tools/profile.js - platform/external/v8 - Git at Google

 // Copyright 2009 the V8 project authors. All rights reserved.
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright
 //       notice, this list of conditions and the following disclaimer.
 //     * Redistributions in binary form must reproduce the above
 //       copyright notice, this list of conditions and the following
 //       disclaimer in the documentation and/or other materials provided
 //       with the distribution.
 //     * Neither the name of Google Inc. nor the names of its
 //       contributors may be used to endorse or promote products derived
 //       from this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.


 /**
  * Creates a profile object for processing profiling-related events
  * and calculating function execution times.
  *
  * @constructor
  */
 function Profile() {
   this.codeMap_ = new CodeMap();
   this.topDownTree_ = new CallTree();
   this.bottomUpTree_ = new CallTree();
 };


 /**
  * Returns whether a function with the specified name must be skipped.
  * Should be overriden by subclasses.
  *
  * @param {string} name Function name.
  */
 Profile.prototype.skipThisFunction = function(name) {
   return false;
 };


 /**
  * Enum for profiler operations that involve looking up existing
  * code entries.
  *
  * @enum {number}
  */
 Profile.Operation = {
   MOVE: 0,
   DELETE: 1,
   TICK: 2
 };


 /**
  * Enum for code state regarding its dynamic optimization.
  *
  * @enum {number}
  */
 Profile.CodeState = {
   COMPILED: 0,
   OPTIMIZABLE: 1,
   OPTIMIZED: 2
 };


 /**
  * Called whenever the specified operation has failed finding a function
  * containing the specified address. Should be overriden by subclasses.
  * See the Profile.Operation enum for the list of
  * possible operations.
  *
  * @param {number} operation Operation.
  * @param {number} addr Address of the unknown code.
  * @param {number} opt_stackPos If an unknown address is encountered
  *     during stack strace processing, specifies a position of the frame
  *     containing the address.
  */
 Profile.prototype.handleUnknownCode = function(
     operation, addr, opt_stackPos) {
 };


 /**
  * Registers a library.
  *
  * @param {string} name Code entry name.
  * @param {number} startAddr Starting address.
  * @param {number} endAddr Ending address.
  */
 Profile.prototype.addLibrary = function(
     name, startAddr, endAddr) {
   var entry = new CodeMap.CodeEntry(
       endAddr - startAddr, name);
   this.codeMap_.addLibrary(startAddr, entry);
   return entry;
 };


 /**
  * Registers statically compiled code entry.
  *
  * @param {string} name Code entry name.
  * @param {number} startAddr Starting address.
  * @param {number} endAddr Ending address.
  */
 Profile.prototype.addStaticCode = function(
     name, startAddr, endAddr) {
   var entry = new CodeMap.CodeEntry(
       endAddr - startAddr, name);
   this.codeMap_.addStaticCode(startAddr, entry);
   return entry;
 };


 /**
  * Registers dynamic (JIT-compiled) code entry.
  *
  * @param {string} type Code entry type.
  * @param {string} name Code entry name.
  * @param {number} start Starting address.
  * @param {number} size Code entry size.
  */
 Profile.prototype.addCode = function(
     type, name, start, size) {
   var entry = new Profile.DynamicCodeEntry(size, type, name);
   this.codeMap_.addCode(start, entry);
   return entry;
 };


 /**
  * Registers dynamic (JIT-compiled) code entry.
  *
  * @param {string} type Code entry type.
  * @param {string} name Code entry name.
  * @param {number} start Starting address.
  * @param {number} size Code entry size.
  * @param {number} funcAddr Shared function object address.
  * @param {Profile.CodeState} state Optimization state.
  */
 Profile.prototype.addFuncCode = function(
     type, name, start, size, funcAddr, state) {
   // As code and functions are in the same address space,
   // it is safe to put them in a single code map.
   var func = this.codeMap_.findDynamicEntryByStartAddress(funcAddr);
   if (!func) {
     func = new Profile.FunctionEntry(name);
     this.codeMap_.addCode(funcAddr, func);
   } else if (func.name !== name) {
     // Function object has been overwritten with a new one.
     func.name = name;
   }
   var entry = this.codeMap_.findDynamicEntryByStartAddress(start);
   if (entry) {
     if (entry.size === size && entry.func === func) {
       // Entry state has changed.
       entry.state = state;
     }
   } else {
     entry = new Profile.DynamicFuncCodeEntry(size, type, func, state);
     this.codeMap_.addCode(start, entry);
   }
   return entry;
 };


 /**
  * Reports about moving of a dynamic code entry.
  *
  * @param {number} from Current code entry address.
  * @param {number} to New code entry address.
  */
 Profile.prototype.moveCode = function(from, to) {
   try {
     this.codeMap_.moveCode(from, to);
   } catch (e) {
     this.handleUnknownCode(Profile.Operation.MOVE, from);
   }
 };


 /**
  * Reports about deletion of a dynamic code entry.
  *
  * @param {number} start Starting address.
  */
 Profile.prototype.deleteCode = function(start) {
   try {
     this.codeMap_.deleteCode(start);
   } catch (e) {
     this.handleUnknownCode(Profile.Operation.DELETE, start);
   }
 };


