v8/tools/profile.mjs
Mythri A aac25548c2 [tools,turboprop] Extend profview to show turboprop information
This cl extends profview to
1. Show Turboprop ticks in a different color in timeline panel
2. In summary panel, show Turboprop optimizations and TurboFan
optimizations as two different entries
3. Fix deopts in summary panel after the rename to deopts
4. Also show information about bailouts (happen only with Turboprop)

Bug: v8:9684
Change-Id: I028b12a55741c789ecc1d212d1517a57496379dc
Reviewed-on: https://chromium-review.googlesource.com/c/v8/v8/+/2573477
Commit-Queue: Mythri Alle <mythria@chromium.org>
Reviewed-by: Ross McIlroy <rmcilroy@chromium.org>
Reviewed-by: Camillo Bruni <cbruni@chromium.org>
Cr-Commit-Position: refs/heads/master@{#71638}
2020-12-07 10:17:25 +00:00

1238 lines
33 KiB
JavaScript

// 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.
import { CodeMap, CodeEntry } from "./codemap.mjs";
import { ConsArray } from "./consarray.mjs";
// Used to associate log entries with source positions in scripts.
// TODO: move to separate modules
export class SourcePosition {
constructor(script, line, column) {
this.script = script;
this.line = line;
this.column = column;
this.entries = [];
}
addEntry(entry) {
this.entries.push(entry);
}
}
export class Script {
name;
source;
// Map<line, Map<column, SourcePosition>>
lineToColumn = new Map();
_entries = [];
constructor(id) {
this.id = id;
this.sourcePositions = [];
}
update(name, source) {
this.name = name;
this.source = source;
}
get length() {
return this.source.length;
}
get entries() {
return this._entries;
}
addSourcePosition(line, column, entry) {
let sourcePosition = this.lineToColumn.get(line)?.get(column);
if (sourcePosition === undefined) {
sourcePosition = new SourcePosition(this, line, column, )
this._addSourcePosition(line, column, sourcePosition);
}
sourcePosition.addEntry(entry);
this._entries.push(entry);
return sourcePosition;
}
_addSourcePosition(line, column, sourcePosition) {
let columnToSourcePosition;
if (this.lineToColumn.has(line)) {
columnToSourcePosition = this.lineToColumn.get(line);
} else {
columnToSourcePosition = new Map();
this.lineToColumn.set(line, columnToSourcePosition);
}
this.sourcePositions.push(sourcePosition);
columnToSourcePosition.set(column, sourcePosition);
}
}
class SourceInfo {
script;
start;
end;
positions;
inlined ;
fns;
disassemble;
setSourcePositionInfo(script, startPos, endPos, sourcePositionTable, inliningPositions, inlinedFunctions) {
this.script = script;
this.start = startPos;
this.end = endPos;
this.positions = sourcePositionTable;
this.inlined = inliningPositions;
this.fns = inlinedFunctions;
}
setDisassemble(code) {
this.disassemble = code;
}
getSourceCode() {
return this.script.source?.substring(this.start, this.end);
}
}
/**
* Creates a profile object for processing profiling-related events
* and calculating function execution times.
*
* @constructor
*/
export class Profile {
codeMap_ = new CodeMap();
topDownTree_ = new CallTree();
bottomUpTree_ = new CallTree();
c_entries_ = {};
ticks_ = [];
scripts_ = [];
urlToScript_ = new Map();
/**
* Returns whether a function with the specified name must be skipped.
* Should be overriden by subclasses.
*
* @param {string} name Function name.
*/
skipThisFunction(name) {
return false;
}
/**
* Enum for profiler operations that involve looking up existing
* code entries.
*
* @enum {number}
*/
static Operation = {
MOVE: 0,
DELETE: 1,
TICK: 2
}
/**
* Enum for code state regarding its dynamic optimization.
*
* @enum {number}
*/
static CodeState = {
COMPILED: 0,
IGNITION: 1,
NATIVE_CONTEXT_INDEPENDENT: 2,
TURBOPROP: 3,
TURBOFAN: 4,
}
/**
* Parser for dynamic code optimization state.
