src/librustc/mir/traversal.rs - third_party/rust - Git at Google

 use rustc_data_structures::bit_set::BitSet;

 use super::*;

 /// Preorder traversal of a graph.
 ///
 /// Preorder traversal is when each node is visited before an of it's
 /// successors
 ///
 /// ```text
 ///
 ///         A
 ///        / \
 ///       /   \
 ///      B     C
 ///       \   /
 ///        \ /
 ///         D
 /// ```
 ///
 /// A preorder traversal of this graph is either `A B D C` or `A C D B`
 #[derive(Clone)]
 pub struct Preorder<'a, 'tcx> {
     body: &'a Body<'tcx>,
     visited: BitSet<BasicBlock>,
     worklist: Vec<BasicBlock>,
     root_is_start_block: bool,
 }

 impl<'a, 'tcx> Preorder<'a, 'tcx> {
     pub fn new(body: &'a Body<'tcx>, root: BasicBlock) -> Preorder<'a, 'tcx> {
         let worklist = vec![root];

         Preorder {
             body,
             visited: BitSet::new_empty(body.basic_blocks().len()),
             worklist,
             root_is_start_block: root == START_BLOCK,
         }
     }
 }

 pub fn preorder<'a, 'tcx>(body: &'a Body<'tcx>) -> Preorder<'a, 'tcx> {
     Preorder::new(body, START_BLOCK)
 }

 impl<'a, 'tcx> Iterator for Preorder<'a, 'tcx> {
     type Item = (BasicBlock, &'a BasicBlockData<'tcx>);

     fn next(&mut self) -> Option<(BasicBlock, &'a BasicBlockData<'tcx>)> {
         while let Some(idx) = self.worklist.pop() {
             if !self.visited.insert(idx) {
                 continue;
             }

             let data = &self.body[idx];

             if let Some(ref term) = data.terminator {
                 self.worklist.extend(term.successors());
             }

             return Some((idx, data));
         }

         None
     }

     fn size_hint(&self) -> (usize, Option<usize>) {
         // All the blocks, minus the number of blocks we've visited.
         let upper = self.body.basic_blocks().len() - self.visited.count();

         let lower = if self.root_is_start_block {
             // We will visit all remaining blocks exactly once.
             upper
         } else {
             self.worklist.len()
         };

         (lower, Some(upper))
     }
 }

 /// Postorder traversal of a graph.
 ///
 /// Postorder traversal is when each node is visited after all of it's
 /// successors, except when the successor is only reachable by a back-edge
 ///
 ///
 /// ```text
 ///
 ///         A
 ///        / \
 ///       /   \
 ///      B     C
 ///       \   /
 ///        \ /
 ///         D
 /// ```
 ///
 /// A Postorder traversal of this graph is `D B C A` or `D C B A`
 pub struct Postorder<'a, 'tcx> {
     body: &'a Body<'tcx>,
     visited: BitSet<BasicBlock>,
     visit_stack: Vec<(BasicBlock, Successors<'a>)>,
     root_is_start_block: bool,
 }

 impl<'a, 'tcx> Postorder<'a, 'tcx> {
     pub fn new(body: &'a Body<'tcx>, root: BasicBlock) -> Postorder<'a, 'tcx> {
         let mut po = Postorder {
             body,
             visited: BitSet::new_empty(body.basic_blocks().len()),
             visit_stack: Vec::new(),
             root_is_start_block: root == START_BLOCK,
         };


         let data = &po.body[root];

         if let Some(ref term) = data.terminator {
             po.visited.insert(root);
             po.visit_stack.push((root, term.successors()));
             po.traverse_successor();
         }

