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/*
 * Copyright 2012 The Netty Project
 *
 * The Netty Project licenses this file to you under the Apache License,
 * version 2.0 (the "License"); you may not use this file except in compliance
 * with the License. You may obtain a copy of the License at:
 *
 *   https://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
 * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
 * License for the specific language governing permissions and limitations
 * under the License.
 */
package io.netty.handler.codec.http;

import io.netty.buffer.ByteBuf;
import io.netty.buffer.ByteBufUtil;
import io.netty.buffer.Unpooled;
import io.netty.channel.ChannelHandlerContext;
import io.netty.channel.ChannelPromise;
import io.netty.channel.FileRegion;
import io.netty.handler.codec.EncoderException;
import io.netty.handler.codec.MessageToMessageEncoder;
import io.netty.util.CharsetUtil;
import io.netty.util.ReferenceCountUtil;
import io.netty.util.concurrent.PromiseCombiner;
import io.netty.util.internal.StringUtil;

import java.util.ArrayList;
import java.util.Iterator;
import java.util.List;
import java.util.Map.Entry;

import static io.netty.buffer.Unpooled.directBuffer;
import static io.netty.buffer.Unpooled.unreleasableBuffer;
import static io.netty.handler.codec.http.HttpConstants.CR;
import static io.netty.handler.codec.http.HttpConstants.LF;

/**
 * Encodes an {@link HttpMessage} or an {@link HttpContent} into
 * a {@link ByteBuf}.
 *
 * 

Extensibility

* * Please note that this encoder is designed to be extended to implement * a protocol derived from HTTP, such as * RTSP and * ICAP. * To implement the encoder of such a derived protocol, extend this class and * implement all abstract methods properly. */ public abstract class HttpObjectEncoder extends MessageToMessageEncoder { static final int CRLF_SHORT = (CR << 8) | LF; private static final int ZERO_CRLF_MEDIUM = ('0' << 16) | CRLF_SHORT; private static final byte[] ZERO_CRLF_CRLF = { '0', CR, LF, CR, LF }; private static final ByteBuf CRLF_BUF = unreleasableBuffer( directBuffer(2).writeByte(CR).writeByte(LF)).asReadOnly(); private static final ByteBuf ZERO_CRLF_CRLF_BUF = unreleasableBuffer( directBuffer(ZERO_CRLF_CRLF.length).writeBytes(ZERO_CRLF_CRLF)).asReadOnly(); private static final float HEADERS_WEIGHT_NEW = 1 / 5f; private static final float HEADERS_WEIGHT_HISTORICAL = 1 - HEADERS_WEIGHT_NEW; private static final float TRAILERS_WEIGHT_NEW = HEADERS_WEIGHT_NEW; private static final float TRAILERS_WEIGHT_HISTORICAL = HEADERS_WEIGHT_HISTORICAL; private static final int ST_INIT = 0; private static final int ST_CONTENT_NON_CHUNK = 1; private static final int ST_CONTENT_CHUNK = 2; private static final int ST_CONTENT_ALWAYS_EMPTY = 3; @SuppressWarnings("RedundantFieldInitialization") private int state = ST_INIT; /** * Used to calculate an exponential moving average of the encoded size of the initial line and the headers for * a guess for future buffer allocations. */ private float headersEncodedSizeAccumulator = 256; /** * Used to calculate an exponential moving average of the encoded size of the trailers for * a guess for future buffer allocations. */ private float trailersEncodedSizeAccumulator = 256; private final List out = new ArrayList(); private static boolean checkContentState(int state) { return state == ST_CONTENT_CHUNK || state == ST_CONTENT_NON_CHUNK || state == ST_CONTENT_ALWAYS_EMPTY; } @Override public void write(ChannelHandlerContext ctx, Object msg, ChannelPromise promise) throws Exception { try { if (acceptOutboundMessage(msg)) { encode(ctx, msg, out); if (out.isEmpty()) { throw new EncoderException( StringUtil.simpleClassName(this) + " must produce at least one message."); } } else { ctx.write(msg, promise); } } catch (EncoderException e) { throw e; } catch (Throwable t) { throw new EncoderException(t); } finally { writeOutList(ctx, out, promise); } } private static void writeOutList(ChannelHandlerContext ctx, List out, ChannelPromise promise) { final int size = out.size(); try { if (size == 1) { ctx.write(out.get(0), promise); } else if (size > 1) { // Check if we can use a voidPromise for our extra writes to reduce GC-Pressure // See https://github.com/netty/netty/issues/2525 if (promise == ctx.voidPromise()) { writeVoidPromise(ctx, out); } else { writePromiseCombiner(ctx, out, promise); } } } finally { out.clear(); } } private static void writeVoidPromise(ChannelHandlerContext ctx, List out) { final ChannelPromise voidPromise = ctx.voidPromise(); for (int i = 0; i < out.size(); i++) { ctx.write(out.get(i), voidPromise); } } private static void writePromiseCombiner(ChannelHandlerContext ctx, List out, ChannelPromise promise) { final PromiseCombiner combiner = new PromiseCombiner(ctx.executor()); for (int i = 0; i < out.size(); i++) { combiner.add(ctx.write(out.get(i))); } combiner.finish(promise); } @Override @SuppressWarnings("ConditionCoveredByFurtherCondition") protected void encode(ChannelHandlerContext ctx, Object msg, List out) throws Exception { // fast-path for common idiom that doesn't require class-checks if (msg == Unpooled.EMPTY_BUFFER) { out.add(Unpooled.EMPTY_BUFFER); return; } // The reason why we perform instanceof checks in this order, // by duplicating some code and without relying on ReferenceCountUtil::release as a generic release // mechanism, is https://bugs.openjdk.org/browse/JDK-8180450. // https://github.com/netty/netty/issues/12708 contains more detail re how the previous version of this // code was interacting with the JIT instanceof optimizations. if (msg instanceof FullHttpMessage) { encodeFullHttpMessage(ctx, msg, out); return; } if (msg instanceof HttpMessage) { final H m; try { m = (H) msg; } catch (Exception rethrow) { ReferenceCountUtil.release(msg); throw rethrow; } if (m instanceof LastHttpContent) { encodeHttpMessageLastContent(ctx, m, out); } else if (m instanceof HttpContent) { encodeHttpMessageNotLastContent(ctx, m, out); } else { encodeJustHttpMessage(ctx, m, out); } } else { encodeNotHttpMessageContentTypes(ctx, msg, out); } } private void encodeJustHttpMessage(ChannelHandlerContext ctx, H m, List out) throws Exception { assert !(m instanceof HttpContent); try { if (state != ST_INIT) { throwUnexpectedMessageTypeEx(m, state); } final ByteBuf buf = encodeInitHttpMessage(ctx, m); assert checkContentState(state); out.add(buf); } finally { ReferenceCountUtil.release(m); } } private void encodeByteBufHttpContent(int state, ChannelHandlerContext ctx, ByteBuf buf, ByteBuf content, HttpHeaders trailingHeaders, List out) { switch (state) { case ST_CONTENT_NON_CHUNK: if (encodeContentNonChunk(out, buf, content)) { break; } // fall-through! case ST_CONTENT_ALWAYS_EMPTY: // We allocated a buffer so add it now. out.add(buf); break; case ST_CONTENT_CHUNK: // We allocated a buffer so add it now. out.add(buf); encodeChunkedHttpContent(ctx, content, trailingHeaders, out); break; default: throw new Error(); } } private void encodeHttpMessageNotLastContent(ChannelHandlerContext ctx, H m, List out) throws Exception { assert m instanceof HttpContent; assert !