Commit 4ca70222 authored by Marja Hölttä's avatar Marja Hölttä Committed by Commit Bot

Revert "Reland [parser] Refactor streaming scanner streams."

This reverts commit 7fa071a4.

Reason for revert: https://bugs.chromium.org/p/chromium/issues/detail?id=729482

Original change's description:
> Reland [parser] Refactor streaming scanner streams.
> 
> Unify, simplify logic, reduce UTF8 specific handling.
> 
> Intend of this is also to have stream views.
> Stream views can be used concurrently by multiple threads, but
> only one thread may fetch new data from the underlying source.
> This together with unified stream view creation is intended to be
> used for parse tasks.
> 
> BUG=v8:6093
> 
> Change-Id: I3bce48185fa2c986d16619a9a8ece3ff4c4f5e60
> Reviewed-on: https://chromium-review.googlesource.com/509489
> Reviewed-by: Daniel Vogelheim <vogelheim@chromium.org>
> Reviewed-by: Marja Hölttä <marja@chromium.org>
> Commit-Queue: Wiktor Garbacz <wiktorg@google.com>
> Cr-Commit-Position: refs/heads/master@{#45688}

TBR=marja@chromium.org,vogelheim@chromium.org,wiktorg@google.com
# Not skipping CQ checks because original CL landed > 1 day ago.
BUG=v8:6093

Change-Id: Iefa7c43a2f6ae3a7f3ef0f77d87b6ae36ae4be99
Reviewed-on: https://chromium-review.googlesource.com/525712Reviewed-by: 's avatarMarja Hölttä <marja@chromium.org>
Reviewed-by: 's avatarDaniel Vogelheim <vogelheim@chromium.org>
Commit-Queue: Marja Hölttä <marja@chromium.org>
Cr-Commit-Position: refs/heads/master@{#45725}
parent 866ee63c
......@@ -1284,6 +1284,11 @@ class V8_EXPORT ScriptCompiler {
* length of the data returned. When the data ends, GetMoreData should
* return 0. Caller takes ownership of the data.
*
* When streaming UTF-8 data, V8 handles multi-byte characters split between
* two data chunks, but doesn't handle multi-byte characters split between
* more than two data chunks. The embedder can avoid this problem by always
* returning at least 2 bytes of data.
*
* If the embedder wants to cancel the streaming, they should make the next
* GetMoreData call return 0. V8 will interpret it as end of data (and most
* probably, parsing will fail). The streaming task will return as soon as
......
......@@ -4,8 +4,6 @@
#include "src/parsing/scanner-character-streams.h"
#include <memory>
#include "include/v8.h"
#include "src/counters.h"
#include "src/globals.h"
......@@ -18,8 +16,7 @@ namespace v8 {
namespace internal {
namespace {
constexpr unibrow::uchar kUtf8Bom = 0xfeff;
constexpr uint8_t kUtf8BomBytes[] = {0xef, 0xbb, 0xbf};
const unibrow::uchar kUtf8Bom = 0xfeff;
} // namespace
// ----------------------------------------------------------------------------
......@@ -33,7 +30,7 @@ class BufferedUtf16CharacterStream : public Utf16CharacterStream {
BufferedUtf16CharacterStream();
protected:
static constexpr size_t kBufferCharacterSize = 512;
static const size_t kBufferSize = 512;
bool ReadBlock() override;
......@@ -43,22 +40,21 @@ class BufferedUtf16CharacterStream : public Utf16CharacterStream {
// Fixed sized buffer that this class reads from.
// The base class' buffer_start_ should always point to buffer_.
uc16 buffer_[kBufferCharacterSize];
static constexpr size_t kBufferSizeInBytes =
sizeof(BufferedUtf16CharacterStream::buffer_);
uc16 buffer_[kBufferSize];
};
BufferedUtf16CharacterStream::BufferedUtf16CharacterStream()
: Utf16CharacterStream(buffer_, buffer_, buffer_, 0) {}
bool BufferedUtf16CharacterStream::ReadBlock() {
DCHECK_EQ(buffer_start_, buffer_);
size_t position = pos();
buffer_pos_ = position;
buffer_start_ = buffer_cursor_ = buffer_;
buffer_cursor_ = buffer_;
buffer_end_ = buffer_ + FillBuffer(position);
DCHECK_EQ(pos(), position);
DCHECK_LE(buffer_end_, buffer_start_ + kBufferCharacterSize);
DCHECK_LE(buffer_end_, buffer_start_ + kBufferSize);
return buffer_cursor_ < buffer_end_;
}
......@@ -91,7 +87,7 @@ GenericStringUtf16CharacterStream::GenericStringUtf16CharacterStream(
size_t GenericStringUtf16CharacterStream::FillBuffer(size_t from_pos) {
if (from_pos >= length_) return 0;
size_t length = i::Min(kBufferCharacterSize, length_ - from_pos);
size_t length = i::Min(kBufferSize, length_ - from_pos);
String::WriteToFlat<uc16>(*string_, buffer_, static_cast<int>(from_pos),
static_cast<int>(from_pos + length));
return length;
......@@ -183,487 +179,635 @@ ExternalOneByteStringUtf16CharacterStream::
size_t ExternalOneByteStringUtf16CharacterStream::FillBuffer(size_t from_pos) {
if (from_pos >= length_) return 0;
size_t length = Min(kBufferCharacterSize, length_ - from_pos);
size_t length = Min(kBufferSize, length_ - from_pos);
i::CopyCharsUnsigned(buffer_, raw_data_ + from_pos, length);
return length;
}
namespace {
// A linked-list container for the chunk data.
// Shared by ChunksView and Chunks (which may execute on different threads).
struct Chunk {
enum Type : uint8_t { ONE_BYTE, TWO_BYTE };
Chunk() : Chunk(ONE_BYTE, 0, nullptr, 0, 0, 0) {}
Chunk(Type type, int first_char_start_offset, const uint8_t* data,
size_t byte_length, size_t char_length, size_t char_pos)
: type(type),
first_char_start_offset(first_char_start_offset),
data(data),
byte_length(byte_length),
char_length(char_length),
char_pos(char_pos) {}
~Chunk() { delete next.Value(); }
static Chunk* CreateOneByte(const uint8_t* data, size_t byte_length,
size_t char_pos, size_t start_offset = 0) {
return new Chunk(ONE_BYTE, static_cast<int>(start_offset), data,
byte_length, byte_length - start_offset, char_pos);
}
static Chunk* CreateTwoByte(const uint8_t* data, size_t byte_length,
size_t char_pos, bool odd_start) {
size_t char_length = (odd_start + byte_length) / 2;
return new Chunk(TWO_BYTE, odd_start, data, byte_length, char_length,
char_pos);
}
// Position of the first character which starts in this chunk.
