Moving data from one buffer to another is fast. Instead * of copying bytes from one place in memory to another, this class just changes * ownership of the underlying byte arrays. * *
This buffer grows with your data. Just like ArrayList, * each buffer starts small. It consumes only the memory it needs to. * *
This buffer pools its byte arrays. When you allocate a
* byte array in Java, the runtime must zero-fill the requested array before
* returning it to you. Even if you're going to write over that space anyway.
* This class avoids zero-fill and GC churn by pooling byte arrays.
*/
public final class Buffer implements BufferedSource, BufferedSink, Cloneable {
private static final byte[] DIGITS =
{ '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', 'a', 'b', 'c', 'd', 'e', 'f' };
static final int REPLACEMENT_CHARACTER = '\ufffd';
Segment head;
long size;
public Buffer() {
}
/** Returns the number of bytes currently in this buffer. */
public long size() {
return size;
}
@Override public Buffer buffer() {
return this;
}
@Override public OutputStream outputStream() {
return new OutputStream() {
@Override public void write(int b) {
writeByte((byte) b);
}
@Override public void write(byte[] data, int offset, int byteCount) {
Buffer.this.write(data, offset, byteCount);
}
@Override public void flush() {
}
@Override public void close() {
}
@Override public String toString() {
return this + ".outputStream()";
}
};
}
@Override public Buffer emitCompleteSegments() {
return this; // Nowhere to emit to!
}
@Override public BufferedSink emit() {
return this; // Nowhere to emit to!
}
@Override public boolean exhausted() {
return size == 0;
}
@Override public void require(long byteCount) throws EOFException {
if (size < byteCount) throw new EOFException();
}
@Override public boolean request(long byteCount) {
return size >= byteCount;
}
@Override public InputStream inputStream() {
return new InputStream() {
@Override public int read() {
if (size > 0) return readByte() & 0xff;
return -1;
}
@Override public int read(byte[] sink, int offset, int byteCount) {
return Buffer.this.read(sink, offset, byteCount);
}
@Override public int available() {
return (int) Math.min(size, Integer.MAX_VALUE);
}
@Override public void close() {
}
@Override public String toString() {
return Buffer.this + ".inputStream()";
}
};
}
/** Copy the contents of this to {@code out}. */
public Buffer copyTo(OutputStream out) throws IOException {
return copyTo(out, 0, size);
}
/**
* Copy {@code byteCount} bytes from this, starting at {@code offset}, to
* {@code out}.
*/
public Buffer copyTo(OutputStream out, long offset, long byteCount) throws IOException {
if (out == null) throw new IllegalArgumentException("out == null");
checkOffsetAndCount(size, offset, byteCount);
if (byteCount == 0) return this;
// Skip segments that we aren't copying from.
Segment s = head;
for (; offset >= (s.limit - s.pos); s = s.next) {
offset -= (s.limit - s.pos);
}
// Copy from one segment at a time.
for (; byteCount > 0; s = s.next) {
int pos = (int) (s.pos + offset);
int toCopy = (int) Math.min(s.limit - pos, byteCount);
out.write(s.data, pos, toCopy);
byteCount -= toCopy;
offset = 0;
}
return this;
}
/** Copy {@code byteCount} bytes from this, starting at {@code offset}, to {@code out}. */
public Buffer copyTo(Buffer out, long offset, long byteCount) {
if (out == null) throw new IllegalArgumentException("out == null");
checkOffsetAndCount(size, offset, byteCount);
if (byteCount == 0) return this;
out.size += byteCount;
// Skip segments that we aren't copying from.
Segment s = head;
for (; offset >= (s.limit - s.pos); s = s.next) {
offset -= (s.limit - s.pos);
}
// Copy one segment at a time.