(m instanceof LastHttpContent); final HttpContent httpContent = (HttpContent) m; try { if (state != ST_INIT) { throwUnexpectedMessageTypeEx(m, state); } final ByteBuf buf = encodeInitHttpMessage(ctx, m); assert checkContentState(state); encodeByteBufHttpContent(state, ctx, buf, httpContent.content(), null, out); } finally { httpContent.release(); } } private void encodeHttpMessageLastContent(ChannelHandlerContext ctx, H m, List out) throws Exception { assert m instanceof LastHttpContent; final LastHttpContent httpContent = (LastHttpContent) m; try { if (state != ST_INIT) { throwUnexpectedMessageTypeEx(m, state); } final ByteBuf buf = encodeInitHttpMessage(ctx, m); assert checkContentState(state); encodeByteBufHttpContent(state, ctx, buf, httpContent.content(), httpContent.trailingHeaders(), out); state = ST_INIT; } finally { httpContent.release(); } } @SuppressWarnings("ConditionCoveredByFurtherCondition") private void encodeNotHttpMessageContentTypes(ChannelHandlerContext ctx, Object msg, List out) { assert !(msg instanceof HttpMessage); if (state == ST_INIT) { try { if (msg instanceof ByteBuf && bypassEncoderIfEmpty((ByteBuf) msg, out)) { return; } throwUnexpectedMessageTypeEx(msg, ST_INIT); } finally { ReferenceCountUtil.release(msg); } } if (msg == LastHttpContent.EMPTY_LAST_CONTENT) { state = encodeEmptyLastHttpContent(state, out); return; } if (msg instanceof LastHttpContent) { encodeLastHttpContent(ctx, (LastHttpContent) msg, out); return; } if (msg instanceof HttpContent) { encodeHttpContent(ctx, (HttpContent) msg, out); return; } if (msg instanceof ByteBuf) { encodeByteBufContent(ctx, (ByteBuf) msg, out); return; } if (msg instanceof FileRegion) { encodeFileRegionContent(ctx, (FileRegion) msg, out); return; } try { throwUnexpectedMessageTypeEx(msg, state); } finally { ReferenceCountUtil.release(msg); } } private void encodeFullHttpMessage(ChannelHandlerContext ctx, Object o, List out) throws Exception { assert o instanceof FullHttpMessage; final FullHttpMessage msg = (FullHttpMessage) o; try { if (state != ST_INIT) { throwUnexpectedMessageTypeEx(o, state); } final H m = (H) o; final ByteBuf buf = ctx.alloc().buffer((int) headersEncodedSizeAccumulator); encodeInitialLine(buf, m); final int state = isContentAlwaysEmpty(m) ? ST_CONTENT_ALWAYS_EMPTY : HttpUtil.isTransferEncodingChunked(m) ? ST_CONTENT_CHUNK : ST_CONTENT_NON_CHUNK; sanitizeHeadersBeforeEncode(m, state == ST_CONTENT_ALWAYS_EMPTY); encodeHeaders(m.headers(), buf); ByteBufUtil.writeShortBE(buf, CRLF_SHORT); headersEncodedSizeAccumulator = HEADERS_WEIGHT_NEW * padSizeForAccumulation(buf.readableBytes()) + HEADERS_WEIGHT_HISTORICAL * headersEncodedSizeAccumulator; encodeByteBufHttpContent(state, ctx, buf, msg.content(), msg.trailingHeaders(), out); } finally { msg.release(); } } private static boolean encodeContentNonChunk(List out, ByteBuf buf, ByteBuf content) { final int contentLength = content.readableBytes(); if (contentLength > 0) { if (buf.writableBytes() >= contentLength) { // merge into other buffer for performance reasons buf.writeBytes(content); out.add(buf); } else { out.add(buf); out.add(content.retain()); } return true; } return false; } private static void throwUnexpectedMessageTypeEx(Object msg, int state) { throw new IllegalStateException("unexpected message type: " + StringUtil.simpleClassName(msg) + ", state: " + state); } private void encodeFileRegionContent(ChannelHandlerContext ctx, FileRegion msg, List out) { try { assert state != ST_INIT; switch (state) { case ST_CONTENT_NON_CHUNK: if (msg.count() > 