 /**
  * Reports about moving of a dynamic code entry.
  *
  * @param {number} from Current code entry address.
  * @param {number} to New code entry address.
  */
 Profile.prototype.moveFunc = function(from, to) {
   if (this.codeMap_.findDynamicEntryByStartAddress(from)) {
     this.codeMap_.moveCode(from, to);
   }
 };


 /**
  * Retrieves a code entry by an address.
  *
  * @param {number} addr Entry address.
  */
 Profile.prototype.findEntry = function(addr) {
   return this.codeMap_.findEntry(addr);
 };


 /**
  * Records a tick event. Stack must contain a sequence of
  * addresses starting with the program counter value.
  *
  * @param {Array<number>} stack Stack sample.
  */
 Profile.prototype.recordTick = function(stack) {
   var processedStack = this.resolveAndFilterFuncs_(stack);
   this.bottomUpTree_.addPath(processedStack);
   processedStack.reverse();
   this.topDownTree_.addPath(processedStack);
 };


 /**
  * Translates addresses into function names and filters unneeded
  * functions.
  *
  * @param {Array<number>} stack Stack sample.
  */
 Profile.prototype.resolveAndFilterFuncs_ = function(stack) {
   var result = [];
   for (var i = 0; i < stack.length; ++i) {
     var entry = this.codeMap_.findEntry(stack[i]);
     if (entry) {
       var name = entry.getName();
       if (!this.skipThisFunction(name)) {
         result.push(name);
       }
     } else {
       this.handleUnknownCode(
           Profile.Operation.TICK, stack[i], i);
     }
   }
   return result;
 };


 /**
  * Performs a BF traversal of the top down call graph.
  *
  * @param {function(CallTree.Node)} f Visitor function.
  */
 Profile.prototype.traverseTopDownTree = function(f) {
   this.topDownTree_.traverse(f);
 };


 /**
  * Performs a BF traversal of the bottom up call graph.
  *
  * @param {function(CallTree.Node)} f Visitor function.
  */
 Profile.prototype.traverseBottomUpTree = function(f) {
   this.bottomUpTree_.traverse(f);
 };


 /**
  * Calculates a top down profile for a node with the specified label.
  * If no name specified, returns the whole top down calls tree.
  *
  * @param {string} opt_label Node label.
  */
 Profile.prototype.getTopDownProfile = function(opt_label) {
   return this.getTreeProfile_(this.topDownTree_, opt_label);
 };


 /**
  * Calculates a bottom up profile for a node with the specified label.
  * If no name specified, returns the whole bottom up calls tree.
  *
  * @param {string} opt_label Node label.
  */
 Profile.prototype.getBottomUpProfile = function(opt_label) {
   return this.getTreeProfile_(this.bottomUpTree_, opt_label);
 };


 /**
  * Helper function for calculating a tree profile.
  *
  * @param {Profile.CallTree} tree Call tree.
  * @param {string} opt_label Node label.
  */
 Profile.prototype.getTreeProfile_ = function(tree, opt_label) {
   if (!opt_label) {
     tree.computeTotalWeights();
     return tree;
   } else {
     var subTree = tree.cloneSubtree(opt_label);
     subTree.computeTotalWeights();
     return subTree;
   }
 };


 /**
  * Calculates a flat profile of callees starting from a node with
  * the specified label. If no name specified, starts from the root.
  *
  * @param {string} opt_label Starting node label.
  */
 Profile.prototype.getFlatProfile = function(opt_label) {
   var counters = new CallTree();
   var rootLabel = opt_label || CallTree.ROOT_NODE_LABEL;
   var precs = {};
   precs[rootLabel] = 0;
   var root = counters.findOrAddChild(rootLabel);

   this.topDownTree_.computeTotalWeights();
   this.topDownTree_.traverseInDepth(
     function onEnter(node) {
       if (!(node.label in precs)) {
         precs[node.label] = 0;
       }
       var nodeLabelIsRootLabel = node.label == rootLabel;
       if (nodeLabelIsRootLabel || precs[rootLabel] > 0) {
         if (precs[rootLabel] == 0) {
           root.selfWeight += node.selfWeight;
           root.totalWeight += node.totalWeight;
         } else {
           var rec = root.findOrAddChild(node.label);
           rec.selfWeight += node.selfWeight;
           if (nodeLabelIsRootLabel || precs[node.label] == 0) {
             rec.totalWeight += node.totalWeight;
           }
         }
         precs[node.label]++;
       }
     },
     function onExit(node) {
       if (node.label == rootLabel || precs[rootLabel] > 0) {
         precs[node.label]--;
       }
     },
     null);

   if (!opt_label) {
     // If we have created a flat profile for the whole program, we don't
     // need an explicit root in it. Thus, replace the counters tree
     // root with the node corresponding to the whole program.
     counters.root_ = root;
   } else {
     // Propagate weights so percents can be calculated correctly.
     counters.getRoot().selfWeight = root.selfWeight;
     counters.getRoot().totalWeight = root.totalWeight;
   }
   return counters;
 };


