org.apache.coyote.http11.Http11InputBuffer Maven / Gradle / Ivy
/*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* The ASF 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
*
* http://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 org.apache.coyote.http11;
import java.io.EOFException;
import java.io.IOException;
import java.nio.ByteBuffer;
import java.nio.charset.StandardCharsets;
import java.util.Arrays;
import org.apache.coyote.CloseNowException;
import org.apache.coyote.InputBuffer;
import org.apache.coyote.Request;
import org.apache.juli.logging.Log;
import org.apache.juli.logging.LogFactory;
import org.apache.tomcat.util.buf.MessageBytes;
import org.apache.tomcat.util.http.HeaderUtil;
import org.apache.tomcat.util.http.MimeHeaders;
import org.apache.tomcat.util.http.parser.HttpParser;
import org.apache.tomcat.util.net.ApplicationBufferHandler;
import org.apache.tomcat.util.net.SocketWrapperBase;
import org.apache.tomcat.util.res.StringManager;
/**
* InputBuffer for HTTP that provides request header parsing as well as transfer encoding.
*/
public class Http11InputBuffer implements InputBuffer, ApplicationBufferHandler {
// -------------------------------------------------------------- Constants
private static final Log log = LogFactory.getLog(Http11InputBuffer.class);
/**
* The string manager for this package.
*/
private static final StringManager sm = StringManager.getManager(Http11InputBuffer.class);
private static final byte[] CLIENT_PREFACE_START =
"PRI * HTTP/2.0\r\n\r\nSM\r\n\r\n".getBytes(StandardCharsets.ISO_8859_1);
/**
* Associated Coyote request.
*/
private final Request request;
/**
* Headers of the associated request.
*/
private final MimeHeaders headers;
private final boolean rejectIllegalHeader;
/**
* State.
*/
private volatile boolean parsingHeader;
/**
* Swallow input ? (in the case of an expectation)
*/
private boolean swallowInput;
/**
* The read buffer.
*/
private ByteBuffer byteBuffer;
/**
* Pos of the end of the header in the buffer, which is also the start of the body.
*/
private int end;
/**
* Wrapper that provides access to the underlying socket.
*/
private SocketWrapperBase> wrapper;
/**
* Underlying input buffer.
*/
private InputBuffer inputStreamInputBuffer;
/**
* Filter library. Note: Filter[Constants.CHUNKED_FILTER] is always the "chunked" filter.
*/
private InputFilter[] filterLibrary;
/**
* Active filters (in order).
*/
private InputFilter[] activeFilters;
/**
* Index of the last active filter.
*/
private int lastActiveFilter;
/**
* Parsing state - used for non blocking parsing so that when more data arrives, we can pick up where we left off.
*/
private byte prevChr = 0;
private byte chr = 0;
private volatile boolean parsingRequestLine;
private int parsingRequestLinePhase = 0;
private boolean parsingRequestLineEol = false;
private int parsingRequestLineStart = 0;
private int parsingRequestLineQPos = -1;
private HeaderParsePosition headerParsePos;
private final HeaderParseData headerData = new HeaderParseData();
private final HttpParser httpParser;
/**
* Maximum allowed size of the HTTP request line plus headers plus any leading blank lines.
*/
private final int headerBufferSize;
/**
* Known size of the NioChannel read buffer.
*/
private int socketReadBufferSize;
// ----------------------------------------------------------- Constructors
public Http11InputBuffer(Request request, int headerBufferSize, boolean rejectIllegalHeader,
HttpParser httpParser) {
this.request = request;
headers = request.getMimeHeaders();
this.headerBufferSize = headerBufferSize;
this.rejectIllegalHeader = rejectIllegalHeader;
this.httpParser = httpParser;
filterLibrary = new InputFilter[0];
activeFilters = new InputFilter[0];
lastActiveFilter = -1;
parsingHeader = true;
parsingRequestLine = true;
parsingRequestLinePhase = 0;
parsingRequestLineEol = false;
parsingRequestLineStart = 0;
parsingRequestLineQPos = -1;
headerParsePos = HeaderParsePosition.HEADER_START;
swallowInput = true;
inputStreamInputBuffer = new SocketInputBuffer();
}
// ------------------------------------------------------------- Properties
/**
* Add an input filter to the filter library.
*
* @throws NullPointerException if the supplied filter is null
*/
void addFilter(InputFilter filter) {
if (filter == null) {
throw new NullPointerException(sm.getString("iib.filter.npe"));
}
InputFilter[] newFilterLibrary = Arrays.copyOf(filterLibrary, filterLibrary.length + 1);
newFilterLibrary[filterLibrary.length] = filter;
filterLibrary = newFilterLibrary;
activeFilters = new InputFilter[filterLibrary.length];
}
/**
* Get filters.
*/
InputFilter[] getFilters() {
return filterLibrary;
}
/**
* Add an input filter to the filter library.
*/
void addActiveFilter(InputFilter filter) {
if (lastActiveFilter == -1) {
filter.setBuffer(inputStreamInputBuffer);
} else {
for (int i = 0; i <= lastActiveFilter; i++) {
if (activeFilters[i] == filter) {
return;
}
}
filter.setBuffer(activeFilters[lastActiveFilter]);
}
activeFilters[++lastActiveFilter] = filter;
filter.setRequest(request);
}
/**
* Set the swallow input flag.
*/
void setSwallowInput(boolean swallowInput) {
this.swallowInput = swallowInput;
}
// ---------------------------------------------------- InputBuffer Methods
@Override
public int doRead(ApplicationBufferHandler handler) throws IOException {
if (lastActiveFilter == -1) {
return inputStreamInputBuffer.doRead(handler);
} else {
return activeFilters[lastActiveFilter].doRead(handler);
}
}
// ------------------------------------------------------- Protected Methods
/**
* Recycle the input buffer. This should be called when closing the connection.