0) { out.add(msg.retain()); break; } // fall-through! case ST_CONTENT_ALWAYS_EMPTY: // Need to produce some output otherwise an // IllegalStateException will be thrown as we did not write anything // Its ok to just write an EMPTY_BUFFER as if there are reference count issues these will be // propagated as the caller of the encode(...) method will release the original // buffer. // Writing an empty buffer will not actually write anything on the wire, so if there is a user // error with msg it will not be visible externally out.add(Unpooled.EMPTY_BUFFER); break; case ST_CONTENT_CHUNK: encodedChunkedFileRegionContent(ctx, msg, out); break; default: throw new Error(); } } finally { msg.release(); } } // Bypass the encoder in case of an empty buffer, so that the following idiom works: // // ch.write(Unpooled.EMPTY_BUFFER).addListener(ChannelFutureListener.CLOSE); // // See https://github.com/netty/netty/issues/2983 for more information. private static boolean bypassEncoderIfEmpty(ByteBuf msg, List out) { if (!msg.isReadable()) { out.add(msg.retain()); return true; } return false; } private void encodeByteBufContent(ChannelHandlerContext ctx, ByteBuf content, List out) { try { assert state != ST_INIT; if (bypassEncoderIfEmpty(content, out)) { return; } encodeByteBufAndTrailers(state, ctx, out, content, null); } finally { content.release(); } } private static int encodeEmptyLastHttpContent(int state, List out) { assert state != ST_INIT; switch (state) { case ST_CONTENT_NON_CHUNK: case ST_CONTENT_ALWAYS_EMPTY: out.add(Unpooled.EMPTY_BUFFER); break; case ST_CONTENT_CHUNK: out.add(ZERO_CRLF_CRLF_BUF.duplicate()); break; default: throw new Error(); } return ST_INIT; } private void encodeLastHttpContent(ChannelHandlerContext ctx, LastHttpContent msg, List out) { assert state != ST_INIT; assert !(msg instanceof HttpMessage); try { encodeByteBufAndTrailers(state, ctx, out, msg.content(), msg.trailingHeaders()); state = ST_INIT; } finally { msg.release(); } } private void encodeHttpContent(ChannelHandlerContext ctx, HttpContent msg, List out) { assert state != ST_INIT; assert !(msg instanceof HttpMessage); assert !(msg instanceof LastHttpContent); try { this.encodeByteBufAndTrailers(state, ctx, out, msg.content(), null); } finally { msg.release(); } } private void encodeByteBufAndTrailers(int state, ChannelHandlerContext ctx, List out, ByteBuf content, HttpHeaders trailingHeaders) { switch (state) { case ST_CONTENT_NON_CHUNK: if (content.isReadable()) { out.add(content.retain()); break; } // fall-through! case ST_CONTENT_ALWAYS_EMPTY: out.add(Unpooled.EMPTY_BUFFER); break; case ST_CONTENT_CHUNK: encodeChunkedHttpContent(ctx, content, trailingHeaders, out); break; default: throw new Error(); } } private void encodeChunkedHttpContent(ChannelHandlerContext ctx, ByteBuf content, HttpHeaders trailingHeaders, List out) { final int contentLength = content.readableBytes(); if (contentLength > 0) { addEncodedLengthHex(ctx, contentLength, out); out.add(content.retain()); out.add(CRLF_BUF.duplicate()); } if (trailingHeaders != null) { encodeTrailingHeaders(ctx, trailingHeaders, out); } else if (contentLength == 0) { // Need to produce some output otherwise an // IllegalStateException will be thrown out.add(content.retain()); } } private void encodeTrailingHeaders(ChannelHandlerContext ctx, HttpHeaders trailingHeaders, List out) { if (trailingHeaders.isEmpty()) { out.add(ZERO_CRLF_CRLF_BUF.duplicate()); } else { ByteBuf buf = ctx.alloc().buffer((int) trailersEncodedSizeAccumulator); ByteBufUtil.writeMediumBE(buf, ZERO_CRLF_MEDIUM); encodeHeaders(trailingHeaders, buf); ByteBufUtil.writeShortBE(buf, CRLF_SHORT); trailersEncodedSizeAccumulator = TRAILERS_WEIGHT_NEW * padSizeForAccumulation(buf.readableBytes()) + TRAILERS_WEIGHT_HISTORICAL * trailersEncodedSizeAccumulator; out.add(buf); } } private ByteBuf encodeInitHttpMessage(ChannelHandlerContext ctx, H m) throws Exception { assert state == ST_INIT; ByteBuf buf = ctx.alloc().buffer((int) headersEncodedSizeAccumulator); // Encode the message. encodeInitialLine(buf, m); state = isContentAlwaysEmpty(m) ? ST_CONTENT_ALWAYS_EMPTY : HttpUtil.isTransferEncodingChunked(m) ? ST_CONTENT_CHUNK : ST_CONTENT_NON_CHUNK; sanitizeHeadersBeforeEncode(m, state == ST_CONTENT_ALWAYS_EMPTY); encodeHeaders(m.headers(), buf); ByteBufUtil.writeShortBE(buf, CRLF_SHORT); headersEncodedSizeAccumulator = HEADERS_WEIGHT_NEW * padSizeForAccumulation(buf.readableBytes()) + HEADERS_WEIGHT_HISTORICAL * headersEncodedSizeAccumulator; return buf; } /** * Encode the {@link HttpHeaders} into a {@link ByteBuf}. */ protected void encodeHeaders(HttpHeaders headers, ByteBuf buf) { Iterator> iter = headers.iteratorCharSequence(); while (iter.hasNext()) { Entry header = iter.next(); HttpHeadersEncoder.encoderHeader(header.getKey(), header.getValue(), buf); } } private static void encodedChunkedFileRegionContent(ChannelHandlerContext ctx, FileRegion msg, List out) { final long contentLength = msg.count(); if (contentLength > 0) { addEncodedLengthHex(ctx, contentLength, out); out.add(msg.retain()); out.add(CRLF_BUF.duplicate()); } else if (contentLength == 0) { // Need to produce some output otherwise an // IllegalStateException will be thrown out.add(msg.retain()); } } private static void addEncodedLengthHex(ChannelHandlerContext ctx, long contentLength, List out) { String lengthHex = Long.toHexString(contentLength); ByteBuf buf = ctx.alloc().buffer(lengthHex.length() + 2); buf.writeCharSequence(lengthHex, CharsetUtil.US_ASCII); ByteBufUtil.writeShortBE(buf, CRLF_SHORT); out.add(buf); } /** * Allows to sanitize headers of the message before encoding these. */ protected void sanitizeHeadersBeforeEncode(@SuppressWarnings("unused") H msg, boolean isAlwaysEmpty) { // noop } /** * Determine whether a message has a content or not. Some message may have headers indicating * a content without having an actual content, e.g the response to an HEAD or CONNECT request. * * @param msg the message to test * @return {@code true} to signal the message has no content */ protected boolean isContentAlwaysEmpty(@SuppressWarnings("unused") H msg) { return false; } @Override @SuppressWarnings("ConditionCoveredByFurtherCondition") public boolean acceptOutboundMessage(Object msg) throws Exception { return msg == Unpooled.EMPTY_BUFFER || msg == LastHttpContent.EMPTY_LAST_CONTENT || msg instanceof FullHttpMessage || msg instanceof HttpMessage || msg instanceof LastHttpContent || msg instanceof HttpContent || msg instanceof ByteBuf || msg instanceof FileRegion; } /** * Add some additional overhead to the buffer. The rational is that it is better to slightly over allocate and waste * some memory, rather than under allocate and require a resize/copy. * * @param readableBytes The readable bytes in the buffer. * @return The {@code readableBytes} with some additional padding. */ private static int padSizeForAccumulation(int readableBytes) { return (readableBytes << 2) / 3; } @Deprecated protected static void encodeAscii(String s, ByteBuf buf) { buf.writeCharSequence(s, CharsetUtil.US_ASCII); } protected abstract void encodeInitialLine(ByteBuf buf, H message) throws Exception; }