// This is always greater or equal to char_pos, so if no char starts in this
// chunk (i.e. char_length == 0) char_pos+1 is returned.
size_t FirstCharPosition() const {
// There are no split chars for one byte chunks, but there might be some
// start offset
if (type == ONE_BYTE) return char_pos;
return char_pos + (first_char_start_offset != 0);
}
size_t OffsetOf(size_t position) const {
DCHECK_LE(FirstCharPosition(), position);
DCHECK_GE(char_pos + char_length, position);
switch (type) {
case ONE_BYTE:
return position - FirstCharPosition() + first_char_start_offset;
case TWO_BYTE:
return 2 * (position - FirstCharPosition()) + first_char_start_offset;
}
UNREACHABLE();
}
size_t CopyToBuffer(uint8_t* buffer, size_t size, size_t offset) const {
switch (type) {
case ONE_BYTE: {
size_t chars_to_copy = i::Min(size / 2, byte_length - offset);
i::CopyCharsUnsigned(reinterpret_cast<uc16*>(buffer), &data[offset],
chars_to_copy);
return 2 * chars_to_copy;
}
case TWO_BYTE: {
size_t bytes_to_copy = i::Min(size, byte_length - offset);
i::MemCopy(buffer, &data[offset], bytes_to_copy);
return bytes_to_copy;
}
}
UNREACHABLE();
}
const Type type;
// Offset to the first byte of first character that starts in this chunk.
const int first_char_start_offset;
const std::unique_ptr<const uint8_t[]> data;
const size_t byte_length;
const size_t char_length;
const size_t char_pos;
base::AtomicValue<const Chunk*> next{nullptr};
const Chunk* prev = nullptr;
};
// An interface that delivers a sequence of Chunks.
class ChunkSource {
public:
virtual ~ChunkSource() {}
// Fetch and return next chunk.
// Returns nullptr if source is exhausted.
// Should not be called after source is exhausted.
virtual Chunk* GetNextChunk() = 0;
};
// ----------------------------------------------------------------------------
// Utf8ExternalStreamingStream - chunked streaming of Utf-8 data.
//
// This implementation is fairly complex, since data arrives in chunks which
// may 'cut' arbitrarily into utf-8 characters. Also, seeking to a given
// character position is tricky because the byte position cannot be dericed
// from the character position.
// Manages chunks, provides seeking to chunk containing start byte or end byte
// of a character. It cannot fetch new data, but can read data fetched by viewed
// stream (also data fetched after this stream view was created). Multiple
// ChunksViews can operate on same chunks concurrently.
class ChunksView {
class Utf8ExternalStreamingStream : public BufferedUtf16CharacterStream {
public:
ChunksView(const ChunksView& other) = default;
virtual ~ChunksView() {}
// Return the chunk containing the last byte of the char at position.
// Position is in chars not bytes.
// If position is behind the end of the stream, nullptr is returned.
virtual const Chunk* SeekToEndOf(size_t position) {
DCHECK_NOT_NULL(current_);
DCHECK_NOT_NULL(last_seen_);
// We almost always 'stream', meaning we want data from the next chunk
if (V8_LIKELY(position >= last_seen_->char_pos)) {
// Fast-forward to last seen chunk
current_ = last_seen_;
// Continue going forward until position found or out of chunks
while (position >= current_->char_pos + current_->char_length) {
const Chunk* next = current_->next.Value();
if (!next) return nullptr;
current_ = last_seen_ = next;
}
} else if (position >= current_->char_pos) {
// Go forward until position found or out of chunks
while (position >= current_->char_pos + current_->char_length) {
current_ = current_->next.Value();
if (!current_) return nullptr;
}
} else {
// Shortcut jump to first chunk
DCHECK_NOT_NULL(start_.get());
DCHECK_EQ(start_->char_pos, 0);
DCHECK_EQ(start_->byte_length, 0);
const Chunk* first = start_->next.Value();
DCHECK_NOT_NULL(first);
DCHECK_EQ(first->char_pos, 0);
if (position < first->char_pos + first->char_length) {
current_ = first;
}
// Go backwards until position found
while (position < current_->char_pos) {
current_ = current_->prev;
DCHECK_NOT_NULL(current_);
}
}
DCHECK_LE(current_->char_pos, position);
DCHECK_LT(position, current_->char_pos + current_->char_length);
return current_;
}
// Return the chunk containing the first byte of the char at position.
// Position is in chars not bytes.
// If position is behind the end of the stream, nullptr is returned.
// This call also guarantees that a whole char is available.
const Chunk* SeekToStartOf(size_t position) {
const Chunk* chunk = SeekToEndOf(position);
if (chunk) {
while (V8_UNLIKELY(position < chunk->FirstCharPosition())) {
chunk = chunk->prev;
DCHECK_NOT_NULL(chunk);
}
current_ = chunk;
}
return chunk;
}
// Returns next chunk if there is one.
// This function never blocks/fetches new data.
const Chunk* MoveToNext() {
DCHECK_NOT_NULL(current_);
DCHECK_NOT_NULL(last_seen_);
const Chunk* next = current_->next.Value();
if (next) {
// Stream view may move to a previously unseen chunk
if (current_ == last_seen_) {
last_seen_ = next;
}
current_ = next;
}
return next;
Utf8ExternalStreamingStream(
ScriptCompiler::ExternalSourceStream* source_stream,
RuntimeCallStats* stats)
: current_({0, {0, 0, unibrow::Utf8::Utf8IncrementalBuffer(0)}}),
source_stream_(source_stream),
stats_(stats) {}
~Utf8ExternalStreamingStream() override {
for (size_t i = 0; i < chunks_.size(); i++) delete[] chunks_[i].data;
}
protected:
ChunksView()
: start_(std::make_shared<Chunk>()),
current_(start_.get()),
last_seen_(current_) {}
// Start sentinel shared between stream and stream views
// start_->next is first chunk with real data
const std::shared_ptr<Chunk> start_;
// Chunk we're currently at.
