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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/. */
// JS lexical scanner.
#include "frontend/TokenStream.h"
#include "mozilla/ArrayUtils.h"
#include "mozilla/Attributes.h"
#include "mozilla/Likely.h"
#include "mozilla/Maybe.h"
#include "mozilla/MemoryChecking.h"
#include "mozilla/ScopeExit.h"
#include "mozilla/Span.h"
#include "mozilla/TemplateLib.h"
#include "mozilla/TextUtils.h"
#include "mozilla/Utf8.h"
#include <algorithm>
#include <iterator>
#include <limits>
#include <stdarg.h>
#include <stdint.h>
#include <stdio.h>
#include <type_traits>
#include <utility>
#include "jsnum.h"
#include "frontend/FrontendContext.h"
#include "frontend/Parser.h"
#include "frontend/ParserAtom.h"
#include "frontend/ReservedWords.h"
#include "js/CharacterEncoding.h" // JS::ConstUTF8CharsZ
#include "js/ColumnNumber.h" // JS::LimitedColumnNumberOneOrigin, JS::ColumnNumberOneOrigin, JS::TaggedColumnNumberOneOrigin
#include "js/ErrorReport.h" // JSErrorBase
#include "js/friend/ErrorMessages.h" // js::GetErrorMessage, JSMSG_*
#include "js/Printf.h" // JS_smprintf
#include "js/RegExpFlags.h" // JS::RegExpFlags
#include "js/UniquePtr.h"
#include "util/Text.h"
#include "util/Unicode.h"
#include "vm/FrameIter.h" // js::{,NonBuiltin}FrameIter
#include "vm/JSContext.h"
#include "vm/Realm.h"
using mozilla::AsciiAlphanumericToNumber;
using mozilla::AssertedCast;
using mozilla::DecodeOneUtf8CodePoint;
using mozilla::IsAscii;
using mozilla::IsAsciiAlpha;
using mozilla::IsAsciiDigit;
using mozilla::IsAsciiHexDigit;
using mozilla::IsTrailingUnit;
using mozilla::MakeScopeExit;
using mozilla::Maybe;
using mozilla::PointerRangeSize;
using mozilla::Span;
using mozilla::Utf8Unit;
using JS::ReadOnlyCompileOptions;
using JS::RegExpFlag;
using JS::RegExpFlags;
struct ReservedWordInfo {
const char* chars; // C string with reserved word text
js::frontend::TokenKind tokentype;
};
static const ReservedWordInfo reservedWords[] = {
#define RESERVED_WORD_INFO(word, name, type) {#word, js::frontend::type},
FOR_EACH_JAVASCRIPT_RESERVED_WORD(RESERVED_WORD_INFO)
#undef RESERVED_WORD_INFO
};
enum class ReservedWordsIndex : size_t {
#define ENTRY_(_1, NAME, _3) NAME,
FOR_EACH_JAVASCRIPT_RESERVED_WORD(ENTRY_)
#undef ENTRY_
};
// Returns a ReservedWordInfo for the specified characters, or nullptr if the
// string is not a reserved word.
template <typename CharT>
static const ReservedWordInfo* FindReservedWord(const CharT* s, size_t length) {
MOZ_ASSERT(length != 0);
size_t i;
const ReservedWordInfo* rw;
const char* chars;
#define JSRW_LENGTH() length
#define JSRW_AT(column) s[column]
#define JSRW_GOT_MATCH(index) \
i = (index); \
goto got_match;
#define JSRW_TEST_GUESS(index) \
i = (index); \
goto test_guess;
#define JSRW_NO_MATCH() goto no_match;
#include "frontend/ReservedWordsGenerated.h"
#undef JSRW_NO_MATCH
#undef JSRW_TEST_GUESS
#undef JSRW_GOT_MATCH
#undef JSRW_AT
#undef JSRW_LENGTH
got_match:
return &reservedWords[i];
test_guess:
rw = &reservedWords[i];
chars = rw->chars;
do {
if (*s++ != static_cast<unsigned char>(*chars++)) {
goto no_match;
}
} while (--length != 0);
return rw;
no_match:
return nullptr;
}
template <>
MOZ_ALWAYS_INLINE const ReservedWordInfo* FindReservedWord<Utf8Unit>(
const Utf8Unit* units, size_t length) {
return FindReservedWord(Utf8AsUnsignedChars(units), length);
}
static const ReservedWordInfo* FindReservedWord(
const js::frontend::TaggedParserAtomIndex atom) {
switch (atom.rawData()) {
#define CASE_(_1, NAME, _3) \
case js::frontend::TaggedParserAtomIndex::WellKnownRawData::NAME(): \
return &reservedWords[size_t(ReservedWordsIndex::NAME)];
FOR_EACH_JAVASCRIPT_RESERVED_WORD(CASE_)
#undef CASE_
}
return nullptr;
}
template <typename CharT>
static constexpr bool IsAsciiBinary(CharT c) {
using UnsignedCharT = std::make_unsigned_t<CharT>;
auto uc = static_cast<UnsignedCharT>(c);
return uc == '0' || uc == '1';
}
template <typename CharT>
static constexpr bool IsAsciiOctal(CharT c) {
using UnsignedCharT = std::make_unsigned_t<CharT>;
auto uc = static_cast<UnsignedCharT>(c);
return '0' <= uc && uc <= '7';
}
template <typename CharT>
static constexpr uint8_t AsciiOctalToNumber(CharT c) {
using UnsignedCharT = std::make_unsigned_t<CharT>;
auto uc = static_cast<UnsignedCharT>(c);
return uc - '0';
}
namespace js {
namespace frontend {
bool IsKeyword(TaggedParserAtomIndex atom) {
if (const ReservedWordInfo* rw = FindReservedWord(atom)) {
return TokenKindIsKeyword(rw->tokentype);
}
return false;
}
TokenKind ReservedWordTokenKind(TaggedParserAtomIndex name) {
if (const ReservedWordInfo* rw = FindReservedWord(name)) {
return rw->tokentype;
}
return TokenKind::Limit;
}
const char* ReservedWordToCharZ(TaggedParserAtomIndex name) {
if (const ReservedWordInfo* rw = FindReservedWord(name)) {
return ReservedWordToCharZ(rw->tokentype);
}
return nullptr;
}
const char* ReservedWordToCharZ(TokenKind tt) {
MOZ_ASSERT(tt != TokenKind::Name);
switch (tt) {
#define EMIT_CASE(word, name, type) \
case type: \
return #word;
FOR_EACH_JAVASCRIPT_RESERVED_WORD(EMIT_CASE)
#undef EMIT_CASE
default:
MOZ_ASSERT_UNREACHABLE("Not a reserved word PropertyName.");
}
return nullptr;
}
TaggedParserAtomIndex TokenStreamAnyChars::reservedWordToPropertyName(
TokenKind tt) const {
MOZ_ASSERT(tt != TokenKind::Name);
switch (tt) {
#define EMIT_CASE(word, name, type) \
case type: \
return TaggedParserAtomIndex::WellKnown::name();
FOR_EACH_JAVASCRIPT_RESERVED_WORD(EMIT_CASE)
#undef EMIT_CASE
default:
MOZ_ASSERT_UNREACHABLE("Not a reserved word TokenKind.");
}
return TaggedParserAtomIndex::null();
}
SourceCoords::SourceCoords(FrontendContext* fc, uint32_t initialLineNumber,
uint32_t initialOffset)
: lineStartOffsets_(fc), initialLineNum_(initialLineNumber), lastIndex_(0) {
// This is actually necessary! Removing it causes compile errors on
// GCC and clang. You could try declaring this:
//
// const uint32_t SourceCoords::MAX_PTR;
//
// which fixes the GCC/clang error, but causes bustage on Windows. Sigh.
//
uint32_t maxPtr = MAX_PTR;
// The first line begins at buffer offset |initialOffset|. MAX_PTR is the
// sentinel. The appends cannot fail because |lineStartOffsets_| has
// statically-allocated elements.
MOZ_ASSERT(lineStartOffsets_.capacity() >= 2);
MOZ_ALWAYS_TRUE(lineStartOffsets_.reserve(2));
lineStartOffsets_.infallibleAppend(initialOffset);
lineStartOffsets_.infallibleAppend(maxPtr);
}
MOZ_ALWAYS_INLINE bool SourceCoords::add(uint32_t lineNum,
uint32_t lineStartOffset) {
uint32_t index = indexFromLineNumber(lineNum);
uint32_t sentinelIndex = lineStartOffsets_.length() - 1;
MOZ_ASSERT(lineStartOffsets_[0] <= lineStartOffset);
MOZ_ASSERT(lineStartOffsets_[sentinelIndex] == MAX_PTR);
if (index == sentinelIndex) {
// We haven't seen this newline before. Update lineStartOffsets_
// only if lineStartOffsets_.append succeeds, to keep sentinel.
// Otherwise return false to tell TokenStream about OOM.
uint32_t maxPtr = MAX_PTR;
if (!lineStartOffsets_.append(maxPtr)) {
static_assert(std::is_same_v<decltype(lineStartOffsets_.allocPolicy()),
TempAllocPolicy&>,
"this function's caller depends on it reporting an "
"error on failure, as TempAllocPolicy ensures");
return false;
}
lineStartOffsets_[index] = lineStartOffset;
} else {
// We have seen this newline before (and ungot it). Do nothing (other
// than checking it hasn't mysteriously changed).
// This path can be executed after hitting OOM, so check index.
MOZ_ASSERT_IF(index < sentinelIndex,
lineStartOffsets_[index] == lineStartOffset);
}
return true;
}
MOZ_ALWAYS_INLINE bool SourceCoords::fill(const SourceCoords& other) {
MOZ_ASSERT(lineStartOffsets_[0] == other.lineStartOffsets_[0]);
MOZ_ASSERT(lineStartOffsets_.back() == MAX_PTR);
MOZ_ASSERT(other.lineStartOffsets_.back() == MAX_PTR);
if (lineStartOffsets_.length() >= other.lineStartOffsets_.length()) {
return true;
}
uint32_t sentinelIndex = lineStartOffsets_.length() - 1;
lineStartOffsets_[sentinelIndex] = other.lineStartOffsets_[sentinelIndex];
for (size_t i = sentinelIndex + 1; i < other.lineStartOffsets_.length();
i++) {
if (!lineStartOffsets_.append(other.lineStartOffsets_[i])) {
return false;
}
}
return true;
}
MOZ_ALWAYS_INLINE uint32_t
SourceCoords::indexFromOffset(uint32_t offset) const {
uint32_t iMin, iMax, iMid;
if (lineStartOffsets_[lastIndex_] <= offset) {
// If we reach here, offset is on a line the same as or higher than
// last time. Check first for the +0, +1, +2 cases, because they
// typically cover 85--98% of cases.
if (offset < lineStartOffsets_[lastIndex_ + 1]) {
return lastIndex_; // index is same as last time
}
// If we reach here, there must be at least one more entry (plus the
// sentinel). Try it.
lastIndex_++;
if (offset < lineStartOffsets_[lastIndex_ + 1]) {
return lastIndex_; // index is one higher than last time
}
// The same logic applies here.
lastIndex_++;
if (offset < lineStartOffsets_[lastIndex_ + 1]) {
return lastIndex_; // index is two higher than last time
}
// No luck. Oh well, we have a better-than-default starting point for
// the binary search.
iMin = lastIndex_ + 1;
MOZ_ASSERT(iMin <
lineStartOffsets_.length() - 1); // -1 due to the sentinel
} else {
iMin = 0;
}
// This is a binary search with deferred detection of equality, which was
// marginally faster in this case than a standard binary search.
// The -2 is because |lineStartOffsets_.length() - 1| is the sentinel, and we
// want one before that.
iMax = lineStartOffsets_.length() - 2;
while (iMax > iMin) {
iMid = iMin + (iMax - iMin) / 2;
if (offset >= lineStartOffsets_[iMid + 1]) {
iMin = iMid + 1; // offset is above lineStartOffsets_[iMid]
} else {
iMax = iMid; // offset is below or within lineStartOffsets_[iMid]
}
}
MOZ_ASSERT(iMax == iMin);
MOZ_ASSERT(lineStartOffsets_[iMin] <= offset);
MOZ_ASSERT(offset < lineStartOffsets_[iMin + 1]);
lastIndex_ = iMin;
return iMin;
}
SourceCoords::LineToken SourceCoords::lineToken(uint32_t offset) const {
return LineToken(indexFromOffset(offset), offset);
}
TokenStreamAnyChars::TokenStreamAnyChars(FrontendContext* fc,
const ReadOnlyCompileOptions& options,
StrictModeGetter* smg)
: fc(fc),
options_(options),
strictModeGetter_(smg),
filename_(options.filename()),
longLineColumnInfo_(fc),
srcCoords(fc, options.lineno, options.scriptSourceOffset),
lineno(options.lineno),
mutedErrors(options.mutedErrors()) {
// |isExprEnding| was initially zeroed: overwrite the true entries here.
isExprEnding[size_t(TokenKind::Comma)] = true;
isExprEnding[size_t(TokenKind::Semi)] = true;
isExprEnding[size_t(TokenKind::Colon)] = true;
isExprEnding[size_t(TokenKind::RightParen)] = true;
isExprEnding[size_t(TokenKind::RightBracket)] = true;
isExprEnding[size_t(TokenKind::RightCurly)] = true;
}
template <typename Unit>
TokenStreamCharsBase<Unit>::TokenStreamCharsBase(FrontendContext* fc,
ParserAtomsTable* parserAtoms,
const Unit* units,
size_t length,
size_t startOffset)
: TokenStreamCharsShared(fc, parserAtoms),
sourceUnits(units, length, startOffset) {}
bool FillCharBufferFromSourceNormalizingAsciiLineBreaks(CharBuffer& charBuffer,
const char16_t* cur,
const char16_t* end) {
MOZ_ASSERT(charBuffer.length() == 0);
while (cur < end) {
char16_t ch = *cur++;
if (ch == '\r') {
ch = '\n';
if (cur < end && *cur == '\n') {
cur++;
}
}
if (!charBuffer.append(ch)) {
return false;
}
}
MOZ_ASSERT(cur == end);
return true;
}
bool FillCharBufferFromSourceNormalizingAsciiLineBreaks(CharBuffer& charBuffer,
const Utf8Unit* cur,
const Utf8Unit* end) {
MOZ_ASSERT(charBuffer.length() == 0);
while (cur < end) {
Utf8Unit unit = *cur++;
if (MOZ_LIKELY(IsAscii(unit))) {
char16_t ch = unit.toUint8();
if (ch == '\r') {
ch = '\n';
if (cur < end && *cur == Utf8Unit('\n')) {
cur++;
}
}
if (!charBuffer.append(ch)) {
return false;
}
continue;
}
Maybe<char32_t> ch = DecodeOneUtf8CodePoint(unit, &cur, end);
MOZ_ASSERT(ch.isSome(),
"provided source text should already have been validated");
if (!AppendCodePointToCharBuffer(charBuffer, ch.value())) {
return false;
}
}
MOZ_ASSERT(cur == end);
return true;
}
template <typename Unit, class AnyCharsAccess>
TokenStreamSpecific<Unit, AnyCharsAccess>::TokenStreamSpecific(
FrontendContext* fc, ParserAtomsTable* parserAtoms,
const ReadOnlyCompileOptions& options, const Unit* units, size_t length)
: TokenStreamChars<Unit, AnyCharsAccess>(fc, parserAtoms, units, length,
options.scriptSourceOffset) {}
bool TokenStreamAnyChars::checkOptions() {
// Constrain starting columns to where they will saturate.
