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/* -*- 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/. */
#ifndef frontend_FullParseHandler_h
#define frontend_FullParseHandler_h
#include "mozilla/Attributes.h"
#include "mozilla/Maybe.h" // mozilla::Maybe
#include "mozilla/PodOperations.h"
#include <cstddef> // std::nullptr_t
#include <string.h>
#include "frontend/FunctionSyntaxKind.h" // FunctionSyntaxKind
#include "frontend/NameAnalysisTypes.h" // PrivateNameKind
#include "frontend/ParseNode.h"
#include "frontend/SharedContext.h"
#include "frontend/Stencil.h"
#include "vm/JSContext.h"
namespace js {
class RegExpObject;
namespace frontend {
class TokenStreamAnyChars;
enum class SourceKind {
// We are parsing from a text source (Parser.h)
Text,
};
// Parse handler used when generating a full parse tree for all code which the
// parser encounters.
class FullParseHandler {
ParseNodeAllocator allocator;
ParseNode* allocParseNode(size_t size) {
return static_cast<ParseNode*>(allocator.allocNode(size));
}
/*
* If this is a full parse to construct the bytecode for a function that
* was previously lazily parsed, we still don't want to full parse the
* inner functions. These members are used for this functionality:
*
* - lazyOuterFunction_ holds the lazyScript for this current parse
* - lazyInnerFunctionIndex is used as we skip over inner functions
* (see skipLazyInnerFunction),
*
* TODO-Stencil: We probably need to snapshot the atoms from the
* lazyOuterFunction here.
*/
const Rooted<BaseScript*> lazyOuterFunction_;
size_t lazyInnerFunctionIndex;
size_t lazyClosedOverBindingIndex;
const SourceKind sourceKind_;
public:
/* new_ methods for creating parse nodes. These report OOM on context. */
JS_DECLARE_NEW_METHODS(new_, allocParseNode, inline)
// FIXME: Use ListNode instead of ListNodeType as an alias (bug 1489008).
using Node = ParseNode*;
#define DECLARE_TYPE(typeName, longTypeName, asMethodName) \
using longTypeName = typeName*;
FOR_EACH_PARSENODE_SUBCLASS(DECLARE_TYPE)
#undef DECLARE_TYPE
using NullNode = std::nullptr_t;
bool isPropertyAccess(Node node) {
return node->isKind(ParseNodeKind::DotExpr) ||
node->isKind(ParseNodeKind::ElemExpr);
}
bool isOptionalPropertyAccess(Node node) {
return node->isKind(ParseNodeKind::OptionalDotExpr) ||
node->isKind(ParseNodeKind::OptionalElemExpr);
}
bool isFunctionCall(Node node) {
// Note: super() is a special form, *not* a function call.
return node->isKind(ParseNodeKind::CallExpr);
}
static bool isUnparenthesizedDestructuringPattern(Node node) {
return !node->isInParens() && (node->isKind(ParseNodeKind::ObjectExpr) ||
node->isKind(ParseNodeKind::ArrayExpr));
}
static bool isParenthesizedDestructuringPattern(Node node) {
// Technically this isn't a destructuring pattern at all -- the grammar
// doesn't treat it as such. But we need to know when this happens to
// consider it a SyntaxError rather than an invalid-left-hand-side
// ReferenceError.
return node->isInParens() && (node->isKind(ParseNodeKind::ObjectExpr) ||
node->isKind(ParseNodeKind::ArrayExpr));
}
FullParseHandler(JSContext* cx, LifoAlloc& alloc,
BaseScript* lazyOuterFunction,
SourceKind kind = SourceKind::Text)
: allocator(cx, alloc),
lazyOuterFunction_(cx, lazyOuterFunction),
lazyInnerFunctionIndex(0),
lazyClosedOverBindingIndex(0),
sourceKind_(kind) {
// The BaseScript::gcthings() array contains the inner function list
// followed by the closed-over bindings data. Advance the index for
// closed-over bindings to the end of the inner functions. The
// nextLazyInnerFunction / nextLazyClosedOverBinding accessors confirm we
// have the expected types. See also: BaseScript::CreateLazy.
if (lazyOuterFunction) {
for (JS::GCCellPtr gcThing : lazyOuterFunction->gcthings()) {
if (gcThing.is<JSObject>()) {
lazyClosedOverBindingIndex++;
} else {
break;
}
}
}
}
static NullNode null() { return NullNode(); }
#define DECLARE_AS(typeName, longTypeName, asMethodName) \
static longTypeName asMethodName(Node node) { return &node->as<typeName>(); }
FOR_EACH_PARSENODE_SUBCLASS(DECLARE_AS)
#undef DECLARE_AS
// The FullParseHandler may be used to create nodes for text sources (from
// Parser.h). With previous binary source formats, some common assumptions on
// offsets are incorrect, e.g. in `a + b`, `a`, `b` and `+` may be stored in
// any order. We use `sourceKind()` to determine whether we need to check
// these assumptions.