// Seek*, MoveToNext alter/work in respect to this.
const Chunk* current_;
// Last chunk this instance of ChunksView has seen so far.
const Chunk* last_seen_;
size_t FillBuffer(size_t position) override;
private:
// A position within the data stream. It stores:
// - The 'physical' position (# of bytes in the stream),
// - the 'logical' position (# of ucs-2 characters, also within the stream),
// - a possibly incomplete utf-8 char at the current 'physical' position.
struct StreamPosition {
size_t bytes;
size_t chars;
unibrow::Utf8::Utf8IncrementalBuffer incomplete_char;
};
// Position contains a StreamPosition and the index of the chunk the position
// points into. (The chunk_no could be derived from pos, but that'd be
// an expensive search through all chunks.)
struct Position {
size_t chunk_no;
StreamPosition pos;
};
// A chunk in the list of chunks, containing:
// - The chunk data (data pointer and length), and
// - the position at the first byte of the chunk.
struct Chunk {
const uint8_t* data;
size_t length;
StreamPosition start;
};
// Within the current chunk, skip forward from current_ towards position.
bool SkipToPosition(size_t position);
// Within the current chunk, fill the buffer_ (while it has capacity).
void FillBufferFromCurrentChunk();
// Fetch a new chunk (assuming current_ is at the end of the current data).
bool FetchChunk();
// Search through the chunks and set current_ to point to the given position.
// (This call is potentially expensive.)
void SearchPosition(size_t position);
std::vector<Chunk> chunks_;
Position current_;
ScriptCompiler::ExternalSourceStream* source_stream_;
RuntimeCallStats* stats_;
};
// A ChunksView subclass that does fetch new data from a ChunkSource if needed.
class Chunks : public ChunksView {
public:
Chunks(std::unique_ptr<ChunkSource> source, RuntimeCallStats* stats)
: source_(std::move(source)),
stats_(stats),
last_added_(start_.get()),
source_exhausted_(false) {}
const Chunk* SeekToEndOf(size_t position) override {
if (!source_exhausted_) {
GetNewDataIfNeeded(position);
}
return ChunksView::SeekToEndOf(position);
}
bool Utf8ExternalStreamingStream::SkipToPosition(size_t position) {
DCHECK_LE(current_.pos.chars, position); // We can only skip forward.
protected:
void GetNewDataIfNeeded(size_t position) {
DCHECK(!source_exhausted_);
DCHECK_NOT_NULL(last_added_);
size_t char_end_pos = last_added_->char_pos + last_added_->char_length;
// Get more data if needed.
if (char_end_pos <= position) {
RuntimeCallTimerScope scope(stats_,
&RuntimeCallStats::GetMoreDataCallback);
while (char_end_pos <= position) {
Chunk* chunk = source_->GetNextChunk();
if (chunk) {
chunk->prev = last_added_;
last_added_->next.SetValue(chunk);
last_added_ = chunk;
char_end_pos += chunk->char_length;
DCHECK_EQ(char_end_pos,
last_added_->char_pos + last_added_->char_length);
} else {
source_exhausted_ = true;
break;
}
}
}
DCHECK_NOT_NULL(last_added_);
last_seen_ = last_added_;
// We either got the chunk we were looking for, or source is exhausted.
DCHECK_IMPLIES(!source_exhausted_, position < char_end_pos);
}
const std::unique_ptr<ChunkSource> source_;
RuntimeCallStats* const stats_;
Chunk* last_added_;
bool source_exhausted_;
};
// Already there? Then return immediately.
if (current_.pos.chars == position) return true;
// ChunkSource for one-byte ExternalSourceStream
class OneByteChunkSource : public ChunkSource {
public:
explicit OneByteChunkSource(ScriptCompiler::ExternalSourceStream* source)
: source_(source) {}
Chunk* GetNextChunk() override {
const uint8_t* data = nullptr;
DCHECK_NOT_NULL(source_);
const size_t byte_len = source_->GetMoreData(&data);
if (V8_UNLIKELY(byte_len == 0)) {
delete[] data;
return nullptr;
const Chunk& chunk = chunks_[current_.chunk_no];
DCHECK(current_.pos.bytes >= chunk.start.bytes);
unibrow::Utf8::Utf8IncrementalBuffer incomplete_char =
chunk.start.incomplete_char;
size_t it = current_.pos.bytes - chunk.start.bytes;
size_t chars = chunk.start.chars;
while (it < chunk.length && chars < position) {
unibrow::uchar t =
unibrow::Utf8::ValueOfIncremental(chunk.data[it], &incomplete_char);
if (t == kUtf8Bom && current_.pos.chars == 0) {
// BOM detected at beginning of the stream. Don't copy it.
} else if (t != unibrow::Utf8::kIncomplete) {
chars++;
if (t > unibrow::Utf16::kMaxNonSurrogateCharCode) chars++;
}
size_t char_pos = byte_pos_;
byte_pos_ += byte_len;
return Chunk::CreateOneByte(data, byte_len, char_pos);
it++;
}
private:
ScriptCompiler::ExternalSourceStream* const source_;
size_t byte_pos_ = 0;
};
current_.pos.bytes += it;
current_.pos.chars = chars;
current_.pos.incomplete_char = incomplete_char;
current_.chunk_no += (it == chunk.length);
// ChunkSource for two-byte ExternalSourceStream
class TwoByteChunkSource : public ChunkSource {
public:
explicit TwoByteChunkSource(ScriptCompiler::ExternalSourceStream* source)
: source_(source) {}
Chunk* GetNextChunk() override {
const uint8_t* data = nullptr;
DCHECK_NOT_NULL(source_);
const size_t byte_len = source_->GetMoreData(&data);
if (V8_UNLIKELY(byte_len == 0)) {
delete[] data;
return nullptr;
}
bool odd_start = (byte_pos_ % 2) == 1;
size_t char_pos = byte_pos_ / 2;
byte_pos_ += byte_len;
return Chunk::CreateTwoByte(data, byte_len, char_pos, odd_start);
}
return current_.pos.chars == position;
}
private:
ScriptCompiler::ExternalSourceStream* const source_;
size_t byte_pos_ = 0;
};
void Utf8ExternalStreamingStream::FillBufferFromCurrentChunk() {
DCHECK_LT(current_.chunk_no, chunks_.size());
DCHECK_EQ(buffer_start_, buffer_cursor_);
DCHECK_LT(buffer_end_ + 1, buffer_start_ + kBufferSize);
// ChunkSource that decodes incoming utf8 to two-byte chunks if needed.
// Byte Order Mark at the beginning of the stream is skipped.
// ASCII only chunks are kept as one-byte chunks.