if (options().column.oneOriginValue() >
JS::LimitedColumnNumberOneOrigin::Limit) {
reportErrorNoOffset(JSMSG_BAD_COLUMN_NUMBER);
return false;
}
return true;
}
void TokenStreamAnyChars::reportErrorNoOffset(unsigned errorNumber, ...) const {
va_list args;
va_start(args, errorNumber);
reportErrorNoOffsetVA(errorNumber, &args);
va_end(args);
}
void TokenStreamAnyChars::reportErrorNoOffsetVA(unsigned errorNumber,
va_list* args) const {
ErrorMetadata metadata;
computeErrorMetadataNoOffset(&metadata);
ReportCompileErrorLatin1VA(fc, std::move(metadata), nullptr, errorNumber,
args);
}
[[nodiscard]] MOZ_ALWAYS_INLINE bool
TokenStreamAnyChars::internalUpdateLineInfoForEOL(uint32_t lineStartOffset) {
prevLinebase = linebase;
linebase = lineStartOffset;
lineno++;
// On overflow, report error.
if (MOZ_UNLIKELY(!lineno)) {
reportErrorNoOffset(JSMSG_BAD_LINE_NUMBER);
return false;
}
return srcCoords.add(lineno, linebase);
}
#ifdef DEBUG
template <>
inline void SourceUnits<char16_t>::assertNextCodePoint(
const PeekedCodePoint<char16_t>& peeked) {
char32_t c = peeked.codePoint();
if (c < unicode::NonBMPMin) {
MOZ_ASSERT(peeked.lengthInUnits() == 1);
MOZ_ASSERT(ptr[0] == c);
} else {
MOZ_ASSERT(peeked.lengthInUnits() == 2);
char16_t lead, trail;
unicode::UTF16Encode(c, &lead, &trail);
MOZ_ASSERT(ptr[0] == lead);
MOZ_ASSERT(ptr[1] == trail);
}
}
template <>
inline void SourceUnits<Utf8Unit>::assertNextCodePoint(
const PeekedCodePoint<Utf8Unit>& peeked) {
char32_t c = peeked.codePoint();
// This is all roughly indulgence of paranoia only for assertions, so the
// reimplementation of UTF-8 encoding a code point is (we think) a virtue.
uint8_t expectedUnits[4] = {};
if (c < 0x80) {
expectedUnits[0] = AssertedCast<uint8_t>(c);
} else if (c < 0x800) {
expectedUnits[0] = 0b1100'0000 | (c >> 6);
expectedUnits[1] = 0b1000'0000 | (c & 0b11'1111);
} else if (c < 0x10000) {
expectedUnits[0] = 0b1110'0000 | (c >> 12);
expectedUnits[1] = 0b1000'0000 | ((c >> 6) & 0b11'1111);
expectedUnits[2] = 0b1000'0000 | (c & 0b11'1111);
} else {
expectedUnits[0] = 0b1111'0000 | (c >> 18);
expectedUnits[1] = 0b1000'0000 | ((c >> 12) & 0b11'1111);
expectedUnits[2] = 0b1000'0000 | ((c >> 6) & 0b11'1111);
expectedUnits[3] = 0b1000'0000 | (c & 0b11'1111);
}
MOZ_ASSERT(peeked.lengthInUnits() <= 4);
for (uint8_t i = 0; i < peeked.lengthInUnits(); i++) {
MOZ_ASSERT(expectedUnits[i] == ptr[i].toUint8());
}
}
#endif // DEBUG
static MOZ_ALWAYS_INLINE void RetractPointerToCodePointBoundary(
const Utf8Unit** ptr, const Utf8Unit* limit) {
MOZ_ASSERT(*ptr <= limit);
// |limit| is a code point boundary.
if (MOZ_UNLIKELY(*ptr == limit)) {
return;
}
// Otherwise rewind past trailing units to the start of the code point.
#ifdef DEBUG
size_t retracted = 0;
#endif
while (MOZ_UNLIKELY(IsTrailingUnit((*ptr)[0]))) {
--*ptr;
#ifdef DEBUG
retracted++;
#endif
}
MOZ_ASSERT(retracted < 4,
"the longest UTF-8 code point is four units, so this should never "
"retract more than three units");
}
static MOZ_ALWAYS_INLINE void RetractPointerToCodePointBoundary(
const char16_t** ptr, const char16_t* limit) {
MOZ_ASSERT(*ptr <= limit);
// |limit| is a code point boundary.
if (MOZ_UNLIKELY(*ptr == limit)) {
return;
}
// Otherwise the pointer must be retracted by one iff it splits a two-unit
// code point.
if (MOZ_UNLIKELY(unicode::IsTrailSurrogate((*ptr)[0]))) {
// Outside test suites testing garbage WTF-16, it's basically guaranteed
// here that |(*ptr)[-1] (*ptr)[0]| is a surrogate pair.
if (MOZ_LIKELY(unicode::IsLeadSurrogate((*ptr)[-1]))) {
--*ptr;
}
}
}
template <typename Unit>
JS::ColumnNumberUnsignedOffset TokenStreamAnyChars::computeColumnOffset(
const LineToken lineToken, const uint32_t offset,
const SourceUnits<Unit>& sourceUnits) const {
lineToken.assertConsistentOffset(offset);
const uint32_t start = srcCoords.lineStart(lineToken);
const uint32_t offsetInLine = offset - start;
if constexpr (std::is_same_v<Unit, char16_t>) {
// Column offset is in UTF-16 code units.
return JS::ColumnNumberUnsignedOffset(offsetInLine);
}
return computeColumnOffsetForUTF8(lineToken, offset, start, offsetInLine,
sourceUnits);
}
template <typename Unit>
JS::ColumnNumberUnsignedOffset TokenStreamAnyChars::computeColumnOffsetForUTF8(
const LineToken lineToken, const uint32_t offset, const uint32_t start,
const uint32_t offsetInLine, const SourceUnits<Unit>& sourceUnits) const {
const uint32_t line = lineNumber(lineToken);
// Reset the previous offset/column number offset cache for this line, if the
// previous lookup wasn't on this line.
if (line != lineOfLastColumnComputation_) {
lineOfLastColumnComputation_ = line;
lastChunkVectorForLine_ = nullptr;
lastOffsetOfComputedColumn_ = start;
lastComputedColumnOffset_ = JS::ColumnNumberUnsignedOffset::zero();
}
// Compute and return the final column number offset from a partially
// calculated offset/column number offset, using the last-cached
// offset/column number offset if they're more optimal.
auto OffsetFromPartial =
[this, offset, &sourceUnits](
uint32_t partialOffset,
JS::ColumnNumberUnsignedOffset partialColumnOffset,
UnitsType unitsType) {
MOZ_ASSERT(partialOffset <= offset);
// If the last lookup on this line was closer to |offset|, use it.
if (partialOffset < this->lastOffsetOfComputedColumn_ &&
this->lastOffsetOfComputedColumn_ <= offset) {
partialOffset = this->lastOffsetOfComputedColumn_;
partialColumnOffset = this->lastComputedColumnOffset_;
}
const Unit* begin = sourceUnits.codeUnitPtrAt(partialOffset);
const Unit* end = sourceUnits.codeUnitPtrAt(offset);
size_t offsetDelta =
AssertedCast<uint32_t>(PointerRangeSize(begin, end));
partialOffset += offsetDelta;
if (unitsType == UnitsType::GuaranteedSingleUnit) {
MOZ_ASSERT(unicode::CountUTF16CodeUnits(begin, end) == offsetDelta,
"guaranteed-single-units also guarantee pointer distance "
"equals UTF-16 code unit count");
partialColumnOffset += JS::ColumnNumberUnsignedOffset(offsetDelta);
} else {
partialColumnOffset += JS::ColumnNumberUnsignedOffset(
AssertedCast<uint32_t>(unicode::CountUTF16CodeUnits(begin, end)));
}
this->lastOffsetOfComputedColumn_ = partialOffset;
this->lastComputedColumnOffset_ = partialColumnOffset;
return partialColumnOffset;
};
// We won't add an entry to |longLineColumnInfo_| for lines where the maximum
// column has offset less than this value. The most common (non-minified)
// long line length is likely 80ch, maybe 100ch, so we use that, rounded up to
// the next power of two for efficient division/multiplication below.
constexpr uint32_t ColumnChunkLength = mozilla::tl::RoundUpPow2<100>::value;
// The index within any associated |Vector<ChunkInfo>| of |offset|'s chunk.
const uint32_t chunkIndex = offsetInLine / ColumnChunkLength;
if (chunkIndex == 0) {
// We don't know from an |offset| in the zeroth chunk that this line is even
// long. First-chunk info is mostly useless, anyway -- we have |start|
// already. So if we have *easy* access to that zeroth chunk, use it --
// otherwise just count pessimally. (This will still benefit from caching
// the last column/offset for computations for successive offsets, so it's
// not *always* worst-case.)
UnitsType unitsType;
if (lastChunkVectorForLine_ && lastChunkVectorForLine_->length() > 0) {
MOZ_ASSERT((*lastChunkVectorForLine_)[0].columnOffset() ==
JS::ColumnNumberUnsignedOffset::zero());
unitsType = (*lastChunkVectorForLine_)[0].unitsType();
} else {
unitsType = UnitsType::PossiblyMultiUnit;
}
return OffsetFromPartial(start, JS::ColumnNumberUnsignedOffset::zero(),
unitsType);
}
// If this line has no chunk vector yet, insert one in the hash map. (The
// required index is allocated and filled further down.)
if (!lastChunkVectorForLine_) {
auto ptr = longLineColumnInfo_.lookupForAdd(line);
if (!ptr) {
// This could rehash and invalidate a cached vector pointer, but the outer
// condition means we don't have a cached pointer.
if (!longLineColumnInfo_.add(ptr, line, Vector<ChunkInfo>(fc))) {
// In case of OOM, just count columns from the start of the line.
fc->recoverFromOutOfMemory();
return OffsetFromPartial(start, JS::ColumnNumberUnsignedOffset::zero(),
UnitsType::PossiblyMultiUnit);
}
}
// Note that adding elements to this vector won't invalidate this pointer.
lastChunkVectorForLine_ = &ptr->value();
}
const Unit* const limit = sourceUnits.codeUnitPtrAt(offset);
auto RetractedOffsetOfChunk = [
#ifdef DEBUG
this,
#endif
start, limit,
&sourceUnits](uint32_t index) {
MOZ_ASSERT(index < this->lastChunkVectorForLine_->length());
uint32_t naiveOffset = start + index * ColumnChunkLength;
const Unit* naivePtr = sourceUnits.codeUnitPtrAt(naiveOffset);
const Unit* actualPtr = naivePtr;
RetractPointerToCodePointBoundary(&actualPtr, limit);
#ifdef DEBUG
if ((*this->lastChunkVectorForLine_)[index].unitsType() ==
UnitsType::GuaranteedSingleUnit) {
MOZ_ASSERT(naivePtr == actualPtr, "miscomputed unitsType value");
}
#endif
return naiveOffset - PointerRangeSize(actualPtr, naivePtr);
};
uint32_t partialOffset;
JS::ColumnNumberUnsignedOffset partialColumnOffset;
UnitsType unitsType;
auto entriesLen = AssertedCast<uint32_t>(lastChunkVectorForLine_->length());
if (chunkIndex < entriesLen) {
// We've computed the chunk |offset| resides in. Compute the column number
// from the chunk.
partialOffset = RetractedOffsetOfChunk(chunkIndex);
partialColumnOffset = (*lastChunkVectorForLine_)[chunkIndex].columnOffset();
// This is exact if |chunkIndex| isn't the last chunk.
unitsType = (*lastChunkVectorForLine_)[chunkIndex].unitsType();
// Otherwise the last chunk is pessimistically assumed to contain multi-unit
// code points because we haven't fully examined its contents yet -- they
// may not have been tokenized yet, they could contain encoding errors, or
// they might not even exist.
MOZ_ASSERT_IF(chunkIndex == entriesLen - 1,
(*lastChunkVectorForLine_)[chunkIndex].unitsType() ==
UnitsType::PossiblyMultiUnit);
} else {
// Extend the vector from its last entry or the start of the line. (This is
// also a suitable partial start point if we must recover from OOM.)
if (entriesLen > 0) {
partialOffset = RetractedOffsetOfChunk(entriesLen - 1);
partialColumnOffset =
(*lastChunkVectorForLine_)[entriesLen - 1].columnOffset();
} else {
partialOffset = start;
partialColumnOffset = JS::ColumnNumberUnsignedOffset::zero();
}
if (!lastChunkVectorForLine_->reserve(chunkIndex + 1)) {
// As earlier, just start from the greatest offset/column in case of OOM.
fc->recoverFromOutOfMemory();
return OffsetFromPartial(partialOffset, partialColumnOffset,
UnitsType::PossiblyMultiUnit);
}
// OOM is no longer possible now. \o/
// The vector always begins with the column of the line start, i.e. zero,
// with chunk units pessimally assumed not single-unit.
if (entriesLen == 0) {
lastChunkVectorForLine_->infallibleAppend(
ChunkInfo(JS::ColumnNumberUnsignedOffset::zero(),
UnitsType::PossiblyMultiUnit));
entriesLen++;
}
do {
const Unit* const begin = sourceUnits.codeUnitPtrAt(partialOffset);
const Unit* chunkLimit = sourceUnits.codeUnitPtrAt(
start + std::min(entriesLen++ * ColumnChunkLength, offsetInLine));
MOZ_ASSERT(begin < chunkLimit);
MOZ_ASSERT(chunkLimit <= limit);
static_assert(
ColumnChunkLength > SourceUnitTraits<Unit>::maxUnitsLength - 1,
"any retraction below is assumed to never underflow to the "
"preceding chunk, even for the longest code point");
// Prior tokenizing ensured that [begin, limit) is validly encoded, and
// |begin < chunkLimit|, so any retraction here can't underflow.
RetractPointerToCodePointBoundary(&chunkLimit, limit);
MOZ_ASSERT(begin < chunkLimit);
MOZ_ASSERT(chunkLimit <= limit);
size_t numUnits = PointerRangeSize(begin, chunkLimit);
size_t numUTF16CodeUnits =
unicode::CountUTF16CodeUnits(begin, chunkLimit);
// If this chunk (which will become non-final at the end of the loop) is
// all single-unit code points, annotate the chunk accordingly.
if (numUnits == numUTF16CodeUnits) {
lastChunkVectorForLine_->back().guaranteeSingleUnits();
}
partialOffset += numUnits;
partialColumnOffset += JS::ColumnNumberUnsignedOffset(numUTF16CodeUnits);
lastChunkVectorForLine_->infallibleEmplaceBack(
partialColumnOffset, UnitsType::PossiblyMultiUnit);
} while (entriesLen < chunkIndex + 1);
// We're at a spot in the current final chunk, and final chunks never have
// complete units information, so be pessimistic.
unitsType = UnitsType::PossiblyMultiUnit;
}
return OffsetFromPartial(partialOffset, partialColumnOffset, unitsType);
}
template <typename Unit, class AnyCharsAccess>
JS::LimitedColumnNumberOneOrigin
GeneralTokenStreamChars<Unit, AnyCharsAccess>::computeColumn(
LineToken lineToken, uint32_t offset) const {
lineToken.assertConsistentOffset(offset);
const TokenStreamAnyChars& anyChars = anyCharsAccess();
JS::ColumnNumberUnsignedOffset columnOffset =
anyChars.computeColumnOffset(lineToken, offset, this->sourceUnits);
if (!lineToken.isFirstLine()) {
return JS::LimitedColumnNumberOneOrigin::fromUnlimited(
JS::ColumnNumberOneOrigin() + columnOffset);
}
if (1 + columnOffset.value() > JS::LimitedColumnNumberOneOrigin::Limit) {
return JS::LimitedColumnNumberOneOrigin::limit();
}
return JS::LimitedColumnNumberOneOrigin::fromUnlimited(
(anyChars.options_.column + columnOffset).oneOriginValue());
}
template <typename Unit, class AnyCharsAccess>
void GeneralTokenStreamChars<Unit, AnyCharsAccess>::computeLineAndColumn(
uint32_t offset, uint32_t* line,
JS::LimitedColumnNumberOneOrigin* column) const {
const TokenStreamAnyChars& anyChars = anyCharsAccess();
auto lineToken = anyChars.lineToken(offset);
*line = anyChars.lineNumber(lineToken);
*column = computeColumn(lineToken, offset);
}
template <class AnyCharsAccess>
MOZ_COLD void TokenStreamChars<Utf8Unit, AnyCharsAccess>::internalEncodingError(
uint8_t relevantUnits, unsigned errorNumber, ...) {
va_list args;
va_start(args, errorNumber);
do {
size_t offset = this->sourceUnits.offset();
ErrorMetadata err;
TokenStreamAnyChars& anyChars = anyCharsAccess();
bool canAddLineOfContext = fillExceptingContext(&err, offset);
if (canAddLineOfContext) {
if (!internalComputeLineOfContext(&err, offset)) {
break;
}
// As this is an encoding error, the computed window-end must be
// identical to the location of the error -- any further on and the
// window would contain invalid Unicode.