         po
     }

     fn traverse_successor(&mut self) {
         // This is quite a complex loop due to 1. the borrow checker not liking it much
         // and 2. what exactly is going on is not clear
         //
         // It does the actual traversal of the graph, while the `next` method on the iterator
         // just pops off of the stack. `visit_stack` is a stack containing pairs of nodes and
         // iterators over the successors of those nodes. Each iteration attempts to get the next
         // node from the top of the stack, then pushes that node and an iterator over the
         // successors to the top of the stack. This loop only grows `visit_stack`, stopping when
         // we reach a child that has no children that we haven't already visited.
         //
         // For a graph that looks like this:
         //
         //         A
         //        / \
         //       /   \
         //      B     C
         //      |     |
         //      |     |
         //      D     |
         //       \   /
         //        \ /
         //         E
         //
         // The state of the stack starts out with just the root node (`A` in this case);
         //     [(A, [B, C])]
         //
         // When the first call to `traverse_successor` happens, the following happens:
         //
         //     [(B, [D]),  // `B` taken from the successors of `A`, pushed to the
         //                 // top of the stack along with the successors of `B`
         //      (A, [C])]
         //
         //     [(D, [E]),  // `D` taken from successors of `B`, pushed to stack
         //      (B, []),
         //      (A, [C])]
         //
         //     [(E, []),   // `E` taken from successors of `D`, pushed to stack
         //      (D, []),
         //      (B, []),
         //      (A, [C])]
         //
         // Now that the top of the stack has no successors we can traverse, each item will
         // be popped off during iteration until we get back to `A`. This yields [E, D, B].
         //
         // When we yield `B` and call `traverse_successor`, we push `C` to the stack, but
         // since we've already visited `E`, that child isn't added to the stack. The last
         // two iterations yield `C` and finally `A` for a final traversal of [E, D, B, C, A]
         loop {
             let bb = if let Some(&mut (_, ref mut iter)) = self.visit_stack.last_mut() {
                 if let Some(&bb) = iter.next() {
                     bb
                 } else {
                     break;
                 }
             } else {
                 break;
             };

             if self.visited.insert(bb) {
                 if let Some(term) = &self.body[bb].terminator {
                     self.visit_stack.push((bb, term.successors()));
                 }
             }
         }
     }
 }

 pub fn postorder<'a, 'tcx>(body: &'a Body<'tcx>) -> Postorder<'a, 'tcx> {
     Postorder::new(body, START_BLOCK)
 }

 impl<'a, 'tcx> Iterator for Postorder<'a, 'tcx> {
     type Item = (BasicBlock, &'a BasicBlockData<'tcx>);

     fn next(&mut self) -> Option<(BasicBlock, &'a BasicBlockData<'tcx>)> {
         let next = self.visit_stack.pop();
         if next.is_some() {
             self.traverse_successor();
         }

         next.map(|(bb, _)| (bb, &self.body[bb]))
     }

     fn size_hint(&self) -> (usize, Option<usize>) {
         // All the blocks, minus the number of blocks we've visited.
         let upper = self.body.basic_blocks().len() - self.visited.count();

         let lower = if self.root_is_start_block {
             // We will visit all remaining blocks exactly once.
             upper
         } else {
             self.visit_stack.len()
         };

         (lower, Some(upper))
     }
 }

 /// Reverse postorder traversal of a graph
 ///
 /// Reverse postorder is the reverse order of a postorder traversal.
 /// This is different to a preorder traversal and represents a natural
 /// linearization of control-flow.
 ///
 /// ```text
 ///
 ///         A
 ///        / \
 ///       /   \
 ///      B     C
 ///       \   /
 ///        \ /
 ///         D
 /// ```
 ///
 /// A reverse postorder traversal of this graph is either `A B C D` or `A C B D`
 /// Note that for a graph containing no loops (i.e., A DAG), this is equivalent to
 /// a topological sort.
 ///
 /// Construction of a `ReversePostorder` traversal requires doing a full
 /// postorder traversal of the graph, therefore this traversal should be
 /// constructed as few times as possible. Use the `reset` method to be able
 /// to re-use the traversal
 #[derive(Clone)]
 pub struct ReversePostorder<'a, 'tcx> {
     body: &'a Body<'tcx>,
     blocks: Vec<BasicBlock>,
     idx: usize
 }

 impl<'a, 'tcx> ReversePostorder<'a, 'tcx> {
     pub fn new(body: &'a Body<'tcx>, root: BasicBlock) -> ReversePostorder<'a, 'tcx> {
         let blocks : Vec<_> = Postorder::new(body, root).map(|(bb, _)| bb).collect();

         let len = blocks.len();

         ReversePostorder {
             body,
             blocks,
             idx: len
         }
     }

     pub fn reset(&mut self) {
         self.idx = self.blocks.len();
     }
 }


 pub fn reverse_postorder<'a, 'tcx>(body: &'a Body<'tcx>) -> ReversePostorder<'a, 'tcx> {
     ReversePostorder::new(body, START_BLOCK)
 }

 impl<'a, 'tcx> Iterator for ReversePostorder<'a, 'tcx> {
     type Item = (BasicBlock, &'a BasicBlockData<'tcx>);

     fn next(&mut self) -> Option<(BasicBlock, &'a BasicBlockData<'tcx>)> {
         if self.idx == 0 { return None; }
         self.idx -= 1;

         self.blocks.get(self.idx).map(|&bb| (bb, &self.body[bb]))
     }

     fn size_hint(&self) -> (usize, Option<usize>) {
         (self.idx, Some(self.idx))
     }
 }

 impl<'a, 'tcx> ExactSizeIterator for ReversePostorder<'a, 'tcx> {}
	use rustc_data_structures::bit_set::BitSet;

	use super::*;