*/
static parseState(s) {
switch (s) {
case '':
return this.CodeState.COMPILED;
case '~':
return this.CodeState.IGNITION;
case '-':
return this.CodeState.NATIVE_CONTEXT_INDEPENDENT;
case '+':
return this.CodeState.TURBOPROP;
case '*':
return this.CodeState.TURBOFAN;
}
throw new Error(`unknown code state: ${s}`);
}
static getKindFromState(state) {
if (state === this.CodeState.COMPILED) {
return "Builtin";
} else if (state === this.CodeState.IGNITION) {
return "Unopt";
} else if (state === this.CodeState.NATIVE_CONTEXT_INDEPENDENT) {
return "NCI";
} else if (state === this.CodeState.TURBOPROP) {
return "Turboprop";
} else if (state === this.CodeState.TURBOFAN) {
return "Opt";
}
throw new Error(`unknown code state: ${state}`);
}
/**
* 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.
*/
handleUnknownCode(operation, addr, opt_stackPos) {}
/**
* Registers a library.
*
* @param {string} name Code entry name.
* @param {number} startAddr Starting address.
* @param {number} endAddr Ending address.
*/
addLibrary(name, startAddr, endAddr) {
const entry = new CodeEntry(endAddr - startAddr, name, 'SHARED_LIB');
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.
*/
addStaticCode(name, startAddr, endAddr) {
const entry = new CodeEntry(endAddr - startAddr, name, 'CPP');
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.
*/
addCode(type, name, timestamp, start, size) {
const entry = new 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.
*/
addFuncCode(type, name, timestamp, 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.
let func = this.codeMap_.findDynamicEntryByStartAddress(funcAddr);
if (!func) {
func = new FunctionEntry(name);
this.codeMap_.addCode(funcAddr, func);
} else if (func.name !== name) {
// Function object has been overwritten with a new one.
func.name = name;
}
let entry = this.codeMap_.findDynamicEntryByStartAddress(start);
if (entry) {
if (entry.size === size && entry.func === func) {
// Entry state has changed.
entry.state = state;
} else {
this.codeMap_.deleteCode(start);
entry = null;
}
}
if (!entry) {
entry = new 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.
*/
moveCode(from, to) {
try {
this.codeMap_.moveCode(from, to);
} catch (e) {
this.handleUnknownCode(Profile.Operation.MOVE, from);
}
}
deoptCode(timestamp, code, inliningId, scriptOffset, bailoutType,
sourcePositionText, deoptReasonText) {
}
/**
* Reports about deletion of a dynamic code entry.
*
* @param {number} start Starting address.
*/
deleteCode(start) {
try {
this.codeMap_.deleteCode(start);
} catch (e) {
this.handleUnknownCode(Profile.Operation.DELETE, start);
}
}
/**
* Adds source positions for given code.
*/
addSourcePositions(start, scriptId, startPos, endPos, sourcePositionTable,
inliningPositions, inlinedFunctions) {
const script = this.getOrCreateScript(scriptId);
const entry = this.codeMap_.findDynamicEntryByStartAddress(start);
if (!entry) return;
// Resolve the inlined functions list.
if (inlinedFunctions.length > 0) {
inlinedFunctions = inlinedFunctions.substring(1).split("S");
for (let i = 0; i < inlinedFunctions.length; i++) {
const funcAddr = parseInt(inlinedFunctions[i]);
const func = this.codeMap_.findDynamicEntryByStartAddress(funcAddr);
if (!func || func.funcId === undefined) {
// TODO: fix
console.warn(`Could not find function ${inlinedFunctions[i]}`);
inlinedFunctions[i] = null;
} else {
inlinedFunctions[i] = func.funcId;
}
}
} else {
inlinedFunctions = [];
}
this.getOrCreateSourceInfo(entry).setSourcePositionInfo(
script, startPos, endPos, sourcePositionTable, inliningPositions,
inlinedFunctions);
}
addDisassemble(start, kind, disassemble) {
const entry = this.codeMap_.findDynamicEntryByStartAddress(start);
if (!entry) return;
this.getOrCreateSourceInfo(entry).setDisassemble(disassemble);
}
getOrCreateSourceInfo(entry) {
return entry.source ?? (entry.source = new SourceInfo());
}
addScriptSource(id, url, source) {
const script = this.getOrCreateScript(id);
script.update(url, source);
this.urlToScript_.set(url, script);
}
getOrCreateScript(id) {
let script = this.scripts_[id];
if (!script) {
script = new Script(id);
this.scripts_[id] = script;
}
return script;
}
getScript(url) {
return this.urlToScript_.get(url);
}
/**
* Reports about moving of a dynamic code entry.