for (; byteCount > 0; s = s.next) {
Segment copy = new Segment(s);
copy.pos += offset;
copy.limit = Math.min(copy.pos + (int) byteCount, copy.limit);
if (out.head == null) {
out.head = copy.next = copy.prev = copy;
} else {
out.head.prev.push(copy);
}
byteCount -= copy.limit - copy.pos;
offset = 0;
}
return this;
}
/** Write the contents of this to {@code out}. */
public Buffer writeTo(OutputStream out) throws IOException {
return writeTo(out, size);
}
/** Write {@code byteCount} bytes from this to {@code out}. */
public Buffer writeTo(OutputStream out, long byteCount) throws IOException {
if (out == null) throw new IllegalArgumentException("out == null");
checkOffsetAndCount(size, 0, byteCount);
Segment s = head;
while (byteCount > 0) {
int toCopy = (int) Math.min(byteCount, s.limit - s.pos);
out.write(s.data, s.pos, toCopy);
s.pos += toCopy;
size -= toCopy;
byteCount -= toCopy;
if (s.pos == s.limit) {
Segment toRecycle = s;
head = s = toRecycle.pop();
SegmentPool.recycle(toRecycle);
}
}
return this;
}
/** Read and exhaust bytes from {@code in} to this. */
public Buffer readFrom(InputStream in) throws IOException {
readFrom(in, Long.MAX_VALUE, true);
return this;
}
/** Read {@code byteCount} bytes from {@code in} to this. */
public Buffer readFrom(InputStream in, long byteCount) throws IOException {
if (byteCount < 0) throw new IllegalArgumentException("byteCount < 0: " + byteCount);
readFrom(in, byteCount, false);
return this;
}
private void readFrom(InputStream in, long byteCount, boolean forever) throws IOException {
if (in == null) throw new IllegalArgumentException("in == null");
while (byteCount > 0 || forever) {
Segment tail = writableSegment(1);
int maxToCopy = (int) Math.min(byteCount, Segment.SIZE - tail.limit);
int bytesRead = in.read(tail.data, tail.limit, maxToCopy);
if (bytesRead == -1) {
if (forever) return;
throw new EOFException();
}
tail.limit += bytesRead;
size += bytesRead;
byteCount -= bytesRead;
}
}
/**
* Returns the number of bytes in segments that are not writable. This is the
* number of bytes that can be flushed immediately to an underlying sink
* without harming throughput.
*/
public long completeSegmentByteCount() {
long result = size;
if (result == 0) return 0;
// Omit the tail if it's still writable.
Segment tail = head.prev;
if (tail.limit < Segment.SIZE && tail.owner) {
result -= tail.limit - tail.pos;
}
return result;
}
@Override public byte readByte() {
if (size == 0) throw new IllegalStateException("size == 0");
Segment segment = head;
int pos = segment.pos;
int limit = segment.limit;
byte[] data = segment.data;
byte b = data[pos++];
size -= 1;
if (pos == limit) {
head = segment.pop();
SegmentPool.recycle(segment);
} else {
segment.pos = pos;
}
return b;
}
/** Returns the byte at {@code pos}. */
public byte getByte(long pos) {
checkOffsetAndCount(size, pos, 1);
for (Segment s = head; true; s = s.next) {
int segmentByteCount = s.limit - s.pos;
if (pos < segmentByteCount) return s.data[s.pos + (int) pos];
pos -= segmentByteCount;
}
}
@Override public short readShort() {
if (size < 2) throw new IllegalStateException("size < 2: " + size);
Segment segment = head;
int pos = segment.pos;
int limit = segment.limit;
// If the short is split across multiple segments, delegate to readByte().
if (limit - pos < 2) {
int s = (readByte() & 0xff) << 8
| (readByte() & 0xff);
return (short) s;
}
byte[] data = segment.data;
int s = (data[pos++] & 0xff) << 8
| (data[pos++] & 0xff);
size -= 2;
if (pos == limit) {
head = segment.pop();
SegmentPool.recycle(segment);
} else {
segment.pos = pos;
}
return (short) s;
}
@Override public int readInt() {
if (size < 4) throw new IllegalStateException("size < 4: " + size);
Segment segment = head;
int pos = segment.pos;
int limit = segment.limit;
// If the int is split across multiple segments, delegate to readByte().
if (limit - pos < 4) {
return (readByte() & 0xff) << 24
| (readByte() & 0xff) << 16
| (readByte() & 0xff) << 8
| (readByte() & 0xff);
}
byte[] data = segment.data;
int i = (data[pos++] & 0xff) << 24
| (data[pos++] & 0xff) << 16
| (data[pos++] & 0xff) << 8
| (data[pos++] & 0xff);
size -= 4;
if (pos == limit) {
head = segment.pop();
SegmentPool.recycle(segment);
} else {
segment.pos = pos;
}
return i;
}
@Override public long readLong() {
if (size < 8) throw new IllegalStateException("size < 8: " + size);
Segment segment = head;
int pos = segment.pos;
int limit = segment.limit;
// If the long is split across multiple segments, delegate to readInt().
if (limit - pos < 8) {
return (readInt() & 0xffffffffL) << 32
| (readInt() & 0xffffffffL);
}
byte[] data = segment.data;
long v = (data[pos++] & 0xffL) << 56
| (data[pos++] & 0xffL) << 48
| (data[pos++] & 0xffL) << 40
| (data[pos++] & 0xffL) << 32
| (data[pos++] & 0xffL) << 24
| (data[pos++] & 0xffL) << 16
| (data[pos++] & 0xffL) << 8
| (data[pos++] & 0xffL);
size -= 8;
if (pos == limit) {
head = segment.pop();
SegmentPool.recycle(segment);
} else {
segment.pos = pos;
}
return v;
}
@Override public short readShortLe() {
return Util.reverseBytesShort(readShort());
}
@Override public int readIntLe() {
return Util.reverseBytesInt(readInt());
}
@Override public long readLongLe() {
return Util.reverseBytesLong(readLong());
}
@Override public long readDecimalLong() {
if (size == 0) throw new IllegalStateException("size == 0");
// This value is always built negatively in order to accommodate Long.MIN_VALUE.