	/// Preorder traversal of a graph.
	///
	/// Preorder traversal is when each node is visited before an of it's
	/// successors
	///
	/// ```text
	///
	/// A
	/// / \
	/// / \
	/// B C
	/// \ /
	/// \ /
	/// D
	/// ```
	///
	/// A preorder traversal of this graph is either `A B D C` or `A C D B`
	#[derive(Clone)]
	pub struct Preorder<'a, 'tcx> {
	body: &'a Body<'tcx>,
	visited: BitSet<BasicBlock>,
	worklist: Vec<BasicBlock>,
	root_is_start_block: bool,
	}

	impl<'a, 'tcx> Preorder<'a, 'tcx> {
	pub fn new(body: &'a Body<'tcx>, root: BasicBlock) -> Preorder<'a, 'tcx> {
	let worklist = vec![root];

	Preorder {
	body,
	visited: BitSet::new_empty(body.basic_blocks().len()),
	worklist,
	root_is_start_block: root == START_BLOCK,
	}
	}
	}

	pub fn preorder<'a, 'tcx>(body: &'a Body<'tcx>) -> Preorder<'a, 'tcx> {
	Preorder::new(body, START_BLOCK)
	}

	impl<'a, 'tcx> Iterator for Preorder<'a, 'tcx> {
	type Item = (BasicBlock, &'a BasicBlockData<'tcx>);

	fn next(&mut self) -> Option<(BasicBlock, &'a BasicBlockData<'tcx>)> {
	while let Some(idx) = self.worklist.pop() {
	if !self.visited.insert(idx) {
	continue;
	}

	let data = &self.body[idx];

	if let Some(ref term) = data.terminator {
	self.worklist.extend(term.successors());
	}

	return Some((idx, data));
	}

	None
	}

	fn size_hint(&self) -> (usize, Option<usize>) {
	// All the blocks, minus the number of blocks we've visited.
	let upper = self.body.basic_blocks().len() - self.visited.count();

	let lower = if self.root_is_start_block {
	// We will visit all remaining blocks exactly once.
	upper
	} else {
	self.worklist.len()
	};

	(lower, Some(upper))
	}
	}

	/// Postorder traversal of a graph.
	///
	/// Postorder traversal is when each node is visited after all of it's
	/// successors, except when the successor is only reachable by a back-edge
	///
	///
	/// ```text
	///
	/// A
	/// / \
	/// / \
	/// B C
	/// \ /
	/// \ /
	/// D
	/// ```
	///
	/// A Postorder traversal of this graph is `D B C A` or `D C B A`
	pub struct Postorder<'a, 'tcx> {
	body: &'a Body<'tcx>,
	visited: BitSet<BasicBlock>,
	visit_stack: Vec<(BasicBlock, Successors<'a>)>,
	root_is_start_block: bool,
	}

	impl<'a, 'tcx> Postorder<'a, 'tcx> {
	pub fn new(body: &'a Body<'tcx>, root: BasicBlock) -> Postorder<'a, 'tcx> {
	let mut po = Postorder {
	body,
	visited: BitSet::new_empty(body.basic_blocks().len()),
	visit_stack: Vec::new(),
	root_is_start_block: root == START_BLOCK,
	};


	let data = &po.body[root];

	if let Some(ref term) = data.terminator {
	po.visited.insert(root);
	po.visit_stack.push((root, term.successors()));
	po.traverse_successor();
	}