*
* @param {number} from Current code entry address.
* @param {number} to New code entry address.
*/
moveFunc(from, to) {
if (this.codeMap_.findDynamicEntryByStartAddress(from)) {
this.codeMap_.moveCode(from, to);
}
}
/**
* Retrieves a code entry by an address.
*
* @param {number} addr Entry address.
*/
findEntry(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.
*/
recordTick(time_ns, vmState, stack) {
const 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.
*/
resolveAndFilterFuncs_(stack) {
const result = [];
let last_seen_c_function = '';
let look_for_first_c_function = false;
for (let i = 0; i < stack.length; ++i) {
const entry = this.codeMap_.findEntry(stack[i]);
if (entry) {
const name = entry.getName();
if (i === 0 && (entry.type === 'CPP' || entry.type === 'SHARED_LIB')) {
look_for_first_c_function = true;
}
if (look_for_first_c_function && entry.type === 'CPP') {
last_seen_c_function = name;
}
if (!this.skipThisFunction(name)) {
result.push(name);
}
} else {
this.handleUnknownCode(Profile.Operation.TICK, stack[i], i);
if (i === 0) result.push("UNKNOWN");
}
if (look_for_first_c_function &&
i > 0 &&
(!entry || entry.type !== 'CPP') &&
last_seen_c_function !== '') {
if (this.c_entries_[last_seen_c_function] === undefined) {
this.c_entries_[last_seen_c_function] = 0;
}
this.c_entries_[last_seen_c_function]++;
look_for_first_c_function = false; // Found it, we're done.
}
}
return result;
}
/**
* Performs a BF traversal of the top down call graph.
*
* @param {function(CallTreeNode)} f Visitor function.
*/
traverseTopDownTree(f) {
this.topDownTree_.traverse(f);
}
/**
* Performs a BF traversal of the bottom up call graph.
*
* @param {function(CallTreeNode)} f Visitor function.
*/
traverseBottomUpTree(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.
*/
getTopDownProfile(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.
*/
getBottomUpProfile(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.
*/
getTreeProfile_(tree, opt_label) {
if (!opt_label) {
tree.computeTotalWeights();
return tree;
} else {
const 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.
*/
getFlatProfile(opt_label) {
const counters = new CallTree();
const rootLabel = opt_label || CallTree.ROOT_NODE_LABEL;
const precs = {};
precs[rootLabel] = 0;
const root = counters.findOrAddChild(rootLabel);
this.topDownTree_.computeTotalWeights();
this.topDownTree_.traverseInDepth(
function onEnter(node) {
if (!(node.label in precs)) {
precs[node.label] = 0;
}
const nodeLabelIsRootLabel = node.label == rootLabel;
if (nodeLabelIsRootLabel || precs[rootLabel] > 0) {
if (precs[rootLabel] == 0) {
root.selfWeight += node.selfWeight;
root.totalWeight += node.totalWeight;
} else {
const 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;
}
getCEntryProfile() {
const result = [new CEntryNode("TOTAL", 0)];
let total_ticks = 0;
for (let f in this.c_entries_) {
const ticks = this.c_entries_[f];
total_ticks += ticks;
result.push(new CEntryNode(f, ticks));
}
result[0].ticks = total_ticks; // Sorting will keep this at index 0.
result.sort((n1, n2) => n2.ticks - n1.ticks || (n2.name < n1.name ? -1 : 1));
return result;
}
/**
* Cleans up function entries that are not referenced by code entries.
*/
cleanUpFuncEntries() {
const referencedFuncEntries = [];
const entries = this.codeMap_.getAllDynamicEntriesWithAddresses();
for (let i = 0, l = entries.length; i < l; ++i) {
if (entries[i][1].constructor === FunctionEntry) {
entries[i][1].used = false;
}
}
for (let i = 0, l = entries.length; i < l; ++i) {
if ("func" in entries[i][1]) {
entries[i][1].func.used = true;
}
}
for (let i = 0, l = entries.length; i < l; ++i) {
if (entries[i][1].constructor === FunctionEntry &&
!entries[i][1].used) {
this.codeMap_.deleteCode(entries[i][0]);
}
}
}
}
class CEntryNode {
constructor(name, ticks) {
this.name = name;
this.ticks = ticks;
}
}
/**
* Creates a dynamic code entry.