SourceKind sourceKind() const { return sourceKind_; }
NameNodeType newName(const ParserName* name, const TokenPos& pos,
JSContext* cx) {
return new_<NameNode>(ParseNodeKind::Name, name, pos);
}
UnaryNodeType newComputedName(Node expr, uint32_t begin, uint32_t end) {
TokenPos pos(begin, end);
return new_<UnaryNode>(ParseNodeKind::ComputedName, pos, expr);
}
UnaryNodeType newSyntheticComputedName(Node expr, uint32_t begin,
uint32_t end) {
TokenPos pos(begin, end);
UnaryNode* node = new_<UnaryNode>(ParseNodeKind::ComputedName, pos, expr);
if (!node) {
return nullptr;
}
node->setSyntheticComputedName();
return node;
}
NameNodeType newObjectLiteralPropertyName(const ParserAtom* atom,
const TokenPos& pos) {
return new_<NameNode>(ParseNodeKind::ObjectPropertyName, atom, pos);
}
NameNodeType newPrivateName(const ParserAtom* atom, const TokenPos& pos) {
return new_<NameNode>(ParseNodeKind::PrivateName, atom, pos);
}
NumericLiteralType newNumber(double value, DecimalPoint decimalPoint,
const TokenPos& pos) {
return new_<NumericLiteral>(value, decimalPoint, pos);
}
BigIntLiteralType newBigInt(BigIntIndex index,
BaseCompilationStencil& stencil,
const TokenPos& pos) {
return new_<BigIntLiteral>(index, stencil, pos);
}
BooleanLiteralType newBooleanLiteral(bool cond, const TokenPos& pos) {
return new_<BooleanLiteral>(cond, pos);
}
NameNodeType newStringLiteral(const ParserAtom* atom, const TokenPos& pos) {
return new_<NameNode>(ParseNodeKind::StringExpr, atom, pos);
}
NameNodeType newTemplateStringLiteral(const ParserAtom* atom,
const TokenPos& pos) {
return new_<NameNode>(ParseNodeKind::TemplateStringExpr, atom, pos);
}
CallSiteNodeType newCallSiteObject(uint32_t begin) {
CallSiteNode* callSiteObj = new_<CallSiteNode>(begin);
if (!callSiteObj) {
return null();
}
ListNode* rawNodes = newArrayLiteral(callSiteObj->pn_pos.begin);
if (!rawNodes) {
return null();
}
addArrayElement(callSiteObj, rawNodes);
return callSiteObj;
}
void addToCallSiteObject(CallSiteNodeType callSiteObj, Node rawNode,
Node cookedNode) {
MOZ_ASSERT(callSiteObj->isKind(ParseNodeKind::CallSiteObj));
MOZ_ASSERT(rawNode->isKind(ParseNodeKind::TemplateStringExpr));
MOZ_ASSERT(cookedNode->isKind(ParseNodeKind::TemplateStringExpr) ||
cookedNode->isKind(ParseNodeKind::RawUndefinedExpr));
addArrayElement(callSiteObj, cookedNode);
addArrayElement(callSiteObj->rawNodes(), rawNode);
/*
* We don't know when the last noSubstTemplate will come in, and we
* don't want to deal with this outside this method
*/
setEndPosition(callSiteObj, callSiteObj->rawNodes());
}
ThisLiteralType newThisLiteral(const TokenPos& pos, Node thisName) {
return new_<ThisLiteral>(pos, thisName);
}
NullLiteralType newNullLiteral(const TokenPos& pos) {
return new_<NullLiteral>(pos);
}
RawUndefinedLiteralType newRawUndefinedLiteral(const TokenPos& pos) {
return new_<RawUndefinedLiteral>(pos);
}
RegExpLiteralType newRegExp(RegExpIndex index, const TokenPos& pos) {
return new_<RegExpLiteral>(index, pos);
}
ConditionalExpressionType newConditional(Node cond, Node thenExpr,
Node elseExpr) {
return new_<ConditionalExpression>(cond, thenExpr, elseExpr);
}
UnaryNodeType newDelete(uint32_t begin, Node expr) {
if (expr->isKind(ParseNodeKind::Name)) {
return newUnary(ParseNodeKind::DeleteNameExpr, begin, expr);
}
if (expr->isKind(ParseNodeKind::DotExpr)) {
return newUnary(ParseNodeKind::DeletePropExpr, begin, expr);
}
if (expr->isKind(ParseNodeKind::ElemExpr)) {
return newUnary(ParseNodeKind::DeleteElemExpr, begin, expr);
}
if (expr->isKind(ParseNodeKind::OptionalChain)) {
Node kid = expr->as<UnaryNode>().kid();
// Handle property deletion explicitly. OptionalCall is handled
// via DeleteExpr.