MOZ_ASSERT_IF(err.lineOfContext != nullptr,
err.lineLength == err.tokenOffset);
}
auto notes = MakeUnique<JSErrorNotes>();
if (!notes) {
ReportOutOfMemory(anyChars.fc);
break;
}
// The largest encoding of a UTF-8 code point is 4 units. (Encoding an
// obsolete 5- or 6-byte code point will complain only about a bad lead
// code unit.)
constexpr size_t MaxWidth = sizeof("0xHH 0xHH 0xHH 0xHH");
MOZ_ASSERT(relevantUnits > 0);
char badUnitsStr[MaxWidth];
char* ptr = badUnitsStr;
while (relevantUnits > 0) {
byteToString(this->sourceUnits.getCodeUnit().toUint8(), ptr);
ptr[4] = ' ';
ptr += 5;
relevantUnits--;
}
ptr[-1] = '\0';
uint32_t line;
JS::LimitedColumnNumberOneOrigin column;
computeLineAndColumn(offset, &line, &column);
if (!notes->addNoteASCII(anyChars.fc, anyChars.getFilename().c_str(), 0,
line, JS::ColumnNumberOneOrigin(column),
GetErrorMessage, nullptr, JSMSG_BAD_CODE_UNITS,
badUnitsStr)) {
break;
}
ReportCompileErrorLatin1VA(anyChars.fc, std::move(err), std::move(notes),
errorNumber, &args);
} while (false);
va_end(args);
}
template <class AnyCharsAccess>
MOZ_COLD void TokenStreamChars<Utf8Unit, AnyCharsAccess>::badLeadUnit(
Utf8Unit lead) {
uint8_t leadValue = lead.toUint8();
char leadByteStr[5];
byteToTerminatedString(leadValue, leadByteStr);
internalEncodingError(1, JSMSG_BAD_LEADING_UTF8_UNIT, leadByteStr);
}
template <class AnyCharsAccess>
MOZ_COLD void TokenStreamChars<Utf8Unit, AnyCharsAccess>::notEnoughUnits(
Utf8Unit lead, uint8_t remaining, uint8_t required) {
uint8_t leadValue = lead.toUint8();
MOZ_ASSERT(required == 2 || required == 3 || required == 4);
MOZ_ASSERT(remaining < 4);
MOZ_ASSERT(remaining < required);
char leadByteStr[5];
byteToTerminatedString(leadValue, leadByteStr);
// |toHexChar| produces the desired decimal numbers for values < 4.
const char expectedStr[] = {toHexChar(required - 1), '\0'};
const char actualStr[] = {toHexChar(remaining - 1), '\0'};
internalEncodingError(remaining, JSMSG_NOT_ENOUGH_CODE_UNITS, leadByteStr,
expectedStr, required == 2 ? "" : "s", actualStr,
remaining == 2 ? " was" : "s were");
}
template <class AnyCharsAccess>
MOZ_COLD void TokenStreamChars<Utf8Unit, AnyCharsAccess>::badTrailingUnit(
uint8_t unitsObserved) {
Utf8Unit badUnit =
this->sourceUnits.addressOfNextCodeUnit()[unitsObserved - 1];
char badByteStr[5];
byteToTerminatedString(badUnit.toUint8(), badByteStr);
internalEncodingError(unitsObserved, JSMSG_BAD_TRAILING_UTF8_UNIT,
badByteStr);
}
template <class AnyCharsAccess>
MOZ_COLD void
TokenStreamChars<Utf8Unit, AnyCharsAccess>::badStructurallyValidCodePoint(
char32_t codePoint, uint8_t codePointLength, const char* reason) {
// Construct a string like "0x203D" (including null terminator) to include
// in the error message. Write the string end-to-start from end to start
// of an adequately sized |char| array, shifting least significant nibbles
// off the number and writing the corresponding hex digits until done, then
// prefixing with "0x". |codePointStr| points at the incrementally
// computed string, within |codePointCharsArray|'s bounds.
// 0x1F'FFFF is the maximum value that can fit in 3+6+6+6 unconstrained
// bits in a four-byte UTF-8 code unit sequence.
constexpr size_t MaxHexSize = sizeof(
"0x1F"
"FFFF"); // including '\0'
char codePointCharsArray[MaxHexSize];
char* codePointStr = std::end(codePointCharsArray);
*--codePointStr = '\0';
// Note that by do-while looping here rather than while-looping, this
// writes a '0' when |codePoint == 0|.
do {
MOZ_ASSERT(codePointCharsArray < codePointStr);
*--codePointStr = toHexChar(codePoint & 0xF);
codePoint >>= 4;
} while (codePoint);
MOZ_ASSERT(codePointCharsArray + 2 <= codePointStr);
*--codePointStr = 'x';
*--codePointStr = '0';
internalEncodingError(codePointLength, JSMSG_FORBIDDEN_UTF8_CODE_POINT,
codePointStr, reason);
}
template <class AnyCharsAccess>
[[nodiscard]] bool
TokenStreamChars<Utf8Unit, AnyCharsAccess>::getNonAsciiCodePointDontNormalize(
Utf8Unit lead, char32_t* codePoint) {
auto onBadLeadUnit = [this, &lead]() { this->badLeadUnit(lead); };
auto onNotEnoughUnits = [this, &lead](uint8_t remaining, uint8_t required) {
this->notEnoughUnits(lead, remaining, required);
};
auto onBadTrailingUnit = [this](uint8_t unitsObserved) {
this->badTrailingUnit(unitsObserved);
};
auto onBadCodePoint = [this](char32_t badCodePoint, uint8_t unitsObserved) {
this->badCodePoint(badCodePoint, unitsObserved);
};
auto onNotShortestForm = [this](char32_t badCodePoint,
uint8_t unitsObserved) {
this->notShortestForm(badCodePoint, unitsObserved);
};
// If a valid code point is decoded, this function call consumes its code
// units. If not, it ungets the lead code unit and invokes the right error
// handler, so on failure we must immediately return false.
SourceUnitsIterator iter(this->sourceUnits);
Maybe<char32_t> maybeCodePoint = DecodeOneUtf8CodePointInline(
lead, &iter, SourceUnitsEnd(), onBadLeadUnit, onNotEnoughUnits,
onBadTrailingUnit, onBadCodePoint, onNotShortestForm);
if (maybeCodePoint.isNothing()) {
return false;
}
*codePoint = maybeCodePoint.value();
return true;
}
template <class AnyCharsAccess>
bool TokenStreamChars<char16_t, AnyCharsAccess>::getNonAsciiCodePoint(
int32_t lead, char32_t* codePoint) {
MOZ_ASSERT(lead != EOF);
MOZ_ASSERT(!isAsciiCodePoint(lead),
"ASCII code unit/point must be handled separately");
MOZ_ASSERT(lead == this->sourceUnits.previousCodeUnit(),
"getNonAsciiCodePoint called incorrectly");
// The code point is usually |lead|: overwrite later if needed.
*codePoint = AssertedCast<char32_t>(lead);
// ECMAScript specifically requires that unpaired UTF-16 surrogates be
// treated as the corresponding code point and not as an error. See
// <https://tc39.github.io/ecma262/#sec-ecmascript-language-types-string-type>.
// Thus this function does not consider any sequence of 16-bit numbers to
// be intrinsically in error.
// Dispense with single-unit code points and lone trailing surrogates.
if (MOZ_LIKELY(!unicode::IsLeadSurrogate(lead))) {
if (MOZ_UNLIKELY(lead == unicode::LINE_SEPARATOR ||
lead == unicode::PARA_SEPARATOR)) {
if (!updateLineInfoForEOL()) {
#ifdef DEBUG
// Assign to a sentinel value to hopefully cause errors.
*codePoint = std::numeric_limits<char32_t>::max();
#endif
MOZ_MAKE_MEM_UNDEFINED(codePoint, sizeof(*codePoint));
return false;
}
*codePoint = '\n';
} else {
MOZ_ASSERT(!IsLineTerminator(*codePoint));
}
return true;
}
// Also handle a lead surrogate not paired with a trailing surrogate.
if (MOZ_UNLIKELY(
this->sourceUnits.atEnd() ||
!unicode::IsTrailSurrogate(this->sourceUnits.peekCodeUnit()))) {
MOZ_ASSERT(!IsLineTerminator(*codePoint));
return true;
}
// Otherwise we have a multi-unit code point.
*codePoint = unicode::UTF16Decode(lead, this->sourceUnits.getCodeUnit());
MOZ_ASSERT(!IsLineTerminator(*codePoint));
return true;
}
template <class AnyCharsAccess>
bool TokenStreamChars<Utf8Unit, AnyCharsAccess>::getNonAsciiCodePoint(
int32_t unit, char32_t* codePoint) {
MOZ_ASSERT(unit != EOF);
MOZ_ASSERT(!isAsciiCodePoint(unit),
"ASCII code unit/point must be handled separately");
Utf8Unit lead = Utf8Unit(static_cast<unsigned char>(unit));
MOZ_ASSERT(lead == this->sourceUnits.previousCodeUnit(),
"getNonAsciiCodePoint called incorrectly");
auto onBadLeadUnit = [this, &lead]() { this->badLeadUnit(lead); };
auto onNotEnoughUnits = [this, &lead](uint_fast8_t remaining,
uint_fast8_t required) {
this->notEnoughUnits(lead, remaining, required);
};
auto onBadTrailingUnit = [this](uint_fast8_t unitsObserved) {
this->badTrailingUnit(unitsObserved);
};
auto onBadCodePoint = [this](char32_t badCodePoint,
uint_fast8_t unitsObserved) {
this->badCodePoint(badCodePoint, unitsObserved);
};
auto onNotShortestForm = [this](char32_t badCodePoint,
uint_fast8_t unitsObserved) {
this->notShortestForm(badCodePoint, unitsObserved);
};
// This consumes the full, valid code point or ungets |lead| and calls the
// appropriate error functor on failure.
SourceUnitsIterator iter(this->sourceUnits);
Maybe<char32_t> maybeCodePoint = DecodeOneUtf8CodePoint(
lead, &iter, SourceUnitsEnd(), onBadLeadUnit, onNotEnoughUnits,
onBadTrailingUnit, onBadCodePoint, onNotShortestForm);
if (maybeCodePoint.isNothing()) {
return false;
}
char32_t cp = maybeCodePoint.value();
if (MOZ_UNLIKELY(cp == unicode::LINE_SEPARATOR ||
cp == unicode::PARA_SEPARATOR)) {
if (!updateLineInfoForEOL()) {
#ifdef DEBUG
// Assign to a sentinel value to hopefully cause errors.
*codePoint = std::numeric_limits<char32_t>::max();
#endif
MOZ_MAKE_MEM_UNDEFINED(codePoint, sizeof(*codePoint));
return false;
}
*codePoint = '\n';
} else {
MOZ_ASSERT(!IsLineTerminator(cp));
*codePoint = cp;
}
return true;
}
template <>
size_t SourceUnits<char16_t>::findWindowStart(size_t offset) const {
// This is JS's understanding of UTF-16 that allows lone surrogates, so
// we have to exclude lone surrogates from [windowStart, offset) ourselves.
const char16_t* const earliestPossibleStart = codeUnitPtrAt(startOffset_);
const char16_t* const initial = codeUnitPtrAt(offset);
const char16_t* p = initial;
auto HalfWindowSize = [&p, &initial]() {
return PointerRangeSize(p, initial);
};
while (true) {
MOZ_ASSERT(earliestPossibleStart <= p);
MOZ_ASSERT(HalfWindowSize() <= WindowRadius);
if (p <= earliestPossibleStart || HalfWindowSize() >= WindowRadius) {
break;
}
char16_t c = p[-1];
// This stops at U+2028 LINE SEPARATOR or U+2029 PARAGRAPH SEPARATOR in
// string and template literals. These code points do affect line and
// column coordinates, even as they encode their literal values.
if (IsLineTerminator(c)) {
break;
}
// Don't allow invalid UTF-16 in pre-context. (Current users don't
// require this, and this behavior isn't currently imposed on
// pre-context, but these facts might change someday.)
if (MOZ_UNLIKELY(unicode::IsLeadSurrogate(c))) {
break;
}
// Optimistically include the code unit, reverting below if needed.
p--;
// If it's not a surrogate at all, keep going.
if (MOZ_LIKELY(!unicode::IsTrailSurrogate(c))) {
continue;
}
// Stop if we don't have a usable surrogate pair.
if (HalfWindowSize() >= WindowRadius ||
p <= earliestPossibleStart || // trail surrogate at low end
!unicode::IsLeadSurrogate(p[-1])) // no paired lead surrogate
{
p++;
break;
}
p--;
}
MOZ_ASSERT(HalfWindowSize() <= WindowRadius);
return offset - HalfWindowSize();
}
template <>
size_t SourceUnits<Utf8Unit>::findWindowStart(size_t offset) const {
// |offset| must be the location of the error or somewhere before it, so we
// know preceding data is valid UTF-8.
const Utf8Unit* const earliestPossibleStart = codeUnitPtrAt(startOffset_);
const Utf8Unit* const initial = codeUnitPtrAt(offset);
const Utf8Unit* p = initial;
auto HalfWindowSize = [&p, &initial]() {
return PointerRangeSize(p, initial);
};
while (true) {
MOZ_ASSERT(earliestPossibleStart <= p);
MOZ_ASSERT(HalfWindowSize() <= WindowRadius);
if (p <= earliestPossibleStart || HalfWindowSize() >= WindowRadius) {
break;
}
// Peek backward for a line break, and only decrement if there is none.
uint8_t prev = p[-1].toUint8();
// First check for the ASCII LineTerminators.
if (prev == '\r' || prev == '\n') {
break;
}
// Now check for the non-ASCII LineTerminators U+2028 LINE SEPARATOR
// (0xE2 0x80 0xA8) and U+2029 PARAGRAPH (0xE2 0x80 0xA9). If there
// aren't three code units available, some comparison here will fail
// before we'd underflow.
if (MOZ_UNLIKELY((prev == 0xA8 || prev == 0xA9) &&
p[-2].toUint8() == 0x80 && p[-3].toUint8() == 0xE2)) {
break;
}
// Rewind over the non-LineTerminator. This can't underflow
// |earliestPossibleStart| because it begins a code point.
while (IsTrailingUnit(*--p)) {
continue;
}
MOZ_ASSERT(earliestPossibleStart <= p);
// But if we underflowed |WindowRadius|, adjust forward and stop.
if (HalfWindowSize() > WindowRadius) {
static_assert(WindowRadius > 3,
"skipping over non-lead code units below must not "
"advance past |offset|");
while (IsTrailingUnit(*++p)) {
continue;
}
MOZ_ASSERT(HalfWindowSize() < WindowRadius);
break;
}
}
MOZ_ASSERT(HalfWindowSize() <= WindowRadius);
return offset - HalfWindowSize();
}
template <>
size_t SourceUnits<char16_t>::findWindowEnd(size_t offset) const {
const char16_t* const initial = codeUnitPtrAt(offset);
const char16_t* p = initial;
auto HalfWindowSize = [&initial, &p]() {
return PointerRangeSize(initial, p);
};
while (true) {
MOZ_ASSERT(p <= limit_);
MOZ_ASSERT(HalfWindowSize() <= WindowRadius);
if (p >= limit_ || HalfWindowSize() >= WindowRadius) {
break;
}
char16_t c = *p;
// This stops at U+2028 LINE SEPARATOR or U+2029 PARAGRAPH SEPARATOR in
// string and template literals. These code points do affect line and
// column coordinates, even as they encode their literal values.
if (IsLineTerminator(c)) {
break;
}
// Don't allow invalid UTF-16 in post-context. (Current users don't
// require this, and this behavior isn't currently imposed on
// pre-context, but these facts might change someday.)
if (MOZ_UNLIKELY(unicode::IsTrailSurrogate(c))) {
break;
}
// Optimistically consume the code unit, ungetting it below if needed.
p++;
// If it's not a surrogate at all, keep going.
if (MOZ_LIKELY(!unicode::IsLeadSurrogate(c))) {
continue;
}
// Retract if the lead surrogate would stand alone at the end of the
// window.
if (HalfWindowSize() >= WindowRadius || // split pair
p >= limit_ || // half-pair at end of source
!unicode::IsTrailSurrogate(*p)) // no paired trail surrogate
{
p--;
break;
}
p++;
}
return offset + HalfWindowSize();
}
template <>
size_t SourceUnits<Utf8Unit>::findWindowEnd(size_t offset) const {
const Utf8Unit* const initial = codeUnitPtrAt(offset);
const Utf8Unit* p = initial;
auto HalfWindowSize = [&initial, &p]() {
return PointerRangeSize(initial, p);
};
while (true) {
MOZ_ASSERT(p <= limit_);
MOZ_ASSERT(HalfWindowSize() <= WindowRadius);
if (p >= limit_ || HalfWindowSize() >= WindowRadius) {
break;
}
// A non-encoding error might be followed by an encoding error within
// |maxEnd|, so we must validate as we go to not include invalid UTF-8
// in the computed window. What joy!
