From 4e2e9be6abed3225406b466099e397acc0f914d2 Mon Sep 17 00:00:00 2001
From: "Matt A. Tobin" <email@mattatobin.com>
Date: Sat, 22 Feb 2020 17:32:39 -0500
Subject: Reclassify heapsnapshot and nsJSInspector as not part of devtools

This resolves Issue #316
---
 devtools/shared/heapsnapshot/DominatorTreeNode.js | 336 ----------------------
 1 file changed, 336 deletions(-)
 delete mode 100644 devtools/shared/heapsnapshot/DominatorTreeNode.js

(limited to 'devtools/shared/heapsnapshot/DominatorTreeNode.js')

diff --git a/devtools/shared/heapsnapshot/DominatorTreeNode.js b/devtools/shared/heapsnapshot/DominatorTreeNode.js
deleted file mode 100644
index 13a847fd0..000000000
--- a/devtools/shared/heapsnapshot/DominatorTreeNode.js
+++ /dev/null
@@ -1,336 +0,0 @@
-/* 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/. */
-"use strict";
-
-const { immutableUpdate } = require("resource://devtools/shared/ThreadSafeDevToolsUtils.js");
-const { Visitor, walk } = require("resource://devtools/shared/heapsnapshot/CensusUtils.js");
-const { deduplicatePaths } = require("resource://devtools/shared/heapsnapshot/shortest-paths");
-
-const DEFAULT_MAX_DEPTH = 4;
-const DEFAULT_MAX_SIBLINGS = 15;
-const DEFAULT_MAX_NUM_PATHS = 5;
-
-/**
- * A single node in a dominator tree.
- *
- * @param {NodeId} nodeId
- * @param {NodeSize} retainedSize
- */
-function DominatorTreeNode(nodeId, label, shallowSize, retainedSize) {
-  // The id of this node.
-  this.nodeId = nodeId;
-
-  // The label structure generated by describing the given node.
-  this.label = label;
-
-  // The shallow size of this node.
-  this.shallowSize = shallowSize;
-
-  // The retained size of this node.
-  this.retainedSize = retainedSize;
-
-  // The id of this node's parent or undefined if this node is the root.
-  this.parentId = undefined;
-
-  // An array of immediately dominated child `DominatorTreeNode`s, or undefined.
-  this.children = undefined;
-
-  // An object of the form returned by `deduplicatePaths`, encoding the set of
-  // the N shortest retaining paths for this node as a graph.
-  this.shortestPaths = undefined;
-
-  // True iff the `children` property does not contain every immediately
-  // dominated node.
-  //
-  // * If children is an array and this property is true: the array does not
-  //   contain the complete set of immediately dominated children.
-  // * If children is an array and this property is false: the array contains
-  //   the complete set of immediately dominated children.
-  // * If children is undefined and this property is true: there exist
-  //   immediately dominated children for this node, but they have not been
-  //   loaded yet.
-  // * If children is undefined and this property is false: this node does not
-  //   dominate any others and therefore has no children.
-  this.moreChildrenAvailable = true;
-}
-
-DominatorTreeNode.prototype = null;
-
-module.exports = DominatorTreeNode;
-
-/**
- * Add `child` to the `parent`'s set of children.
- *
- * @param {DominatorTreeNode} parent
- * @param {DominatorTreeNode} child
- */
-DominatorTreeNode.addChild = function (parent, child) {
-  if (parent.children === undefined) {
-    parent.children = [];
-  }
-
-  parent.children.push(child);
-  child.parentId = parent.nodeId;
-};
-
-/**
- * A Visitor that is used to generate a label for a node in the heap snapshot
- * and get its shallow size as well while we are at it.
- */
-function LabelAndShallowSizeVisitor() {
-  // As we walk the description, we accumulate edges in this array.
-  this._labelPieces = [];
-
-  // Once we reach the non-zero count leaf node in the description, we move the
-  // labelPieces here to signify that we no longer need to accumulate edges.
-  this._label = undefined;
-
-  // Once we reach the non-zero count leaf node in the description, we grab the
-  // shallow size and place it here.