if (kid->isKind(ParseNodeKind::DotExpr) ||
kid->isKind(ParseNodeKind::OptionalDotExpr) ||
kid->isKind(ParseNodeKind::ElemExpr) ||
kid->isKind(ParseNodeKind::OptionalElemExpr)) {
return newUnary(ParseNodeKind::DeleteOptionalChainExpr, begin, kid);
}
}
return newUnary(ParseNodeKind::DeleteExpr, begin, expr);
}
UnaryNodeType newTypeof(uint32_t begin, Node kid) {
ParseNodeKind pnk = kid->isKind(ParseNodeKind::Name)
? ParseNodeKind::TypeOfNameExpr
: ParseNodeKind::TypeOfExpr;
return newUnary(pnk, begin, kid);
}
UnaryNodeType newUnary(ParseNodeKind kind, uint32_t begin, Node kid) {
TokenPos pos(begin, kid->pn_pos.end);
return new_<UnaryNode>(kind, pos, kid);
}
UnaryNodeType newUpdate(ParseNodeKind kind, uint32_t begin, Node kid) {
TokenPos pos(begin, kid->pn_pos.end);
return new_<UnaryNode>(kind, pos, kid);
}
UnaryNodeType newSpread(uint32_t begin, Node kid) {
TokenPos pos(begin, kid->pn_pos.end);
return new_<UnaryNode>(ParseNodeKind::Spread, pos, kid);
}
private:
BinaryNodeType newBinary(ParseNodeKind kind, Node left, Node right) {
TokenPos pos(left->pn_pos.begin, right->pn_pos.end);
return new_<BinaryNode>(kind, pos, left, right);
}
public:
Node appendOrCreateList(ParseNodeKind kind, Node left, Node right,
ParseContext* pc) {
return ParseNode::appendOrCreateList(kind, left, right, this, pc);
}
// Expressions
ListNodeType newArrayLiteral(uint32_t begin) {
return new_<ListNode>(ParseNodeKind::ArrayExpr, TokenPos(begin, begin + 1));
}
MOZ_MUST_USE bool addElision(ListNodeType literal, const TokenPos& pos) {
MOZ_ASSERT(literal->isKind(ParseNodeKind::ArrayExpr));
NullaryNode* elision = new_<NullaryNode>(ParseNodeKind::Elision, pos);
if (!elision) {
return false;
}
addList(/* list = */ literal, /* kid = */ elision);
literal->setHasNonConstInitializer();
return true;
}
MOZ_MUST_USE bool addSpreadElement(ListNodeType literal, uint32_t begin,
Node inner) {
MOZ_ASSERT(literal->isKind(ParseNodeKind::ArrayExpr));
UnaryNodeType spread = newSpread(begin, inner);
if (!spread) {
return false;
}
addList(/* list = */ literal, /* kid = */ spread);
literal->setHasNonConstInitializer();
return true;
}
void addArrayElement(ListNodeType literal, Node element) {
if (!element->isConstant()) {
literal->setHasNonConstInitializer();
}
addList(/* list = */ literal, /* kid = */ element);
}
CallNodeType newCall(Node callee, Node args, JSOp callOp) {
return new_<CallNode>(ParseNodeKind::CallExpr, callOp, callee, args);
}
OptionalCallNodeType newOptionalCall(Node callee, Node args, JSOp callOp) {
return new_<CallNode>(ParseNodeKind::OptionalCallExpr, callOp, callee,
args);
}
ListNodeType newArguments(const TokenPos& pos) {
return new_<ListNode>(ParseNodeKind::Arguments, pos);
}
CallNodeType newSuperCall(Node callee, Node args, bool isSpread) {
return new_<CallNode>(ParseNodeKind::SuperCallExpr,
isSpread ? JSOp::SpreadSuperCall : JSOp::SuperCall,
callee, args);
}
CallNodeType newTaggedTemplate(Node tag, Node args, JSOp callOp) {
return new_<CallNode>(ParseNodeKind::TaggedTemplateExpr, callOp, tag, args);
}
ListNodeType newObjectLiteral(uint32_t begin) {
return new_<ListNode>(ParseNodeKind::ObjectExpr,
TokenPos(begin, begin + 1));
}
ClassNodeType newClass(Node name, Node heritage,
LexicalScopeNodeType memberBlock,
const TokenPos& pos) {
return new_<ClassNode>(name, heritage, memberBlock, pos);
}
ListNodeType newClassMemberList(uint32_t begin) {
return new_<ListNode>(ParseNodeKind::ClassMemberList,
TokenPos(begin, begin + 1));
}
ClassNamesType newClassNames(Node outer, Node inner, const TokenPos& pos) {
return new_<ClassNames>(outer, inner, pos);
}
BinaryNodeType newNewTarget(NullaryNodeType newHolder,
NullaryNodeType targetHolder) {
return new_<BinaryNode>(ParseNodeKind::NewTargetExpr, newHolder,
targetHolder);
}
NullaryNodeType newPosHolder(const TokenPos& pos) {
return new_<NullaryNode>(ParseNodeKind::PosHolder, pos);
}
UnaryNodeType newSuperBase(Node thisName, const TokenPos& pos) {
return new_<UnaryNode>(ParseNodeKind::SuperBase, pos, thisName);
}
MOZ_MUST_USE bool addPrototypeMutation(ListNodeType literal, uint32_t begin,
Node expr) {
MOZ_ASSERT(literal->isKind(ParseNodeKind::ObjectExpr));
// Object literals with mutated [[Prototype]] are non-constant so that
// singleton objects will have Object.prototype as their [[Prototype]].