Utf8Unit lead = *p;
if (mozilla::IsAscii(lead)) {
if (IsSingleUnitLineTerminator(lead)) {
break;
}
p++;
continue;
}
PeekedCodePoint<Utf8Unit> peeked = PeekCodePoint(p, limit_);
if (peeked.isNone()) {
break; // encoding error
}
char32_t c = peeked.codePoint();
if (MOZ_UNLIKELY(c == unicode::LINE_SEPARATOR ||
c == unicode::PARA_SEPARATOR)) {
break;
}
MOZ_ASSERT(!IsLineTerminator(c));
uint8_t len = peeked.lengthInUnits();
if (HalfWindowSize() + len > WindowRadius) {
break;
}
p += len;
}
MOZ_ASSERT(HalfWindowSize() <= WindowRadius);
return offset + HalfWindowSize();
}
template <typename Unit, class AnyCharsAccess>
bool TokenStreamSpecific<Unit, AnyCharsAccess>::advance(size_t position) {
const Unit* end = this->sourceUnits.codeUnitPtrAt(position);
while (this->sourceUnits.addressOfNextCodeUnit() < end) {
if (!getCodePoint()) {
return false;
}
}
TokenStreamAnyChars& anyChars = anyCharsAccess();
Token* cur = const_cast<Token*>(&anyChars.currentToken());
cur->pos.begin = this->sourceUnits.offset();
cur->pos.end = cur->pos.begin;
#ifdef DEBUG
cur->type = TokenKind::Limit;
#endif
MOZ_MAKE_MEM_UNDEFINED(&cur->type, sizeof(cur->type));
anyChars.lookahead = 0;
return true;
}
template <typename Unit, class AnyCharsAccess>
void TokenStreamSpecific<Unit, AnyCharsAccess>::seekTo(const Position& pos) {
TokenStreamAnyChars& anyChars = anyCharsAccess();
this->sourceUnits.setAddressOfNextCodeUnit(pos.buf,
/* allowPoisoned = */ true);
anyChars.flags = pos.flags;
anyChars.lineno = pos.lineno;
anyChars.linebase = pos.linebase;
anyChars.prevLinebase = pos.prevLinebase;
anyChars.lookahead = pos.lookahead;
anyChars.tokens[anyChars.cursor()] = pos.currentToken;
for (unsigned i = 0; i < anyChars.lookahead; i++) {
anyChars.tokens[anyChars.aheadCursor(1 + i)] = pos.lookaheadTokens[i];
}
}
template <typename Unit, class AnyCharsAccess>
bool TokenStreamSpecific<Unit, AnyCharsAccess>::seekTo(
const Position& pos, const TokenStreamAnyChars& other) {
if (!anyCharsAccess().srcCoords.fill(other.srcCoords)) {
return false;
}
seekTo(pos);
return true;
}
void TokenStreamAnyChars::computeErrorMetadataNoOffset(
ErrorMetadata* err) const {
err->isMuted = mutedErrors;
err->filename = filename_;
err->lineNumber = 0;
err->columnNumber = JS::ColumnNumberOneOrigin();
MOZ_ASSERT(err->lineOfContext == nullptr);
}
bool TokenStreamAnyChars::fillExceptingContext(ErrorMetadata* err,
uint32_t offset) const {
err->isMuted = mutedErrors;
// If this TokenStreamAnyChars doesn't have location information, try to
// get it from the caller.
if (!filename_) {
JSContext* maybeCx = context()->maybeCurrentJSContext();
if (maybeCx) {
NonBuiltinFrameIter iter(maybeCx,
FrameIter::FOLLOW_DEBUGGER_EVAL_PREV_LINK,
maybeCx->realm()->principals());
if (!iter.done() && iter.filename()) {
err->filename = JS::ConstUTF8CharsZ(iter.filename());
JS::TaggedColumnNumberOneOrigin columnNumber;
err->lineNumber = iter.computeLine(&columnNumber);
err->columnNumber =
JS::ColumnNumberOneOrigin(columnNumber.oneOriginValue());
return false;
}
}
}
// Otherwise use this TokenStreamAnyChars's location information.
err->filename = filename_;
return true;
}
template <>
inline void SourceUnits<char16_t>::computeWindowOffsetAndLength(
const char16_t* encodedWindow, size_t encodedTokenOffset,
size_t* utf16TokenOffset, size_t encodedWindowLength,
size_t* utf16WindowLength) const {
MOZ_ASSERT_UNREACHABLE("shouldn't need to recompute for UTF-16");
}
template <>
inline void SourceUnits<Utf8Unit>::computeWindowOffsetAndLength(
const Utf8Unit* encodedWindow, size_t encodedTokenOffset,
size_t* utf16TokenOffset, size_t encodedWindowLength,
size_t* utf16WindowLength) const {
MOZ_ASSERT(encodedTokenOffset <= encodedWindowLength,
"token offset must be within the window, and the two lambda "
"calls below presume this ordering of values");
const Utf8Unit* const encodedWindowEnd = encodedWindow + encodedWindowLength;
size_t i = 0;
auto ComputeUtf16Count = [&i, &encodedWindow](const Utf8Unit* limit) {
while (encodedWindow < limit) {
Utf8Unit lead = *encodedWindow++;
if (MOZ_LIKELY(IsAscii(lead))) {
// ASCII contributes a single UTF-16 code unit.
i++;
continue;
}
Maybe<char32_t> cp = DecodeOneUtf8CodePoint(lead, &encodedWindow, limit);
MOZ_ASSERT(cp.isSome(),
"computed window should only contain valid UTF-8");
i += unicode::IsSupplementary(cp.value()) ? 2 : 1;
}
return i;
};
// Compute the token offset from |i == 0| and the initial |encodedWindow|.
const Utf8Unit* token = encodedWindow + encodedTokenOffset;
MOZ_ASSERT(token <= encodedWindowEnd);
*utf16TokenOffset = ComputeUtf16Count(token);
// Compute the window length, picking up from |i| and |encodedWindow| that,
// in general, were modified just above.
*utf16WindowLength = ComputeUtf16Count(encodedWindowEnd);
}
template <typename Unit>
bool TokenStreamCharsBase<Unit>::addLineOfContext(ErrorMetadata* err,
uint32_t offset) const {
// Rename the variable to make meaning clearer: an offset into source units
// in Unit encoding.
size_t encodedOffset = offset;
// These are also offsets into source units in Unit encoding.
size_t encodedWindowStart = sourceUnits.findWindowStart(encodedOffset);
size_t encodedWindowEnd = sourceUnits.findWindowEnd(encodedOffset);
size_t encodedWindowLength = encodedWindowEnd - encodedWindowStart;
MOZ_ASSERT(encodedWindowLength <= SourceUnits::WindowRadius * 2);
// Don't add a useless "line" of context when the window ends up empty
// because of an invalid encoding at the start of a line.
if (encodedWindowLength == 0) {
MOZ_ASSERT(err->lineOfContext == nullptr,
"ErrorMetadata::lineOfContext must be null so we don't "
"have to set the lineLength/tokenOffset fields");
return true;
}
CharBuffer lineOfContext(fc);
const Unit* encodedWindow = sourceUnits.codeUnitPtrAt(encodedWindowStart);
if (!FillCharBufferFromSourceNormalizingAsciiLineBreaks(
lineOfContext, encodedWindow, encodedWindow + encodedWindowLength)) {
return false;
}
size_t utf16WindowLength = lineOfContext.length();
// The windowed string is null-terminated.
if (!lineOfContext.append('\0')) {
return false;
}
err->lineOfContext.reset(lineOfContext.extractOrCopyRawBuffer());
if (!err->lineOfContext) {
return false;
}
size_t encodedTokenOffset = encodedOffset - encodedWindowStart;
MOZ_ASSERT(encodedTokenOffset <= encodedWindowLength,
"token offset must be inside the window");
// The length in UTF-8 code units of a code point is always greater than or
// equal to the same code point's length in UTF-16 code points. ASCII code
// points are 1 unit in either encoding. Code points in [U+0080, U+10000)
// are 2-3 UTF-8 code units to 1 UTF-16 code unit. And code points in
// [U+10000, U+10FFFF] are 4 UTF-8 code units to 2 UTF-16 code units.
//
// Therefore, if encoded window length equals the length in UTF-16 (this is
// always the case for Unit=char16_t), the UTF-16 offsets are exactly the
// encoded offsets. Otherwise we must convert offset/length from UTF-8 to
// UTF-16.
if constexpr (std::is_same_v<Unit, char16_t>) {
MOZ_ASSERT(utf16WindowLength == encodedWindowLength,
"UTF-16 to UTF-16 shouldn't change window length");
err->tokenOffset = encodedTokenOffset;
err->lineLength = encodedWindowLength;
} else {
static_assert(std::is_same_v<Unit, Utf8Unit>, "should only see UTF-8 here");
bool simple = utf16WindowLength == encodedWindowLength;
#ifdef DEBUG
auto isAscii = [](Unit u) { return IsAscii(u); };
MOZ_ASSERT(std::all_of(encodedWindow, encodedWindow + encodedWindowLength,
isAscii) == simple,
"equal window lengths in UTF-8 should correspond only to "
"wholly-ASCII text");
#endif
if (simple) {
err->tokenOffset = encodedTokenOffset;
err->lineLength = encodedWindowLength;
} else {
sourceUnits.computeWindowOffsetAndLength(
encodedWindow, encodedTokenOffset, &err->tokenOffset,
encodedWindowLength, &err->lineLength);
}
}
return true;
}
template <typename Unit, class AnyCharsAccess>
bool TokenStreamSpecific<Unit, AnyCharsAccess>::computeErrorMetadata(
ErrorMetadata* err, const ErrorOffset& errorOffset) const {
if (errorOffset.is<NoOffset>()) {
anyCharsAccess().computeErrorMetadataNoOffset(err);
return true;
}
uint32_t offset;
if (errorOffset.is<uint32_t>()) {
offset = errorOffset.as<uint32_t>();
} else {
offset = this->sourceUnits.offset();
}
// This function's return value isn't a success/failure indication: it
// returns true if this TokenStream can be used to provide a line of
// context.
if (fillExceptingContext(err, offset)) {
// Add a line of context from this TokenStream to help with debugging.
return internalComputeLineOfContext(err, offset);
}
// We can't fill in any more here.
return true;
}
template <typename Unit, class AnyCharsAccess>
void TokenStreamSpecific<Unit, AnyCharsAccess>::reportIllegalCharacter(
int32_t cp) {
UniqueChars display = JS_smprintf("U+%04X", cp);
if (!display) {
ReportOutOfMemory(anyCharsAccess().fc);
return;
}
error(JSMSG_ILLEGAL_CHARACTER, display.get());
}
// We have encountered a '\': check for a Unicode escape sequence after it.
// Return the length of the escape sequence and the encoded code point (by
// value) if we found a Unicode escape sequence, and skip all code units
// involed. Otherwise, return 0 and don't advance along the buffer.
template <typename Unit, class AnyCharsAccess>
uint32_t GeneralTokenStreamChars<Unit, AnyCharsAccess>::matchUnicodeEscape(
char32_t* codePoint) {
MOZ_ASSERT(this->sourceUnits.previousCodeUnit() == Unit('\\'));
int32_t unit = getCodeUnit();
if (unit != 'u') {
// NOTE: |unit| may be EOF here.
ungetCodeUnit(unit);
MOZ_ASSERT(this->sourceUnits.previousCodeUnit() == Unit('\\'));
return 0;
}
char16_t v;
unit = getCodeUnit();
if (IsAsciiHexDigit(unit) && this->sourceUnits.matchHexDigits(3, &v)) {
*codePoint = (AsciiAlphanumericToNumber(unit) << 12) | v;
return 5;
}
if (unit == '{') {
return matchExtendedUnicodeEscape(codePoint);
}
// NOTE: |unit| may be EOF here, so this ungets either one or two units.
ungetCodeUnit(unit);
ungetCodeUnit('u');
MOZ_ASSERT(this->sourceUnits.previousCodeUnit() == Unit('\\'));
return 0;
}
template <typename Unit, class AnyCharsAccess>
uint32_t
GeneralTokenStreamChars<Unit, AnyCharsAccess>::matchExtendedUnicodeEscape(
char32_t* codePoint) {
MOZ_ASSERT(this->sourceUnits.previousCodeUnit() == Unit('{'));
int32_t unit = getCodeUnit();
// Skip leading zeroes.
uint32_t leadingZeroes = 0;
while (unit == '0') {
leadingZeroes++;
unit = getCodeUnit();
}
size_t i = 0;
uint32_t code = 0;
while (IsAsciiHexDigit(unit) && i < 6) {
code = (code << 4) | AsciiAlphanumericToNumber(unit);
unit = getCodeUnit();
i++;
}
uint32_t gotten =
2 + // 'u{'
leadingZeroes + i + // significant hexdigits
(unit != EOF); // subtract a get if it didn't contribute to length
if (unit == '}' && (leadingZeroes > 0 || i > 0) &&
code <= unicode::NonBMPMax) {
*codePoint = code;
return gotten;
}
this->sourceUnits.unskipCodeUnits(gotten);
MOZ_ASSERT(this->sourceUnits.previousCodeUnit() == Unit('\\'));
return 0;
}
template <typename Unit, class AnyCharsAccess>
uint32_t
GeneralTokenStreamChars<Unit, AnyCharsAccess>::matchUnicodeEscapeIdStart(
char32_t* codePoint) {
uint32_t length = matchUnicodeEscape(codePoint);
if (MOZ_LIKELY(length > 0)) {
if (MOZ_LIKELY(unicode::IsIdentifierStart(*codePoint))) {
return length;
}
this->sourceUnits.unskipCodeUnits(length);
}
MOZ_ASSERT(this->sourceUnits.previousCodeUnit() == Unit('\\'));
return 0;
}
template <typename Unit, class AnyCharsAccess>
bool GeneralTokenStreamChars<Unit, AnyCharsAccess>::matchUnicodeEscapeIdent(
char32_t* codePoint) {
uint32_t length = matchUnicodeEscape(codePoint);
if (MOZ_LIKELY(length > 0)) {
if (MOZ_LIKELY(unicode::IsIdentifierPart(*codePoint))) {
return true;
}
this->sourceUnits.unskipCodeUnits(length);
}
MOZ_ASSERT(this->sourceUnits.previousCodeUnit() == Unit('\\'));
return false;
}
template <typename Unit, class AnyCharsAccess>
[[nodiscard]] bool
TokenStreamSpecific<Unit, AnyCharsAccess>::matchIdentifierStart(
IdentifierEscapes* sawEscape) {
int32_t unit = getCodeUnit();
if (unit == EOF) {
error(JSMSG_MISSING_PRIVATE_NAME);
return false;
}
if (MOZ_LIKELY(isAsciiCodePoint(unit))) {
if (unicode::IsIdentifierStart(char16_t(unit))) {
*sawEscape = IdentifierEscapes::None;
return true;
}
if (unit == '\\') {
char32_t codePoint;
uint32_t escapeLength = matchUnicodeEscapeIdStart(&codePoint);
if (escapeLength != 0) {
*sawEscape = IdentifierEscapes::SawUnicodeEscape;
return true;
}
// We could point "into" a mistyped escape, e.g. for "\u{41H}" we
// could point at the 'H'. But we don't do that now, so the code
// unit after the '\' isn't necessarily bad, so just point at the
// start of the actually-invalid escape.
ungetCodeUnit('\\');
error(JSMSG_BAD_ESCAPE);
return false;
}
}
// Unget the lead code unit before peeking at the full code point.
ungetCodeUnit(unit);
PeekedCodePoint<Unit> peeked = this->sourceUnits.peekCodePoint();
if (!peeked.isNone() && unicode::IsIdentifierStart(peeked.codePoint())) {
this->sourceUnits.consumeKnownCodePoint(peeked);
*sawEscape = IdentifierEscapes::None;
return true;
}
error(JSMSG_MISSING_PRIVATE_NAME);
return false;
}
template <typename Unit, class AnyCharsAccess>
bool TokenStreamSpecific<Unit, AnyCharsAccess>::getDirectives(
bool isMultiline, bool shouldWarnDeprecated) {
// Match directive comments used in debugging, such as "//# sourceURL" and
// "//# sourceMappingURL". Use of "//@" instead of "//#" is deprecated.
