gecko-dev/dom/chrome-webidl/DominatorTree.webidl
Nika Layzell 2b21840f81 Bug 1489301 - Part 4: Remove unnecessary [Exposed=System] annotations, r=bzbarsky
We don't need to expose on both Window and System anymore, as Window now
implies System. I don't remove unnecessary [Exposed=Window] annotations, as
WebIDL upstream has removed PrimaryGlobal.

Differential Revision: https://phabricator.services.mozilla.com/D9399
2018-10-23 16:03:51 -04:00

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/* -*- Mode: IDL; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this file,
* You can obtain one at http://mozilla.org/MPL/2.0/.
*/
typedef unsigned long long NodeId;
typedef unsigned long long NodeSize;
/**
* In a directed graph with a root node `R`, a node `A` is said to "dominate" a
* node `B` iff every path from `R` to `B` contains `A`. A node `A` is said to
* be the "immediate dominator" of a node `B` iff it dominates `B`, is not `B`
* itself, and does not dominate any other nodes which also dominate `B` in
* turn.
*
* If we take every node from a graph `G` and create a new graph `T` with edges
* to each node from its immediate dominator, then `T` is a tree (each node has
* only one immediate dominator, or none if it is the root). This tree is called
* a "dominator tree".
*
* This interface represents a dominator tree constructed from a HeapSnapshot's
* heap graph. The domination relationship and dominator trees are useful tools
* for analyzing heap graphs because they tell you:
*
* - Exactly what could be reclaimed by the GC if some node `A` became
* unreachable: those nodes which are dominated by `A`,
*
* - The "retained size" of a node in the heap graph, in contrast to its
* "shallow size". The "shallow size" is the space taken by a node itself,
* not counting anything it references. The "retained size" of a node is its
* shallow size plus the size of all the things that would be collected if
* the original node wasn't (directly or indirectly) referencing them. In
* other words, the retained size is the shallow size of a node plus the
* shallow sizes of every other node it dominates. For example, the root
* node in a binary tree might have a small shallow size that does not take
* up much space itself, but it dominates the rest of the binary tree and
* its retained size is therefore significant (assuming no external
* references into the tree).
*/
[ChromeOnly, Exposed=(Window,Worker)]
interface DominatorTree {
/**
* The `NodeId` for the root of the dominator tree. This is a "meta-root" in
* that it has an edge to each GC root in the heap snapshot this dominator
* tree was created from.
*/
readonly attribute NodeId root;
/**
* Get the retained size of the node with the given id. If given an invalid
* id, null is returned. Throws an error on OOM.
*/
[Throws]
NodeSize? getRetainedSize(NodeId node);
/**
* Get the set of ids of nodes immediately dominated by the node with the
* given id. The resulting array is sorted by greatest to least retained
* size. If given an invalid id, null is returned. Throws an error on OOM.
*/
[Throws]
sequence<NodeId>? getImmediatelyDominated(NodeId node);
/**
* Get the immediate dominator of the node with the given id. Returns null if
* given an invalid id, or the id of the root node.
*/
NodeId? getImmediateDominator(NodeId node);
};