2

 Here is another example:

 ```rust
 fn closure(mut f: impl FnMut()) {
     f();
 }

 fn main() {
     let mut x: i32 = 10;
     closure(|| {
         x += 10;  // The closure mutates the value of x
         println!("Hi {}", x)
     });
     println!("Value of x after return {}", x);
 }
 ```

 ```rust,ignore
 _4 = &mut _1;
 _3 = [closure@mut.rs:7:13: 10:6] { x: move _4 };
 ```
 This time along, in the line `_4 = &mut _1;`, we see that the borrow is changed to mutable borrow.
 Fair enough! The closure increments `x` by 10.

 ### Example 3

 One more example:

 ```rust
 fn closure(f: impl FnOnce()) {
     f();
 }

 fn main() {
     let x = vec![21];
     closure(|| {
         drop(x);  // Makes x unusable after the fact.
     });
     // println!("Value of x after return {:?}", x);
 }
 ```

 ```rust,ignore
 _6 = [closure@move.rs:7:13: 9:6] { x: move _1 }; // bb16[3]: scope 1 at move.rs:7:13: 9:6
 ```
 Here, `x` is directly moved into the closure and the access to it will not be permitted after the
 closure.

 ## Inferences in the compiler

 Now let's dive into rustc code and see how all these inferences are done by the compiler.

 Let's start with defining a term that we will be using quite a bit in the rest of the discussion -
 *upvar*. An **upvar** is a variable that is local to the function where the closure is defined. So,
 in the above examples, **x** will be an upvar to the closure. They are also sometimes referred to as
 the *free variables* meaning they are not bound to the context of the closure.
 [`compiler/rustc_passes/src/upvars.rs`][upvars] defines a query called *upvars_mentioned*
 for this purpose.

 [upvars]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_passes/upvars/index.html

 Other than lazy invocation, one other thing that distinguishes a closure from a
 normal function is that it can use the upvars. It borrows these upvars from its surrounding
 context; therefore the compiler has to determine the upvar's borrow type. The compiler starts with
 assigning an immutable borrow type and lowers the restriction (that is, changes it from
 **immutable** to **mutable** to **move**) as needed, based on the usage. In the Example 1 above, the
 closure only uses the variable for printing but does not modify it in any way and therefore, in the
 `mir_dump`, we find the borrow type for the upvar `x` to be immutable.  In example 2, however, the
 closure modifies `x` and increments it by some value.  Because of this mutation, the compiler, which
 started off assigning `x` as an immutable reference type, has to adjust it as a mutable reference.
 Likewise in the third example, the closure drops the vector and therefore this requires the variable
 `x` to be moved into the closure. Depending on the borrow kind, the closure has to implement the
 appropriate trait: `Fn` trait for immutable borrow, `FnMut` for mutable borrow,
 and `FnOnce` for move semantics.

 Most of the code related to the closure is in the
 [`compiler/rustc_hir_typeck/src/upvar.rs`][upvar] file and the data structures are
 declared in the file [`compiler/rustc_middle/src/ty/mod.rs`][ty].

 [upvar]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_hir_typeck/upvar/index.html
 [ty]:https://doc.rust-lang.org/nightly/nightly-rustc/rustc_middle/ty/index.html

 Before we go any further, let's discuss how we can examine the flow of control through the rustc
 codebase. For closures specifically, set the `RUSTC_LOG` env variable as below and collect the
 output in a file:

 ```console
 > RUSTC_LOG=rustc_hir_typeck::upvar rustc +stage1 -Z dump-mir=all \
     <.rs file to compile> 2> <file where the output will be dumped>
 ```

 This uses the stage1 compiler and enables `debug!` logging for the
 `rustc_hir_typeck::upvar` module.

 The other option is to step through the code using lldb or gdb.

 1. `rust-lldb build/host/stage1/bin/rustc test.rs`
 2. In lldb:
     1. `b upvar.rs:134`  // Setting the breakpoint on a certain line in the upvar.rs file
     2. `r`  // Run the program until it hits the breakpoint

 Let's start with [`upvar.rs`][upvar]. This file has something called
 the [`euv::ExprUseVisitor`] which walks the source of the closure and
 invokes a callback for each upvar that is borrowed, mutated, or moved.

 [`euv::ExprUseVisitor`]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_hir_typeck/expr_use_visitor/struct.ExprUseVisitor.html

 ```rust
 fn main() {
     let mut x = vec![21];
     let _cl = || {
         let y = x[0];  // 1.
         x[0] += 1;  // 2.
     };
 }
 ```

 In the above example, our visitor will be called twice, for the lines marked 1 and 2, once for a
 shared borrow and another one for a mutable borrow. It will also tell us what was borrowed.

 The callbacks are defined by implementing the [`Delegate`] trait. The
 [`InferBorrowKind`][ibk] type implements `Delegate` and keeps a map that
 records for each upvar which mode of capture was required. The modes of capture
 can be `ByValue` (moved) or `ByRef` (borrowed). For `ByRef` borrows, the possible
 [`BorrowKind`]s are `ImmBorrow`, `UniqueImmBorrow`, `MutBorrow` as defined in the
 [`compiler/rustc_middle/src/ty/mod.rs`][middle_ty].