long value = 0;
int seen = 0;
boolean negative = false;
boolean done = false;
long overflowZone = Long.MIN_VALUE / 10;
long overflowDigit = (Long.MIN_VALUE % 10) + 1;
do {
Segment segment = head;
byte[] data = segment.data;
int pos = segment.pos;
int limit = segment.limit;
for (; pos < limit; pos++, seen++) {
byte b = data[pos];
if (b >= '0' && b <= '9') {
int digit = '0' - b;
// Detect when the digit would cause an overflow.
if (value < overflowZone || value == overflowZone && digit < overflowDigit) {
Buffer buffer = new Buffer().writeDecimalLong(value).writeByte(b);
if (!negative) buffer.readByte(); // Skip negative sign.
throw new NumberFormatException("Number too large: " + buffer.readUtf8());
}
value *= 10;
value += digit;
} else if (b == '-' && seen == 0) {
negative = true;
overflowDigit -= 1;
} else {
if (seen == 0) {
throw new NumberFormatException(
"Expected leading [0-9] or '-' character but was 0x" + Integer.toHexString(b));
}
// Set a flag to stop iteration. We still need to run through segment updating below.
done = true;
break;
}
}
if (pos == limit) {
head = segment.pop();
SegmentPool.recycle(segment);
} else {
segment.pos = pos;
}
} while (!done && head != null);
size -= seen;
return negative ? value : -value;
}
@Override public long readHexadecimalUnsignedLong() {
if (size == 0) throw new IllegalStateException("size == 0");
long value = 0;
int seen = 0;
boolean done = false;
do {
Segment segment = head;
byte[] data = segment.data;
int pos = segment.pos;
int limit = segment.limit;
for (; pos < limit; pos++, seen++) {
int digit;
byte b = data[pos];
if (b >= '0' && b <= '9') {
digit = b - '0';
} else if (b >= 'a' && b <= 'f') {
digit = b - 'a' + 10;
} else if (b >= 'A' && b <= 'F') {
digit = b - 'A' + 10; // We never write uppercase, but we support reading it.
} else {
if (seen == 0) {
throw new NumberFormatException(
"Expected leading [0-9a-fA-F] character but was 0x" + Integer.toHexString(b));
}
// Set a flag to stop iteration. We still need to run through segment updating below.
done = true;
break;
}
// Detect when the shift will overflow.
if ((value & 0xf000000000000000L) != 0) {
Buffer buffer = new Buffer().writeHexadecimalUnsignedLong(value).writeByte(b);
throw new NumberFormatException("Number too large: " + buffer.readUtf8());
}
value <<= 4;
value |= digit;
}
if (pos == limit) {
head = segment.pop();
SegmentPool.recycle(segment);
} else {
segment.pos = pos;
}
} while (!done && head != null);
size -= seen;
return value;
}
@Override public ByteString readByteString() {
return new ByteString(readByteArray());
}
@Override public ByteString readByteString(long byteCount) throws EOFException {
return new ByteString(readByteArray(byteCount));
}
@Override public void readFully(Buffer sink, long byteCount) throws EOFException {
if (size < byteCount) {
sink.write(this, size); // Exhaust ourselves.
throw new EOFException();
}
sink.write(this, byteCount);
}
@Override public long readAll(Sink sink) throws IOException {
long byteCount = size;
if (byteCount > 0) {
sink.write(this, byteCount);
}
return byteCount;
}
@Override public String readUtf8() {
try {
return readString(size, Util.UTF_8);
} catch (EOFException e) {
throw new AssertionError(e);
}
}
@Override public String readUtf8(long byteCount) throws EOFException {
return readString(byteCount, Util.UTF_8);
}
@Override public String readString(Charset charset) {
try {
return readString(size, charset);
} catch (EOFException e) {
throw new AssertionError(e);
}
}
@Override public String readString(long byteCount, Charset charset) throws EOFException {
checkOffsetAndCount(size, 0, byteCount);
if (charset == null) throw new IllegalArgumentException("charset == null");
if (byteCount > Integer.MAX_VALUE) {
throw new IllegalArgumentException("byteCount > Integer.MAX_VALUE: " + byteCount);
}
if (byteCount == 0) return "";
Segment s = head;
if (s.pos + byteCount > s.limit) {
// If the string spans multiple segments, delegate to readBytes().