// Performance is optimized for source files with mostly ASCII characters.
class Utf8ChunkSource : public ChunkSource {
public:
explicit Utf8ChunkSource(ScriptCompiler::ExternalSourceStream* source)
: source_(source),
incomplete_char_(unibrow::Utf8::Utf8IncrementalBuffer(0)) {}
const Chunk& chunk = chunks_[current_.chunk_no];
protected:
size_t ComputeAsciiPrefixLength(const uint8_t* data, size_t byte_length) {
if (incomplete_char_ != unibrow::Utf8::Utf8IncrementalBuffer(0)) {
return 0;
}
for (size_t i = 0; i < byte_length; ++i) {
if (data[i] > unibrow::Utf8::kMaxOneByteChar) {
return i;
}
// The buffer_ is writable, but buffer_*_ members are const. So we get a
// non-const pointer into buffer that points to the same char as buffer_end_.
uint16_t* cursor = buffer_ + (buffer_end_ - buffer_start_);
DCHECK_EQ(cursor, buffer_end_);
// If the current chunk is the last (empty) chunk we'll have to process
// any left-over, partial characters.
if (chunk.length == 0) {
unibrow::uchar t =
unibrow::Utf8::ValueOfIncrementalFinish(&current_.pos.incomplete_char);
if (t != unibrow::Utf8::kBufferEmpty) {
DCHECK(t < unibrow::Utf16::kMaxNonSurrogateCharCode);
*cursor = static_cast<uc16>(t);
buffer_end_++;
current_.pos.chars++;
}
return byte_length;
return;
}
size_t ConvertToUtf16(const uint8_t* data, size_t byte_length,
size_t ascii_prefix_len, const uint8_t** result) {
DCHECK_IMPLIES(ascii_prefix_len != 0,
incomplete_char_ == unibrow::Utf8::Utf8IncrementalBuffer(0));
// We get at most 1 character per byte.
// Only exception is the first byte of chunk which may finish an incomplete
// surrogate pair, hence addition of 1.
uc16* decoded_data = new uc16[byte_length + 1];
i::CopyCharsUnsigned(decoded_data, data, ascii_prefix_len);
size_t decoded_len = ascii_prefix_len;
for (size_t i = ascii_prefix_len; i < byte_length; ++i) {
unibrow::Utf8::Utf8IncrementalBuffer incomplete_char =
current_.pos.incomplete_char;
size_t it;
for (it = current_.pos.bytes - chunk.start.bytes;
it < chunk.length && cursor + 1 < buffer_start_ + kBufferSize; it++) {
unibrow::uchar t =
unibrow::Utf8::ValueOfIncremental(data[i], &incomplete_char_);
unibrow::Utf8::ValueOfIncremental(chunk.data[it], &incomplete_char);
if (t == unibrow::Utf8::kIncomplete) continue;
if (V8_LIKELY(t < kUtf8Bom)) {
decoded_data[decoded_len++] = static_cast<uc16>(t);
} else if (V8_UNLIKELY(is_at_first_char_ && t == kUtf8Bom)) {
// Skip BOM at the beggining of the stream
is_at_first_char_ = false;
*(cursor++) = static_cast<uc16>(t); // The by most frequent case.
} else if (t == kUtf8Bom && current_.pos.bytes + it == 2) {
// BOM detected at beginning of the stream. Don't copy it.
} else if (t <= unibrow::Utf16::kMaxNonSurrogateCharCode) {
decoded_data[decoded_len++] = static_cast<uc16>(t);
*(cursor++) = static_cast<uc16>(t);
} else {
decoded_data[decoded_len++] = unibrow::Utf16::LeadSurrogate(t);
decoded_data[decoded_len++] = unibrow::Utf16::TrailSurrogate(t);
*(cursor++) = unibrow::Utf16::LeadSurrogate(t);
*(cursor++) = unibrow::Utf16::TrailSurrogate(t);
}
}
*result = reinterpret_cast<uint8_t*>(decoded_data);
return 2 * decoded_len;
}
// Skip possible BOM at the beginning of the stream.
// Return number of bytes skipped.
size_t SkipBOM(const uint8_t* data, size_t byte_length) {
if (V8_UNLIKELY(is_at_first_char_ && byte_length >= 3 &&
data[0] == kUtf8BomBytes[0] &&
data[1] == kUtf8BomBytes[1] &&
data[2] == kUtf8BomBytes[2])) {
return 3;
}
return 0;
}
current_.pos.bytes = chunk.start.bytes + it;
current_.pos.chars += (cursor - buffer_end_);
current_.pos.incomplete_char = incomplete_char;
current_.chunk_no += (it == chunk.length);
Chunk* GetNextChunk() override {
const uint8_t* data = nullptr;
size_t byte_length = 0;
if (!is_at_end_) {
byte_length = source_->GetMoreData(&data);
}
// end of stream
if (V8_UNLIKELY(byte_length == 0)) {
delete[] data;
is_at_end_ = true;
unibrow::uchar t =
unibrow::Utf8::ValueOfIncrementalFinish(&incomplete_char_);
if (t != unibrow::Utf8::kBufferEmpty) {
DCHECK(t < unibrow::Utf16::kMaxNonSurrogateCharCode);
uc16* char_data = new uc16[1];
char_data[0] = static_cast<uc16>(t);
return Chunk::CreateTwoByte(reinterpret_cast<uint8_t*>(char_data), 2,
char_pos_++, false);
}
return nullptr;
}
size_t skipped = SkipBOM(data, byte_length);
if (V8_UNLIKELY(skipped == byte_length)) {
is_at_first_char_ = false;
delete[] data;
return GetNextChunk();
}
size_t ascii_prefix_len =
ComputeAsciiPrefixLength(data + skipped, byte_length - skipped);
bool is_ascii_only = ascii_prefix_len == (byte_length - skipped);
if (V8_LIKELY(is_ascii_only)) {
is_at_first_char_ = false;
Chunk* chunk =
Chunk::CreateOneByte(data, byte_length, char_pos_, skipped);
char_pos_ += chunk->char_length;
return chunk;
}
const uint8_t* decoded_data;
size_t decoded_byte_len = ConvertToUtf16(
data + skipped, byte_length - skipped, ascii_prefix_len, &decoded_data);
delete[] data;
if (V8_UNLIKELY(decoded_byte_len == 0)) {
delete[] decoded_data;
return GetNextChunk();
buffer_end_ = cursor;
}
bool Utf8ExternalStreamingStream::FetchChunk() {
RuntimeCallTimerScope scope(stats_, &RuntimeCallStats::GetMoreDataCallback);
DCHECK_EQ(current_.chunk_no, chunks_.size());
DCHECK(chunks_.empty() || chunks_.back().length != 0);
const uint8_t* chunk = nullptr;
size_t length = source_stream_->GetMoreData(&chunk);
chunks_.push_back({chunk, length, current_.pos});
return length > 0;
}
void Utf8ExternalStreamingStream::SearchPosition(size_t position) {
// If current_ already points to the right position, we're done.