 /**
  * Cleans up function entries that are not referenced by code entries.
  */
 Profile.prototype.cleanUpFuncEntries = function() {
   var referencedFuncEntries = [];
   var entries = this.codeMap_.getAllDynamicEntriesWithAddresses();
   for (var i = 0, l = entries.length; i < l; ++i) {
     if (entries[i][1].constructor === Profile.FunctionEntry) {
       entries[i][1].used = false;
     }
   }
   for (var i = 0, l = entries.length; i < l; ++i) {
     if ("func" in entries[i][1]) {
       entries[i][1].func.used = true;
     }
   }
   for (var i = 0, l = entries.length; i < l; ++i) {
     if (entries[i][1].constructor === Profile.FunctionEntry &&
         !entries[i][1].used) {
       this.codeMap_.deleteCode(entries[i][0]);
     }
   }
 };


 /**
  * Creates a dynamic code entry.
  *
  * @param {number} size Code size.
  * @param {string} type Code type.
  * @param {string} name Function name.
  * @constructor
  */
 Profile.DynamicCodeEntry = function(size, type, name) {
   CodeMap.CodeEntry.call(this, size, name);
   this.type = type;
 };


 /**
  * Returns node name.
  */
 Profile.DynamicCodeEntry.prototype.getName = function() {
   return this.type + ': ' + this.name;
 };


 /**
  * Returns raw node name (without type decoration).
  */
 Profile.DynamicCodeEntry.prototype.getRawName = function() {
   return this.name;
 };


 Profile.DynamicCodeEntry.prototype.isJSFunction = function() {
   return false;
 };


 Profile.DynamicCodeEntry.prototype.toString = function() {
   return this.getName() + ': ' + this.size.toString(16);
 };


 /**
  * Creates a dynamic code entry.
  *
  * @param {number} size Code size.
  * @param {string} type Code type.
  * @param {Profile.FunctionEntry} func Shared function entry.
  * @param {Profile.CodeState} state Code optimization state.
  * @constructor
  */
 Profile.DynamicFuncCodeEntry = function(size, type, func, state) {
   CodeMap.CodeEntry.call(this, size);
   this.type = type;
   this.func = func;
   this.state = state;
 };

 Profile.DynamicFuncCodeEntry.STATE_PREFIX = ["", "~", "*"];

 /**
  * Returns node name.
  */
 Profile.DynamicFuncCodeEntry.prototype.getName = function() {
   var name = this.func.getName();
   return this.type + ': ' + Profile.DynamicFuncCodeEntry.STATE_PREFIX[this.state] + name;
 };


 /**
  * Returns raw node name (without type decoration).
  */
 Profile.DynamicFuncCodeEntry.prototype.getRawName = function() {
   return this.func.getName();
 };


 Profile.DynamicFuncCodeEntry.prototype.isJSFunction = function() {
   return true;
 };


 Profile.DynamicFuncCodeEntry.prototype.toString = function() {
   return this.getName() + ': ' + this.size.toString(16);
 };


 /**
  * Creates a shared function object entry.
  *
  * @param {string} name Function name.
  * @constructor
  */
 Profile.FunctionEntry = function(name) {
   CodeMap.CodeEntry.call(this, 0, name);
 };


 /**
  * Returns node name.
  */
 Profile.FunctionEntry.prototype.getName = function() {
   var name = this.name;
   if (name.length == 0) {
     name = '<anonymous>';
   } else if (name.charAt(0) == ' ') {
     // An anonymous function with location: " aaa.js:10".
     name = '<anonymous>' + name;
   }
   return name;
 };

 Profile.FunctionEntry.prototype.toString = CodeMap.CodeEntry.prototype.toString;

 /**
  * Constructs a call graph.
  *
  * @constructor
  */
 function CallTree() {
   this.root_ = new CallTree.Node(
       CallTree.ROOT_NODE_LABEL);
 };


 /**
  * The label of the root node.
  */
 CallTree.ROOT_NODE_LABEL = '';


 /**
  * @private
  */
 CallTree.prototype.totalsComputed_ = false;


 /**
  * Returns the tree root.
  */
 CallTree.prototype.getRoot = function() {
   return this.root_;
 };


 /**
  * Adds the specified call path, constructing nodes as necessary.
  *
  * @param {Array<string>} path Call path.
  */
 CallTree.prototype.addPath = function(path) {
   if (path.length == 0) {
     return;
   }
   var curr = this.root_;
   for (var i = 0; i < path.length; ++i) {
     curr = curr.findOrAddChild(path[i]);
   }
   curr.selfWeight++;
   this.totalsComputed_ = false;
 };


 /**
  * Finds an immediate child of the specified parent with the specified
  * label, creates a child node if necessary. If a parent node isn't
  * specified, uses tree root.
  *
  * @param {string} label Child node label.
  */
 CallTree.prototype.findOrAddChild = function(label) {
   return this.root_.findOrAddChild(label);
 };