return new String(readByteArray(byteCount), charset);
}
String result = new String(s.data, s.pos, (int) byteCount, charset);
s.pos += byteCount;
size -= byteCount;
if (s.pos == s.limit) {
head = s.pop();
SegmentPool.recycle(s);
}
return result;
}
@Override public String readUtf8Line() throws EOFException {
long newline = indexOf((byte) '\n');
if (newline == -1) {
return size != 0 ? readUtf8(size) : null;
}
return readUtf8Line(newline);
}
@Override public String readUtf8LineStrict() throws EOFException {
long newline = indexOf((byte) '\n');
if (newline == -1) {
Buffer data = new Buffer();
copyTo(data, 0, Math.min(32, size));
throw new EOFException("\\n not found: size=" + size()
+ " content=" + data.readByteString().hex() + "...");
}
return readUtf8Line(newline);
}
String readUtf8Line(long newline) throws EOFException {
if (newline > 0 && getByte(newline - 1) == '\r') {
// Read everything until '\r\n', then skip the '\r\n'.
String result = readUtf8((newline - 1));
skip(2);
return result;
} else {
// Read everything until '\n', then skip the '\n'.
String result = readUtf8(newline);
skip(1);
return result;
}
}
@Override public int readUtf8CodePoint() throws EOFException {
if (size == 0) throw new EOFException();
byte b0 = getByte(0);
int codePoint;
int byteCount;
int min;
if ((b0 & 0x80) == 0) {
// 0xxxxxxx.
codePoint = b0 & 0x7f;
byteCount = 1; // 7 bits (ASCII).
min = 0x0;
} else if ((b0 & 0xe0) == 0xc0) {
// 0x110xxxxx
codePoint = b0 & 0x1f;
byteCount = 2; // 11 bits (5 + 6).
min = 0x80;
} else if ((b0 & 0xf0) == 0xe0) {
// 0x1110xxxx
codePoint = b0 & 0x0f;
byteCount = 3; // 16 bits (4 + 6 + 6).
min = 0x800;
} else if ((b0 & 0xf8) == 0xf0) {
// 0x11110xxx
codePoint = b0 & 0x07;
byteCount = 4; // 21 bits (3 + 6 + 6 + 6).
min = 0x10000;
} else {
// We expected the first byte of a code point but got something else.
skip(1);
return REPLACEMENT_CHARACTER;
}
if (size < byteCount) {
throw new EOFException("size < " + byteCount + ": " + size
+ " (to read code point prefixed 0x" + Integer.toHexString(b0) + ")");
}
// Read the continuation bytes. If we encounter a non-continuation byte, the sequence consumed
// thus far is truncated and is decoded as the replacement character. That non-continuation byte
// is left in the stream for processing by the next call to readUtf8CodePoint().
for (int i = 1; i < byteCount; i++) {
byte b = getByte(i);
if ((b & 0xc0) == 0x80) {
// 0x10xxxxxx
codePoint <<= 6;
codePoint |= b & 0x3f;
} else {
skip(i);
return REPLACEMENT_CHARACTER;
}
}
skip(byteCount);
if (codePoint > 0x10ffff) {
return REPLACEMENT_CHARACTER; // Reject code points larger than the Unicode maximum.
}
if (codePoint >= 0xd800 && codePoint <= 0xdfff) {
return REPLACEMENT_CHARACTER; // Reject partial surrogates.
}
if (codePoint < min) {
return REPLACEMENT_CHARACTER; // Reject overlong code points.
}
return codePoint;
}
@Override public byte[] readByteArray() {
try {
return readByteArray(size);
} catch (EOFException e) {
throw new AssertionError(e);
}
}
@Override public byte[] readByteArray(long byteCount) throws EOFException {
checkOffsetAndCount(size, 0, byteCount);
if (byteCount > Integer.MAX_VALUE) {
throw new IllegalArgumentException("byteCount > Integer.MAX_VALUE: " + byteCount);
}
byte[] result = new byte[(int) byteCount];
readFully(result);
return result;
}
@Override public int read(byte[] sink) {
return read(sink, 0, sink.length);
}
@Override public void readFully(byte[] sink) throws EOFException {
int offset = 0;
while (offset < sink.length) {
int read = read(sink, offset, sink.length - offset);
if (read == -1) throw new EOFException();
offset += read;
}
}
@Override public int read(byte[] sink, int offset, int byteCount) {
checkOffsetAndCount(sink.length, offset, byteCount);
Segment s = head;
if (s == null) return -1;
int toCopy = Math.min(byteCount, s.limit - s.pos);
System.arraycopy(s.data, s.pos, sink, offset, toCopy);
s.pos += toCopy;
size -= toCopy;
if (s.pos == s.limit) {
head = s.pop();
SegmentPool.recycle(s);
}
return toCopy;
}
/**
* Discards all bytes in this buffer. Calling this method when you're done
* with a buffer will return its segments to the pool.