*
* @param {number} size Code size.
* @param {string} type Code type.
* @param {string} name Function name.
* @constructor
*/
class DynamicCodeEntry extends CodeEntry {
constructor(size, type, name) {
super(size, name, type);
}
getName() {
return this.type + ': ' + this.name;
}
/**
* Returns raw node name (without type decoration).
*/
getRawName() {
return this.name;
}
isJSFunction() {
return false;
}
toString() {
return this.getName() + ': ' + this.size.toString(16);
}
}
/**
* Creates a dynamic code entry.
*
* @param {number} size Code size.
* @param {string} type Code type.
* @param {FunctionEntry} func Shared function entry.
* @param {Profile.CodeState} state Code optimization state.
* @constructor
*/
class DynamicFuncCodeEntry extends CodeEntry {
constructor(size, type, func, state) {
super(size, '', type);
this.func = func;
func.addDynamicCode(this);
this.state = state;
}
getSourceCode() {
return this.source?.getSourceCode();
}
static STATE_PREFIX = ["", "~", "-", "+", "*"];
getState() {
return DynamicFuncCodeEntry.STATE_PREFIX[this.state];
}
getName() {
const name = this.func.getName();
return this.type + ': ' + this.getState() + name;
}
/**
* Returns raw node name (without type decoration).
*/
getRawName() {
return this.func.getName();
}
isJSFunction() {
return true;
}
toString() {
return this.getName() + ': ' + this.size.toString(16);
}
}
/**
* Creates a shared function object entry.
*
* @param {string} name Function name.
* @constructor
*/
class FunctionEntry extends CodeEntry {
// Contains the list of generated code for this function.
_codeEntries = new Set();
constructor(name) {
super(0, name);
}
addDynamicCode(code) {
if (code.func != this) {
throw new Error("Adding dynamic code to wrong function");
}
this._codeEntries.add(code);
}
getSourceCode() {
// All code entries should map to the same source positions.
return this._codeEntries.values().next().value.getSourceCode();
}
/**
* Returns node name.
*/
getName() {
let 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;
}
}
/**
* Constructs a call graph.
*
* @constructor
*/
class CallTree {
root_ = new CallTreeNode(CallTree.ROOT_NODE_LABEL);
totalsComputed_ = false;
/**
* The label of the root node.
*/
static ROOT_NODE_LABEL = '';
/**
* Returns the tree root.
*/
getRoot() {
return this.root_;
}
/**
* Adds the specified call path, constructing nodes as necessary.
*
* @param {Array<string>} path Call path.
*/
addPath(path) {
if (path.length == 0) {
return;
}
let curr = this.root_;
for (let 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.
*/
findOrAddChild(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.
*/
cloneSubtree(label) {
const subTree = new CallTree();
this.traverse((node, parent) => {
if (!parent && node.label != label) {
return null;
}
const child = (parent ? parent : subTree).findOrAddChild(node.label);
child.selfWeight += node.selfWeight;
return child;
});
return subTree;
}
/**
* Computes total weights in the call graph.
*/
computeTotalWeights() {
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(CallTreeNode, *)} f Visitor function.
* The second parameter is the result of calling 'f' on the parent node.
*/
traverse(f) {
const pairsToProcess = new ConsArray();
pairsToProcess.concat([{ node: this.root_, param: null }]);
while (!pairsToProcess.atEnd()) {
const pair = pairsToProcess.next();
const node = pair.node;
const newParam = f(node, pair.param);
const morePairsToProcess = [];
node.forEachChild((child) => {
morePairsToProcess.push({ node: child, param: newParam });
});
pairsToProcess.concat(morePairsToProcess);
}
}
/**
* Performs an indepth call graph traversal.
*
* @param {function(CallTreeNode)} enter A function called
* prior to visiting node's children.
* @param {function(CallTreeNode)} exit A function called
* after visiting node's children.
*/
traverseInDepth(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 {CallTreeNode} opt_parent Node parent.
*/
class CallTreeNode {
/**
* Node self weight (how many times this node was the last node in
* a call path).
* @type {number}
*/
selfWeight = 0;
/**
* Node total weight (includes weights of all children).