//
// This is expected to be the common case, since we typically call
// FillBuffer right after the current buffer.
if (current_.pos.chars == position) return;
// No chunks. Fetch at least one, so we can assume !chunks_.empty() below.
if (chunks_.empty()) {
DCHECK_EQ(current_.chunk_no, 0u);
DCHECK_EQ(current_.pos.bytes, 0u);
DCHECK_EQ(current_.pos.chars, 0u);
FetchChunk();
}
// Search for the last chunk whose start position is less or equal to
// position.
size_t chunk_no = chunks_.size() - 1;
while (chunk_no > 0 && chunks_[chunk_no].start.chars > position) {
chunk_no--;
}
// Did we find the terminating (zero-length) chunk? Then we're seeking
// behind the end of the data, and position does not exist.
// Set current_ to point to the terminating chunk.
if (chunks_[chunk_no].length == 0) {
current_ = {chunk_no, chunks_[chunk_no].start};
return;
}
// Did we find the non-last chunk? Then our position must be within chunk_no.
if (chunk_no + 1 < chunks_.size()) {
// Fancy-pants optimization for ASCII chunks within a utf-8 stream.
// (Many web sites declare utf-8 encoding, but use only (or almost only) the
// ASCII subset for their JavaScript sources. We can exploit this, by
// checking whether the # bytes in a chunk are equal to the # chars, and if
// so avoid the expensive SkipToPosition.)
bool ascii_only_chunk =
chunks_[chunk_no].start.incomplete_char ==
unibrow::Utf8::Utf8IncrementalBuffer(0) &&
(chunks_[chunk_no + 1].start.bytes - chunks_[chunk_no].start.bytes) ==
(chunks_[chunk_no + 1].start.chars - chunks_[chunk_no].start.chars);
if (ascii_only_chunk) {
size_t skip = position - chunks_[chunk_no].start.chars;
current_ = {chunk_no,
{chunks_[chunk_no].start.bytes + skip,
chunks_[chunk_no].start.chars + skip,
unibrow::Utf8::Utf8IncrementalBuffer(0)}};
} else {
current_ = {chunk_no, chunks_[chunk_no].start};
SkipToPosition(position);
}
// Since position was within the chunk, SkipToPosition should have found
// something.
DCHECK_EQ(position, current_.pos.chars);
return;
}
// What's left: We're in the last, non-terminating chunk. Our position
// may be in the chunk, but it may also be in 'future' chunks, which we'll
// have to obtain.
DCHECK_EQ(chunk_no, chunks_.size() - 1);
current_ = {chunk_no, chunks_[chunk_no].start};
bool have_more_data = true;
bool found = SkipToPosition(position);
while (have_more_data && !found) {
DCHECK_EQ(current_.chunk_no, chunks_.size());
have_more_data = FetchChunk();
found = have_more_data && SkipToPosition(position);
}
// We'll return with a postion != the desired position only if we're out
// of data. In that case, we'll point to the terminating chunk.
DCHECK_EQ(found, current_.pos.chars == position);
DCHECK_EQ(have_more_data, chunks_.back().length != 0);
DCHECK_IMPLIES(!found, !have_more_data);
DCHECK_IMPLIES(!found, current_.chunk_no == chunks_.size() - 1);
}
size_t Utf8ExternalStreamingStream::FillBuffer(size_t position) {
buffer_cursor_ = buffer_;
buffer_end_ = buffer_;
SearchPosition(position);
bool out_of_data = current_.chunk_no != chunks_.size() &&
chunks_[current_.chunk_no].length == 0;
if (out_of_data) return 0;
// Fill the buffer, until we have at least one char (or are out of data).
// (The embedder might give us 1-byte blocks within a utf-8 char, so we
// can't guarantee progress with one chunk. Thus we iterate.)
while (!out_of_data && buffer_cursor_ == buffer_end_) {
// At end of current data, but there might be more? Then fetch it.
if (current_.chunk_no == chunks_.size()) {
out_of_data = !FetchChunk();
}
is_at_first_char_ = false;
Chunk* chunk =
Chunk::CreateTwoByte(decoded_data, decoded_byte_len, char_pos_, false);
char_pos_ += chunk->char_length;
return chunk;
FillBufferFromCurrentChunk();
}
DCHECK_EQ(current_.pos.chars - position,
static_cast<size_t>(buffer_end_ - buffer_cursor_));
return buffer_end_ - buffer_cursor_;
}
// ----------------------------------------------------------------------------
// Chunks - helper for One- + TwoByteExternalStreamingStream
namespace {
struct Chunk {
const uint8_t* data;
size_t byte_length;
size_t byte_pos;
};
typedef std::vector<struct Chunk> Chunks;
void DeleteChunks(Chunks& chunks) {
for (size_t i = 0; i < chunks.size(); i++) delete[] chunks[i].data;
}
// Return the chunk index for the chunk containing position.
// If position is behind the end of the stream, the index of the last,
// zero-length chunk is returned.
size_t FindChunk(Chunks& chunks, ScriptCompiler::ExternalSourceStream* source,
size_t position, RuntimeCallStats* stats) {
size_t end_pos =
chunks.empty() ? 0 : (chunks.back().byte_pos + chunks.back().byte_length);
// Get more data if needed. We usually won't enter the loop body.
bool out_of_data = !chunks.empty() && chunks.back().byte_length == 0;
{
RuntimeCallTimerScope scope(stats, &RuntimeCallStats::GetMoreDataCallback);
while (!out_of_data && end_pos <= position + 1) {
const uint8_t* chunk = nullptr;
size_t len = source->GetMoreData(&chunk);
chunks.push_back({chunk, len, end_pos});
end_pos += len;
out_of_data = (len == 0);
}
}
// Here, we should always have at least one chunk, and we either have the
// chunk we were looking for, or we're out of data. Also, out_of_data and
// end_pos are current (and designate whether we have exhausted the stream,
// and the length of data received so far, respectively).