*/
public void clear() {
try {
skip(size);
} catch (EOFException e) {
throw new AssertionError(e);
}
}
/** Discards {@code byteCount} bytes from the head of this buffer. */
@Override public void skip(long byteCount) throws EOFException {
while (byteCount > 0) {
if (head == null) throw new EOFException();
int toSkip = (int) Math.min(byteCount, head.limit - head.pos);
size -= toSkip;
byteCount -= toSkip;
head.pos += toSkip;
if (head.pos == head.limit) {
Segment toRecycle = head;
head = toRecycle.pop();
SegmentPool.recycle(toRecycle);
}
}
}
@Override public Buffer write(ByteString byteString) {
if (byteString == null) throw new IllegalArgumentException("byteString == null");
byteString.write(this);
return this;
}
@Override public Buffer writeUtf8(String string) {
return writeUtf8(string, 0, string.length());
}
@Override public Buffer writeUtf8(String string, int beginIndex, int endIndex) {
if (string == null) throw new IllegalArgumentException("string == null");
if (beginIndex < 0) throw new IllegalAccessError("beginIndex < 0: " + beginIndex);
if (endIndex < beginIndex) {
throw new IllegalArgumentException("endIndex < beginIndex: " + endIndex + " < " + beginIndex);
}
if (endIndex > string.length()) {
throw new IllegalArgumentException(
"endIndex > string.length: " + endIndex + " > " + string.length());
}
// Transcode a UTF-16 Java String to UTF-8 bytes.
for (int i = beginIndex; i < endIndex;) {
int c = string.charAt(i);
if (c < 0x80) {
Segment tail = writableSegment(1);
byte[] data = tail.data;
int segmentOffset = tail.limit - i;
int runLimit = Math.min(endIndex, Segment.SIZE - segmentOffset);
// Emit a 7-bit character with 1 byte.
data[segmentOffset + i++] = (byte) c; // 0xxxxxxx
// Fast-path contiguous runs of ASCII characters. This is ugly, but yields a ~4x performance
// improvement over independent calls to writeByte().
while (i < runLimit) {
c = string.charAt(i);
if (c >= 0x80) break;
data[segmentOffset + i++] = (byte) c; // 0xxxxxxx
}
int runSize = i + segmentOffset - tail.limit; // Equivalent to i - (previous i).
tail.limit += runSize;
size += runSize;
} else if (c < 0x800) {
// Emit a 11-bit character with 2 bytes.
writeByte(c >> 6 | 0xc0); // 110xxxxx
writeByte(c & 0x3f | 0x80); // 10xxxxxx
i++;
} else if (c < 0xd800 || c > 0xdfff) {
// Emit a 16-bit character with 3 bytes.
writeByte(c >> 12 | 0xe0); // 1110xxxx
writeByte(c >> 6 & 0x3f | 0x80); // 10xxxxxx
writeByte(c & 0x3f | 0x80); // 10xxxxxx
i++;
} else {
// c is a surrogate. Make sure it is a high surrogate & that its successor is a low
// surrogate. If not, the UTF-16 is invalid, in which case we emit a replacement character.
int low = i + 1 < endIndex ? string.charAt(i + 1) : 0;
if (c > 0xdbff || low < 0xdc00 || low > 0xdfff) {
writeByte('?');
i++;
continue;
}
// UTF-16 high surrogate: 110110xxxxxxxxxx (10 bits)
// UTF-16 low surrogate: 110111yyyyyyyyyy (10 bits)
// Unicode code point: 00010000000000000000 + xxxxxxxxxxyyyyyyyyyy (21 bits)
int codePoint = 0x010000 + ((c & ~0xd800) << 10 | low & ~0xdc00);
// Emit a 21-bit character with 4 bytes.
writeByte(codePoint >> 18 | 0xf0); // 11110xxx
writeByte(codePoint >> 12 & 0x3f | 0x80); // 10xxxxxx
writeByte(codePoint >> 6 & 0x3f | 0x80); // 10xxyyyy
writeByte(codePoint & 0x3f | 0x80); // 10yyyyyy
i += 2;
}
}
return this;
}
@Override public Buffer writeUtf8CodePoint(int codePoint) {
if (codePoint < 0x80) {
// Emit a 7-bit code point with 1 byte.
writeByte(codePoint);
} else if (codePoint < 0x800) {
// Emit a 11-bit code point with 2 bytes.
writeByte(codePoint >> 6 | 0xc0); // 110xxxxx
writeByte(codePoint & 0x3f | 0x80); // 10xxxxxx
} else if (codePoint < 0x10000) {
if (codePoint >= 0xd800 && codePoint <= 0xdfff) {
throw new IllegalArgumentException(
"Unexpected code point: " + Integer.toHexString(codePoint));
}
// Emit a 16-bit code point with 3 bytes.