 /**
  * Creates a subtree by cloning and merging all subtrees rooted at nodes
  * with a given label. E.g. cloning the following call tree on label 'A'
  * will give the following result:
  *
  *           <A>--<B>                                     <B>
  *          /                                            /
  *     <root>             == clone on 'A' ==>  <root>--<A>
  *          \                                            \
  *           <C>--<A>--<D>                                <D>
  *
  * And <A>'s selfWeight will be the sum of selfWeights of <A>'s from the
  * source call tree.
  *
  * @param {string} label The label of the new root node.
  */
 CallTree.prototype.cloneSubtree = function(label) {
   var subTree = new CallTree();
   this.traverse(function(node, parent) {
     if (!parent && node.label != label) {
       return null;
     }
     var child = (parent ? parent : subTree).findOrAddChild(node.label);
     child.selfWeight += node.selfWeight;
     return child;
   });
   return subTree;
 };


 /**
  * Computes total weights in the call graph.
  */
 CallTree.prototype.computeTotalWeights = function() {
   if (this.totalsComputed_) {
     return;
   }
   this.root_.computeTotalWeight();
   this.totalsComputed_ = true;
 };


 /**
  * Traverses the call graph in preorder. This function can be used for
  * building optionally modified tree clones. This is the boilerplate code
  * for this scenario:
  *
  * callTree.traverse(function(node, parentClone) {
  *   var nodeClone = cloneNode(node);
  *   if (parentClone)
  *     parentClone.addChild(nodeClone);
  *   return nodeClone;
  * });
  *
  * @param {function(CallTree.Node, *)} f Visitor function.
  *    The second parameter is the result of calling 'f' on the parent node.
  */
 CallTree.prototype.traverse = function(f) {
   var pairsToProcess = new ConsArray();
   pairsToProcess.concat([{node: this.root_, param: null}]);
   while (!pairsToProcess.atEnd()) {
     var pair = pairsToProcess.next();
     var node = pair.node;
     var newParam = f(node, pair.param);
     var morePairsToProcess = [];
     node.forEachChild(function (child) {
         morePairsToProcess.push({node: child, param: newParam}); });
     pairsToProcess.concat(morePairsToProcess);
   }
 };


 /**
  * Performs an indepth call graph traversal.
  *
  * @param {function(CallTree.Node)} enter A function called
  *     prior to visiting node's children.
  * @param {function(CallTree.Node)} exit A function called
  *     after visiting node's children.
  */
 CallTree.prototype.traverseInDepth = function(enter, exit) {
   function traverse(node) {
     enter(node);
     node.forEachChild(traverse);
     exit(node);
   }
   traverse(this.root_);
 };


 /**
  * Constructs a call graph node.
  *
  * @param {string} label Node label.
  * @param {CallTree.Node} opt_parent Node parent.
  */
 CallTree.Node = function(label, opt_parent) {
   this.label = label;
   this.parent = opt_parent;
   this.children = {};
 };


 /**
  * Node self weight (how many times this node was the last node in
  * a call path).
  * @type {number}
  */
 CallTree.Node.prototype.selfWeight = 0;


 /**
  * Node total weight (includes weights of all children).
  * @type {number}
  */
 CallTree.Node.prototype.totalWeight = 0;


 /**
  * Adds a child node.
  *
  * @param {string} label Child node label.
  */
 CallTree.Node.prototype.addChild = function(label) {
   var child = new CallTree.Node(label, this);
   this.children[label] = child;
   return child;
 };


 /**
  * Computes node's total weight.
  */
 CallTree.Node.prototype.computeTotalWeight =
     function() {
   var totalWeight = this.selfWeight;
   this.forEachChild(function(child) {
       totalWeight += child.computeTotalWeight(); });
   return this.totalWeight = totalWeight;
 };


 /**
  * Returns all node's children as an array.
  */
 CallTree.Node.prototype.exportChildren = function() {
   var result = [];
   this.forEachChild(function (node) { result.push(node); });
   return result;
 };


 /**
  * Finds an immediate child with the specified label.
  *
  * @param {string} label Child node label.
  */
 CallTree.Node.prototype.findChild = function(label) {
   return this.children[label] || null;
 };


 /**
  * Finds an immediate child with the specified label, creates a child
  * node if necessary.
  *
  * @param {string} label Child node label.
  */
 CallTree.Node.prototype.findOrAddChild = function(label) {
   return this.findChild(label) || this.addChild(label);
 };


 /**
  * Calls the specified function for every child.
  *
  * @param {function(CallTree.Node)} f Visitor function.
  */
 CallTree.Node.prototype.forEachChild = function(f) {
   for (var c in this.children) {
     f(this.children[c]);
   }
 };


 /**
  * Walks up from the current node up to the call tree root.
  *
  * @param {function(CallTree.Node)} f Visitor function.
  */
 CallTree.Node.prototype.walkUpToRoot = function(f) {
   for (var curr = this; curr != null; curr = curr.parent) {
     f(curr);
   }
 };


 /**
  * Tries to find a node with the specified path.
  *
  * @param {Array<string>} labels The path.
  * @param {function(CallTree.Node)} opt_f Visitor function.
  */
 CallTree.Node.prototype.descendToChild = function(
     labels, opt_f) {
   for (var pos = 0, curr = this; pos < labels.length && curr != null; pos++) {
     var child = curr.findChild(labels[pos]);
     if (opt_f) {
       opt_f(child, pos);
     }
     curr = child;
   }
   return curr;
 };
	// Copyright 2009 the V8 project authors. All rights reserved.
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are
	// met:
	//
	// * Redistributions of source code must retain the above copyright
	// notice, this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above
	// copyright notice, this list of conditions and the following
	// disclaimer in the documentation and/or other materials provided
	// with the distribution.
	// * Neither the name of Google Inc. nor the names of its
	// contributors may be used to endorse or promote products derived
	// from this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.