DCHECK(!chunks.empty());
DCHECK_EQ(end_pos, chunks.back().byte_pos + chunks.back().byte_length);
DCHECK_EQ(out_of_data, chunks.back().byte_length == 0);
DCHECK(position < end_pos || out_of_data);
// Edge case: position is behind the end of stream: Return the last (length 0)
// chunk to indicate the end of the stream.
if (position >= end_pos) {
DCHECK(out_of_data);
return chunks.size() - 1;
}
// We almost always 'stream', meaning we want data from the last chunk, so
// let's look at chunks back-to-front.
size_t chunk_no = chunks.size() - 1;
while (chunks[chunk_no].byte_pos > position) {
DCHECK_NE(chunk_no, 0u);
chunk_no--;
}
DCHECK_LE(chunks[chunk_no].byte_pos, position);
DCHECK_LT(position, chunks[chunk_no].byte_pos + chunks[chunk_no].byte_length);
return chunk_no;
}
} // anonymous namespace
// ----------------------------------------------------------------------------
// OneByteExternalStreamingStream
//
// A stream of latin-1 encoded, chunked data.
class OneByteExternalStreamingStream : public BufferedUtf16CharacterStream {
public:
explicit OneByteExternalStreamingStream(
ScriptCompiler::ExternalSourceStream* source, RuntimeCallStats* stats)
: source_(source), stats_(stats) {}
~OneByteExternalStreamingStream() override { DeleteChunks(chunks_); }
protected:
size_t FillBuffer(size_t position) override;
private:
Chunks chunks_;
ScriptCompiler::ExternalSourceStream* source_;
unibrow::Utf8::Utf8IncrementalBuffer incomplete_char_;
bool is_at_first_char_ = true;
bool is_at_end_ = false;
size_t char_pos_ = 0;
RuntimeCallStats* stats_;
};
} // anonymous namespace
size_t OneByteExternalStreamingStream::FillBuffer(size_t position) {
const Chunk& chunk = chunks_[FindChunk(chunks_, source_, position, stats_)];
if (chunk.byte_length == 0) return 0;
size_t start_pos = position - chunk.byte_pos;
size_t len = i::Min(kBufferSize, chunk.byte_length - start_pos);
i::CopyCharsUnsigned(buffer_, chunk.data + start_pos, len);
return len;
}
#if !(V8_TARGET_ARCH_MIPS || V8_TARGET_ARCH_MIPS64)
// ----------------------------------------------------------------------------
// TwoByteExternalStreamingStream
//
// A stream of ucs-2 data, delivered in chunks. Chunks may be 'cut' into the
// middle of characters (or even contain only one byte), which adds a bit
// of complexity. This stream avoid all data copying, except for characters
// that cross chunk boundaries.
// A stream of chunked data
class ExternalStreamingStream : public BufferedUtf16CharacterStream {
class TwoByteExternalStreamingStream : public Utf16CharacterStream {
public:
explicit ExternalStreamingStream(std::unique_ptr<ChunkSource> source,
RuntimeCallStats* stats)
: chunks_(new Chunks(std::move(source), stats)) {}
explicit TwoByteExternalStreamingStream(
ScriptCompiler::ExternalSourceStream* source, RuntimeCallStats* stats);
~TwoByteExternalStreamingStream() override;
protected:
bool ReadBlock() override;
size_t FillBuffer(size_t position) override;
std::unique_ptr<ChunksView> chunks_;
Chunks chunks_;
ScriptCompiler::ExternalSourceStream* source_;
RuntimeCallStats* stats_;
uc16 one_char_buffer_;
};
bool ExternalStreamingStream::ReadBlock() {
TwoByteExternalStreamingStream::TwoByteExternalStreamingStream(
ScriptCompiler::ExternalSourceStream* source, RuntimeCallStats* stats)
: Utf16CharacterStream(&one_char_buffer_, &one_char_buffer_,
&one_char_buffer_, 0),
source_(source),
stats_(stats),
one_char_buffer_(0) {}
TwoByteExternalStreamingStream::~TwoByteExternalStreamingStream() {
DeleteChunks(chunks_);
}
bool TwoByteExternalStreamingStream::ReadBlock() {
size_t position = pos();
// Find chunk in which the position belongs
const Chunk* chunk = chunks_->SeekToEndOf(position);
// Out of data? Return false.
if (!chunk) {
buffer_cursor_ = buffer_end_ = buffer_start_;
// We'll search for the 2nd byte of our character, to make sure we
// have enough data for at least one character.
size_t chunk_no = FindChunk(chunks_, source_, 2 * position + 1, stats_);
// Out of data? Return 0.
if (chunks_[chunk_no].byte_length == 0) {
buffer_cursor_ = buffer_start_;
buffer_end_ = buffer_start_;
return false;
}
bool odd_start = chunk->first_char_start_offset == 1;
if (odd_start || chunk->type != Chunk::TWO_BYTE) {
return BufferedUtf16CharacterStream::ReadBlock();
Chunk& current = chunks_[chunk_no];
// Annoying edge case: Chunks may not be 2-byte aligned, meaning that a
// character may be split between the previous and the current chunk.
// If we find such a lonely byte at the beginning of the chunk, we'll use
// one_char_buffer_ to hold the full character.
bool lonely_byte = (chunks_[chunk_no].byte_pos == (2 * position + 1));
if (lonely_byte) {
DCHECK_NE(chunk_no, 0u);
Chunk& previous_chunk = chunks_[chunk_no - 1];
#ifdef V8_TARGET_BIG_ENDIAN
uc16 character = current.data[0] |
previous_chunk.data[previous_chunk.byte_length - 1] << 8;
#else
uc16 character = previous_chunk.data[previous_chunk.byte_length - 1] |
current.data[0] << 8;
#endif
one_char_buffer_ = character;
buffer_pos_ = position;
buffer_start_ = &one_char_buffer_;
buffer_cursor_ = &one_char_buffer_;
buffer_end_ = &one_char_buffer_ + 1;
return true;
}
// Aligned access is important on MIPS and ARM.
DCHECK_EQ((reinterpret_cast<uintptr_t>(chunk->data.get()) % 2), 0);
// Common case: character is in current chunk.