writeByte(codePoint >> 12 | 0xe0); // 1110xxxx
writeByte(codePoint >> 6 & 0x3f | 0x80); // 10xxxxxx
writeByte(codePoint & 0x3f | 0x80); // 10xxxxxx
} else if (codePoint <= 0x10ffff) {
// Emit a 21-bit code point with 4 bytes.
writeByte(codePoint >> 18 | 0xf0); // 11110xxx
writeByte(codePoint >> 12 & 0x3f | 0x80); // 10xxxxxx
writeByte(codePoint >> 6 & 0x3f | 0x80); // 10xxxxxx
writeByte(codePoint & 0x3f | 0x80); // 10xxxxxx
} else {
throw new IllegalArgumentException(
"Unexpected code point: " + Integer.toHexString(codePoint));
}
return this;
}
@Override public Buffer writeString(String string, Charset charset) {
return writeString(string, 0, string.length(), charset);
}
@Override
public Buffer writeString(String string, int beginIndex, int endIndex, Charset charset) {
if (string == null) throw new IllegalArgumentException("string == null");
if (beginIndex < 0) throw new IllegalAccessError("beginIndex < 0: " + beginIndex);
if (endIndex < beginIndex) {
throw new IllegalArgumentException("endIndex < beginIndex: " + endIndex + " < " + beginIndex);
}
if (endIndex > string.length()) {
throw new IllegalArgumentException(
"endIndex > string.length: " + endIndex + " > " + string.length());
}
if (charset == null) throw new IllegalArgumentException("charset == null");
if (charset.equals(Util.UTF_8)) return writeUtf8(string);
byte[] data = string.substring(beginIndex, endIndex).getBytes(charset);
return write(data, 0, data.length);
}
@Override public Buffer write(byte[] source) {
if (source == null) throw new IllegalArgumentException("source == null");
return write(source, 0, source.length);
}
@Override public Buffer write(byte[] source, int offset, int byteCount) {
if (source == null) throw new IllegalArgumentException("source == null");
checkOffsetAndCount(source.length, offset, byteCount);
int limit = offset + byteCount;
while (offset < limit) {
Segment tail = writableSegment(1);
int toCopy = Math.min(limit - offset, Segment.SIZE - tail.limit);
System.arraycopy(source, offset, tail.data, tail.limit, toCopy);
offset += toCopy;
tail.limit += toCopy;
}
size += byteCount;
return this;
}
@Override public long writeAll(Source source) throws IOException {
if (source == null) throw new IllegalArgumentException("source == null");
long totalBytesRead = 0;
for (long readCount; (readCount = source.read(this, Segment.SIZE)) != -1; ) {
totalBytesRead += readCount;
}
return totalBytesRead;
}
@Override public BufferedSink write(Source source, long byteCount) throws IOException {
while (byteCount > 0) {
long read = source.read(this, byteCount);
if (read == -1) throw new EOFException();
byteCount -= read;
}
return this;
}
@Override public Buffer writeByte(int b) {
Segment tail = writableSegment(1);
tail.data[tail.limit++] = (byte) b;
size += 1;
return this;
}
@Override public Buffer writeShort(int s) {
Segment tail = writableSegment(2);
byte[] data = tail.data;
int limit = tail.limit;
data[limit++] = (byte) ((s >>> 8) & 0xff);
data[limit++] = (byte) (s & 0xff);
tail.limit = limit;
size += 2;
return this;
}
@Override public Buffer writeShortLe(int s) {
return writeShort(Util.reverseBytesShort((short) s));
}
@Override public Buffer writeInt(int i) {
Segment tail = writableSegment(4);
byte[] data = tail.data;
int limit = tail.limit;
data[limit++] = (byte) ((i >>> 24) & 0xff);
data[limit++] = (byte) ((i >>> 16) & 0xff);
data[limit++] = (byte) ((i >>> 8) & 0xff);
data[limit++] = (byte) (i & 0xff);
tail.limit = limit;
size += 4;
return this;
}
@Override public Buffer writeIntLe(int i) {
return writeInt(Util.reverseBytesInt(i));
}
@Override public Buffer writeLong(long v) {
Segment tail = writableSegment(8);
byte[] data = tail.data;
int limit = tail.limit;
data[limit++] = (byte) ((v >>> 56L) & 0xff);
data[limit++] = (byte) ((v >>> 48L) & 0xff);
data[limit++] = (byte) ((v >>> 40L) & 0xff);
data[limit++] = (byte) ((v >>> 32L) & 0xff);
data[limit++] = (byte) ((v >>> 24L) & 0xff);
data[limit++] = (byte) ((v >>> 16L) & 0xff);
data[limit++] = (byte) ((v >>> 8L) & 0xff);
data[limit++] = (byte) (v & 0xff);
tail.limit = limit;
size += 8;
return this;
}
@Override public Buffer writeLongLe(long v) {
return writeLong(reverseBytesLong(v));
}
@Override public Buffer writeDecimalLong(long v) {
if (v == 0) {
// Both a shortcut and required since the following code can't handle zero.