//
// To avoid a crashing bug in IE, several JavaScript transpilers wrap single
// line comments containing a source mapping URL inside a multiline
// comment. To avoid potentially expensive lookahead and backtracking, we
// only check for this case if we encounter a '#' code unit.
bool res = getDisplayURL(isMultiline, shouldWarnDeprecated) &&
getSourceMappingURL(isMultiline, shouldWarnDeprecated);
if (!res) {
badToken();
}
return res;
}
[[nodiscard]] bool TokenStreamCharsShared::copyCharBufferTo(
UniquePtr<char16_t[], JS::FreePolicy>* destination) {
size_t length = charBuffer.length();
*destination = fc->getAllocator()->make_pod_array<char16_t>(length + 1);
if (!*destination) {
return false;
}
std::copy(charBuffer.begin(), charBuffer.end(), destination->get());
(*destination)[length] = '\0';
return true;
}
template <typename Unit, class AnyCharsAccess>
[[nodiscard]] bool TokenStreamSpecific<Unit, AnyCharsAccess>::getDirective(
bool isMultiline, bool shouldWarnDeprecated, const char* directive,
uint8_t directiveLength, const char* errorMsgPragma,
UniquePtr<char16_t[], JS::FreePolicy>* destination) {
// Stop if we don't find |directive|. (Note that |directive| must be
// ASCII, so there are no tricky encoding issues to consider in matching
// UTF-8/16-agnostically.)
if (!this->sourceUnits.matchCodeUnits(directive, directiveLength)) {
return true;
}
if (shouldWarnDeprecated) {
if (!warning(JSMSG_DEPRECATED_PRAGMA, errorMsgPragma)) {
return false;
}
}
this->charBuffer.clear();
do {
int32_t unit = peekCodeUnit();
if (unit == EOF) {
break;
}
if (MOZ_LIKELY(isAsciiCodePoint(unit))) {
if (unicode::IsSpace(AssertedCast<Latin1Char>(unit))) {
break;
}
consumeKnownCodeUnit(unit);
// Debugging directives can occur in both single- and multi-line
// comments. If we're currently inside a multi-line comment, we
// also must recognize multi-line comment terminators.
if (isMultiline && unit == '*' && peekCodeUnit() == '/') {
ungetCodeUnit('*');
break;
}
if (!this->charBuffer.append(unit)) {
return false;
}
continue;
}
// This ignores encoding errors: subsequent caller-side code to
// handle the remaining source text in the comment will do so.
PeekedCodePoint<Unit> peeked = this->sourceUnits.peekCodePoint();
if (peeked.isNone() || unicode::IsSpace(peeked.codePoint())) {
break;
}
MOZ_ASSERT(!IsLineTerminator(peeked.codePoint()),
"!IsSpace must imply !IsLineTerminator or else we'll fail to "
"maintain line-info/flags for EOL");
this->sourceUnits.consumeKnownCodePoint(peeked);
if (!AppendCodePointToCharBuffer(this->charBuffer, peeked.codePoint())) {
return false;
}
} while (true);
if (this->charBuffer.empty()) {
// The directive's URL was missing, but comments can contain anything,
// so it isn't an error.
return true;
}
return copyCharBufferTo(destination);
}
template <typename Unit, class AnyCharsAccess>
bool TokenStreamSpecific<Unit, AnyCharsAccess>::getDisplayURL(
bool isMultiline, bool shouldWarnDeprecated) {
// Match comments of the form "//# sourceURL=<url>" or
// "/\* //# sourceURL=<url> *\/"
//
// Note that while these are labeled "sourceURL" in the source text,
// internally we refer to it as a "displayURL" to distinguish what the
// developer would like to refer to the source as from the source's actual
// URL.
static constexpr char sourceURLDirective[] = " sourceURL=";
constexpr uint8_t sourceURLDirectiveLength = js_strlen(sourceURLDirective);
return getDirective(isMultiline, shouldWarnDeprecated, sourceURLDirective,
sourceURLDirectiveLength, "sourceURL",
&anyCharsAccess().displayURL_);
}
template <typename Unit, class AnyCharsAccess>
bool TokenStreamSpecific<Unit, AnyCharsAccess>::getSourceMappingURL(
bool isMultiline, bool shouldWarnDeprecated) {
// Match comments of the form "//# sourceMappingURL=<url>" or
// "/\* //# sourceMappingURL=<url> *\/"
static constexpr char sourceMappingURLDirective[] = " sourceMappingURL=";
constexpr uint8_t sourceMappingURLDirectiveLength =
js_strlen(sourceMappingURLDirective);
return getDirective(isMultiline, shouldWarnDeprecated,
sourceMappingURLDirective,
sourceMappingURLDirectiveLength, "sourceMappingURL",
&anyCharsAccess().sourceMapURL_);
}
template <typename Unit, class AnyCharsAccess>
MOZ_ALWAYS_INLINE Token*
GeneralTokenStreamChars<Unit, AnyCharsAccess>::newTokenInternal(
TokenKind kind, TokenStart start, TokenKind* out) {
MOZ_ASSERT(kind < TokenKind::Limit);
MOZ_ASSERT(kind != TokenKind::Eol,
"TokenKind::Eol should never be used in an actual Token, only "
"returned by peekTokenSameLine()");
TokenStreamAnyChars& anyChars = anyCharsAccess();
anyChars.flags.isDirtyLine = true;
Token* token = anyChars.allocateToken();
*out = token->type = kind;
token->pos = TokenPos(start.offset(), this->sourceUnits.offset());
MOZ_ASSERT(token->pos.begin <= token->pos.end);
// NOTE: |token->modifier| is set in |newToken()| so that optimized,
// non-debug code won't do any work to pass a modifier-argument that will
// never be used.
return token;
}
template <typename Unit, class AnyCharsAccess>
MOZ_COLD bool GeneralTokenStreamChars<Unit, AnyCharsAccess>::badToken() {
// We didn't get a token, so don't set |flags.isDirtyLine|.
anyCharsAccess().flags.hadError = true;
// Poisoning sourceUnits on error establishes an invariant: once an
// erroneous token has been seen, sourceUnits will not be consulted again.
// This is true because the parser will deal with the illegal token by
// aborting parsing immediately.
this->sourceUnits.poisonInDebug();
return false;
};
bool AppendCodePointToCharBuffer(CharBuffer& charBuffer, char32_t codePoint) {
MOZ_ASSERT(codePoint <= unicode::NonBMPMax,
"should only be processing code points validly decoded from UTF-8 "
"or WTF-16 source text (surrogate code points permitted)");
char16_t units[2];
unsigned numUnits = 0;
unicode::UTF16Encode(codePoint, units, &numUnits);
MOZ_ASSERT(numUnits == 1 || numUnits == 2,
"UTF-16 code points are only encoded in one or two units");
if (!charBuffer.append(units[0])) {
return false;
}
if (numUnits == 1) {
return true;
}
return charBuffer.append(units[1]);
}
template <typename Unit, class AnyCharsAccess>
bool TokenStreamSpecific<Unit, AnyCharsAccess>::putIdentInCharBuffer(
const Unit* identStart) {
const Unit* const originalAddress = this->sourceUnits.addressOfNextCodeUnit();
this->sourceUnits.setAddressOfNextCodeUnit(identStart);
auto restoreNextRawCharAddress = MakeScopeExit([this, originalAddress]() {
this->sourceUnits.setAddressOfNextCodeUnit(originalAddress);
});
this->charBuffer.clear();
do {
int32_t unit = getCodeUnit();
if (unit == EOF) {
break;
}
char32_t codePoint;
if (MOZ_LIKELY(isAsciiCodePoint(unit))) {
if (unicode::IsIdentifierPart(char16_t(unit)) || unit == '#') {
if (!this->charBuffer.append(unit)) {
return false;
}
continue;
}
if (unit != '\\' || !matchUnicodeEscapeIdent(&codePoint)) {
break;
}
} else {
// |restoreNextRawCharAddress| undoes all gets, and this function
// doesn't update line/column info.
char32_t cp;
if (!getNonAsciiCodePointDontNormalize(toUnit(unit), &cp)) {
return false;
}
codePoint = cp;
if (!unicode::IsIdentifierPart(codePoint)) {
break;
}
}
if (!AppendCodePointToCharBuffer(this->charBuffer, codePoint)) {
return false;
}
} while (true);
return true;
}
template <typename Unit, class AnyCharsAccess>
[[nodiscard]] bool TokenStreamSpecific<Unit, AnyCharsAccess>::identifierName(
TokenStart start, const Unit* identStart, IdentifierEscapes escaping,
Modifier modifier, NameVisibility visibility, TokenKind* out) {
// Run the bad-token code for every path out of this function except the
// two success-cases.
auto noteBadToken = MakeScopeExit([this]() { this->badToken(); });
// We've already consumed an initial code point in the identifer, to *know*
// that this is an identifier. So no need to worry about not consuming any
// code points in the loop below.
int32_t unit;
while (true) {
unit = peekCodeUnit();
if (unit == EOF) {
break;
}
if (MOZ_LIKELY(isAsciiCodePoint(unit))) {
consumeKnownCodeUnit(unit);
if (MOZ_UNLIKELY(
!unicode::IsIdentifierPart(static_cast<char16_t>(unit)))) {
// Handle a Unicode escape -- otherwise it's not part of the
// identifier.
char32_t codePoint;
if (unit != '\\' || !matchUnicodeEscapeIdent(&codePoint)) {
ungetCodeUnit(unit);
break;
}
escaping = IdentifierEscapes::SawUnicodeEscape;
}
} else {
// This ignores encoding errors: subsequent caller-side code to
// handle source text after the IdentifierName will do so.
PeekedCodePoint<Unit> peeked = this->sourceUnits.peekCodePoint();
if (peeked.isNone() || !unicode::IsIdentifierPart(peeked.codePoint())) {
break;
}
MOZ_ASSERT(!IsLineTerminator(peeked.codePoint()),
"IdentifierPart must guarantee !IsLineTerminator or "
"else we'll fail to maintain line-info/flags for EOL");
this->sourceUnits.consumeKnownCodePoint(peeked);
}
}
TaggedParserAtomIndex atom;
if (MOZ_UNLIKELY(escaping == IdentifierEscapes::SawUnicodeEscape)) {
// Identifiers containing Unicode escapes have to be converted into
// tokenbuf before atomizing.
if (!putIdentInCharBuffer(identStart)) {
return false;
}
atom = drainCharBufferIntoAtom();
} else {
// Escape-free identifiers can be created directly from sourceUnits.
const Unit* chars = identStart;
size_t length = this->sourceUnits.addressOfNextCodeUnit() - identStart;
// Private identifiers start with a '#', and so cannot be reserved words.
if (visibility == NameVisibility::Public) {
// Represent reserved words lacking escapes as reserved word tokens.
if (const ReservedWordInfo* rw = FindReservedWord(chars, length)) {
noteBadToken.release();
newSimpleToken(rw->tokentype, start, modifier, out);
return true;
}
}
atom = atomizeSourceChars(Span(chars, length));
}
if (!atom) {
return false;
}
noteBadToken.release();
if (visibility == NameVisibility::Private) {
newPrivateNameToken(atom, start, modifier, out);
return true;
}
newNameToken(atom, start, modifier, out);
return true;
}
enum FirstCharKind {
// A char16_t has the 'OneChar' kind if it, by itself, constitutes a valid
// token that cannot also be a prefix of a longer token. E.g. ';' has the
// OneChar kind, but '+' does not, because '++' and '+=' are valid longer
// tokens
// that begin with '+'.
//
// The few token kinds satisfying these properties cover roughly 35--45%
// of the tokens seen in practice.
//
// We represent the 'OneChar' kind with any positive value less than
// TokenKind::Limit. This representation lets us associate
// each one-char token char16_t with a TokenKind and thus avoid
// a subsequent char16_t-to-TokenKind conversion.
OneChar_Min = 0,
OneChar_Max = size_t(TokenKind::Limit) - 1,
Space = size_t(TokenKind::Limit),
Ident,
Dec,
String,
EOL,
ZeroDigit,
Other,
LastCharKind = Other
};
// OneChar: 40, 41, 44, 58, 59, 91, 93, 123, 125, 126:
// '(', ')', ',', ':', ';', '[', ']', '{', '}', '~'
// Ident: 36, 65..90, 95, 97..122: '$', 'A'..'Z', '_', 'a'..'z'
// Dot: 46: '.'