* @type {number}
*/
totalWeight = 0;
children = {};
constructor(label, opt_parent) {
this.label = label;
this.parent = opt_parent;
}
/**
* Adds a child node.
*
* @param {string} label Child node label.
*/
addChild(label) {
const child = new CallTreeNode(label, this);
this.children[label] = child;
return child;
}
/**
* Computes node's total weight.
*/
computeTotalWeight() {
let totalWeight = this.selfWeight;
this.forEachChild(function (child) {
totalWeight += child.computeTotalWeight();
});
return this.totalWeight = totalWeight;
}
/**
* Returns all node's children as an array.
*/
exportChildren() {
const result = [];
this.forEachChild(function (node) { result.push(node); });
return result;
}
/**
* Finds an immediate child with the specified label.
*
* @param {string} label Child node label.
*/
findChild(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.
*/
findOrAddChild(label) {
return this.findChild(label) || this.addChild(label);
}
/**
* Calls the specified function for every child.
*
* @param {function(CallTreeNode)} f Visitor function.
*/
forEachChild(f) {
for (let c in this.children) {
f(this.children[c]);
}
}
/**
* Walks up from the current node up to the call tree root.
*
* @param {function(CallTreeNode)} f Visitor function.
*/
walkUpToRoot(f) {
for (let 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(CallTreeNode)} opt_f Visitor function.
*/
descendToChild(labels, opt_f) {
let curr = this;
for (let pos = 0; pos < labels.length && curr != null; pos++) {
const child = curr.findChild(labels[pos]);
if (opt_f) {
opt_f(child, pos);
}
curr = child;
}
return curr;
}
}
export function JsonProfile() {
this.codeMap_ = new CodeMap();
this.codeEntries_ = [];
this.functionEntries_ = [];
this.ticks_ = [];
this.scripts_ = [];
}
JsonProfile.prototype.addLibrary = function (
name, startAddr, endAddr) {
const entry = new CodeEntry(
endAddr - startAddr, name, 'SHARED_LIB');
this.codeMap_.addLibrary(startAddr, entry);
entry.codeId = this.codeEntries_.length;
this.codeEntries_.push({ name: entry.name, type: entry.type });
return entry;
};
JsonProfile.prototype.addStaticCode = function (
name, startAddr, endAddr) {
const entry = new CodeEntry(
endAddr - startAddr, name, 'CPP');
this.codeMap_.addStaticCode(startAddr, entry);
entry.codeId = this.codeEntries_.length;
this.codeEntries_.push({ name: entry.name, type: entry.type });
return entry;
};
JsonProfile.prototype.addCode = function (
kind, name, timestamp, start, size) {
let codeId = this.codeEntries_.length;
// Find out if we have a static code entry for the code. If yes, we will
// make sure it is written to the JSON file just once.
let staticEntry = this.codeMap_.findAddress(start);
if (staticEntry && staticEntry.entry.type === 'CPP') {
codeId = staticEntry.entry.codeId;
}
const entry = new CodeEntry(size, name, 'CODE');
this.codeMap_.addCode(start, entry);
entry.codeId = codeId;
this.codeEntries_[codeId] = {
name: entry.name,
timestamp: timestamp,
type: entry.type,
kind: kind,
};
return entry;
};
JsonProfile.prototype.addFuncCode = function (
kind, name, timestamp, 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.
let func = this.codeMap_.findDynamicEntryByStartAddress(funcAddr);
if (!func) {
func = new CodeEntry(0, name, 'SFI');
this.codeMap_.addCode(funcAddr, func);
func.funcId = this.functionEntries_.length;
this.functionEntries_.push({ name, codes: [] });
} else if (func.name !== name) {
// Function object has been overwritten with a new one.
func.name = name;
func.funcId = this.functionEntries_.length;
this.functionEntries_.push({ name, codes: [] });
}
// TODO(jarin): Insert the code object into the SFI's code list.
let entry = this.codeMap_.findDynamicEntryByStartAddress(start);
if (entry) {
if (entry.size === size && entry.func === func) {
// Entry state has changed.