return writeByte('0');
}
boolean negative = false;
if (v < 0) {
v = -v;
if (v < 0) { // Only true for Long.MIN_VALUE.
return writeUtf8("-9223372036854775808");
}
negative = true;
}
// Binary search for character width which favors matching lower numbers.
int width = //
v < 100000000L
? v < 10000L
? v < 100L
? v < 10L ? 1 : 2
: v < 1000L ? 3 : 4
: v < 1000000L
? v < 100000L ? 5 : 6
: v < 10000000L ? 7 : 8
: v < 1000000000000L
? v < 10000000000L
? v < 1000000000L ? 9 : 10
: v < 100000000000L ? 11 : 12
: v < 1000000000000000L
? v < 10000000000000L ? 13
: v < 100000000000000L ? 14 : 15
: v < 100000000000000000L
? v < 10000000000000000L ? 16 : 17
: v < 1000000000000000000L ? 18 : 19;
if (negative) {
++width;
}
Segment tail = writableSegment(width);
byte[] data = tail.data;
int pos = tail.limit + width; // We write backwards from right to left.
while (v != 0) {
int digit = (int) (v % 10);
data[--pos] = DIGITS[digit];
v /= 10;
}
if (negative) {
data[--pos] = '-';
}
tail.limit += width;
this.size += width;
return this;
}
@Override public Buffer writeHexadecimalUnsignedLong(long v) {
if (v == 0) {
// Both a shortcut and required since the following code can't handle zero.
return writeByte('0');
}
int width = Long.numberOfTrailingZeros(Long.highestOneBit(v)) / 4 + 1;
Segment tail = writableSegment(width);
byte[] data = tail.data;
for (int pos = tail.limit + width - 1, start = tail.limit; pos >= start; pos--) {
data[pos] = DIGITS[(int) (v & 0xF)];
v >>>= 4;
}
tail.limit += width;
size += width;
return this;
}
/**
* Returns a tail segment that we can write at least {@code minimumCapacity}
* bytes to, creating it if necessary.
*/
Segment writableSegment(int minimumCapacity) {
if (minimumCapacity < 1 || minimumCapacity > Segment.SIZE) throw new IllegalArgumentException();
if (head == null) {
head = SegmentPool.take(); // Acquire a first segment.
return head.next = head.prev = head;
}
Segment tail = head.prev;
if (tail.limit + minimumCapacity > Segment.SIZE || !tail.owner) {
tail = tail.push(SegmentPool.take()); // Append a new empty segment to fill up.
}
return tail;
}
@Override public void write(Buffer source, long byteCount) {
// Move bytes from the head of the source buffer to the tail of this buffer
// while balancing two conflicting goals: don't waste CPU and don't waste
// memory.
//
//
// Don't waste CPU (ie. don't copy data around).
//
// Copying large amounts of data is expensive. Instead, we prefer to
// reassign entire segments from one buffer to the other.
//
//
// Don't waste memory.
//
// As an invariant, adjacent pairs of segments in a buffer should be at
// least 50% full, except for the head segment and the tail segment.
//
// The head segment cannot maintain the invariant because the application is
// consuming bytes from this segment, decreasing its level.
//
// The tail segment cannot maintain the invariant because the application is
// producing bytes, which may require new nearly-empty tail segments to be
// appended.
//
//
// Moving segments between buffers
//
// When writing one buffer to another, we prefer to reassign entire segments
// over copying bytes into their most compact form. Suppose we have a buffer
// with these segment levels [91%, 61%]. If we append a buffer with a
// single [72%] segment, that yields [91%, 61%, 72%]. No bytes are copied.
//
// Or suppose we have a buffer with these segment levels: [100%, 2%], and we
// want to append it to a buffer with these segment levels [99%, 3%]. This
// operation will yield the following segments: [100%, 2%, 99%, 3%]. That
// is, we do not spend time copying bytes around to achieve more efficient
// memory use like [100%, 100%, 4%].
//
// When combining buffers, we will compact adjacent buffers when their
// combined level doesn't exceed 100%. For example, when we start with
// [100%, 40%] and append [30%, 80%], the result is [100%, 70%, 80%].
