/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*-
* vim: set ts=8 sts=2 et sw=2 tw=80:
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "builtin/Eval.h"
#include "mozilla/HashFunctions.h"
#include "mozilla/Range.h"
#include "frontend/BytecodeCompiler.h" // frontend::CompileEvalScript
#include "gc/HashUtil.h"
#include "js/CompilationAndEvaluation.h"
#include "js/EnvironmentChain.h" // JS::EnvironmentChain
#include "js/friend/ErrorMessages.h" // js::GetErrorMessage, JSMSG_*
#include "js/friend/JSMEnvironment.h" // JS::NewJSMEnvironment, JS::ExecuteInJSMEnvironment, JS::GetJSMEnvironmentOfScriptedCaller, JS::IsJSMEnvironment
#include "js/friend/WindowProxy.h" // js::IsWindowProxy
#include "js/SourceText.h"
#include "js/StableStringChars.h"
#include "vm/EnvironmentObject.h"
#include "vm/FrameIter.h"
#include "vm/GlobalObject.h"
#include "vm/Interpreter.h"
#include "vm/JSContext.h"
#include "vm/JSONParser.h"
#include "gc/Marking-inl.h"
#include "vm/EnvironmentObject-inl.h"
#include "vm/JSContext-inl.h"
#include "vm/Stack-inl.h"
using namespace js;
using mozilla::AddToHash;
using JS::AutoCheckCannotGC;
using JS::AutoStableStringChars;
using JS::CompileOptions;
using JS::SourceText;
// We should be able to assert this for *any* fp->environmentChain().
static void AssertInnerizedEnvironmentChain(JSContext* cx, JSObject& env) {
#ifdef DEBUG
RootedObject obj(cx);
for (obj = &env; obj; obj = obj->enclosingEnvironment()) {
MOZ_ASSERT(!IsWindowProxy(obj));
}
#endif
}
static bool IsEvalCacheCandidate(JSScript* script) {
if (!script->isDirectEvalInFunction()) {
return false;
}
// Make sure there are no inner objects (which may be used directly by script
// and clobbered) or inner functions (which may have wrong scope).
for (JS::GCCellPtr gcThing : script->gcthings()) {
if (gcThing.is<JSObject>()) {
return false;
}
}
return true;
}
/* static */
HashNumber EvalCacheHashPolicy::hash(
const EvalCacheLookup& l) {
HashNumber hash = HashStringChars(l.str);
return AddToHash(hash, l.callerScript, l.pc);
}
/* static */
bool EvalCacheHashPolicy::match(
const EvalCacheEntry& cacheEntry,
const EvalCacheLookup& l) {
MOZ_ASSERT(IsEvalCacheCandidate(cacheEntry.script));
return EqualStrings(cacheEntry.str, l.str) &&
cacheEntry.callerScript == l.callerScript && cacheEntry.pc == l.pc;
}
void EvalCacheLookup::trace(JSTracer* trc) {
TraceNullableRoot(trc, &str,
"EvalCacheLookup::str");
TraceNullableRoot(trc, &callerScript,
"EvalCacheLookup::callerScript");
}
// Add the script to the eval cache when EvalKernel is finished
class EvalScriptGuard {
JSContext* cx_;
Rooted<JSScript*> script_;
/* These fields are only valid if lookup_.str is non-nullptr. */
Rooted<EvalCacheLookup> lookup_;
mozilla::Maybe<DependentAddPtr<EvalCache>> p_;
Rooted<JSLinearString*> lookupStr_;
public:
explicit EvalScriptGuard(JSContext* cx)
: cx_(cx), script_(cx), lookup_(cx), lookupStr_(cx) {}
~EvalScriptGuard() {
if (script_ && !cx_->isExceptionPending()) {
script_->cacheForEval();
EvalCacheLookup& lookup = lookup_.get();
EvalCacheEntry cacheEntry = {lookupStr_, script_, lookup.callerScript,
lookup.pc};
lookup.str = lookupStr_;
if (lookup.str && IsEvalCacheCandidate(script_)) {
// Ignore failure to add cache entry.
if (!p_->add(cx_, cx_->caches().evalCache, lookup, cacheEntry)) {
cx_->recoverFromOutOfMemory();
}
}
}
}
void lookupInEvalCache(JSLinearString* str, JSScript* callerScript,
jsbytecode* pc) {
lookupStr_ = str;
EvalCacheLookup& lookup = lookup_.get();
lookup.str = str;
lookup.callerScript = callerScript;
lookup.pc = pc;
p_.emplace(cx_, cx_->caches().evalCache, lookup);
if (*p_) {
script_ = (*p_)->script;
p_->remove(cx_, cx_->caches().evalCache, lookup);
}
}
void setNewScript(JSScript* script) {
// JSScript::fullyInitFromStencil has already called js_CallNewScriptHook.