-  this._shallowSize = 0;
-}
-
-DominatorTreeNode.LabelAndShallowSizeVisitor = LabelAndShallowSizeVisitor;
-
-LabelAndShallowSizeVisitor.prototype = Object.create(Visitor);
-
-/**
- * @overrides Visitor.prototype.enter
- */
-LabelAndShallowSizeVisitor.prototype.enter = function (breakdown, report, edge) {
-  if (this._labelPieces && edge) {
-    this._labelPieces.push(edge);
-  }
-};
-
-/**
- * @overrides Visitor.prototype.exit
- */
-LabelAndShallowSizeVisitor.prototype.exit = function (breakdown, report, edge) {
-  if (this._labelPieces && edge) {
-    this._labelPieces.pop();
-  }
-};
-
-/**
- * @overrides Visitor.prototype.count
- */
-LabelAndShallowSizeVisitor.prototype.count = function (breakdown, report, edge) {
-  if (report.count === 0) {
-    return;
-  }
-
-  this._label = this._labelPieces;
-  this._labelPieces = undefined;
-
-  this._shallowSize = report.bytes;
-};
-
-/**
- * Get the generated label structure accumulated by this visitor.
- *
- * @returns {Object}
- */
-LabelAndShallowSizeVisitor.prototype.label = function () {
-  return this._label;
-};
-
-/**
- * Get the shallow size of the node this visitor visited.
- *
- * @returns {Number}
- */
-LabelAndShallowSizeVisitor.prototype.shallowSize = function () {
-  return this._shallowSize;
-};
-
-/**
- * Generate a label structure for the node with the given id and grab its
- * shallow size.
- *
- * What is a "label" structure? HeapSnapshot.describeNode essentially takes a
- * census of a single node rather than the whole heap graph. The resulting
- * report has only one count leaf that is non-zero. The label structure is the
- * path in this report from the root to the non-zero count leaf.
- *
- * @param {Number} nodeId
- * @param {HeapSnapshot} snapshot
- * @param {Object} breakdown
- *
- * @returns {Object}
- *          An object with the following properties:
- *          - {Number} shallowSize
- *          - {Object} label
- */
-DominatorTreeNode.getLabelAndShallowSize = function (nodeId,
-                                                     snapshot,
-                                                     breakdown) {
-  const description = snapshot.describeNode(breakdown, nodeId);
-
-  const visitor = new LabelAndShallowSizeVisitor();
-  walk(breakdown, description, visitor);
-
-  return {
-    label: visitor.label(),
-    shallowSize: visitor.shallowSize(),
-  };
-};
-
-/**
- * Do a partial traversal of the given dominator tree and convert it into a tree
- * of `DominatorTreeNode`s. Dominator trees have a node for every node in the
- * snapshot's heap graph, so we must not allocate a JS object for every node. It
- * would be way too many and the node count is effectively unbounded.
- *
- * Go no deeper down the tree than `maxDepth` and only consider at most
- * `maxSiblings` within any single node's children.
- *
- * @param {DominatorTree} dominatorTree
- * @param {HeapSnapshot} snapshot
- * @param {Object} breakdown
- * @param {Number} maxDepth
- * @param {Number} maxSiblings
- *
- * @returns {DominatorTreeNode}
- */
-DominatorTreeNode.partialTraversal = function (dominatorTree,
-                                               snapshot,
-                                               breakdown,
-                                               maxDepth = DEFAULT_MAX_DEPTH,
-                                               maxSiblings = DEFAULT_MAX_SIBLINGS) {
-  function dfs(nodeId, depth) {
-    const { label, shallowSize } =
-      DominatorTreeNode.getLabelAndShallowSize(nodeId, snapshot, breakdown);
-    const retainedSize = dominatorTree.getRetainedSize(nodeId);
-    const node = new DominatorTreeNode(nodeId, label, shallowSize, retainedSize);
-    const childNodeIds = dominatorTree.getImmediatelyDominated(nodeId);
-
-    const newDepth = depth + 1;
-    if (newDepth < maxDepth) {
-      const endIdx = Math.min(childNodeIds.length, maxSiblings);
-      for (let i = 0; i < endIdx; i++) {
-        DominatorTreeNode.addChild(node, dfs(childNodeIds[i], newDepth));
-      }
-      node.moreChildrenAvailable = endIdx < childNodeIds.length;
-    } else {
-      node.moreChildrenAvailable = childNodeIds.length > 0;
-    }
-
-    return node;
-  }
-
-  return dfs(dominatorTree.root, 0);
-};
-
-/**
- * Insert more children into the given (partially complete) dominator tree.