literal->setHasNonConstInitializer();
UnaryNode* mutation = newUnary(ParseNodeKind::MutateProto, begin, expr);
if (!mutation) {
return false;
}
addList(/* list = */ literal, /* kid = */ mutation);
return true;
}
BinaryNodeType newPropertyDefinition(Node key, Node val) {
MOZ_ASSERT(isUsableAsObjectPropertyName(key));
checkAndSetIsDirectRHSAnonFunction(val);
return new_<PropertyDefinition>(key, val, AccessorType::None);
}
void addPropertyDefinition(ListNodeType literal, BinaryNodeType propdef) {
MOZ_ASSERT(literal->isKind(ParseNodeKind::ObjectExpr));
MOZ_ASSERT(propdef->isKind(ParseNodeKind::PropertyDefinition));
if (!propdef->right()->isConstant()) {
literal->setHasNonConstInitializer();
}
addList(/* list = */ literal, /* kid = */ propdef);
}
MOZ_MUST_USE bool addPropertyDefinition(ListNodeType literal, Node key,
Node val) {
BinaryNode* propdef = newPropertyDefinition(key, val);
if (!propdef) {
return false;
}
addPropertyDefinition(literal, propdef);
return true;
}
MOZ_MUST_USE bool addShorthand(ListNodeType literal, NameNodeType name,
NameNodeType expr) {
MOZ_ASSERT(literal->isKind(ParseNodeKind::ObjectExpr));
MOZ_ASSERT(name->isKind(ParseNodeKind::ObjectPropertyName));
MOZ_ASSERT(expr->isKind(ParseNodeKind::Name));
MOZ_ASSERT(name->atom() == expr->atom());
literal->setHasNonConstInitializer();
BinaryNode* propdef = newBinary(ParseNodeKind::Shorthand, name, expr);
if (!propdef) {
return false;
}
addList(/* list = */ literal, /* kid = */ propdef);
return true;
}
MOZ_MUST_USE bool addSpreadProperty(ListNodeType literal, uint32_t begin,
Node inner) {
MOZ_ASSERT(literal->isKind(ParseNodeKind::ObjectExpr));
literal->setHasNonConstInitializer();
ParseNode* spread = newSpread(begin, inner);
if (!spread) {
return false;
}
addList(/* list = */ literal, /* kid = */ spread);
return true;
}
MOZ_MUST_USE bool addObjectMethodDefinition(ListNodeType literal, Node key,
FunctionNodeType funNode,
AccessorType atype) {
literal->setHasNonConstInitializer();
checkAndSetIsDirectRHSAnonFunction(funNode);
ParseNode* propdef =
newObjectMethodOrPropertyDefinition(key, funNode, atype);
if (!propdef) {
return false;
}
addList(/* list = */ literal, /* kid = */ propdef);
return true;
}
MOZ_MUST_USE ClassMethod* newClassMethodDefinition(
Node key, FunctionNodeType funNode, AccessorType atype, bool isStatic,
mozilla::Maybe<FunctionNodeType> initializerIfPrivate) {
MOZ_ASSERT(isUsableAsObjectPropertyName(key));
checkAndSetIsDirectRHSAnonFunction(funNode);
if (initializerIfPrivate.isSome()) {
return new_<ClassMethod>(key, funNode, atype, isStatic,
initializerIfPrivate.value());
}
return new_<ClassMethod>(key, funNode, atype, isStatic, nullptr);
}
MOZ_MUST_USE ClassField* newClassFieldDefinition(Node name,
FunctionNodeType initializer,
bool isStatic) {
MOZ_ASSERT(isUsableAsObjectPropertyName(name));
return new_<ClassField>(name, initializer, isStatic);
}
MOZ_MUST_USE bool addClassMemberDefinition(ListNodeType memberList,
Node member) {
MOZ_ASSERT(memberList->isKind(ParseNodeKind::ClassMemberList));
// Constructors can be surrounded by LexicalScopes.
MOZ_ASSERT(member->isKind(ParseNodeKind::ClassMethod) ||
member->isKind(ParseNodeKind::ClassField) ||
(member->isKind(ParseNodeKind::LexicalScope) &&
member->as<LexicalScopeNode>().scopeBody()->isKind(
ParseNodeKind::ClassMethod)));
addList(/* list = */ memberList, /* kid = */ member);
return true;
}
UnaryNodeType newInitialYieldExpression(uint32_t begin, Node gen) {
TokenPos pos(begin, begin + 1);
return new_<UnaryNode>(ParseNodeKind::InitialYield, pos, gen);
}
UnaryNodeType newYieldExpression(uint32_t begin, Node value) {
TokenPos pos(begin, value ? value->pn_pos.end : begin + 1);
return new_<UnaryNode>(ParseNodeKind::YieldExpr, pos, value);
}
UnaryNodeType newYieldStarExpression(uint32_t begin, Node value) {
TokenPos pos(begin, value->pn_pos.end);
return new_<UnaryNode>(ParseNodeKind::YieldStarExpr, pos, value);
}
UnaryNodeType newAwaitExpression(uint32_t begin, Node value) {
TokenPos pos(begin, value ? value->pn_pos.end : begin + 1);
return new_<UnaryNode>(ParseNodeKind::AwaitExpr, pos, value);
}
UnaryNodeType newOptionalChain(uint32_t begin, Node value) {
TokenPos pos(begin, value->pn_pos.end);
return new_<UnaryNode>(ParseNodeKind::OptionalChain, pos, value);
}
// Statements
ListNodeType newStatementList(const TokenPos& pos) {
return new_<ListNode>(ParseNodeKind::StatementList, pos);
}
MOZ_MUST_USE bool isFunctionStmt(Node stmt) {
while (stmt->isKind(ParseNodeKind::LabelStmt)) {
stmt = stmt->as<LabeledStatement>().statement();
}
return stmt->is<FunctionNode>();
}
void addStatementToList(ListNodeType list, Node stmt) {
MOZ_ASSERT(list->isKind(ParseNodeKind::StatementList));
addList(/* list = */ list, /* kid = */ stmt);
if (isFunctionStmt(stmt)) {
// Notify the emitter that the block contains body-level function
// definitions that should be processed before the rest of nodes.