MOZ_ASSERT(!script_ && script);
script_ = script;
}
bool foundScript() {
return !!script_; }
HandleScript script() {
MOZ_ASSERT(script_);
return script_;
}
};
enum class EvalJSONResult { Failure, Success, NotJSON };
template <
typename CharT>
static bool EvalStringMightBeJSON(
const mozilla::Range<
const CharT> chars) {
// If the eval string starts with '(' or '[' and ends with ')' or ']', it
// may be JSON. Try the JSON parser first because it's much faster. If
// the eval string isn't JSON, JSON parsing will probably fail quickly, so
// little time will be lost.
size_t length = chars.length();
if (length < 2) {
return false;
}
// It used to be that strings in JavaScript forbid U+2028 LINE SEPARATOR
// and U+2029 PARAGRAPH SEPARATOR, so something like
//
// eval("['" + "\u2028" + "']");
//
// i.e. an array containing a string with a line separator in it, *would*
// be JSON but *would not* be valid JavaScript. Handing such a string to
// the JSON parser would then fail to recognize a syntax error. As of
// <https://tc39.github.io/proposal-json-superset/> JavaScript strings may
// contain these two code points, so it's safe to JSON-parse eval strings
// that contain them.
CharT first = chars[0], last = chars[length - 1];
return (first ==
'[' && last ==
']') || (first ==
'(' && last ==
')');
}
template <
typename CharT>
static EvalJSONResult ParseEvalStringAsJSON(
JSContext* cx,
const mozilla::Range<
const CharT> chars,
MutableHandleValue rval) {
size_t len = chars.length();
MOZ_ASSERT((chars[0] ==
'(' && chars[len - 1] ==
')') ||
(chars[0] ==
'[' && chars[len - 1] ==
']'));
auto jsonChars = (chars[0] ==
'[') ? chars
: mozilla::Range<
const CharT>(
chars.begin().get() + 1U, len - 2);
Rooted<JSONParser<CharT>> parser(
cx, cx, jsonChars, JSONParser<CharT>::ParseType::AttemptForEval);
if (!parser.parse(rval)) {
return EvalJSONResult::Failure;
}
return rval.isUndefined() ? EvalJSONResult::NotJSON : EvalJSONResult::Success;
}
static EvalJSONResult TryEvalJSON(JSContext* cx, JSLinearString* str,
MutableHandleValue rval) {
if (str->hasLatin1Chars()) {
AutoCheckCannotGC nogc;
if (!EvalStringMightBeJSON(str->latin1Range(nogc))) {
return EvalJSONResult::NotJSON;
}
}
else {
AutoCheckCannotGC nogc;
if (!EvalStringMightBeJSON(str->twoByteRange(nogc))) {
return EvalJSONResult::NotJSON;
}
}
AutoStableStringChars linearChars(cx);
if (!linearChars.init(cx, str)) {
return EvalJSONResult::Failure;
}
return linearChars.isLatin1()
? ParseEvalStringAsJSON(cx, linearChars.latin1Range(), rval)
: ParseEvalStringAsJSON(cx, linearChars.twoByteRange(), rval);
}
enum EvalType { DIRECT_EVAL, INDIRECT_EVAL };
// 18.2.1.1 PerformEval
//
// Common code implementing direct and indirect eval.
//
// Evaluate v, if it is a string, in the context of the given calling
// frame, with the provided scope chain, with the semantics of either a direct
// or indirect eval (see ES5 10.4.2). If this is an indirect eval, env
// must be the global lexical environment.