	/**
	* Creates a profile object for processing profiling-related events
	* and calculating function execution times.
	*
	* @constructor
	*/
	function Profile() {
	this.codeMap_ = new CodeMap();
	this.topDownTree_ = new CallTree();
	this.bottomUpTree_ = new CallTree();
	};


	/**
	* Returns whether a function with the specified name must be skipped.
	* Should be overriden by subclasses.
	*
	* @param {string} name Function name.
	*/
	Profile.prototype.skipThisFunction = function(name) {
	return false;
	};


	/**
	* Enum for profiler operations that involve looking up existing
	* code entries.
	*
	* @enum {number}
	*/
	Profile.Operation = {
	MOVE: 0,
	DELETE: 1,
	TICK: 2
	};


	/**
	* Enum for code state regarding its dynamic optimization.
	*
	* @enum {number}
	*/
	Profile.CodeState = {
	COMPILED: 0,
	OPTIMIZABLE: 1,
	OPTIMIZED: 2
	};


	/**
	* Called whenever the specified operation has failed finding a function
	* containing the specified address. Should be overriden by subclasses.
	* See the Profile.Operation enum for the list of
	* possible operations.
	*
	* @param {number} operation Operation.
	* @param {number} addr Address of the unknown code.
	* @param {number} opt_stackPos If an unknown address is encountered
	* during stack strace processing, specifies a position of the frame
	* containing the address.
	*/
	Profile.prototype.handleUnknownCode = function(
	operation, addr, opt_stackPos) {
	};


	/**
	* Registers a library.
	*
	* @param {string} name Code entry name.
	* @param {number} startAddr Starting address.
	* @param {number} endAddr Ending address.
	*/
	Profile.prototype.addLibrary = function(
	name, startAddr, endAddr) {
	var entry = new CodeMap.CodeEntry(
	endAddr - startAddr, name);
	this.codeMap_.addLibrary(startAddr, entry);
	return entry;
	};


	/**
	* Registers statically compiled code entry.
	*
	* @param {string} name Code entry name.
	* @param {number} startAddr Starting address.
	* @param {number} endAddr Ending address.
	*/
	Profile.prototype.addStaticCode = function(
	name, startAddr, endAddr) {
	var entry = new CodeMap.CodeEntry(
	endAddr - startAddr, name);
	this.codeMap_.addStaticCode(startAddr, entry);
	return entry;
	};


	/**
	* Registers dynamic (JIT-compiled) code entry.
	*
	* @param {string} type Code entry type.
	* @param {string} name Code entry name.
	* @param {number} start Starting address.
	* @param {number} size Code entry size.
	*/
	Profile.prototype.addCode = function(
	type, name, start, size) {
	var entry = new Profile.DynamicCodeEntry(size, type, name);
	this.codeMap_.addCode(start, entry);
	return entry;
	};


	/**
	* Registers dynamic (JIT-compiled) code entry.
	*
	* @param {string} type Code entry type.
	* @param {string} name Code entry name.
	* @param {number} start Starting address.
	* @param {number} size Code entry size.
	* @param {number} funcAddr Shared function object address.
	* @param {Profile.CodeState} state Optimization state.
	*/
	Profile.prototype.addFuncCode = function(
	type, name, start, size, funcAddr, state) {
	// As code and functions are in the same address space,
	// it is safe to put them in a single code map.
	var func = this.codeMap_.findDynamicEntryByStartAddress(funcAddr);
	if (!func) {
	func = new Profile.FunctionEntry(name);
	this.codeMap_.addCode(funcAddr, func);
	} else if (func.name !== name) {
	// Function object has been overwritten with a new one.
	func.name = name;
	}
	var entry = this.codeMap_.findDynamicEntryByStartAddress(start);
	if (entry) {
	if (entry.size === size && entry.func === func) {
	// Entry state has changed.
	entry.state = state;
	}
	} else {
	entry = new Profile.DynamicFuncCodeEntry(size, type, func, state);
	this.codeMap_.addCode(start, entry);
	}
	return entry;
	};


	/**
	* Reports about moving of a dynamic code entry.
	*
	* @param {number} from Current code entry address.
	* @param {number} to New code entry address.
	*/
	Profile.prototype.moveCode = function(from, to) {
	try {
	this.codeMap_.moveCode(from, to);
	} catch (e) {
	this.handleUnknownCode(Profile.Operation.MOVE, from);
	}
	};


	/**
	* Reports about deletion of a dynamic code entry.
	*
	* @param {number} start Starting address.
	*/
	Profile.prototype.deleteCode = function(start) {
	try {
	this.codeMap_.deleteCode(start);
	} catch (e) {
	this.handleUnknownCode(Profile.Operation.DELETE, start);
	}
	};