list->setHasTopLevelFunctionDeclarations();
}
}
void setListEndPosition(ListNodeType list, const TokenPos& pos) {
MOZ_ASSERT(list->isKind(ParseNodeKind::StatementList));
list->pn_pos.end = pos.end;
}
void addCaseStatementToList(ListNodeType list, CaseClauseType caseClause) {
MOZ_ASSERT(list->isKind(ParseNodeKind::StatementList));
addList(/* list = */ list, /* kid = */ caseClause);
if (caseClause->statementList()->hasTopLevelFunctionDeclarations()) {
list->setHasTopLevelFunctionDeclarations();
}
}
MOZ_MUST_USE bool prependInitialYield(ListNodeType stmtList, Node genName) {
MOZ_ASSERT(stmtList->isKind(ParseNodeKind::StatementList));
TokenPos yieldPos(stmtList->pn_pos.begin, stmtList->pn_pos.begin + 1);
NullaryNode* makeGen =
new_<NullaryNode>(ParseNodeKind::Generator, yieldPos);
if (!makeGen) {
return false;
}
ParseNode* genInit =
newAssignment(ParseNodeKind::AssignExpr, /* lhs = */ genName,
/* rhs = */ makeGen);
if (!genInit) {
return false;
}
UnaryNode* initialYield =
newInitialYieldExpression(yieldPos.begin, genInit);
if (!initialYield) {
return false;
}
stmtList->prepend(initialYield);
return true;
}
BinaryNodeType newSetThis(Node thisName, Node value) {
return newBinary(ParseNodeKind::SetThis, thisName, value);
}
NullaryNodeType newEmptyStatement(const TokenPos& pos) {
return new_<NullaryNode>(ParseNodeKind::EmptyStmt, pos);
}
BinaryNodeType newImportDeclaration(Node importSpecSet, Node moduleSpec,
const TokenPos& pos) {
return new_<BinaryNode>(ParseNodeKind::ImportDecl, pos, importSpecSet,
moduleSpec);
}
BinaryNodeType newImportSpec(Node importNameNode, Node bindingName) {
return newBinary(ParseNodeKind::ImportSpec, importNameNode, bindingName);
}
UnaryNodeType newExportDeclaration(Node kid, const TokenPos& pos) {
return new_<UnaryNode>(ParseNodeKind::ExportStmt, pos, kid);
}
BinaryNodeType newExportFromDeclaration(uint32_t begin, Node exportSpecSet,
Node moduleSpec) {
BinaryNode* decl = new_<BinaryNode>(ParseNodeKind::ExportFromStmt,
exportSpecSet, moduleSpec);
if (!decl) {
return nullptr;
}
decl->pn_pos.begin = begin;
return decl;
}
BinaryNodeType newExportDefaultDeclaration(Node kid, Node maybeBinding,
const TokenPos& pos) {
if (maybeBinding) {
MOZ_ASSERT(maybeBinding->isKind(ParseNodeKind::Name));
MOZ_ASSERT(!maybeBinding->isInParens());
checkAndSetIsDirectRHSAnonFunction(kid);
}
return new_<BinaryNode>(ParseNodeKind::ExportDefaultStmt, pos, kid,
maybeBinding);
}
BinaryNodeType newExportSpec(Node bindingName, Node exportName) {
return newBinary(ParseNodeKind::ExportSpec, bindingName, exportName);
}
NullaryNodeType newExportBatchSpec(const TokenPos& pos) {
return new_<NullaryNode>(ParseNodeKind::ExportBatchSpecStmt, pos);
}
BinaryNodeType newImportMeta(NullaryNodeType importHolder,
NullaryNodeType metaHolder) {
return new_<BinaryNode>(ParseNodeKind::ImportMetaExpr, importHolder,
metaHolder);
}
BinaryNodeType newCallImport(NullaryNodeType importHolder, Node singleArg) {
return new_<BinaryNode>(ParseNodeKind::CallImportExpr, importHolder,
singleArg);
}
UnaryNodeType newExprStatement(Node expr, uint32_t end) {
MOZ_ASSERT_IF(sourceKind() == SourceKind::Text, expr->pn_pos.end <= end);
return new_<UnaryNode>(ParseNodeKind::ExpressionStmt,
TokenPos(expr->pn_pos.begin, end), expr);
}
UnaryNodeType newExprStatement(Node expr) {
return newExprStatement(expr, expr->pn_pos.end);
}
TernaryNodeType newIfStatement(uint32_t begin, Node cond, Node thenBranch,
Node elseBranch) {
TernaryNode* node =
new_<TernaryNode>(ParseNodeKind::IfStmt, cond, thenBranch, elseBranch);
if (!node) {
return nullptr;
}
node->pn_pos.begin = begin;
return node;
}
BinaryNodeType newDoWhileStatement(Node body, Node cond,
const TokenPos& pos) {
return new_<BinaryNode>(ParseNodeKind::DoWhileStmt, pos, body, cond);
}
BinaryNodeType newWhileStatement(uint32_t begin, Node cond, Node body) {
TokenPos pos(begin, body->pn_pos.end);
return new_<BinaryNode>(ParseNodeKind::WhileStmt, pos, cond, body);
}
ForNodeType newForStatement(uint32_t begin, TernaryNodeType forHead,
Node body, unsigned iflags) {
return new_<ForNode>(TokenPos(begin, body->pn_pos.end), forHead, body,