DCHECK_LE(current.byte_pos, 2 * position);
DCHECK_LT(2 * position + 1, current.byte_pos + current.byte_length);
// Determine # of full ucs-2 chars in stream, and whether we started on an odd
// byte boundary.
bool odd_start = (current.byte_pos % 2) == 1;
size_t number_chars = (current.byte_length - odd_start) / 2;
buffer_start_ = reinterpret_cast<const uint16_t*>(chunk->data.get());
buffer_end_ = buffer_start_ + chunk->char_length;
buffer_pos_ = chunk->char_pos;
// Point the buffer_*_ members into the current chunk and set buffer_cursor_
// to point to position. Be careful when converting the byte positions (in
// Chunk) to the ucs-2 character positions (in buffer_*_ members).
buffer_start_ = reinterpret_cast<const uint16_t*>(current.data + odd_start);
buffer_end_ = buffer_start_ + number_chars;
buffer_pos_ = (current.byte_pos + odd_start) / 2;
buffer_cursor_ = buffer_start_ + (position - buffer_pos_);
DCHECK_EQ(position, pos());
return true;
}
size_t ExternalStreamingStream::FillBuffer(size_t position) {
size_t copied_bytes = 0;
const Chunk* chunk = chunks_->SeekToStartOf(position);
#else
// ----------------------------------------------------------------------------
// TwoByteExternalBufferedStream
//
// This class is made specifically to address unaligned access to 16-bit data
// in MIPS and ARM architectures. It replaces class
// TwoByteExternalStreamingStream which in some cases does have unaligned
// accesse to 16-bit data
class TwoByteExternalBufferedStream : public Utf16CharacterStream {
public:
explicit TwoByteExternalBufferedStream(
ScriptCompiler::ExternalSourceStream* source, RuntimeCallStats* stats);
~TwoByteExternalBufferedStream();
protected:
static const size_t kBufferSize = 512;
bool ReadBlock() override;
// FillBuffer should read up to kBufferSize characters at position and store
// them into buffer_[0..]. It returns the number of characters stored.
size_t FillBuffer(size_t position, size_t chunk_no);
// Fixed sized buffer that this class reads from.
// The base class' buffer_start_ should always point to buffer_.
uc16 buffer_[kBufferSize];
Chunks chunks_;
ScriptCompiler::ExternalSourceStream* source_;
RuntimeCallStats* stats_;
};
TwoByteExternalBufferedStream::TwoByteExternalBufferedStream(
ScriptCompiler::ExternalSourceStream* source, RuntimeCallStats* stats)
: Utf16CharacterStream(buffer_, buffer_, buffer_, 0),
source_(source),
stats_(stats) {}
TwoByteExternalBufferedStream::~TwoByteExternalBufferedStream() {
DeleteChunks(chunks_);
}
bool TwoByteExternalBufferedStream::ReadBlock() {
size_t position = pos();
// Find chunk in which the position belongs
size_t chunk_no = FindChunk(chunks_, source_, 2 * position + 1, stats_);
// Out of data? Return 0.
if (!chunk) {
return 0;
}
size_t offset = chunk->OffsetOf(position);
while (copied_bytes < kBufferSizeInBytes && chunk) {
// Stop copying if next chunk could be used directly and at least one char
// was copied.
if (chunk->type == Chunk::TWO_BYTE && copied_bytes > 2 &&
chunk->first_char_start_offset == 0) {
break;
if (chunks_[chunk_no].byte_length == 0) {
buffer_cursor_ = buffer_start_;
buffer_end_ = buffer_start_;
return false;
}
size_t space_left = kBufferSizeInBytes - copied_bytes;
DCHECK_IMPLIES(chunk->type == Chunk::ONE_BYTE, (copied_bytes % 2) == 0);
copied_bytes += chunk->CopyToBuffer(
reinterpret_cast<uint8_t*>(buffer_) + copied_bytes, space_left, offset);
// chunk after the first one are copied from beginning
offset = 0;
chunk = chunks_->MoveToNext();
Chunk& current = chunks_[chunk_no];
bool odd_start = current.byte_pos % 2;
// Common case: character is in current chunk.
DCHECK_LE(current.byte_pos, 2 * position + odd_start);
DCHECK_LT(2 * position + 1, current.byte_pos + current.byte_length);
// If character starts on odd address copy text in buffer so there is always
// aligned access to characters. This is important on MIPS and ARM
// architectures. Otherwise read characters from memory directly.
if (!odd_start) {
buffer_start_ = reinterpret_cast<const uint16_t*>(current.data);
size_t number_chars = current.byte_length / 2;
buffer_end_ = buffer_start_ + number_chars;
buffer_pos_ = current.byte_pos / 2;
buffer_cursor_ = buffer_start_ + (position - buffer_pos_);
DCHECK_EQ(position, pos());
return true;
} else {
buffer_start_ = buffer_;
buffer_pos_ = position;
buffer_cursor_ = buffer_;
buffer_end_ = buffer_ + FillBuffer(position, chunk_no);
DCHECK_EQ(pos(), position);
DCHECK_LE(buffer_end_, buffer_start_ + kBufferSize);
return buffer_cursor_ < buffer_end_;
}
return copied_bytes / 2;
}
size_t TwoByteExternalBufferedStream::FillBuffer(size_t position,
size_t chunk_no) {
DCHECK_EQ(chunks_[chunk_no].byte_pos % 2, 1u);
bool odd_start = true;
// Align buffer_pos_ to the size of the buffer.
{
size_t new_pos = position / kBufferSize * kBufferSize;
if (new_pos != position) {
chunk_no = FindChunk(chunks_, source_, 2 * new_pos + 1, stats_);
buffer_pos_ = new_pos;
buffer_cursor_ = buffer_start_ + (position - buffer_pos_);
position = new_pos;
odd_start = chunks_[chunk_no].byte_pos % 2;
}
}
Chunk* current = &chunks_[chunk_no];
// Annoying edge case: Chunks may not be 2-byte aligned, meaning that a
// character may be split between the previous and the current chunk.
// If we find such a lonely byte at the beginning of the chunk, we'll copy
// it to the first byte in buffer_.
size_t totalLength = 0;
bool lonely_byte = (current->byte_pos == (2 * position + 1));
if (lonely_byte) {
DCHECK_NE(chunk_no, 0u);
Chunk& previous_chunk = chunks_[chunk_no - 1];
*reinterpret_cast<uint8_t*>(buffer_) =
previous_chunk.data[previous_chunk.byte_length - 1];
totalLength++;
}
// Common case: character is in current chunk.