	/**
	* Reports about moving of a dynamic code entry.
	*
	* @param {number} from Current code entry address.
	* @param {number} to New code entry address.
	*/
	Profile.prototype.moveFunc = function(from, to) {
	if (this.codeMap_.findDynamicEntryByStartAddress(from)) {
	this.codeMap_.moveCode(from, to);
	}
	};


	/**
	* Retrieves a code entry by an address.
	*
	* @param {number} addr Entry address.
	*/
	Profile.prototype.findEntry = function(addr) {
	return this.codeMap_.findEntry(addr);
	};


	/**
	* Records a tick event. Stack must contain a sequence of
	* addresses starting with the program counter value.
	*
	* @param {Array<number>} stack Stack sample.
	*/
	Profile.prototype.recordTick = function(stack) {
	var processedStack = this.resolveAndFilterFuncs_(stack);
	this.bottomUpTree_.addPath(processedStack);
	processedStack.reverse();
	this.topDownTree_.addPath(processedStack);
	};


	/**
	* Translates addresses into function names and filters unneeded
	* functions.
	*
	* @param {Array<number>} stack Stack sample.
	*/
	Profile.prototype.resolveAndFilterFuncs_ = function(stack) {
	var result = [];
	for (var i = 0; i < stack.length; ++i) {
	var entry = this.codeMap_.findEntry(stack[i]);
	if (entry) {
	var name = entry.getName();
	if (!this.skipThisFunction(name)) {
	result.push(name);
	}
	} else {
	this.handleUnknownCode(
	Profile.Operation.TICK, stack[i], i);
	}
	}
	return result;
	};


	/**
	* Performs a BF traversal of the top down call graph.
	*
	* @param {function(CallTree.Node)} f Visitor function.
	*/
	Profile.prototype.traverseTopDownTree = function(f) {
	this.topDownTree_.traverse(f);
	};


	/**
	* Performs a BF traversal of the bottom up call graph.
	*
	* @param {function(CallTree.Node)} f Visitor function.
	*/
	Profile.prototype.traverseBottomUpTree = function(f) {
	this.bottomUpTree_.traverse(f);
	};


	/**
	* Calculates a top down profile for a node with the specified label.
	* If no name specified, returns the whole top down calls tree.
	*
	* @param {string} opt_label Node label.
	*/
	Profile.prototype.getTopDownProfile = function(opt_label) {
	return this.getTreeProfile_(this.topDownTree_, opt_label);
	};


	/**
	* Calculates a bottom up profile for a node with the specified label.
	* If no name specified, returns the whole bottom up calls tree.
	*
	* @param {string} opt_label Node label.
	*/
	Profile.prototype.getBottomUpProfile = function(opt_label) {
	return this.getTreeProfile_(this.bottomUpTree_, opt_label);
	};


	/**
	* Helper function for calculating a tree profile.
	*
	* @param {Profile.CallTree} tree Call tree.
	* @param {string} opt_label Node label.
	*/
	Profile.prototype.getTreeProfile_ = function(tree, opt_label) {
	if (!opt_label) {
	tree.computeTotalWeights();
	return tree;
	} else {
	var subTree = tree.cloneSubtree(opt_label);
	subTree.computeTotalWeights();
	return subTree;
	}
	};


	/**
	* Calculates a flat profile of callees starting from a node with
	* the specified label. If no name specified, starts from the root.
	*
	* @param {string} opt_label Starting node label.
	*/
	Profile.prototype.getFlatProfile = function(opt_label) {
	var counters = new CallTree();
	var rootLabel = opt_label \|\| CallTree.ROOT_NODE_LABEL;
	var precs = {};
	precs[rootLabel] = 0;
	var root = counters.findOrAddChild(rootLabel);

	this.topDownTree_.computeTotalWeights();
	this.topDownTree_.traverseInDepth(
	function onEnter(node) {
	if (!(node.label in precs)) {
	precs[node.label] = 0;
	}
	var nodeLabelIsRootLabel = node.label == rootLabel;
	if (nodeLabelIsRootLabel \|\| precs[rootLabel] > 0) {
	if (precs[rootLabel] == 0) {
	root.selfWeight += node.selfWeight;
	root.totalWeight += node.totalWeight;
	} else {
	var rec = root.findOrAddChild(node.label);
	rec.selfWeight += node.selfWeight;
	if (nodeLabelIsRootLabel \|\| precs[node.label] == 0) {
	rec.totalWeight += node.totalWeight;
	}
	}
	precs[node.label]++;
	}
	},
	function onExit(node) {
	if (node.label == rootLabel \|\| precs[rootLabel] > 0) {
	precs[node.label]--;
	}
	},
	null);

	if (!opt_label) {
	// If we have created a flat profile for the whole program, we don't
	// need an explicit root in it. Thus, replace the counters tree
	// root with the node corresponding to the whole program.
	counters.root_ = root;
	} else {
	// Propagate weights so percents can be calculated correctly.
	counters.getRoot().selfWeight = root.selfWeight;
	counters.getRoot().totalWeight = root.totalWeight;
	}
	return counters;
	};