iflags);
}
TernaryNodeType newForHead(Node init, Node test, Node update,
const TokenPos& pos) {
return new_<TernaryNode>(ParseNodeKind::ForHead, init, test, update, pos);
}
TernaryNodeType newForInOrOfHead(ParseNodeKind kind, Node target,
Node iteratedExpr, const TokenPos& pos) {
MOZ_ASSERT(kind == ParseNodeKind::ForIn || kind == ParseNodeKind::ForOf);
return new_<TernaryNode>(kind, target, nullptr, iteratedExpr, pos);
}
SwitchStatementType newSwitchStatement(
uint32_t begin, Node discriminant,
LexicalScopeNodeType lexicalForCaseList, bool hasDefault) {
return new_<SwitchStatement>(begin, discriminant, lexicalForCaseList,
hasDefault);
}
CaseClauseType newCaseOrDefault(uint32_t begin, Node expr, Node body) {
return new_<CaseClause>(expr, body, begin);
}
ContinueStatementType newContinueStatement(const ParserName* label,
const TokenPos& pos) {
return new_<ContinueStatement>(label, pos);
}
BreakStatementType newBreakStatement(const ParserName* label,
const TokenPos& pos) {
return new_<BreakStatement>(label, pos);
}
UnaryNodeType newReturnStatement(Node expr, const TokenPos& pos) {
MOZ_ASSERT_IF(expr && sourceKind() == SourceKind::Text,
pos.encloses(expr->pn_pos));
return new_<UnaryNode>(ParseNodeKind::ReturnStmt, pos, expr);
}
UnaryNodeType newExpressionBody(Node expr) {
return new_<UnaryNode>(ParseNodeKind::ReturnStmt, expr->pn_pos, expr);
}
BinaryNodeType newWithStatement(uint32_t begin, Node expr, Node body) {
return new_<BinaryNode>(ParseNodeKind::WithStmt,
TokenPos(begin, body->pn_pos.end), expr, body);
}
LabeledStatementType newLabeledStatement(const ParserName* label, Node stmt,
uint32_t begin) {
return new_<LabeledStatement>(label, stmt, begin);
}
UnaryNodeType newThrowStatement(Node expr, const TokenPos& pos) {
MOZ_ASSERT_IF(sourceKind() == SourceKind::Text, pos.encloses(expr->pn_pos));
return new_<UnaryNode>(ParseNodeKind::ThrowStmt, pos, expr);
}
TernaryNodeType newTryStatement(uint32_t begin, Node body,
LexicalScopeNodeType catchScope,
Node finallyBlock) {
return new_<TryNode>(begin, body, catchScope, finallyBlock);
}
DebuggerStatementType newDebuggerStatement(const TokenPos& pos) {
return new_<DebuggerStatement>(pos);
}
NameNodeType newPropertyName(const ParserName* name, const TokenPos& pos) {
return new_<NameNode>(ParseNodeKind::PropertyNameExpr, name, pos);
}
PropertyAccessType newPropertyAccess(Node expr, NameNodeType key) {
return new_<PropertyAccess>(expr, key, expr->pn_pos.begin, key->pn_pos.end);
}
PropertyByValueType newPropertyByValue(Node lhs, Node index, uint32_t end) {
return new_<PropertyByValue>(lhs, index, lhs->pn_pos.begin, end);
}
OptionalPropertyAccessType newOptionalPropertyAccess(Node expr,
NameNodeType key) {
return new_<OptionalPropertyAccess>(expr, key, expr->pn_pos.begin,
key->pn_pos.end);
}
OptionalPropertyByValueType newOptionalPropertyByValue(Node lhs, Node index,
uint32_t end) {
return new_<OptionalPropertyByValue>(lhs, index, lhs->pn_pos.begin, end);
}
bool setupCatchScope(LexicalScopeNodeType lexicalScope, Node catchName,
Node catchBody) {
BinaryNode* catchClause;
if (catchName) {
catchClause =
new_<BinaryNode>(ParseNodeKind::Catch, catchName, catchBody);
} else {
catchClause = new_<BinaryNode>(ParseNodeKind::Catch, catchBody->pn_pos,
catchName, catchBody);
}
if (!catchClause) {
return false;
}
lexicalScope->setScopeBody(catchClause);
return true;
}
inline MOZ_MUST_USE bool setLastFunctionFormalParameterDefault(
FunctionNodeType funNode, Node defaultValue);
void checkAndSetIsDirectRHSAnonFunction(Node pn) {
if (IsAnonymousFunctionDefinition(pn)) {
pn->setDirectRHSAnonFunction(true);
}
}
FunctionNodeType newFunction(FunctionSyntaxKind syntaxKind,
const TokenPos& pos) {
return new_<FunctionNode>(syntaxKind, pos);
}
BinaryNodeType newObjectMethodOrPropertyDefinition(Node key, Node value,
AccessorType atype) {
MOZ_ASSERT(isUsableAsObjectPropertyName(key));
return new_<PropertyDefinition>(key, value, atype);
}
BinaryNodeType newShorthandPropertyDefinition(Node key, Node value) {
MOZ_ASSERT(isUsableAsObjectPropertyName(key));
