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cobalt / cobalt / e83fce97d7405b0b5e569d961aa431b1112ac6ac / . / src / third_party / v8 / tools / profile.mjs
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// 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";
// 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 {
constructor(id, name, source) {
this.id = id;
this.name = name;
this.source = source;
this.sourcePositions = [];
// Map<line, Map<column, SourcePosition>>
this.lineToColumn = new Map();
}
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);
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);
}
}
/**
* 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,
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.
*/
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, script, startPos, endPos, sourcePositions,
inliningPositions, inlinedFunctions) {
// CLI does not need source code => ignore.
}
/**
* Adds script source code.
*/
addScriptSource(id, url, source) {
const script = new Script(id, url, source);
this.scripts_[id] = script;
this.urlToScript_.set(url, script);
}
/**
* Adds script source code.
*/
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;
this.state = state;
}
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 {
constructor(name) {
super(0, name);
}
/**
* 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);
if (state === 0) {
kind = "Builtin";
} else if (state === 1) {
kind = "Unopt";
} else if (state === 2) {
kind = "Opt";
}
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');
};