	/**
	* Cleans up function entries that are not referenced by code entries.
	*/
	Profile.prototype.cleanUpFuncEntries = function() {
	var referencedFuncEntries = [];
	var entries = this.codeMap_.getAllDynamicEntriesWithAddresses();
	for (var i = 0, l = entries.length; i < l; ++i) {
	if (entries[i][1].constructor === Profile.FunctionEntry) {
	entries[i][1].used = false;
	}
	}
	for (var i = 0, l = entries.length; i < l; ++i) {
	if ("func" in entries[i][1]) {
	entries[i][1].func.used = true;
	}
	}
	for (var i = 0, l = entries.length; i < l; ++i) {
	if (entries[i][1].constructor === Profile.FunctionEntry &&
	!entries[i][1].used) {
	this.codeMap_.deleteCode(entries[i][0]);
	}
	}
	};


	/**
	* Creates a dynamic code entry.
	*
	* @param {number} size Code size.
	* @param {string} type Code type.
	* @param {string} name Function name.
	* @constructor
	*/
	Profile.DynamicCodeEntry = function(size, type, name) {
	CodeMap.CodeEntry.call(this, size, name);
	this.type = type;
	};


	/**
	* Returns node name.
	*/
	Profile.DynamicCodeEntry.prototype.getName = function() {
	return this.type + ': ' + this.name;
	};


	/**
	* Returns raw node name (without type decoration).
	*/
	Profile.DynamicCodeEntry.prototype.getRawName = function() {
	return this.name;
	};


	Profile.DynamicCodeEntry.prototype.isJSFunction = function() {
	return false;
	};


	Profile.DynamicCodeEntry.prototype.toString = function() {
	return this.getName() + ': ' + this.size.toString(16);
	};


	/**
	* Creates a dynamic code entry.
	*
	* @param {number} size Code size.
	* @param {string} type Code type.
	* @param {Profile.FunctionEntry} func Shared function entry.
	* @param {Profile.CodeState} state Code optimization state.
	* @constructor
	*/
	Profile.DynamicFuncCodeEntry = function(size, type, func, state) {
	CodeMap.CodeEntry.call(this, size);
	this.type = type;
	this.func = func;
	this.state = state;
	};

	Profile.DynamicFuncCodeEntry.STATE_PREFIX = ["", "~", "*"];

	/**
	* Returns node name.
	*/
	Profile.DynamicFuncCodeEntry.prototype.getName = function() {
	var name = this.func.getName();
	return this.type + ': ' + Profile.DynamicFuncCodeEntry.STATE_PREFIX[this.state] + name;
	};


	/**
	* Returns raw node name (without type decoration).
	*/
	Profile.DynamicFuncCodeEntry.prototype.getRawName = function() {
	return this.func.getName();
	};


	Profile.DynamicFuncCodeEntry.prototype.isJSFunction = function() {
	return true;
	};


	Profile.DynamicFuncCodeEntry.prototype.toString = function() {
	return this.getName() + ': ' + this.size.toString(16);
	};


	/**
	* Creates a shared function object entry.
	*
	* @param {string} name Function name.
	* @constructor
	*/
	Profile.FunctionEntry = function(name) {
	CodeMap.CodeEntry.call(this, 0, name);
	};


	/**
	* Returns node name.
	*/
	Profile.FunctionEntry.prototype.getName = function() {
	var name = this.name;
	if (name.length == 0) {
	name = '<anonymous>';
	} else if (name.charAt(0) == ' ') {
	// An anonymous function with location: " aaa.js:10".
	name = '<anonymous>' + name;
	}
	return name;
	};

	Profile.FunctionEntry.prototype.toString = CodeMap.CodeEntry.prototype.toString;

	/**
	* Constructs a call graph.
	*
	* @constructor
	*/
	function CallTree() {
	this.root_ = new CallTree.Node(
	CallTree.ROOT_NODE_LABEL);
	};


	/**
	* The label of the root node.
	*/
	CallTree.ROOT_NODE_LABEL = '';


	/**
	* @private
	*/
	CallTree.prototype.totalsComputed_ = false;


	/**
	* Returns the tree root.
	*/
	CallTree.prototype.getRoot = function() {
	return this.root_;
	};


	/**
	* Adds the specified call path, constructing nodes as necessary.
	*
	* @param {Array<string>} path Call path.
	*/
	CallTree.prototype.addPath = function(path) {
	if (path.length == 0) {
	return;
	}
	var curr = this.root_;
	for (var i = 0; i < path.length; ++i) {
	curr = curr.findOrAddChild(path[i]);
	}
	curr.selfWeight++;
	this.totalsComputed_ = false;
	};


	/**
	* Finds an immediate child of the specified parent with the specified
	* label, creates a child node if necessary. If a parent node isn't
	* specified, uses tree root.
	*
	* @param {string} label Child node label.
	*/
	CallTree.prototype.findOrAddChild = function(label) {
	return this.root_.findOrAddChild(label);
	};