entry.state = state;
} else {
this.codeMap_.deleteCode(start);
entry = null;
}
}
if (!entry) {
entry = new CodeEntry(size, name, 'JS');
this.codeMap_.addCode(start, entry);
entry.codeId = this.codeEntries_.length;
this.functionEntries_[func.funcId].codes.push(entry.codeId);
kind = Profile.getKindFromState(state);
this.codeEntries_.push({
name: entry.name,
type: entry.type,
kind: kind,
func: func.funcId,
tm: timestamp,
});
}
return entry;
};
JsonProfile.prototype.moveCode = function (from, to) {
try {
this.codeMap_.moveCode(from, to);
} catch (e) {
printErr(`Move: unknown source ${from}`);
}
};
JsonProfile.prototype.addSourcePositions = function (
start, script, startPos, endPos, sourcePositions, inliningPositions,
inlinedFunctions) {
const entry = this.codeMap_.findDynamicEntryByStartAddress(start);
if (!entry) return;
const codeId = entry.codeId;
// Resolve the inlined functions list.
if (inlinedFunctions.length > 0) {
inlinedFunctions = inlinedFunctions.substring(1).split("S");
for (let i = 0; i < inlinedFunctions.length; i++) {
const funcAddr = parseInt(inlinedFunctions[i]);
const func = this.codeMap_.findDynamicEntryByStartAddress(funcAddr);
if (!func || func.funcId === undefined) {
printErr(`Could not find function ${inlinedFunctions[i]}`);
inlinedFunctions[i] = null;
} else {
inlinedFunctions[i] = func.funcId;
}
}
} else {
inlinedFunctions = [];
}
this.codeEntries_[entry.codeId].source = {
script: script,
start: startPos,
end: endPos,
positions: sourcePositions,
inlined: inliningPositions,
fns: inlinedFunctions
};
};
JsonProfile.prototype.addScriptSource = function (id, url, source) {
this.scripts_[id] = new Script(id, url, source);
};
JsonProfile.prototype.deoptCode = function (
timestamp, code, inliningId, scriptOffset, bailoutType,
sourcePositionText, deoptReasonText) {
let entry = this.codeMap_.findDynamicEntryByStartAddress(code);
if (entry) {
let codeId = entry.codeId;
if (!this.codeEntries_[codeId].deopt) {
// Only add the deopt if there was no deopt before.
// The subsequent deoptimizations should be lazy deopts for
// other on-stack activations.
this.codeEntries_[codeId].deopt = {
tm: timestamp,
inliningId: inliningId,
scriptOffset: scriptOffset,
posText: sourcePositionText,
reason: deoptReasonText,
bailoutType: bailoutType,
};
}
}
};
JsonProfile.prototype.deleteCode = function (start) {
try {
this.codeMap_.deleteCode(start);
} catch (e) {
printErr(`Delete: unknown address ${start}`);
}
};
JsonProfile.prototype.moveFunc = function (from, to) {
if (this.codeMap_.findDynamicEntryByStartAddress(from)) {
this.codeMap_.moveCode(from, to);
}
};
JsonProfile.prototype.findEntry = function (addr) {
return this.codeMap_.findEntry(addr);
};
JsonProfile.prototype.recordTick = function (time_ns, vmState, stack) {
// TODO(jarin) Resolve the frame-less case (when top of stack is
// known code).
const processedStack = [];
for (let i = 0; i < stack.length; i++) {
const resolved = this.codeMap_.findAddress(stack[i]);
if (resolved) {
processedStack.push(resolved.entry.codeId, resolved.offset);
} else {
processedStack.push(-1, stack[i]);
}
}
this.ticks_.push({ tm: time_ns, vm: vmState, s: processedStack });
};
function writeJson(s) {
write(JSON.stringify(s, null, 2));
}
JsonProfile.prototype.writeJson = function () {
// Write out the JSON in a partially manual way to avoid creating too-large
// strings in one JSON.stringify call when there are a lot of ticks.
write('{\n')
write(' "code": ');
writeJson(this.codeEntries_);
write(',\n');
write(' "functions": ');
writeJson(this.functionEntries_);
write(',\n');
write(' "ticks": [\n');
for (let i = 0; i < this.ticks_.length; i++) {
write(' ');
writeJson(this.ticks_[i]);
if (i < this.ticks_.length - 1) {
write(',\n');
} else {
write('\n');
}
}
write(' ],\n');
write(' "scripts": ');
writeJson(this.scripts_);
write('}\n');
};