 [`BorrowKind`]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_middle/ty/enum.BorrowKind.html
 [middle_ty]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_middle/ty/index.html

 `Delegate` defines a few different methods (the different callbacks):
 **consume** for *move* of a variable, **borrow** for a *borrow* of some kind
 (shared or mutable), and **mutate** when we see an *assignment* of something.

 All of these callbacks have a common argument *cmt* which stands for Category,
 Mutability and Type and is defined in
 [`compiler/rustc_hir_typeck/src/expr_use_visitor.rs`][cmt]. Borrowing from the code
 comments, "`cmt` is a complete categorization of a value indicating where it
 originated and how it is located, as well as the mutability of the memory in
 which the value is stored". Based on the callback (consume, borrow etc.), we
 will call the relevant `adjust_upvar_borrow_kind_for_<something>` and pass the
 `cmt` along. Once the borrow type is adjusted, we store it in the table, which
 basically says what borrows were made for each closure.

 ```rust,ignore
 self.tables
     .borrow_mut()
     .upvar_capture_map
     .extend(delegate.adjust_upvar_captures);
 ```

 [`Delegate`]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_hir_typeck/expr_use_visitor/trait.Delegate.html
 [ibk]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_hir_typeck/upvar/struct.InferBorrowKind.html
 [cmt]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_hir_typeck/expr_use_visitor/index.html
	# Closure Capture Inference

	This section describes how rustc handles closures. Closures in Rust are
	effectively "desugared" into structs that contain the values they use (or
	references to the values they use) from their creator's stack frame. rustc has
	the job of figuring out which values a closure uses and how, so it can decide
	whether to capture a given variable by shared reference, mutable reference, or
	by move. rustc also has to figure out which of the closure traits ([`Fn`][fn],
	[`FnMut`][fn_mut], or [`FnOnce`][fn_once]) a closure is capable of
	implementing.

	[fn]: https://doc.rust-lang.org/std/ops/trait.Fn.html
	[fn_mut]:https://doc.rust-lang.org/std/ops/trait.FnMut.html
	[fn_once]: https://doc.rust-lang.org/std/ops/trait.FnOnce.html

	Let's start with a few examples:

	### Example 1

	To start, let's take a look at how the closure in the following example is desugared:

	```rust
	fn closure(f: impl Fn()) {
	f();
	}

	fn main() {
	let x: i32 = 10;
	closure(\|\| println!("Hi {}", x)); // The closure just reads x.
	println!("Value of x after return {}", x);
	}
	```

	Let's say the above is the content of a file called `immut.rs`. If we compile
	`immut.rs` using the following command. The [`-Z dump-mir=all`][dump-mir] flag will cause
	`rustc` to generate and dump the [MIR][mir] to a directory called `mir_dump`.
	```console
	> rustc +stage1 immut.rs -Z dump-mir=all
	```

	[mir]: ./mir/index.md
	[dump-mir]: ./mir/passes.md

	After we run this command, we will see a newly generated directory in our
	current working directory called `mir_dump`, which will contain several files.
	If we look at file `rustc.main.-------.mir_map.0.mir`, we will find, among
	other things, it also contains this line:

	```rust,ignore
	_4 = &_1;
	_3 = [closure@immut.rs:7:13: 7:36] { x: move _4 };
	```

	Note that in the MIR examples in this chapter, `_1` is `x`.

	Here in first line `_4 = &_1;`, the `mir_dump` tells us that `x` was borrowed
	as an immutable reference. This is what we would hope as our closure just
	reads `x`.

	### Example 2

	Here is another example:

	```rust
	fn closure(mut f: impl FnMut()) {
	f();
	}

	fn main() {
	let mut x: i32 = 10;
	closure(\|\| {
	x += 10; // The closure mutates the value of x
	println!("Hi {}", x)
	});
	println!("Value of x after return {}", x);
	}
	```

	```rust,ignore
	_4 = &mut _1;
	_3 = [closure@mut.rs:7:13: 10:6] { x: move _4 };
	```
	This time along, in the line `_4 = &mut _1;`, we see that the borrow is changed to mutable borrow.
	Fair enough! The closure increments `x` by 10.

	### Example 3

	One more example:

	```rust
	fn closure(f: impl FnOnce()) {
	f();
	}

	fn main() {
	let x = vec![21];
	closure(\|\| {
	drop(x); // Makes x unusable after the fact.
	});
	// println!("Value of x after return {:?}", x);
	}
	```

	```rust,ignore
	_6 = [closure@move.rs:7:13: 9:6] { x: move _1 }; // bb16[3]: scope 1 at move.rs:7:13: 9:6
	```
	Here, `x` is directly moved into the closure and the access to it will not be permitted after the
	closure.

	## Inferences in the compiler

	Now let's dive into rustc code and see how all these inferences are done by the compiler.