	/**
	* Creates a subtree by cloning and merging all subtrees rooted at nodes
	* with a given label. E.g. cloning the following call tree on label 'A'
	* will give the following result:
	*
	* <A>--<B> <B>
	* / /
	* <root> == clone on 'A' ==> <root>--<A>
	* \ \
	* <C>--<A>--<D> <D>
	*
	* And <A>'s selfWeight will be the sum of selfWeights of <A>'s from the
	* source call tree.
	*
	* @param {string} label The label of the new root node.
	*/
	CallTree.prototype.cloneSubtree = function(label) {
	var subTree = new CallTree();
	this.traverse(function(node, parent) {
	if (!parent && node.label != label) {
	return null;
	}
	var child = (parent ? parent : subTree).findOrAddChild(node.label);
	child.selfWeight += node.selfWeight;
	return child;
	});
	return subTree;
	};


	/**
	* Computes total weights in the call graph.
	*/
	CallTree.prototype.computeTotalWeights = function() {
	if (this.totalsComputed_) {
	return;
	}
	this.root_.computeTotalWeight();
	this.totalsComputed_ = true;
	};


	/**
	* Traverses the call graph in preorder. This function can be used for
	* building optionally modified tree clones. This is the boilerplate code
	* for this scenario:
	*
	* callTree.traverse(function(node, parentClone) {
	* var nodeClone = cloneNode(node);
	* if (parentClone)
	* parentClone.addChild(nodeClone);
	* return nodeClone;
	* });
	*
	* @param {function(CallTree.Node, *)} f Visitor function.
	* The second parameter is the result of calling 'f' on the parent node.
	*/
	CallTree.prototype.traverse = function(f) {
	var pairsToProcess = new ConsArray();
	pairsToProcess.concat([{node: this.root_, param: null}]);
	while (!pairsToProcess.atEnd()) {
	var pair = pairsToProcess.next();
	var node = pair.node;
	var newParam = f(node, pair.param);
	var morePairsToProcess = [];
	node.forEachChild(function (child) {
	morePairsToProcess.push({node: child, param: newParam}); });
	pairsToProcess.concat(morePairsToProcess);
	}
	};


	/**
	* Performs an indepth call graph traversal.
	*
	* @param {function(CallTree.Node)} enter A function called
	* prior to visiting node's children.
	* @param {function(CallTree.Node)} exit A function called
	* after visiting node's children.
	*/
	CallTree.prototype.traverseInDepth = function(enter, exit) {
	function traverse(node) {
	enter(node);
	node.forEachChild(traverse);
	exit(node);
	}
	traverse(this.root_);
	};


	/**
	* Constructs a call graph node.
	*
	* @param {string} label Node label.
	* @param {CallTree.Node} opt_parent Node parent.
	*/
	CallTree.Node = function(label, opt_parent) {
	this.label = label;
	this.parent = opt_parent;
	this.children = {};
	};


	/**
	* Node self weight (how many times this node was the last node in
	* a call path).
	* @type {number}
	*/
	CallTree.Node.prototype.selfWeight = 0;


	/**
	* Node total weight (includes weights of all children).
	* @type {number}
	*/
	CallTree.Node.prototype.totalWeight = 0;


	/**
	* Adds a child node.
	*
	* @param {string} label Child node label.
	*/
	CallTree.Node.prototype.addChild = function(label) {
	var child = new CallTree.Node(label, this);
	this.children[label] = child;
	return child;
	};


	/**
	* Computes node's total weight.
	*/
	CallTree.Node.prototype.computeTotalWeight =
	function() {
	var totalWeight = this.selfWeight;
	this.forEachChild(function(child) {
	totalWeight += child.computeTotalWeight(); });
	return this.totalWeight = totalWeight;
	};


	/**
	* Returns all node's children as an array.
	*/
	CallTree.Node.prototype.exportChildren = function() {
	var result = [];
	this.forEachChild(function (node) { result.push(node); });
	return result;
	};


	/**
	* Finds an immediate child with the specified label.
	*
	* @param {string} label Child node label.
	*/
	CallTree.Node.prototype.findChild = function(label) {
	return this.children[label] \|\| null;
	};


	/**
	* Finds an immediate child with the specified label, creates a child
	* node if necessary.
	*
	* @param {string} label Child node label.
	*/
	CallTree.Node.prototype.findOrAddChild = function(label) {
	return this.findChild(label) \|\| this.addChild(label);
	};


	/**
	* Calls the specified function for every child.
	*
	* @param {function(CallTree.Node)} f Visitor function.
	*/
	CallTree.Node.prototype.forEachChild = function(f) {
	for (var c in this.children) {
	f(this.children[c]);
	}
	};


	/**
	* Walks up from the current node up to the call tree root.
	*
	* @param {function(CallTree.Node)} f Visitor function.
	*/
	CallTree.Node.prototype.walkUpToRoot = function(f) {
	for (var curr = this; curr != null; curr = curr.parent) {
	f(curr);
	}
	};


	/**
	* Tries to find a node with the specified path.
	*
	* @param {Array<string>} labels The path.
	* @param {function(CallTree.Node)} opt_f Visitor function.
	*/
	CallTree.Node.prototype.descendToChild = function(
	labels, opt_f) {
	for (var pos = 0, curr = this; pos < labels.length && curr != null; pos++) {
	var child = curr.findChild(labels[pos]);
	if (opt_f) {
	opt_f(child, pos);
	}
	curr = child;
	}
	return curr;
	};