//
// On success, store the completion value in call.rval and return true.
static bool EvalKernel(JSContext* cx, HandleValue v, EvalType evalType,
AbstractFramePtr caller, HandleObject env,
jsbytecode* pc, MutableHandleValue vp) {
MOZ_ASSERT((evalType == INDIRECT_EVAL) == !caller);
MOZ_ASSERT((evalType == INDIRECT_EVAL) == !pc);
MOZ_ASSERT_IF(evalType == INDIRECT_EVAL,
env->is<GlobalLexicalEnvironmentObject>());
AssertInnerizedEnvironmentChain(cx, *env);
// "Dynamic Code Brand Checks" adds support for Object values.
// https://tc39.es/proposal-dynamic-code-brand-checks/#sec-performeval
// Steps 2-4.
RootedString str(cx);
if (v.isString()) {
str = v.toString();
}
else if (v.isObject()) {
RootedObject obj(cx, &v.toObject());
if (!cx->getCodeForEval(obj, &str)) {
return false;
}
}
if (!str) {
vp.set(v);
return true;
}
// Steps 6-8.
JS::RootedVector<JSString*> parameterStrings(cx);
JS::RootedVector<Value> parameterArgs(cx);
bool canCompileStrings =
false;
if (!cx->isRuntimeCodeGenEnabled(
JS::RuntimeCode::JS, str,
evalType == DIRECT_EVAL ? JS::CompilationType::DirectEval
: JS::CompilationType::IndirectEval,
parameterStrings, str, parameterArgs, v, &canCompileStrings)) {
return false;
}
if (!canCompileStrings) {
JS_ReportErrorNumberASCII(cx, GetErrorMessage, nullptr,
JSMSG_CSP_BLOCKED_EVAL);
return false;
}
// Step 9 ff.
// Per ES5, indirect eval runs in the global scope. (eval is specified this
// way so that the compiler can make assumptions about what bindings may or
// may not exist in the current frame if it doesn't see 'eval'.)
MOZ_ASSERT_IF(
evalType != DIRECT_EVAL,
cx->global() == &env->as<GlobalLexicalEnvironmentObject>().global());
Rooted<JSLinearString*> linearStr(cx, str->ensureLinear(cx));
if (!linearStr) {
return false;
}
RootedScript callerScript(cx, caller ? caller.script() : nullptr);
EvalJSONResult ejr = TryEvalJSON(cx, linearStr, vp);
if (ejr != EvalJSONResult::NotJSON) {
return ejr == EvalJSONResult::Success;
}
EvalScriptGuard esg(cx);
if (evalType == DIRECT_EVAL && caller.isFunctionFrame()) {
esg.lookupInEvalCache(linearStr, callerScript, pc);
}
if (!esg.foundScript()) {
RootedScript maybeScript(cx);
uint32_t lineno;
const char* filename;
bool mutedErrors;
uint32_t pcOffset;
if (evalType == DIRECT_EVAL) {
DescribeScriptedCallerForDirectEval(cx, callerScript, pc, &filename,
&lineno, &pcOffset, &mutedErrors);
maybeScript = callerScript;
}
else {
DescribeScriptedCallerForCompilation(cx, &maybeScript, &filename, &lineno,
&pcOffset, &mutedErrors);
}
const char* introducerFilename = filename;
if (maybeScript && maybeScript->scriptSource()->introducerFilename()) {
introducerFilename = maybeScript->scriptSource()->introducerFilename();
}
Rooted<Scope*> enclosing(cx);
if (evalType == DIRECT_EVAL) {
enclosing = callerScript->innermostScope(pc);
}
else {
enclosing = &cx->global()->emptyGlobalScope();
}
CompileOptions options(cx);
options.setIsRunOnce(
true)
.setNoScriptRval(
false)
.setMutedErrors(mutedErrors)
.setDeferDebugMetadata();
RootedScript introScript(cx);
if (evalType == DIRECT_EVAL && IsStrictEvalPC(pc)) {
options.setForceStrictMode();
}
if (introducerFilename) {
options.setFileAndLine(filename, 1);
options.setIntroductionInfo(introducerFilename,
"eval", lineno, pcOffset);
introScript = maybeScript;
}
else {
options.setFileAndLine(
"eval", 1);
options.setIntroductionType(
"eval");
}
options.setNonSyntacticScope(
enclosing->hasOnChain(ScopeKind::NonSyntactic));
AutoStableStringChars linearChars(cx);
if (!linearChars.initTwoByte(cx, linearStr)) {
return false;
}
SourceText<char16_t> srcBuf;
if (!srcBuf.initMaybeBorrowed(cx, linearChars)) {
return false;
}
RootedScript script(
cx, frontend::CompileEvalScript(cx, options, srcBuf, enclosing, env));
if (!script) {
return false;
}
RootedValue undefValue(cx);
JS::InstantiateOptions instantiateOptions(options);
if (!JS::UpdateDebugMetadata(cx, script, instantiateOptions, undefValue,
nullptr, introScript, maybeScript)) {
return false;
}
esg.setNewScript(script);
}
return ExecuteKernel(cx, esg.script(), env, NullFramePtr()
/* evalInFrame */,
vp);
}
bool js::IndirectEval(JSContext* cx,
unsigned argc, Value* vp) {
CallArgs args = CallArgsFromVp(argc, vp);
RootedObject globalLexical(cx, &cx->global()->lexicalEnvironment());
// Note we'll just pass |undefined| here, then return it directly (or throw
// if runtime codegen is disabled), if no argument is provided.