// Equals: 61: '='
// String: 34, 39, 96: '"', '\'', '`'
// Dec: 49..57: '1'..'9'
// Plus: 43: '+'
// ZeroDigit: 48: '0'
// Space: 9, 11, 12, 32: '\t', '\v', '\f', ' '
// EOL: 10, 13: '\n', '\r'
//
#define T_COMMA size_t(TokenKind::Comma)
#define T_COLON size_t(TokenKind::Colon)
#define T_BITNOT size_t(TokenKind::BitNot)
#define T_LP size_t(TokenKind::LeftParen)
#define T_RP size_t(TokenKind::RightParen)
#define T_SEMI size_t(TokenKind::Semi)
#define T_LB size_t(TokenKind::LeftBracket)
#define T_RB size_t(TokenKind::RightBracket)
#define T_LC size_t(TokenKind::LeftCurly)
#define T_RC size_t(TokenKind::RightCurly)
#define _______ Other
static const uint8_t firstCharKinds[] = {
// clang-format off
/* 0 1 2 3 4 5 6 7 8 9 */
/* 0+ */ _______, _______, _______, _______, _______, _______, _______, _______, _______, Space,
/* 10+ */ EOL, Space, Space, EOL, _______, _______, _______, _______, _______, _______,
/* 20+ */ _______, _______, _______, _______, _______, _______, _______, _______, _______, _______,
/* 30+ */ _______, _______, Space, _______, String, _______, Ident, _______, _______, String,
/* 40+ */ T_LP, T_RP, _______, _______, T_COMMA, _______, _______, _______,ZeroDigit, Dec,
/* 50+ */ Dec, Dec, Dec, Dec, Dec, Dec, Dec, Dec, T_COLON, T_SEMI,
/* 60+ */ _______, _______, _______, _______, _______, Ident, Ident, Ident, Ident, Ident,
/* 70+ */ Ident, Ident, Ident, Ident, Ident, Ident, Ident, Ident, Ident, Ident,
/* 80+ */ Ident, Ident, Ident, Ident, Ident, Ident, Ident, Ident, Ident, Ident,
/* 90+ */ Ident, T_LB, _______, T_RB, _______, Ident, String, Ident, Ident, Ident,
/* 100+ */ Ident, Ident, Ident, Ident, Ident, Ident, Ident, Ident, Ident, Ident,
/* 110+ */ Ident, Ident, Ident, Ident, Ident, Ident, Ident, Ident, Ident, Ident,
/* 120+ */ Ident, Ident, Ident, T_LC, _______, T_RC,T_BITNOT, _______
// clang-format on
};
#undef T_COMMA
#undef T_COLON
#undef T_BITNOT
#undef T_LP
#undef T_RP
#undef T_SEMI
#undef T_LB
#undef T_RB
#undef T_LC
#undef T_RC
#undef _______
static_assert(LastCharKind < (1 << (sizeof(firstCharKinds[0]) * 8)),
"Elements of firstCharKinds[] are too small");
template <>
void SourceUnits<char16_t>::consumeRestOfSingleLineComment() {
while (MOZ_LIKELY(!atEnd())) {
char16_t unit = peekCodeUnit();
if (IsLineTerminator(unit)) {
return;
}
consumeKnownCodeUnit(unit);
}
}
template <>
void SourceUnits<Utf8Unit>::consumeRestOfSingleLineComment() {
while (MOZ_LIKELY(!atEnd())) {
const Utf8Unit unit = peekCodeUnit();
if (IsSingleUnitLineTerminator(unit)) {
return;
}
if (MOZ_LIKELY(IsAscii(unit))) {
consumeKnownCodeUnit(unit);
continue;
}
PeekedCodePoint<Utf8Unit> peeked = peekCodePoint();
if (peeked.isNone()) {
return;
}
char32_t c = peeked.codePoint();
if (MOZ_UNLIKELY(c == unicode::LINE_SEPARATOR ||
c == unicode::PARA_SEPARATOR)) {
return;
}
consumeKnownCodePoint(peeked);
}
}
template <typename Unit, class AnyCharsAccess>
[[nodiscard]] MOZ_ALWAYS_INLINE bool
TokenStreamSpecific<Unit, AnyCharsAccess>::matchInteger(
IsIntegerUnit isIntegerUnit, int32_t* nextUnit) {
int32_t unit = getCodeUnit();
if (!isIntegerUnit(unit)) {
*nextUnit = unit;
return true;
}
return matchIntegerAfterFirstDigit(isIntegerUnit, nextUnit);
}
template <typename Unit, class AnyCharsAccess>
[[nodiscard]] MOZ_ALWAYS_INLINE bool
TokenStreamSpecific<Unit, AnyCharsAccess>::matchIntegerAfterFirstDigit(
IsIntegerUnit isIntegerUnit, int32_t* nextUnit) {
int32_t unit;
while (true) {
unit = getCodeUnit();
if (isIntegerUnit(unit)) {
continue;
}
if (unit != '_') {
break;
}
unit = getCodeUnit();
if (!isIntegerUnit(unit)) {
if (unit == '_') {
ungetCodeUnit(unit);
error(JSMSG_NUMBER_MULTIPLE_ADJACENT_UNDERSCORES);
} else {
ungetCodeUnit(unit);
ungetCodeUnit('_');
error(JSMSG_NUMBER_END_WITH_UNDERSCORE);
}
return false;
}
}
*nextUnit = unit;
return true;
}
template <typename Unit, class AnyCharsAccess>
[[nodiscard]] bool TokenStreamSpecific<Unit, AnyCharsAccess>::decimalNumber(
int32_t unit, TokenStart start, const Unit* numStart, Modifier modifier,
TokenKind* out) {
// Run the bad-token code for every path out of this function except the
// one success-case.
auto noteBadToken = MakeScopeExit([this]() { this->badToken(); });
// Consume integral component digits.
if (IsAsciiDigit(unit)) {
if (!matchIntegerAfterFirstDigit(IsAsciiDigit, &unit)) {
return false;
}
}
// Numbers contain no escapes, so we can read directly from |sourceUnits|.
double dval;
bool isBigInt = false;
DecimalPoint decimalPoint = NoDecimal;
if (unit != '.' && unit != 'e' && unit != 'E' && unit != 'n') {
// NOTE: |unit| may be EOF here.
ungetCodeUnit(unit);
// Most numbers are pure decimal integers without fractional component
// or exponential notation. Handle that with optimized code.
if (!GetDecimalInteger(numStart, this->sourceUnits.addressOfNextCodeUnit(),
&dval)) {
ReportOutOfMemory(this->fc);
return false;
}
} else if (unit == 'n') {
isBigInt = true;
unit = peekCodeUnit();
} else {
// Consume any decimal dot and fractional component.
if (unit == '.') {
decimalPoint = HasDecimal;
if (!matchInteger(IsAsciiDigit, &unit)) {
return false;
}
}
// Consume any exponential notation.
if (unit == 'e' || unit == 'E') {
unit = getCodeUnit();
if (unit == '+' || unit == '-') {
unit = getCodeUnit();
}
// Exponential notation must contain at least one digit.
if (!IsAsciiDigit(unit)) {
ungetCodeUnit(unit);
error(JSMSG_MISSING_EXPONENT);
return false;
}
// Consume exponential digits.
if (!matchIntegerAfterFirstDigit(IsAsciiDigit, &unit)) {
return false;
}
}
ungetCodeUnit(unit);
if (!GetDecimal(numStart, this->sourceUnits.addressOfNextCodeUnit(),
&dval)) {
ReportOutOfMemory(this->fc);
return false;
}
}
// Number followed by IdentifierStart is an error. (This is the only place
// in ECMAScript where token boundary is inadequate to properly separate
// two tokens, necessitating this unaesthetic lookahead.)
if (unit != EOF) {
if (MOZ_LIKELY(isAsciiCodePoint(unit))) {
if (unicode::IsIdentifierStart(char16_t(unit))) {
error(JSMSG_IDSTART_AFTER_NUMBER);
return false;
}
} else {
// This ignores encoding errors: subsequent caller-side code to
// handle source text after the number will do so.
PeekedCodePoint<Unit> peeked = this->sourceUnits.peekCodePoint();
if (!peeked.isNone() && unicode::IsIdentifierStart(peeked.codePoint())) {
error(JSMSG_IDSTART_AFTER_NUMBER);
return false;
}
}
}
noteBadToken.release();
if (isBigInt) {
return bigIntLiteral(start, modifier, out);
}
newNumberToken(dval, decimalPoint, start, modifier, out);
return true;
}
template <typename Unit, class AnyCharsAccess>
[[nodiscard]] bool TokenStreamSpecific<Unit, AnyCharsAccess>::regexpLiteral(
TokenStart start, TokenKind* out) {
MOZ_ASSERT(this->sourceUnits.previousCodeUnit() == Unit('/'));
this->charBuffer.clear();
auto ProcessNonAsciiCodePoint = [this](int32_t lead) {
MOZ_ASSERT(lead != EOF);
MOZ_ASSERT(!this->isAsciiCodePoint(lead));
char32_t codePoint;
if (!this->getNonAsciiCodePointDontNormalize(this->toUnit(lead),
&codePoint)) {
return false;
}
if (MOZ_UNLIKELY(codePoint == unicode::LINE_SEPARATOR ||
codePoint == unicode::PARA_SEPARATOR)) {
this->sourceUnits.ungetLineOrParagraphSeparator();
this->error(JSMSG_UNTERMINATED_REGEXP);
return false;
}
return AppendCodePointToCharBuffer(this->charBuffer, codePoint);
};
auto ReportUnterminatedRegExp = [this](int32_t unit) {
this->ungetCodeUnit(unit);
this->error(JSMSG_UNTERMINATED_REGEXP);
};
bool inCharClass = false;
do {
int32_t unit = getCodeUnit();
if (unit == EOF) {
ReportUnterminatedRegExp(unit);
return badToken();
}
if (MOZ_UNLIKELY(!isAsciiCodePoint(unit))) {
if (!ProcessNonAsciiCodePoint(unit)) {
return badToken();
}
continue;
}
if (unit == '\\') {
if (!this->charBuffer.append(unit)) {
return badToken();
}
unit = getCodeUnit();
if (unit == EOF) {
ReportUnterminatedRegExp(unit);
return badToken();
}
// Fallthrough only handles ASCII code points, so
// deal with non-ASCII and skip everything else.
if (MOZ_UNLIKELY(!isAsciiCodePoint(unit))) {
if (!ProcessNonAsciiCodePoint(unit)) {
return badToken();
}
continue;
}
} else if (unit == '[') {
inCharClass = true;
} else if (unit == ']') {
inCharClass = false;
} else if (unit == '/' && !inCharClass) {
// For IE compat, allow unescaped / in char classes.
break;
}
// NOTE: Non-ASCII LineTerminators were handled by
// ProcessNonAsciiCodePoint calls above.
if (unit == '\r' || unit == '\n') {
ReportUnterminatedRegExp(unit);
return badToken();
}
MOZ_ASSERT(!IsLineTerminator(AssertedCast<char32_t>(unit)));
if (!this->charBuffer.append(unit)) {
return badToken();
}
} while (true);
int32_t unit;
RegExpFlags reflags = RegExpFlag::NoFlags;
while (true) {
uint8_t flag;
unit = getCodeUnit();
if (unit == 'd') {
flag = RegExpFlag::HasIndices;
} else if (unit == 'g') {
flag = RegExpFlag::Global;
} else if (unit == 'i') {
flag = RegExpFlag::IgnoreCase;
} else if (unit == 'm') {
flag = RegExpFlag::Multiline;
} else if (unit == 's') {
flag = RegExpFlag::DotAll;
} else if (unit == 'u') {
flag = RegExpFlag::Unicode;
} else if (unit == 'v') {
flag = RegExpFlag::UnicodeSets;
} else if (unit == 'y') {
flag = RegExpFlag::Sticky;
} else if (IsAsciiAlpha(unit)) {
flag = RegExpFlag::NoFlags;
} else {
break;
}
if ((reflags & flag) || flag == RegExpFlag::NoFlags) {
ungetCodeUnit(unit);
char buf[2] = {char(unit), '\0'};
error(JSMSG_BAD_REGEXP_FLAG, buf);
return badToken();
}
// /u and /v flags are mutually exclusive.
if (((reflags & RegExpFlag::Unicode) && (flag & RegExpFlag::UnicodeSets)) ||
((reflags & RegExpFlag::UnicodeSets) && (flag & RegExpFlag::Unicode))) {
ungetCodeUnit(unit);
char buf[2] = {char(unit), '\0'};
error(JSMSG_BAD_REGEXP_FLAG, buf);
return badToken();
}
reflags |= flag;
}
ungetCodeUnit(unit);
newRegExpToken(reflags, start, out);
return true;
}
template <typename Unit, class AnyCharsAccess>
[[nodiscard]] bool TokenStreamSpecific<Unit, AnyCharsAccess>::bigIntLiteral(
TokenStart start, Modifier modifier, TokenKind* out) {
MOZ_ASSERT(this->sourceUnits.previousCodeUnit() == toUnit('n'));
MOZ_ASSERT(this->sourceUnits.offset() > start.offset());
uint32_t length = this->sourceUnits.offset() - start.offset();
MOZ_ASSERT(length >= 2);
this->charBuffer.clear();
mozilla::Range<const Unit> chars(
this->sourceUnits.codeUnitPtrAt(start.offset()), length);
for (uint32_t idx = 0; idx < length - 1; idx++) {
int32_t unit = CodeUnitValue(chars[idx]);
// Char buffer may start with a 0[bBoOxX] prefix, then follows with
// binary, octal, decimal, or hex digits. Already checked by caller, as
// the "n" indicating bigint comes at the end.
MOZ_ASSERT(isAsciiCodePoint(unit));
// Skip over any separators.
if (unit == '_') {
continue;
}
if (!AppendCodePointToCharBuffer(this->charBuffer, unit)) {
return false;
}
}
newBigIntToken(start, modifier, out);
return true;
}
template <typename Unit, class AnyCharsAccess>
void GeneralTokenStreamChars<Unit,
AnyCharsAccess>::consumeOptionalHashbangComment() {
MOZ_ASSERT(this->sourceUnits.atStart(),
"HashBangComment can only appear immediately at the start of a "
"Script or Module");
// HashbangComment ::
// #! SingleLineCommentChars_opt
if (!matchCodeUnit('#')) {
// HashbangComment is optional at start of Script or Module.
return;
}
if (!matchCodeUnit('!')) {
// # not followed by ! at start of Script or Module is an error, but normal
// parsing code will handle that error just fine if we let it.
ungetCodeUnit('#');
return;
}
// This doesn't consume a concluding LineTerminator, and it stops consuming
// just before any encoding error. The subsequent |getToken| call will call
// |getTokenInternal| below which will handle these possibilities.
this->sourceUnits.consumeRestOfSingleLineComment();
}
template <typename Unit, class AnyCharsAccess>
[[nodiscard]] bool TokenStreamSpecific<Unit, AnyCharsAccess>::getTokenInternal(
TokenKind* const ttp, const Modifier modifier) {
// Assume we'll fail: success cases will overwrite this.
#ifdef DEBUG
*ttp = TokenKind::Limit;
#endif
MOZ_MAKE_MEM_UNDEFINED(ttp, sizeof(*ttp));
// This loop runs more than once only when whitespace or comments are
// encountered.
do {
int32_t unit = peekCodeUnit();
if (MOZ_UNLIKELY(unit == EOF)) {
MOZ_ASSERT(this->sourceUnits.atEnd());
anyCharsAccess().flags.isEOF = true;
TokenStart start(this->sourceUnits, 0);
newSimpleToken(TokenKind::Eof, start, modifier, ttp);
return true;
}
if (MOZ_UNLIKELY(!isAsciiCodePoint(unit))) {
// Non-ASCII code points can only be identifiers or whitespace. It would
// be nice to compute these *after* discarding whitespace, but IN A WORLD
// where |unicode::IsSpace| requires consuming a variable number of code
// units, it's easier to assume it's an identifier and maybe do a little
// wasted work, than to unget and compute and reget if whitespace.
TokenStart start(this->sourceUnits, 0);
const Unit* identStart = this->sourceUnits.addressOfNextCodeUnit();
PeekedCodePoint<Unit> peeked = this->sourceUnits.peekCodePoint();
if (peeked.isNone()) {
MOZ_ALWAYS_FALSE(getCodePoint());
return badToken();
}
char32_t cp = peeked.codePoint();
if (unicode::IsSpace(cp)) {
this->sourceUnits.consumeKnownCodePoint(peeked);
if (IsLineTerminator(cp)) {
if (!updateLineInfoForEOL()) {
return badToken();
}
anyCharsAccess().updateFlagsForEOL();
}
continue;
}
static_assert(isAsciiCodePoint('$'),
"IdentifierStart contains '$', but as "
"!IsUnicodeIDStart('$'), ensure that '$' is never "
"handled here");
static_assert(isAsciiCodePoint('_'),
"IdentifierStart contains '_', but as "
"!IsUnicodeIDStart('_'), ensure that '_' is never "
"handled here");
if (MOZ_LIKELY(unicode::IsUnicodeIDStart(cp))) {
this->sourceUnits.consumeKnownCodePoint(peeked);
MOZ_ASSERT(!IsLineTerminator(cp),
"IdentifierStart must guarantee !IsLineTerminator "
"or else we'll fail to maintain line-info/flags "
"for EOL here");
return identifierName(start, identStart, IdentifierEscapes::None,
modifier, NameVisibility::Public, ttp);
}
reportIllegalCharacter(cp);
return badToken();
} // !isAsciiCodePoint(unit)
consumeKnownCodeUnit(unit);
// Get the token kind, based on the first char. The ordering of c1kind
// comparison is based on the frequency of tokens in real code:
// Parsemark (which represents typical JS code on the web) and the
// Unreal demo (which represents asm.js code).