DCHECK_LE(current->byte_pos, 2 * position + odd_start);
DCHECK_LT(2 * position + 1, current->byte_pos + current->byte_length);
// Copy characters from current chunk starting from chunk_pos to the end of
// buffer or chunk.
size_t chunk_pos = position - current->byte_pos / 2;
size_t start_offset = odd_start && chunk_pos != 0;
size_t bytes_to_move =
i::Min(2 * kBufferSize - lonely_byte,
current->byte_length - 2 * chunk_pos + start_offset);
i::MemMove(reinterpret_cast<uint8_t*>(buffer_) + lonely_byte,
current->data + 2 * chunk_pos - start_offset, bytes_to_move);
// Fill up the rest of the buffer if there is space and data left.
totalLength += bytes_to_move;
position = (current->byte_pos + current->byte_length) / 2;
if (position - buffer_pos_ < kBufferSize) {
chunk_no = FindChunk(chunks_, source_, 2 * position + 1, stats_);
current = &chunks_[chunk_no];
odd_start = current->byte_pos % 2;
bytes_to_move = i::Min(2 * kBufferSize - totalLength, current->byte_length);
while (bytes_to_move) {
// Common case: character is in current chunk.
DCHECK_LE(current->byte_pos, 2 * position + odd_start);
DCHECK_LT(2 * position + 1, current->byte_pos + current->byte_length);
i::MemMove(reinterpret_cast<uint8_t*>(buffer_) + totalLength,
current->data, bytes_to_move);
totalLength += bytes_to_move;
position = (current->byte_pos + current->byte_length) / 2;
chunk_no = FindChunk(chunks_, source_, 2 * position + 1, stats_);
current = &chunks_[chunk_no];
odd_start = current->byte_pos % 2;
bytes_to_move =
i::Min(2 * kBufferSize - totalLength, current->byte_length);
}
}
return totalLength / 2;
}
#endif
// ----------------------------------------------------------------------------
// ScannerStream: Create stream instances.
......@@ -706,20 +850,20 @@ Utf16CharacterStream* ScannerStream::For(
ScriptCompiler::ExternalSourceStream* source_stream,
v8::ScriptCompiler::StreamedSource::Encoding encoding,
RuntimeCallStats* stats) {
std::unique_ptr<ChunkSource> source;
switch (encoding) {
case v8::ScriptCompiler::StreamedSource::TWO_BYTE:
source.reset(new TwoByteChunkSource(source_stream));
break;
#if !(V8_TARGET_ARCH_MIPS || V8_TARGET_ARCH_MIPS64)
return new TwoByteExternalStreamingStream(source_stream, stats);
#else
return new TwoByteExternalBufferedStream(source_stream, stats);
#endif
case v8::ScriptCompiler::StreamedSource::ONE_BYTE:
source.reset(new OneByteChunkSource(source_stream));
break;
return new OneByteExternalStreamingStream(source_stream, stats);
case v8::ScriptCompiler::StreamedSource::UTF8:
source.reset(new Utf8ChunkSource(source_stream));
break;
return new Utf8ExternalStreamingStream(source_stream, stats);
}
DCHECK_NOT_NULL(source.get());
return new ExternalStreamingStream(std::move(source), stats);
UNREACHABLE();
return nullptr;
}
} // namespace internal
......
......@@ -39,13 +39,6 @@ class ChunkSource : public v8::ScriptCompiler::ExternalSourceStream {
}
chunks_.push_back({nullptr, 0});
}
ChunkSource(const uint8_t* data, size_t len, size_t chunk_size)
: current_(0) {
for (size_t i = 0; i < len; i += chunk_size) {
chunks_.push_back({data + i, i::Min(chunk_size, len - i)});
}
chunks_.push_back({nullptr, 0});
}
~ChunkSource() {}
bool SetBookmark() override { return false; }
void ResetToBookmark() override {}
......@@ -442,18 +435,6 @@ TEST(CharacterStreams) {
TestCharacterStreams(buffer, arraysize(buffer) - 1, 576, 3298);
}
TEST(Uft8MultipleBOMChunks) {
const char* chunks = "\xef\xbb\xbf\0\xef\xbb\xbf\0\xef\xbb\xbf\0a\0";
const uint16_t unicode[] = {0xFEFF, 0xFEFF, 97};
ChunkSource chunk_source(chunks);
std::unique_ptr<i::Utf16CharacterStream> stream(i::ScannerStream::For(
&chunk_source, v8::ScriptCompiler::StreamedSource::UTF8, nullptr));
for (size_t i = 0; i < arraysize(unicode); i++) {
CHECK_EQ(unicode[i], stream->Advance());
}
CHECK_EQ(i::Utf16CharacterStream::kEndOfInput, stream->Advance());
}
// Regression test for crbug.com/651333. Read invalid utf-8.
TEST(Regress651333) {
const uint8_t bytes[] =
......@@ -515,36 +496,3 @@ TEST(Regress6377) {
CHECK_EQ(i::Utf16CharacterStream::kEndOfInput, stream->Advance());
}
}
TEST(Regress724166) {
// Chunk size has to be multiple of kBufferCharacterSize
constexpr size_t kBufferCharacterSize = 512;
constexpr size_t kChunkSize = kBufferCharacterSize * 8;
constexpr size_t kChunks = 4;
uint8_t buffer[kChunkSize * kChunks];
for (size_t j = 0; j < kChunks; ++j) {
for (size_t i = 0; i < kChunkSize; ++i) {
buffer[kChunkSize * j + i] = (i % 0x7e) + 1;
}
}
// Add BOM at the beginning
buffer[0] = '\xef';
buffer[1] = '\xbb';
buffer[2] = '\xbf';
ChunkSource chunk_source(buffer, arraysize(buffer), kChunkSize);
std::unique_ptr<i::Utf16CharacterStream> stream(i::ScannerStream::For(
&chunk_source, v8::ScriptCompiler::StreamedSource::UTF8, nullptr));
for (size_t i = 0; i < arraysize(buffer) - 3; ++i) {
CHECK_EQ(static_cast<i::uc32>(buffer[i + 3]), stream->Advance());
}
CHECK_EQ(i::Utf16CharacterStream::kEndOfInput, stream->Advance());
for (int z = -8; z < 8; ++z) {
for (size_t j = kBufferCharacterSize + z; j < arraysize(buffer);
j += kBufferCharacterSize) {
stream->Seek(j);
for (size_t i = j; i < arraysize(buffer) - 3; ++i) {
CHECK_EQ(static_cast<i::uc32>(buffer[i + 3]), stream->Advance());
}
}
}
}
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