return EvalKernel(cx, args.get(0), INDIRECT_EVAL, NullFramePtr(),
globalLexical, nullptr, args.rval());
}
bool js::DirectEval(JSContext* cx, HandleValue v, MutableHandleValue vp) {
// Direct eval can assume it was called from an interpreted or baseline frame.
ScriptFrameIter iter(cx);
AbstractFramePtr caller = iter.abstractFramePtr();
MOZ_ASSERT(JSOp(*iter.pc()) == JSOp::Eval ||
JSOp(*iter.pc()) == JSOp::StrictEval ||
JSOp(*iter.pc()) == JSOp::SpreadEval ||
JSOp(*iter.pc()) == JSOp::StrictSpreadEval);
MOZ_ASSERT(caller.realm() == caller.script()->realm());
RootedObject envChain(cx, caller.environmentChain());
return EvalKernel(cx, v, DIRECT_EVAL, caller, envChain, iter.pc(), vp);
}
bool js::IsAnyBuiltinEval(JSFunction* fun) {
return fun->maybeNative() == IndirectEval;
}
static bool ExecuteInExtensibleLexicalEnvironment(
JSContext* cx, HandleScript scriptArg,
Handle<ExtensibleLexicalEnvironmentObject*> env) {
CHECK_THREAD(cx);
cx->check(env);
cx->check(scriptArg);
MOZ_RELEASE_ASSERT(scriptArg->hasNonSyntacticScope());
RootedValue rval(cx);
return ExecuteKernel(cx, scriptArg, env, NullFramePtr()
/* evalInFrame */,
&rval);
}
JS_PUBLIC_API
bool js::ExecuteInFrameScriptEnvironment(
JSContext* cx, HandleObject objArg, HandleScript scriptArg,
MutableHandleObject envArg) {
Rooted<NonSyntacticVariablesObject*> varEnv(
cx, NonSyntacticVariablesObject::create(cx));
if (!varEnv) {
return false;
}
JS::EnvironmentChain envChain(cx, JS::SupportUnscopables::No);
if (!envChain.append(objArg)) {
return false;
}
Rooted<WithEnvironmentObject*> env(
cx, js::CreateObjectsForEnvironmentChain(cx, envChain, varEnv));
if (!env) {
return false;
}
// Create lexical environment with |this| == objArg, which should be a Gecko
// MessageManager.
// NOTE: This is required behavior for Gecko FrameScriptLoader, where some
// callers try to bind methods from the message manager in their scope chain
// to |this|, and will fail if it is not bound to a message manager.
ObjectRealm& realm = ObjectRealm::get(varEnv);
Rooted<NonSyntacticLexicalEnvironmentObject*> lexicalEnv(
cx, realm.getOrCreateNonSyntacticLexicalEnvironment(cx, env, varEnv));
if (!lexicalEnv) {
return false;
}
if (!ExecuteInExtensibleLexicalEnvironment(cx, scriptArg, lexicalEnv)) {
return false;
}
envArg.set(lexicalEnv);
return true;
}
JS_PUBLIC_API JSObject* JS::NewJSMEnvironment(JSContext* cx) {
Rooted<NonSyntacticVariablesObject*> varEnv(
cx, NonSyntacticVariablesObject::create(cx));
if (!varEnv) {
return nullptr;
}
// Force the NonSyntacticLexicalEnvironmentObject to be created.