	Let's start with defining a term that we will be using quite a bit in the rest of the discussion -
	upvar. An upvar is a variable that is local to the function where the closure is defined. So,
	in the above examples, x will be an upvar to the closure. They are also sometimes referred to as
	the free variables meaning they are not bound to the context of the closure.
	[`compiler/rustc_passes/src/upvars.rs`][upvars] defines a query called upvars_mentioned
	for this purpose.

	[upvars]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_passes/upvars/index.html

	Other than lazy invocation, one other thing that distinguishes a closure from a
	normal function is that it can use the upvars. It borrows these upvars from its surrounding
	context; therefore the compiler has to determine the upvar's borrow type. The compiler starts with
	assigning an immutable borrow type and lowers the restriction (that is, changes it from
	immutable to mutable to move) as needed, based on the usage. In the Example 1 above, the
	closure only uses the variable for printing but does not modify it in any way and therefore, in the
	`mir_dump`, we find the borrow type for the upvar `x` to be immutable. In example 2, however, the
	closure modifies `x` and increments it by some value. Because of this mutation, the compiler, which
	started off assigning `x` as an immutable reference type, has to adjust it as a mutable reference.
	Likewise in the third example, the closure drops the vector and therefore this requires the variable
	`x` to be moved into the closure. Depending on the borrow kind, the closure has to implement the
	appropriate trait: `Fn` trait for immutable borrow, `FnMut` for mutable borrow,
	and `FnOnce` for move semantics.

	Most of the code related to the closure is in the
	[`compiler/rustc_hir_typeck/src/upvar.rs`][upvar] file and the data structures are
	declared in the file [`compiler/rustc_middle/src/ty/mod.rs`][ty].

	[upvar]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_hir_typeck/upvar/index.html
	[ty]:https://doc.rust-lang.org/nightly/nightly-rustc/rustc_middle/ty/index.html

	Before we go any further, let's discuss how we can examine the flow of control through the rustc
	codebase. For closures specifically, set the `RUSTC_LOG` env variable as below and collect the
	output in a file:

	```console
	> RUSTC_LOG=rustc_hir_typeck::upvar rustc +stage1 -Z dump-mir=all \
	<.rs file to compile> 2> <file where the output will be dumped>
	```

	This uses the stage1 compiler and enables `debug!` logging for the
	`rustc_hir_typeck::upvar` module.

	The other option is to step through the code using lldb or gdb.

	1. `rust-lldb build/host/stage1/bin/rustc test.rs`
	2. In lldb:
	1. `b upvar.rs:134` // Setting the breakpoint on a certain line in the upvar.rs file
	2. `r` // Run the program until it hits the breakpoint

	Let's start with [`upvar.rs`][upvar]. This file has something called
	the [`euv::ExprUseVisitor`] which walks the source of the closure and
	invokes a callback for each upvar that is borrowed, mutated, or moved.

	[`euv::ExprUseVisitor`]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_hir_typeck/expr_use_visitor/struct.ExprUseVisitor.html

	```rust
	fn main() {
	let mut x = vec![21];
	let _cl = \|\| {
	let y = x[0]; // 1.
	x[0] += 1; // 2.
	};
	}
	```

	In the above example, our visitor will be called twice, for the lines marked 1 and 2, once for a
	shared borrow and another one for a mutable borrow. It will also tell us what was borrowed.

	The callbacks are defined by implementing the [`Delegate`] trait. The
	[`InferBorrowKind`][ibk] type implements `Delegate` and keeps a map that
	records for each upvar which mode of capture was required. The modes of capture
	can be `ByValue` (moved) or `ByRef` (borrowed). For `ByRef` borrows, the possible
	[`BorrowKind`]s are `ImmBorrow`, `UniqueImmBorrow`, `MutBorrow` as defined in the
	[`compiler/rustc_middle/src/ty/mod.rs`][middle_ty].

	[`BorrowKind`]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_middle/ty/enum.BorrowKind.html
	[middle_ty]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_middle/ty/index.html

	`Delegate` defines a few different methods (the different callbacks):
	consume for move of a variable, borrow for a borrow of some kind
	(shared or mutable), and mutate when we see an assignment of something.

	All of these callbacks have a common argument cmt which stands for Category,
	Mutability and Type and is defined in
	[`compiler/rustc_hir_typeck/src/expr_use_visitor.rs`][cmt]. Borrowing from the code
	comments, "`cmt` is a complete categorization of a value indicating where it
	originated and how it is located, as well as the mutability of the memory in
	which the value is stored". Based on the callback (consume, borrow etc.), we
	will call the relevant `adjust_upvar_borrow_kind_for_<something>` and pass the
	`cmt` along. Once the borrow type is adjusted, we store it in the table, which
	basically says what borrows were made for each closure.

	```rust,ignore
	self.tables
	.borrow_mut()
	.upvar_capture_map
	.extend(delegate.adjust_upvar_captures);
	```

	[`Delegate`]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_hir_typeck/expr_use_visitor/trait.Delegate.html
	[ibk]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_hir_typeck/upvar/struct.InferBorrowKind.html
	[cmt]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_hir_typeck/expr_use_visitor/index.html