	po
	}

	fn traverse_successor(&mut self) {
	// This is quite a complex loop due to 1. the borrow checker not liking it much
	// and 2. what exactly is going on is not clear
	//
	// It does the actual traversal of the graph, while the `next` method on the iterator
	// just pops off of the stack. `visit_stack` is a stack containing pairs of nodes and
	// iterators over the successors of those nodes. Each iteration attempts to get the next
	// node from the top of the stack, then pushes that node and an iterator over the
	// successors to the top of the stack. This loop only grows `visit_stack`, stopping when
	// we reach a child that has no children that we haven't already visited.
	//
	// For a graph that looks like this:
	//
	// A
	// / \
	// / \
	// B C
	// \| \|
	// \| \|
	// D \|
	// \ /
	// \ /
	// E
	//
	// The state of the stack starts out with just the root node (`A` in this case);
	// [(A, [B, C])]
	//
	// When the first call to `traverse_successor` happens, the following happens:
	//
	// [(B, [D]), // `B` taken from the successors of `A`, pushed to the
	// // top of the stack along with the successors of `B`
	// (A, [C])]
	//
	// [(D, [E]), // `D` taken from successors of `B`, pushed to stack
	// (B, []),
	// (A, [C])]
	//
	// [(E, []), // `E` taken from successors of `D`, pushed to stack
	// (D, []),
	// (B, []),
	// (A, [C])]
	//
	// Now that the top of the stack has no successors we can traverse, each item will
	// be popped off during iteration until we get back to `A`. This yields [E, D, B].
	//
	// When we yield `B` and call `traverse_successor`, we push `C` to the stack, but
	// since we've already visited `E`, that child isn't added to the stack. The last
	// two iterations yield `C` and finally `A` for a final traversal of [E, D, B, C, A]
	loop {
	let bb = if let Some(&mut (_, ref mut iter)) = self.visit_stack.last_mut() {
	if let Some(&bb) = iter.next() {
	bb
	} else {
	break;
	}
	} else {
	break;
	};

	if self.visited.insert(bb) {
	if let Some(term) = &self.body[bb].terminator {
	self.visit_stack.push((bb, term.successors()));
	}
	}
	}
	}
	}

	pub fn postorder<'a, 'tcx>(body: &'a Body<'tcx>) -> Postorder<'a, 'tcx> {
	Postorder::new(body, START_BLOCK)
	}

	impl<'a, 'tcx> Iterator for Postorder<'a, 'tcx> {
	type Item = (BasicBlock, &'a BasicBlockData<'tcx>);

	fn next(&mut self) -> Option<(BasicBlock, &'a BasicBlockData<'tcx>)> {
	let next = self.visit_stack.pop();
	if next.is_some() {
	self.traverse_successor();
	}

	next.map(\|(bb, _)\| (bb, &self.body[bb]))
	}

	fn size_hint(&self) -> (usize, Option<usize>) {
	// All the blocks, minus the number of blocks we've visited.
	let upper = self.body.basic_blocks().len() - self.visited.count();

	let lower = if self.root_is_start_block {
	// We will visit all remaining blocks exactly once.
	upper
	} else {
	self.visit_stack.len()
	};

	(lower, Some(upper))
	}
	}

	/// Reverse postorder traversal of a graph
	///
	/// Reverse postorder is the reverse order of a postorder traversal.
	/// This is different to a preorder traversal and represents a natural
	/// linearization of control-flow.
	///
	/// ```text
	///
	/// A
	/// / \
	/// / \
	/// B C
	/// \ /
	/// \ /
	/// D
	/// ```
	///
	/// A reverse postorder traversal of this graph is either `A B C D` or `A C B D`
	/// Note that for a graph containing no loops (i.e., A DAG), this is equivalent to
	/// a topological sort.
	///
	/// Construction of a `ReversePostorder` traversal requires doing a full
	/// postorder traversal of the graph, therefore this traversal should be
	/// constructed as few times as possible. Use the `reset` method to be able
	/// to re-use the traversal
	#[derive(Clone)]
	pub struct ReversePostorder<'a, 'tcx> {
	body: &'a Body<'tcx>,
	blocks: Vec<BasicBlock>,
	idx: usize
	}

	impl<'a, 'tcx> ReversePostorder<'a, 'tcx> {
	pub fn new(body: &'a Body<'tcx>, root: BasicBlock) -> ReversePostorder<'a, 'tcx> {
	let blocks : Vec<_> = Postorder::new(body, root).map(\|(bb, _)\| bb).collect();

	let len = blocks.len();

	ReversePostorder {
	body,
	blocks,
	idx: len
	}
	}

	pub fn reset(&mut self) {
	self.idx = self.blocks.len();
	}
	}


	pub fn reverse_postorder<'a, 'tcx>(body: &'a Body<'tcx>) -> ReversePostorder<'a, 'tcx> {
	ReversePostorder::new(body, START_BLOCK)
	}

	impl<'a, 'tcx> Iterator for ReversePostorder<'a, 'tcx> {
	type Item = (BasicBlock, &'a BasicBlockData<'tcx>);

	fn next(&mut self) -> Option<(BasicBlock, &'a BasicBlockData<'tcx>)> {
	if self.idx == 0 { return None; }
	self.idx -= 1;

	self.blocks.get(self.idx).map(\|&bb\| (bb, &self.body[bb]))
	}

	fn size_hint(&self) -> (usize, Option<usize>) {
	(self.idx, Some(self.idx))
	}
	}

	impl<'a, 'tcx> ExactSizeIterator for ReversePostorder<'a, 'tcx> {}