//
// Parsemark Unreal
// OneChar 32.9% 39.7%
// Space 25.0% 0.6%
// Ident 19.2% 36.4%
// Dec 7.2% 5.1%
// String 7.9% 0.0%
// EOL 1.7% 0.0%
// ZeroDigit 0.4% 4.9%
// Other 5.7% 13.3%
//
// The ordering is based mostly only Parsemark frequencies, with Unreal
// frequencies used to break close categories (e.g. |Dec| and
// |String|). |Other| is biggish, but no other token kind is common
// enough for it to be worth adding extra values to FirstCharKind.
FirstCharKind c1kind = FirstCharKind(firstCharKinds[unit]);
// Look for an unambiguous single-char token.
//
if (c1kind <= OneChar_Max) {
TokenStart start(this->sourceUnits, -1);
newSimpleToken(TokenKind(c1kind), start, modifier, ttp);
return true;
}
// Skip over non-EOL whitespace chars.
//
if (c1kind == Space) {
continue;
}
// Look for an identifier.
//
if (c1kind == Ident) {
TokenStart start(this->sourceUnits, -1);
return identifierName(
start, this->sourceUnits.addressOfNextCodeUnit() - 1,
IdentifierEscapes::None, modifier, NameVisibility::Public, ttp);
}
// Look for a decimal number.
//
if (c1kind == Dec) {
TokenStart start(this->sourceUnits, -1);
const Unit* numStart = this->sourceUnits.addressOfNextCodeUnit() - 1;
return decimalNumber(unit, start, numStart, modifier, ttp);
}
// Look for a string or a template string.
//
if (c1kind == String) {
return getStringOrTemplateToken(static_cast<char>(unit), modifier, ttp);
}
// Skip over EOL chars, updating line state along the way.
//
if (c1kind == EOL) {
if (unit == '\r') {
matchLineTerminator('\n');
}
if (!updateLineInfoForEOL()) {
return badToken();
}
anyCharsAccess().updateFlagsForEOL();
continue;
}
// From a '0', look for a hexadecimal, binary, octal, or "noctal" (a
// number starting with '0' that contains '8' or '9' and is treated as
// decimal) number.
//
if (c1kind == ZeroDigit) {
TokenStart start(this->sourceUnits, -1);
int radix;
bool isBigInt = false;
const Unit* numStart;
unit = getCodeUnit();
if (unit == 'x' || unit == 'X') {
radix = 16;
unit = getCodeUnit();
if (!IsAsciiHexDigit(unit)) {
// NOTE: |unit| may be EOF here.
ungetCodeUnit(unit);
error(JSMSG_MISSING_HEXDIGITS);
return badToken();
}
// one past the '0x'
numStart = this->sourceUnits.addressOfNextCodeUnit() - 1;
if (!matchIntegerAfterFirstDigit(IsAsciiHexDigit, &unit)) {
return badToken();
}
} else if (unit == 'b' || unit == 'B') {
radix = 2;
unit = getCodeUnit();
if (!IsAsciiBinary(unit)) {
// NOTE: |unit| may be EOF here.
ungetCodeUnit(unit);
error(JSMSG_MISSING_BINARY_DIGITS);
return badToken();
}
// one past the '0b'
numStart = this->sourceUnits.addressOfNextCodeUnit() - 1;
if (!matchIntegerAfterFirstDigit(IsAsciiBinary, &unit)) {
return badToken();
}
} else if (unit == 'o' || unit == 'O') {
radix = 8;
unit = getCodeUnit();
if (!IsAsciiOctal(unit)) {
// NOTE: |unit| may be EOF here.
ungetCodeUnit(unit);
error(JSMSG_MISSING_OCTAL_DIGITS);
return badToken();
}
// one past the '0o'
numStart = this->sourceUnits.addressOfNextCodeUnit() - 1;
if (!matchIntegerAfterFirstDigit(IsAsciiOctal, &unit)) {
return badToken();
}
} else if (IsAsciiDigit(unit)) {
// Reject octal literals that appear in strict mode code.
if (!strictModeError(JSMSG_DEPRECATED_OCTAL_LITERAL)) {
return badToken();
}
// The above test doesn't catch a few edge cases; see
// |GeneralParser::maybeParseDirective|. Record the violation so that
// that function can handle them.
anyCharsAccess().setSawDeprecatedOctalLiteral();
radix = 8;
// one past the '0'
numStart = this->sourceUnits.addressOfNextCodeUnit() - 1;
bool nonOctalDecimalIntegerLiteral = false;
do {
if (unit >= '8') {
nonOctalDecimalIntegerLiteral = true;
}
unit = getCodeUnit();
} while (IsAsciiDigit(unit));
if (unit == '_') {
ungetCodeUnit(unit);
error(JSMSG_SEPARATOR_IN_ZERO_PREFIXED_NUMBER);
return badToken();
}
if (unit == 'n') {
ungetCodeUnit(unit);
error(JSMSG_BIGINT_INVALID_SYNTAX);
return badToken();
}
if (nonOctalDecimalIntegerLiteral) {
// Use the decimal scanner for the rest of the number.
return decimalNumber(unit, start, numStart, modifier, ttp);
}
} else if (unit == '_') {
// Give a more explicit error message when '_' is used after '0'.
ungetCodeUnit(unit);
error(JSMSG_SEPARATOR_IN_ZERO_PREFIXED_NUMBER);
return badToken();
} else {
// '0' not followed by [XxBbOo0-9_]; scan as a decimal number.
ungetCodeUnit(unit);
numStart = this->sourceUnits.addressOfNextCodeUnit() - 1; // The '0'.
return decimalNumber('0', start, numStart, modifier, ttp);
}
if (unit == 'n') {
isBigInt = true;
unit = peekCodeUnit();
} else {
ungetCodeUnit(unit);
}
// Error if an identifier-start code point appears immediately
// after the number. Somewhat surprisingly, if we don't check
// here, we'll never check at all.
if (MOZ_LIKELY(isAsciiCodePoint(unit))) {
if (unicode::IsIdentifierStart(char16_t(unit))) {
error(JSMSG_IDSTART_AFTER_NUMBER);
return badToken();
}
} else if (MOZ_LIKELY(unit != EOF)) {
// This ignores encoding errors: subsequent caller-side code to
// handle source text after the number will do so.
PeekedCodePoint<Unit> peeked = this->sourceUnits.peekCodePoint();
if (!peeked.isNone() &&
unicode::IsIdentifierStart(peeked.codePoint())) {
error(JSMSG_IDSTART_AFTER_NUMBER);
return badToken();
}
}
if (isBigInt) {
return bigIntLiteral(start, modifier, ttp);
}
double dval;
if (!GetFullInteger(numStart, this->sourceUnits.addressOfNextCodeUnit(),
radix, IntegerSeparatorHandling::SkipUnderscore,
&dval)) {
ReportOutOfMemory(this->fc);
return badToken();
}
newNumberToken(dval, NoDecimal, start, modifier, ttp);
return true;
}
MOZ_ASSERT(c1kind == Other);
// This handles everything else. Simple tokens distinguished solely by
// TokenKind should set |simpleKind| and break, to share simple-token
// creation code for all such tokens. All other tokens must be handled
// by returning (or by continuing from the loop enclosing this).
//
TokenStart start(this->sourceUnits, -1);
TokenKind simpleKind;
#ifdef DEBUG
simpleKind = TokenKind::Limit; // sentinel value for code after switch
#endif
// The block a ways above eliminated all non-ASCII, so cast to the
// smallest type possible to assist the C++ compiler.
switch (AssertedCast<uint8_t>(CodeUnitValue(toUnit(unit)))) {
case '.':
if (IsAsciiDigit(peekCodeUnit())) {
return decimalNumber('.', start,
this->sourceUnits.addressOfNextCodeUnit() - 1,
modifier, ttp);
}
unit = getCodeUnit();
if (unit == '.') {
if (matchCodeUnit('.')) {
simpleKind = TokenKind::TripleDot;
break;
}
}
// NOTE: |unit| may be EOF here. A stray '.' at EOF would be an
// error, but subsequent code will handle it.
ungetCodeUnit(unit);
simpleKind = TokenKind::Dot;
break;
case '#': {
#ifdef ENABLE_RECORD_TUPLE
if (matchCodeUnit('{')) {
simpleKind = TokenKind::HashCurly;
break;
}
if (matchCodeUnit('[')) {
simpleKind = TokenKind::HashBracket;
break;
}
#endif
TokenStart start(this->sourceUnits, -1);
const Unit* identStart = this->sourceUnits.addressOfNextCodeUnit() - 1;
IdentifierEscapes sawEscape;
if (!matchIdentifierStart(&sawEscape)) {
return badToken();
}
return identifierName(start, identStart, sawEscape, modifier,
NameVisibility::Private, ttp);
}
case '=':
if (matchCodeUnit('=')) {
simpleKind = matchCodeUnit('=') ? TokenKind::StrictEq : TokenKind::Eq;
} else if (matchCodeUnit('>')) {
simpleKind = TokenKind::Arrow;
} else {
simpleKind = TokenKind::Assign;
}
break;
case '+':
if (matchCodeUnit('+')) {
simpleKind = TokenKind::Inc;
} else {
simpleKind =
matchCodeUnit('=') ? TokenKind::AddAssign : TokenKind::Add;
}
break;
case '\\': {
char32_t codePoint;
if (uint32_t escapeLength = matchUnicodeEscapeIdStart(&codePoint)) {
return identifierName(
start,
this->sourceUnits.addressOfNextCodeUnit() - escapeLength - 1,
IdentifierEscapes::SawUnicodeEscape, modifier,
NameVisibility::Public, ttp);
}
// We could point "into" a mistyped escape, e.g. for "\u{41H}" we
// could point at the 'H'. But we don't do that now, so the code
// unit after the '\' isn't necessarily bad, so just point at the
// start of the actually-invalid escape.
ungetCodeUnit('\\');
error(JSMSG_BAD_ESCAPE);
return badToken();
}
case '|':
if (matchCodeUnit('|')) {
simpleKind = matchCodeUnit('=') ? TokenKind::OrAssign : TokenKind::Or;
} else {
simpleKind =
matchCodeUnit('=') ? TokenKind::BitOrAssign : TokenKind::BitOr;
}
break;
case '^':
simpleKind =
matchCodeUnit('=') ? TokenKind::BitXorAssign : TokenKind::BitXor;
break;
case '&':
if (matchCodeUnit('&')) {
simpleKind =
matchCodeUnit('=') ? TokenKind::AndAssign : TokenKind::And;
} else {
simpleKind =
matchCodeUnit('=') ? TokenKind::BitAndAssign : TokenKind::BitAnd;
}
break;
case '?':
if (matchCodeUnit('.')) {
unit = getCodeUnit();
if (IsAsciiDigit(unit)) {
// if the code unit is followed by a number, for example it has the
// following form `<...> ?.5 <..> then it should be treated as a
// ternary rather than as an optional chain
simpleKind = TokenKind::Hook;
ungetCodeUnit(unit);
ungetCodeUnit('.');
} else {
ungetCodeUnit(unit);
simpleKind = TokenKind::OptionalChain;
}
} else if (matchCodeUnit('?')) {
simpleKind = matchCodeUnit('=') ? TokenKind::CoalesceAssign
: TokenKind::Coalesce;
} else {
simpleKind = TokenKind::Hook;
}
break;
case '!':
if (matchCodeUnit('=')) {
simpleKind = matchCodeUnit('=') ? TokenKind::StrictNe : TokenKind::Ne;
} else {
simpleKind = TokenKind::Not;
}
break;
case '<':
if (anyCharsAccess().options().allowHTMLComments) {
// Treat HTML begin-comment as comment-till-end-of-line.
if (matchCodeUnit('!')) {
if (matchCodeUnit('-')) {
if (matchCodeUnit('-')) {
this->sourceUnits.consumeRestOfSingleLineComment();
continue;
}
ungetCodeUnit('-');
}
ungetCodeUnit('!');
}
}
if (matchCodeUnit('<')) {
simpleKind =
matchCodeUnit('=') ? TokenKind::LshAssign : TokenKind::Lsh;
} else {
simpleKind = matchCodeUnit('=') ? TokenKind::Le : TokenKind::Lt;
}
break;
case '>':
if (matchCodeUnit('>')) {
if (matchCodeUnit('>')) {
simpleKind =
matchCodeUnit('=') ? TokenKind::UrshAssign : TokenKind::Ursh;
} else {
simpleKind =
matchCodeUnit('=') ? TokenKind::RshAssign : TokenKind::Rsh;
}
} else {
simpleKind = matchCodeUnit('=') ? TokenKind::Ge : TokenKind::Gt;
}
break;
case '*':
if (matchCodeUnit('*')) {
simpleKind =
matchCodeUnit('=') ? TokenKind::PowAssign : TokenKind::Pow;
} else {
simpleKind =
matchCodeUnit('=') ? TokenKind::MulAssign : TokenKind::Mul;
}
break;
case '/':
// Look for a single-line comment.
if (matchCodeUnit('/')) {
unit = getCodeUnit();
if (unit == '@' || unit == '#') {
bool shouldWarn = unit == '@';
if (!getDirectives(false, shouldWarn)) {
return false;
}
} else {
// NOTE: |unit| may be EOF here.
ungetCodeUnit(unit);
}
this->sourceUnits.consumeRestOfSingleLineComment();
continue;
}
// Look for a multi-line comment.
if (matchCodeUnit('*')) {
TokenStreamAnyChars& anyChars = anyCharsAccess();
unsigned linenoBefore = anyChars.lineno;
do {
int32_t unit = getCodeUnit();
if (unit == EOF) {
error(JSMSG_UNTERMINATED_COMMENT);
return badToken();
}
if (unit == '*' && matchCodeUnit('/')) {
break;
}
if (unit == '@' || unit == '#') {
bool shouldWarn = unit == '@';
if (!getDirectives(true, shouldWarn)) {
return badToken();
}
} else if (MOZ_LIKELY(isAsciiCodePoint(unit))) {
if (!getFullAsciiCodePoint(unit)) {
return badToken();
}
} else {
char32_t codePoint;
if (!getNonAsciiCodePoint(unit, &codePoint)) {
return badToken();
}
}
} while (true);
if (linenoBefore != anyChars.lineno) {
anyChars.updateFlagsForEOL();
}
continue;
}
// Look for a regexp.
if (modifier == SlashIsRegExp) {
return regexpLiteral(start, ttp);
}
simpleKind = matchCodeUnit('=') ? TokenKind::DivAssign : TokenKind::Div;
break;
case '%':
simpleKind = matchCodeUnit('=') ? TokenKind::ModAssign : TokenKind::Mod;
break;
case '-':
if (matchCodeUnit('-')) {
if (anyCharsAccess().options().allowHTMLComments &&
!anyCharsAccess().flags.isDirtyLine) {
if (matchCodeUnit('>')) {
this->sourceUnits.consumeRestOfSingleLineComment();
continue;
}
}
simpleKind = TokenKind::Dec;
} else {
simpleKind =
matchCodeUnit('=') ? TokenKind::SubAssign : TokenKind::Sub;
}
break;
#ifdef ENABLE_DECORATORS
case '@':
simpleKind = TokenKind::At;
break;
#endif
default:
// We consumed a bad ASCII code point/unit. Put it back so the
// error location is the bad code point.
ungetCodeUnit(unit);
reportIllegalCharacter(unit);
return badToken();
} // switch (AssertedCast<uint8_t>(CodeUnitValue(toUnit(unit))))
MOZ_ASSERT(simpleKind != TokenKind::Limit,
"switch-statement should have set |simpleKind| before "
"breaking");
newSimpleToken(simpleKind, start, modifier, ttp);
return true;
} while (true);
}
template <typename Unit, class AnyCharsAccess>
bool TokenStreamSpecific<Unit, AnyCharsAccess>::getStringOrTemplateToken(
char untilChar, Modifier modifier, TokenKind* out) {
MOZ_ASSERT(untilChar == '\'' || untilChar == '"' || untilChar == '`',
"unexpected string/template literal delimiter");
bool parsingTemplate = (untilChar == '`');
bool templateHead = false;
TokenStart start(this->sourceUnits, -1);
this->charBuffer.clear();
// Run the bad-token code for every path out of this function except the
// one success-case.
auto noteBadToken = MakeScopeExit([this]() { this->badToken(); });
auto ReportPrematureEndOfLiteral = [this, untilChar](unsigned errnum) {
// Unicode separators aren't end-of-line in template or (as of
// recently) string literals, so this assertion doesn't allow them.