return newBinary(ParseNodeKind::Shorthand, key, value);
}
ListNodeType newParamsBody(const TokenPos& pos) {
return new_<ListNode>(ParseNodeKind::ParamsBody, pos);
}
void setFunctionFormalParametersAndBody(FunctionNodeType funNode,
ListNodeType paramsBody) {
MOZ_ASSERT_IF(paramsBody, paramsBody->isKind(ParseNodeKind::ParamsBody));
funNode->setBody(paramsBody);
}
void setFunctionBox(FunctionNodeType funNode, FunctionBox* funbox) {
funNode->setFunbox(funbox);
funbox->functionNode = funNode;
}
void addFunctionFormalParameter(FunctionNodeType funNode, Node argpn) {
addList(/* list = */ funNode->body(), /* kid = */ argpn);
}
void setFunctionBody(FunctionNodeType funNode, LexicalScopeNodeType body) {
MOZ_ASSERT(funNode->body()->isKind(ParseNodeKind::ParamsBody));
addList(/* list = */ funNode->body(), /* kid = */ body);
}
ModuleNodeType newModule(const TokenPos& pos) {
return new_<ModuleNode>(pos);
}
LexicalScopeNodeType newLexicalScope(LexicalScope::ParserData* bindings,
Node body,
ScopeKind kind = ScopeKind::Lexical) {
return new_<LexicalScopeNode>(bindings, body, kind);
}
CallNodeType newNewExpression(uint32_t begin, Node ctor, Node args,
bool isSpread) {
return new_<CallNode>(ParseNodeKind::NewExpr,
isSpread ? JSOp::SpreadNew : JSOp::New,
TokenPos(begin, args->pn_pos.end), ctor, args);
}
AssignmentNodeType newAssignment(ParseNodeKind kind, Node lhs, Node rhs) {
if ((kind == ParseNodeKind::AssignExpr ||
kind == ParseNodeKind::CoalesceAssignExpr ||
kind == ParseNodeKind::OrAssignExpr ||
kind == ParseNodeKind::AndAssignExpr ||
kind == ParseNodeKind::InitExpr) &&
lhs->isKind(ParseNodeKind::Name) && !lhs->isInParens()) {
checkAndSetIsDirectRHSAnonFunction(rhs);
}
return new_<AssignmentNode>(kind, lhs, rhs);
}
bool isUnparenthesizedAssignment(Node node) {
if ((node->isKind(ParseNodeKind::AssignExpr)) && !node->isInParens()) {
return true;
}
return false;
}
bool isUnparenthesizedUnaryExpression(Node node) {
if (!node->isInParens()) {
ParseNodeKind kind = node->getKind();
return kind == ParseNodeKind::VoidExpr ||
kind == ParseNodeKind::NotExpr ||
kind == ParseNodeKind::BitNotExpr ||
kind == ParseNodeKind::PosExpr || kind == ParseNodeKind::NegExpr ||
kind == ParseNodeKind::AwaitExpr || IsTypeofKind(kind) ||
IsDeleteKind(kind);
}
return false;
}
bool isReturnStatement(Node node) {
return node->isKind(ParseNodeKind::ReturnStmt);
}
bool isStatementPermittedAfterReturnStatement(Node node) {
ParseNodeKind kind = node->getKind();
return kind == ParseNodeKind::Function || kind == ParseNodeKind::VarStmt ||
kind == ParseNodeKind::BreakStmt ||
kind == ParseNodeKind::ThrowStmt || kind == ParseNodeKind::EmptyStmt;
}
bool isSuperBase(Node node) { return node->isKind(ParseNodeKind::SuperBase); }
bool isUsableAsObjectPropertyName(Node node) {
return node->isKind(ParseNodeKind::NumberExpr) ||
node->isKind(ParseNodeKind::BigIntExpr) ||
node->isKind(ParseNodeKind::ObjectPropertyName) ||
node->isKind(ParseNodeKind::StringExpr) ||
node->isKind(ParseNodeKind::ComputedName) ||
node->isKind(ParseNodeKind::PrivateName);
}
AssignmentNodeType finishInitializerAssignment(NameNodeType nameNode,
Node init) {
MOZ_ASSERT(nameNode->isKind(ParseNodeKind::Name));
MOZ_ASSERT(!nameNode->isInParens());
checkAndSetIsDirectRHSAnonFunction(init);
return newAssignment(ParseNodeKind::AssignExpr, nameNode, init);
}
void setBeginPosition(Node pn, Node oth) {
setBeginPosition(pn, oth->pn_pos.begin);
}
void setBeginPosition(Node pn, uint32_t begin) {
pn->pn_pos.begin = begin;
MOZ_ASSERT_IF(sourceKind() == SourceKind::Text,
pn->pn_pos.begin <= pn->pn_pos.end);
}
void setEndPosition(Node pn, Node oth) {
setEndPosition(pn, oth->pn_pos.end);
}
void setEndPosition(Node pn, uint32_t end) {
pn->pn_pos.end = end;
MOZ_ASSERT_IF(sourceKind() == SourceKind::Text,
pn->pn_pos.begin <= pn->pn_pos.end);
}
uint32_t getFunctionNameOffset(Node func, TokenStreamAnyChars& ts) {
return func->pn_pos.begin;
}
bool isDeclarationKind(ParseNodeKind kind) {
return kind == ParseNodeKind::VarStmt || kind == ParseNodeKind::LetDecl ||
kind == ParseNodeKind::ConstDecl;
}