//
//
// Splitting segments
//
// Occasionally we write only part of a source buffer to a sink buffer. For
// example, given a sink [51%, 91%], we may want to write the first 30% of
// a source [92%, 82%] to it. To simplify, we first transform the source to
// an equivalent buffer [30%, 62%, 82%] and then move the head segment,
// yielding sink [51%, 91%, 30%] and source [62%, 82%].
if (source == null) throw new IllegalArgumentException("source == null");
if (source == this) throw new IllegalArgumentException("source == this");
checkOffsetAndCount(source.size, 0, byteCount);
while (byteCount > 0) {
// Is a prefix of the source's head segment all that we need to move?
if (byteCount < (source.head.limit - source.head.pos)) {
Segment tail = head != null ? head.prev : null;
if (tail != null && tail.owner
&& (byteCount + tail.limit - (tail.shared ? 0 : tail.pos) <= Segment.SIZE)) {
// Our existing segments are sufficient. Move bytes from source's head to our tail.
source.head.writeTo(tail, (int) byteCount);
source.size -= byteCount;
size += byteCount;
return;
} else {
// We're going to need another segment. Split the source's head
// segment in two, then move the first of those two to this buffer.
source.head = source.head.split((int) byteCount);
}
}
// Remove the source's head segment and append it to our tail.
Segment segmentToMove = source.head;
long movedByteCount = segmentToMove.limit - segmentToMove.pos;
source.head = segmentToMove.pop();
if (head == null) {
head = segmentToMove;
head.next = head.prev = head;
} else {
Segment tail = head.prev;
tail = tail.push(segmentToMove);
tail.compact();
}
source.size -= movedByteCount;
size += movedByteCount;
byteCount -= movedByteCount;
}
}
@Override public long read(Buffer sink, long byteCount) {
if (sink == null) throw new IllegalArgumentException("sink == null");
if (byteCount < 0) throw new IllegalArgumentException("byteCount < 0: " + byteCount);
if (size == 0) return -1L;
if (byteCount > size) byteCount = size;
sink.write(this, byteCount);
return byteCount;
}
@Override public long indexOf(byte b) {
return indexOf(b, 0);
}
/**
* Returns the index of {@code b} in this at or beyond {@code fromIndex}, or
* -1 if this buffer does not contain {@code b} in that range.
*/
@Override public long indexOf(byte b, long fromIndex) {
if (fromIndex < 0) throw new IllegalArgumentException("fromIndex < 0");
Segment s = head;
if (s == null) return -1L;
long offset = 0L;
do {
int segmentByteCount = s.limit - s.pos;
if (fromIndex >= segmentByteCount) {
fromIndex -= segmentByteCount;
} else {
byte[] data = s.data;
for (int pos = (int) (s.pos + fromIndex), limit = s.limit; pos < limit; pos++) {
if (data[pos] == b) return offset + pos - s.pos;
}
fromIndex = 0;
}
offset += segmentByteCount;
s = s.next;
} while (s != head);
return -1L;
}
@Override public long indexOf(ByteString bytes) throws IOException {
return indexOf(bytes, 0);
}
@Override public long indexOf(ByteString bytes, long fromIndex) throws IOException {
if (bytes.size() == 0) throw new IllegalArgumentException("bytes is empty");
while (true) {
fromIndex = indexOf(bytes.getByte(0), fromIndex);
if (fromIndex == -1) {
return -1;
}
if (rangeEquals(fromIndex, bytes)) {
return fromIndex;
}
fromIndex++;
}
}
@Override public long indexOfElement(ByteString targetBytes) {
return indexOfElement(targetBytes, 0);
}
@Override public long indexOfElement(ByteString targetBytes, long fromIndex) {
if (fromIndex < 0) throw new IllegalArgumentException("fromIndex < 0");
Segment s = head;
if (s == null) return -1L;
long offset = 0L;
byte[] toFind = targetBytes.toByteArray();
do {
int segmentByteCount = s.limit - s.pos;
if (fromIndex >= segmentByteCount) {
fromIndex -= segmentByteCount;
} else {
byte[] data = s.data;
for (long pos = s.pos + fromIndex, limit = s.limit; pos < limit; pos++) {
byte b = data[(int) pos];
for (byte targetByte : toFind) {
if (b == targetByte) return offset + pos - s.pos;
}
}
fromIndex = 0;
}
offset += segmentByteCount;
s = s.next;
} while (s != head);
return -1L;
}
boolean rangeEquals(long offset, ByteString bytes) {
int byteCount = bytes.size();
if (size - offset < byteCount) {
return false;
}
for (int i = 0; i < byteCount; i++) {
if (getByte(offset + i) != bytes.getByte(i)) {
return false;
}
}
return true;
}
@Override public void flush() {
}
@Override public void close() {
}
@Override public Timeout timeout() {
return Timeout.NONE;
}
/** For testing. This returns the sizes of the segments in this buffer. */
List