- *
- * The tree is updated in an immutable and persistent manner: a new tree is
- * returned, but all unmodified subtrees (which is most) are shared with the
- * original tree. Only the modified nodes are re-allocated.
- *
- * @param {DominatorTreeNode} tree
- * @param {Array<NodeId>} path
- * @param {Array<DominatorTreeNode>} newChildren
- * @param {Boolean} moreChildrenAvailable
- *
- * @returns {DominatorTreeNode}
- */
-DominatorTreeNode.insert = function (tree, path, newChildren, moreChildrenAvailable) {
-  function insert(tree, i) {
-    if (tree.nodeId !== path[i]) {
-      return tree;
-    }
-
-    if (i == path.length - 1) {
-      return immutableUpdate(tree, {
-        children: (tree.children || []).concat(newChildren),
-        moreChildrenAvailable,
-      });
-    }
-
-    return tree.children
-      ? immutableUpdate(tree, {
-        children: tree.children.map(c => insert(c, i + 1))
-      })
-      : tree;
-  }
-
-  return insert(tree, 0);
-};
-
-/**
- * Get the new canonical node with the given `id` in `tree` that exists along
- * `path`. If there is no such node along `path`, return null.
- *
- * This is useful if we have a reference to a now-outdated DominatorTreeNode due
- * to a recent call to DominatorTreeNode.insert and want to get the up-to-date
- * version. We don't have to walk the whole tree: if there is an updated version
- * of the node then it *must* be along the path.
- *
- * @param {NodeId} id
- * @param {DominatorTreeNode} tree
- * @param {Array<NodeId>} path
- *
- * @returns {DominatorTreeNode|null}
- */
-DominatorTreeNode.getNodeByIdAlongPath = function (id, tree, path) {
-  function find(node, i) {
-    if (!node || node.nodeId !== path[i]) {
-      return null;
-    }
-
-    if (node.nodeId === id) {
-      return node;
-    }
-
-    if (i === path.length - 1 || !node.children) {
-      return null;
-    }
-
-    const nextId = path[i + 1];
-    return find(node.children.find(c => c.nodeId === nextId), i + 1);
-  }
-
-  return find(tree, 0);
-};
-
-/**
- * Find the shortest retaining paths for the given set of DominatorTreeNodes,
- * and populate each node's `shortestPaths` property with them in place.
- *
- * @param {HeapSnapshot} snapshot
- * @param {Object} breakdown
- * @param {NodeId} start
- * @param {Array<DominatorTreeNode>} treeNodes
- * @param {Number} maxNumPaths
- */
-DominatorTreeNode.attachShortestPaths = function (snapshot,
-                                                  breakdown,
-                                                  start,
-                                                  treeNodes,
-                                                  maxNumPaths = DEFAULT_MAX_NUM_PATHS) {
-  const idToTreeNode = new Map();
-  const targets = [];
-  for (let node of treeNodes) {
-    const id = node.nodeId;
-    idToTreeNode.set(id, node);
-    targets.push(id);
-  }
-
-  const shortestPaths = snapshot.computeShortestPaths(start,
-                                                      targets,
-                                                      maxNumPaths);
-
-  for (let [target, paths] of shortestPaths) {
-    const deduped = deduplicatePaths(target, paths);
-    deduped.nodes = deduped.nodes.map(id => {
-      const { label } =
-        DominatorTreeNode.getLabelAndShallowSize(id, snapshot, breakdown);
-      return { id, label };
-    });
-
-    idToTreeNode.get(target).shortestPaths = deduped;
-  }
-};
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