ObjectRealm& realm = ObjectRealm::get(varEnv);
MOZ_ASSERT(!realm.getNonSyntacticLexicalEnvironment(varEnv));
if (!realm.getOrCreateNonSyntacticLexicalEnvironment(cx, varEnv)) {
return nullptr;
}
return varEnv;
}
JS_PUBLIC_API
bool JS::ExecuteInJSMEnvironment(JSContext* cx,
HandleScript scriptArg,
HandleObject varEnv) {
JS::EnvironmentChain emptyChain(cx, JS::SupportUnscopables::No);
return ExecuteInJSMEnvironment(cx, scriptArg, varEnv, emptyChain);
}
JS_PUBLIC_API
bool JS::ExecuteInJSMEnvironment(
JSContext* cx, HandleScript scriptArg, HandleObject varEnv,
const EnvironmentChain& targetObj) {
cx->check(varEnv);
MOZ_ASSERT(
ObjectRealm::get(varEnv).getNonSyntacticLexicalEnvironment(varEnv));
MOZ_DIAGNOSTIC_ASSERT(scriptArg->noScriptRval());
Rooted<ExtensibleLexicalEnvironmentObject*> env(
cx, ExtensibleLexicalEnvironmentObject::forVarEnvironment(varEnv));
// If the Gecko subscript loader specifies target objects, we need to add
// them to the environment. These are added after the NSVO environment.
if (!targetObj.empty()) {
// The environment chain will be as follows:
// GlobalObject / SystemGlobal
// GlobalLexicalEnvironmentObject[this=global]
// NonSyntacticVariablesObject (the JSMEnvironment)
// NonSyntacticLexicalEnvironmentObject[this=nsvo]
// WithEnvironmentObject[target=targetObj]
// NonSyntacticLexicalEnvironmentObject[this=targetObj] (*)
//
// (*) This environment intercepts JSOp::GlobalThis.
// Wrap the target objects in WithEnvironments.
Rooted<WithEnvironmentObject*> envChain(
cx, js::CreateObjectsForEnvironmentChain(cx, targetObj, env));
if (!envChain) {
return false;
}
// See CreateNonSyntacticEnvironmentChain
if (!JSObject::setQualifiedVarObj(cx, envChain)) {
return false;
}
// Create an extensible lexical environment for the target object.
env = ObjectRealm::get(envChain).getOrCreateNonSyntacticLexicalEnvironment(
cx, envChain);
if (!env) {
return false;
}
}
return ExecuteInExtensibleLexicalEnvironment(cx, scriptArg, env);
}
JS_PUBLIC_API JSObject* JS::GetJSMEnvironmentOfScriptedCaller(JSContext* cx) {
FrameIter iter(cx);
if (iter.done()) {
return nullptr;
}
// WASM frames don't always provide their environment, but we also shouldn't
// expect to see any calling into here.
MOZ_RELEASE_ASSERT(!iter.isWasm());
RootedObject env(cx, iter.environmentChain(cx));
while (env && !env->is<NonSyntacticVariablesObject>()) {
env = env->enclosingEnvironment();
}
return env;
}
JS_PUBLIC_API
bool JS::IsJSMEnvironment(JSObject* obj) {
// NOTE: This also returns true if the NonSyntacticVariablesObject was
// created for reasons other than the JSM loader.
return obj->is<NonSyntacticVariablesObject>();
}
#ifdef JSGC_HASH_TABLE_CHECKS
void RuntimeCaches::checkEvalCacheAfterMinorGC() {
gc::CheckTableAfterMovingGC(evalCache, [](
const auto& entry) {
CheckGCThingAfterMovingGC(entry.str);
CheckGCThingAfterMovingGC(entry.script);
CheckGCThingAfterMovingGC(entry.callerScript);
return EvalCacheLookup(entry.str, entry.callerScript, entry.pc);
});
}
#endif