MOZ_ASSERT(this->sourceUnits.atEnd() ||
this->sourceUnits.peekCodeUnit() == Unit('\r') ||
this->sourceUnits.peekCodeUnit() == Unit('\n'),
"must be parked at EOF or EOL to call this function");
// The various errors reported here include language like "in a ''
// literal" or similar, with '' being '', "", or `` as appropriate.
const char delimiters[] = {untilChar, untilChar, '\0'};
this->error(errnum, delimiters);
return;
};
// We need to detect any of these chars: " or ', \n (or its
// equivalents), \\, EOF. Because we detect EOL sequences here and
// put them back immediately, we can use getCodeUnit().
int32_t unit;
while ((unit = getCodeUnit()) != untilChar) {
if (unit == EOF) {
ReportPrematureEndOfLiteral(JSMSG_EOF_BEFORE_END_OF_LITERAL);
return false;
}
// Non-ASCII code points are always directly appended -- even
// U+2028 LINE SEPARATOR and U+2029 PARAGRAPH SEPARATOR that are
// ordinarily LineTerminatorSequences. (They contribute their literal
// values to template and [as of recently] string literals, but they're
// line terminators when computing line/column coordinates.) Handle
// the non-ASCII case early for readability.
if (MOZ_UNLIKELY(!isAsciiCodePoint(unit))) {
char32_t cp;
if (!getNonAsciiCodePointDontNormalize(toUnit(unit), &cp)) {
return false;
}
if (MOZ_UNLIKELY(cp == unicode::LINE_SEPARATOR ||
cp == unicode::PARA_SEPARATOR)) {
if (!updateLineInfoForEOL()) {
return false;
}
anyCharsAccess().updateFlagsForEOL();
} else {
MOZ_ASSERT(!IsLineTerminator(cp));
}
if (!AppendCodePointToCharBuffer(this->charBuffer, cp)) {
return false;
}
continue;
}
if (unit == '\\') {
// When parsing templates, we don't immediately report errors for
// invalid escapes; these are handled by the parser. We don't
// append to charBuffer in those cases because it won't be read.
unit = getCodeUnit();
if (unit == EOF) {
ReportPrematureEndOfLiteral(JSMSG_EOF_IN_ESCAPE_IN_LITERAL);
return false;
}
// Non-ASCII |unit| isn't handled by code after this, so dedicate
// an unlikely special-case to it and then continue.
if (MOZ_UNLIKELY(!isAsciiCodePoint(unit))) {
char32_t codePoint;
if (!getNonAsciiCodePoint(unit, &codePoint)) {
return false;
}
// If we consumed U+2028 LINE SEPARATOR or U+2029 PARAGRAPH
// SEPARATOR, they'll be normalized to '\n'. '\' followed by
// LineContinuation represents no code points, so don't append
// in this case.
if (codePoint != '\n') {
if (!AppendCodePointToCharBuffer(this->charBuffer, codePoint)) {
return false;
}
}
continue;
}
// The block above eliminated all non-ASCII, so cast to the
// smallest type possible to assist the C++ compiler.
switch (AssertedCast<uint8_t>(CodeUnitValue(toUnit(unit)))) {
case 'b':
unit = '\b';
break;
case 'f':
unit = '\f';
break;
case 'n':
unit = '\n';
break;
case 'r':
unit = '\r';
break;
case 't':
unit = '\t';
break;
case 'v':
unit = '\v';
break;
case '\r':
matchLineTerminator('\n');
[[fallthrough]];
case '\n': {
// LineContinuation represents no code points. We're manually
// consuming a LineTerminatorSequence, so we must manually
// update line/column info.
if (!updateLineInfoForEOL()) {
return false;
}
continue;
}
// Unicode character specification.
case 'u': {
int32_t c2 = getCodeUnit();
if (c2 == EOF) {
ReportPrematureEndOfLiteral(JSMSG_EOF_IN_ESCAPE_IN_LITERAL);
return false;
}
// First handle a delimited Unicode escape, e.g. \u{1F4A9}.
if (c2 == '{') {
uint32_t start = this->sourceUnits.offset() - 3;
uint32_t code = 0;
bool first = true;
bool valid = true;
do {
int32_t u3 = getCodeUnit();
if (u3 == EOF) {
if (parsingTemplate) {
TokenStreamAnyChars& anyChars = anyCharsAccess();
anyChars.setInvalidTemplateEscape(start,
InvalidEscapeType::Unicode);
valid = false;
break;
}
reportInvalidEscapeError(start, InvalidEscapeType::Unicode);
return false;
}
if (u3 == '}') {
if (first) {
if (parsingTemplate) {
TokenStreamAnyChars& anyChars = anyCharsAccess();
anyChars.setInvalidTemplateEscape(
start, InvalidEscapeType::Unicode);
valid = false;
break;
}
reportInvalidEscapeError(start, InvalidEscapeType::Unicode);
return false;
}
break;
}
// Beware: |u3| may be a non-ASCII code point here; if
// so it'll pass into this |if|-block.
if (!IsAsciiHexDigit(u3)) {
if (parsingTemplate) {
// We put the code unit back so that we read it
// on the next pass, which matters if it was
// '`' or '\'.
ungetCodeUnit(u3);
TokenStreamAnyChars& anyChars = anyCharsAccess();
anyChars.setInvalidTemplateEscape(start,
InvalidEscapeType::Unicode);
valid = false;
break;
}
reportInvalidEscapeError(start, InvalidEscapeType::Unicode);
return false;
}
code = (code << 4) | AsciiAlphanumericToNumber(u3);
if (code > unicode::NonBMPMax) {
if (parsingTemplate) {
TokenStreamAnyChars& anyChars = anyCharsAccess();
anyChars.setInvalidTemplateEscape(
start + 3, InvalidEscapeType::UnicodeOverflow);
valid = false;
break;
}
reportInvalidEscapeError(start + 3,
InvalidEscapeType::UnicodeOverflow);
return false;
}
first = false;
} while (true);
if (!valid) {
continue;
}
MOZ_ASSERT(code <= unicode::NonBMPMax);
if (!AppendCodePointToCharBuffer(this->charBuffer, code)) {
return false;
}
continue;
} // end of delimited Unicode escape handling
// Otherwise it must be a fixed-length \uXXXX Unicode escape.
// If it isn't, this is usually an error -- but if this is a
// template literal, we must defer error reporting because
// malformed escapes are okay in *tagged* template literals.
char16_t v;
if (IsAsciiHexDigit(c2) && this->sourceUnits.matchHexDigits(3, &v)) {
unit = (AsciiAlphanumericToNumber(c2) << 12) | v;
} else {
// Beware: |c2| may not be an ASCII code point here!
ungetCodeUnit(c2);
uint32_t start = this->sourceUnits.offset() - 2;
if (parsingTemplate) {
TokenStreamAnyChars& anyChars = anyCharsAccess();
anyChars.setInvalidTemplateEscape(start,
InvalidEscapeType::Unicode);
continue;
}
reportInvalidEscapeError(start, InvalidEscapeType::Unicode);
return false;
}
break;
} // case 'u'
// Hexadecimal character specification.
case 'x': {
char16_t v;
if (this->sourceUnits.matchHexDigits(2, &v)) {
unit = v;
} else {
uint32_t start = this->sourceUnits.offset() - 2;
if (parsingTemplate) {
TokenStreamAnyChars& anyChars = anyCharsAccess();
anyChars.setInvalidTemplateEscape(start,
InvalidEscapeType::Hexadecimal);
continue;
}
reportInvalidEscapeError(start, InvalidEscapeType::Hexadecimal);
return false;
}
break;
}
default: {
if (!IsAsciiOctal(unit)) {
// \8 or \9 in an untagged template literal is a syntax error,
// reported in GeneralParser::noSubstitutionUntaggedTemplate.
//
// Tagged template literals, however, may contain \8 and \9. The
// "cooked" representation of such a part will be |undefined|, and
// the "raw" representation will contain the literal characters.
//
// function f(parts) {
// assertEq(parts[0], undefined);
// assertEq(parts.raw[0], "\\8");
// return "composed";
// }
// assertEq(f`\8`, "composed");
if (unit == '8' || unit == '9') {
TokenStreamAnyChars& anyChars = anyCharsAccess();
if (parsingTemplate) {
anyChars.setInvalidTemplateEscape(
this->sourceUnits.offset() - 2,
InvalidEscapeType::EightOrNine);
continue;
}
// \8 and \9 are forbidden in string literals in strict mode code.
if (!strictModeError(JSMSG_DEPRECATED_EIGHT_OR_NINE_ESCAPE)) {
return false;
}
// The above test doesn't catch a few edge cases; see
// |GeneralParser::maybeParseDirective|. Record the violation so
// that that function can handle them.
anyChars.setSawDeprecatedEightOrNineEscape();
}
break;
}
// Octal character specification.
int32_t val = AsciiOctalToNumber(unit);
unit = peekCodeUnit();
if (MOZ_UNLIKELY(unit == EOF)) {
ReportPrematureEndOfLiteral(JSMSG_EOF_IN_ESCAPE_IN_LITERAL);
return false;
}
// Strict mode code allows only \0 followed by a non-digit.
if (val != 0 || IsAsciiDigit(unit)) {
TokenStreamAnyChars& anyChars = anyCharsAccess();
if (parsingTemplate) {
anyChars.setInvalidTemplateEscape(this->sourceUnits.offset() - 2,
InvalidEscapeType::Octal);
continue;
}
if (!strictModeError(JSMSG_DEPRECATED_OCTAL_ESCAPE)) {
return false;
}
// The above test doesn't catch a few edge cases; see
// |GeneralParser::maybeParseDirective|. Record the violation so
// that that function can handle them.
anyChars.setSawDeprecatedOctalEscape();
}
if (IsAsciiOctal(unit)) {
val = 8 * val + AsciiOctalToNumber(unit);
consumeKnownCodeUnit(unit);
unit = peekCodeUnit();
if (MOZ_UNLIKELY(unit == EOF)) {
ReportPrematureEndOfLiteral(JSMSG_EOF_IN_ESCAPE_IN_LITERAL);
return false;
}
if (IsAsciiOctal(unit)) {
int32_t save = val;
val = 8 * val + AsciiOctalToNumber(unit);
if (val <= 0xFF) {
consumeKnownCodeUnit(unit);
} else {
val = save;
}
}
}
unit = char16_t(val);
break;
} // default
} // switch (AssertedCast<uint8_t>(CodeUnitValue(toUnit(unit))))
if (!this->charBuffer.append(unit)) {
return false;
}
continue;
} // (unit == '\\')
if (unit == '\r' || unit == '\n') {
if (!parsingTemplate) {
// String literals don't allow ASCII line breaks.
ungetCodeUnit(unit);
ReportPrematureEndOfLiteral(JSMSG_EOL_BEFORE_END_OF_STRING);
return false;
}
if (unit == '\r') {
unit = '\n';
matchLineTerminator('\n');
}
if (!updateLineInfoForEOL()) {
return false;
}
anyCharsAccess().updateFlagsForEOL();
} else if (parsingTemplate && unit == '$' && matchCodeUnit('{')) {
templateHead = true;
break;
}
if (!this->charBuffer.append(unit)) {
return false;
}
}
TaggedParserAtomIndex atom = drainCharBufferIntoAtom();
if (!atom) {
return false;
}
noteBadToken.release();
MOZ_ASSERT_IF(!parsingTemplate, !templateHead);
TokenKind kind = !parsingTemplate ? TokenKind::String
: templateHead ? TokenKind::TemplateHead
: TokenKind::NoSubsTemplate;
newAtomToken(kind, atom, start, modifier, out);
return true;
}
const char* TokenKindToDesc(TokenKind tt) {
switch (tt) {
#define EMIT_CASE(name, desc) \
case TokenKind::name: \
return desc;
FOR_EACH_TOKEN_KIND(EMIT_CASE)
#undef EMIT_CASE
case TokenKind::Limit:
MOZ_ASSERT_UNREACHABLE("TokenKind::Limit should not be passed.");
break;
}
return "<bad TokenKind>";
}
#ifdef DEBUG
const char* TokenKindToString(TokenKind tt) {
switch (tt) {
# define EMIT_CASE(name, desc) \
case TokenKind::name: \
return "TokenKind::" #name;
FOR_EACH_TOKEN_KIND(EMIT_CASE)
# undef EMIT_CASE
case TokenKind::Limit:
break;
}
return "<bad TokenKind>";
}
#endif
template class TokenStreamCharsBase<Utf8Unit>;
template class TokenStreamCharsBase<char16_t>;
template class GeneralTokenStreamChars<char16_t, TokenStreamAnyCharsAccess>;
template class TokenStreamChars<char16_t, TokenStreamAnyCharsAccess>;
template class TokenStreamSpecific<char16_t, TokenStreamAnyCharsAccess>;
template class GeneralTokenStreamChars<
Utf8Unit, ParserAnyCharsAccess<GeneralParser<FullParseHandler, Utf8Unit>>>;
template class GeneralTokenStreamChars<
Utf8Unit,
ParserAnyCharsAccess<GeneralParser<SyntaxParseHandler, Utf8Unit>>>;
template class GeneralTokenStreamChars<
char16_t, ParserAnyCharsAccess<GeneralParser<FullParseHandler, char16_t>>>;
template class GeneralTokenStreamChars<
char16_t,
ParserAnyCharsAccess<GeneralParser<SyntaxParseHandler, char16_t>>>;
template class TokenStreamChars<
Utf8Unit, ParserAnyCharsAccess<GeneralParser<FullParseHandler, Utf8Unit>>>;
template class TokenStreamChars<
Utf8Unit,
ParserAnyCharsAccess<GeneralParser<SyntaxParseHandler, Utf8Unit>>>;
template class TokenStreamChars<
char16_t, ParserAnyCharsAccess<GeneralParser<FullParseHandler, char16_t>>>;
template class TokenStreamChars<
char16_t,
ParserAnyCharsAccess<GeneralParser<SyntaxParseHandler, char16_t>>>;
template class TokenStreamSpecific<
Utf8Unit, ParserAnyCharsAccess<GeneralParser<FullParseHandler, Utf8Unit>>>;
template class TokenStreamSpecific<
Utf8Unit,
ParserAnyCharsAccess<GeneralParser<SyntaxParseHandler, Utf8Unit>>>;
template class TokenStreamSpecific<
char16_t, ParserAnyCharsAccess<GeneralParser<FullParseHandler, char16_t>>>;
template class TokenStreamSpecific<
char16_t,
ParserAnyCharsAccess<GeneralParser<SyntaxParseHandler, char16_t>>>;
} // namespace frontend
} // namespace js
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