ListNodeType newList(ParseNodeKind kind, const TokenPos& pos) {
MOZ_ASSERT(!isDeclarationKind(kind));
return new_<ListNode>(kind, pos);
}
public:
ListNodeType newList(ParseNodeKind kind, Node kid) {
MOZ_ASSERT(!isDeclarationKind(kind));
return new_<ListNode>(kind, kid);
}
ListNodeType newDeclarationList(ParseNodeKind kind, const TokenPos& pos) {
MOZ_ASSERT(isDeclarationKind(kind));
return new_<ListNode>(kind, pos);
}
bool isDeclarationList(Node node) {
return isDeclarationKind(node->getKind());
}
Node singleBindingFromDeclaration(ListNodeType decl) {
MOZ_ASSERT(isDeclarationList(decl));
MOZ_ASSERT(decl->count() == 1);
return decl->head();
}
ListNodeType newCommaExpressionList(Node kid) {
return new_<ListNode>(ParseNodeKind::CommaExpr, kid);
}
void addList(ListNodeType list, Node kid) {
if (sourceKind_ == SourceKind::Text) {
list->append(kid);
} else {
list->appendWithoutOrderAssumption(kid);
}
}
void setListHasNonConstInitializer(ListNodeType literal) {
literal->setHasNonConstInitializer();
}
template <typename NodeType>
MOZ_MUST_USE NodeType parenthesize(NodeType node) {
node->setInParens(true);
return node;
}
template <typename NodeType>
MOZ_MUST_USE NodeType setLikelyIIFE(NodeType node) {
return parenthesize(node);
}
bool isName(Node node) { return node->isKind(ParseNodeKind::Name); }
bool isArgumentsName(Node node, JSContext* cx) {
return node->isKind(ParseNodeKind::Name) &&
node->as<NameNode>().atom() == cx->parserNames().arguments;
}
bool isEvalName(Node node, JSContext* cx) {
return node->isKind(ParseNodeKind::Name) &&
node->as<NameNode>().atom() == cx->parserNames().eval;
}
bool isAsyncKeyword(Node node, JSContext* cx) {
return node->isKind(ParseNodeKind::Name) &&
node->pn_pos.begin + strlen("async") == node->pn_pos.end &&
node->as<NameNode>().atom() == cx->parserNames().async;
}
bool isPrivateName(Node node) {
return node->isKind(ParseNodeKind::PrivateName);
}
bool isPrivateField(Node node) {
if (node->isKind(ParseNodeKind::ElemExpr) ||
node->isKind(ParseNodeKind::OptionalElemExpr)) {
PropertyByValueBase& pbv = node->as<PropertyByValueBase>();
if (isPrivateName(&pbv.key())) {
return true;
}
}
if (node->isKind(ParseNodeKind::OptionalChain)) {
return isPrivateField(node->as<UnaryNode>().kid());
}
return false;
}
const ParserName* maybeDottedProperty(Node pn) {
return pn->is<PropertyAccessBase>() ? pn->as<PropertyAccessBase>().name()
: nullptr;
}
const ParserAtom* isStringExprStatement(Node pn, TokenPos* pos) {
if (pn->is<UnaryNode>()) {
UnaryNode* unary = &pn->as<UnaryNode>();
if (const ParserAtom* atom = unary->isStringExprStatement()) {
*pos = unary->kid()->pn_pos;
return atom;
}
}
return nullptr;
}
bool canSkipLazyInnerFunctions() { return !!lazyOuterFunction_; }
bool canSkipLazyClosedOverBindings() { return !!lazyOuterFunction_; }
bool canSkipRegexpSyntaxParse() { return !!lazyOuterFunction_; }
JSFunction* nextLazyInnerFunction() {
return &lazyOuterFunction_->gcthings()[lazyInnerFunctionIndex++]
.as<JSObject>()
.as<JSFunction>();
}
JSAtom* nextLazyClosedOverBinding() {
auto gcthings = lazyOuterFunction_->gcthings();
// Trailing nullptrs were elided in PerHandlerParser::finishFunction().
if (lazyClosedOverBindingIndex >= gcthings.Length()) {
return nullptr;
}
// These entries are either JSAtom* or nullptr, so use the 'asCell()'
// accessor which is faster.
gc::Cell* cell = gcthings[lazyClosedOverBindingIndex++].asCell();
MOZ_ASSERT_IF(cell, cell->as<JSString>()->isAtom());
return static_cast<JSAtom*>(cell);
}
void setPrivateNameKind(Node node, PrivateNameKind kind) {
MOZ_ASSERT(node->is<NameNode>());
node->as<NameNode>().setPrivateNameKind(kind);
}
};
inline bool FullParseHandler::setLastFunctionFormalParameterDefault(
FunctionNodeType funNode, Node defaultValue) {
ListNode* body = funNode->body();
ParseNode* arg = body->last();
ParseNode* pn = newAssignment(ParseNodeKind::AssignExpr, arg, defaultValue);
if (!pn) {
return false;
}
body->replaceLast(pn);
return true;
}
} // namespace frontend
} // namespace js
#endif /* frontend_FullParseHandler_h */
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