*/
void recycle() {
wrapper = null;
request.recycle();
for (int i = 0; i <= lastActiveFilter; i++) {
activeFilters[i].recycle();
}
byteBuffer.limit(0).position(0);
lastActiveFilter = -1;
swallowInput = true;
chr = 0;
prevChr = 0;
headerParsePos = HeaderParsePosition.HEADER_START;
parsingRequestLinePhase = 0;
parsingRequestLineEol = false;
parsingRequestLineStart = 0;
parsingRequestLineQPos = -1;
headerData.recycle();
// Recycled last because they are volatile
// All variables visible to this thread are guaranteed to be visible to
// any other thread once that thread reads the same volatile. The first
// action when parsing input data is to read one of these volatiles.
parsingRequestLine = true;
parsingHeader = true;
}
/**
* End processing of current HTTP request. Note: All bytes of the current request should have been already consumed.
* This method only resets all the pointers so that we are ready to parse the next HTTP request.
*/
void nextRequest() {
request.recycle();
if (byteBuffer.position() > 0) {
if (byteBuffer.remaining() > 0) {
// Copy leftover bytes to the beginning of the buffer
byteBuffer.compact();
byteBuffer.flip();
} else {
// Reset position and limit to 0
byteBuffer.position(0).limit(0);
}
}
// Recycle filters
for (int i = 0; i <= lastActiveFilter; i++) {
activeFilters[i].recycle();
}
// Reset pointers
lastActiveFilter = -1;
parsingHeader = true;
swallowInput = true;
headerParsePos = HeaderParsePosition.HEADER_START;
parsingRequestLine = true;
parsingRequestLinePhase = 0;
parsingRequestLineEol = false;
parsingRequestLineStart = 0;
parsingRequestLineQPos = -1;
headerData.recycle();
}
/**
* Read the request line. This function is meant to be used during the HTTP request header parsing. Do NOT attempt
* to read the request body using it.
*
* @throws IOException If an exception occurs during the underlying socket read operations, or if the given buffer
* is not big enough to accommodate the whole line.
*
* @return true if data is properly fed; false if no data is available immediately and thread should be freed
*/
boolean parseRequestLine(boolean keptAlive, int connectionTimeout, int keepAliveTimeout) throws IOException {
// check state
if (!parsingRequestLine) {
return true;
}
//
// Skipping blank lines
//
if (parsingRequestLinePhase < 2) {
do {
// Read new bytes if needed
if (byteBuffer.position() >= byteBuffer.limit()) {
if (keptAlive) {
// Haven't read any request data yet so use the keep-alive
// timeout.
wrapper.setReadTimeout(keepAliveTimeout);
}
if (!fill(false)) {
return false;
}
// At least one byte of the request has been received.
// Switch to the socket timeout.
wrapper.setReadTimeout(connectionTimeout);
}
if (!keptAlive && byteBuffer.position() == 0 && byteBuffer.limit() >= CLIENT_PREFACE_START.length) {
boolean prefaceMatch = true;
for (int i = 0; i < CLIENT_PREFACE_START.length && prefaceMatch; i++) {
if (CLIENT_PREFACE_START[i] != byteBuffer.get(i)) {
prefaceMatch = false;
}
}
if (prefaceMatch) {
// HTTP/2 preface matched
parsingRequestLinePhase = -1;
return false;
}
}
// Set the start time once we start reading data (even if it is
// just skipping blank lines)
if (parsingRequestLinePhase == 0) {
parsingRequestLinePhase = 1;
request.setStartTimeNanos(System.nanoTime());
}
chr = byteBuffer.get();
} while (chr == Constants.CR || chr == Constants.LF);
byteBuffer.position(byteBuffer.position() - 1);
parsingRequestLineStart = byteBuffer.position();
parsingRequestLinePhase = 2;
}
if (parsingRequestLinePhase == 2) {
//
// Reading the method name
// Method name is a token
//
boolean space = false;
while (!space) {
// Read new bytes if needed
if (byteBuffer.position() >= byteBuffer.limit()) {
if (!fill(false)) {
return false;
}
}
// Spec says method name is a token followed by a single SP but
// also be tolerant of multiple SP and/or HT.
int pos = byteBuffer.position();
chr = byteBuffer.get();
if (chr == Constants.SP || chr == Constants.HT) {
space = true;
request.method().setBytes(byteBuffer.array(), parsingRequestLineStart,
pos - parsingRequestLineStart);
} else if (!HttpParser.isToken(chr)) {
// Avoid unknown protocol triggering an additional error
request.protocol().setString(Constants.HTTP_11);
String invalidMethodValue = parseInvalid(parsingRequestLineStart, byteBuffer);
throw new IllegalArgumentException(sm.getString("iib.invalidmethod", invalidMethodValue));
}
}
parsingRequestLinePhase = 3;
}
if (parsingRequestLinePhase == 3) {
// Spec says single SP but also be tolerant of multiple SP and/or HT
boolean space = true;
while (space) {
// Read new bytes if needed
if (byteBuffer.position() >= byteBuffer.limit()) {
if (!fill(false)) {
return false;
}
}
chr = byteBuffer.get();
if (chr != Constants.SP && chr != Constants.HT) {
space = false;
byteBuffer.position(byteBuffer.position() - 1);
}
}
parsingRequestLineStart = byteBuffer.position();
parsingRequestLinePhase = 4;
}
if (parsingRequestLinePhase == 4) {
// Mark the current buffer position
int end = 0;
//
// Reading the URI
//
boolean space = false;
while (!space) {
// Read new bytes if needed
if (byteBuffer.position() >= byteBuffer.limit()) {
if (!fill(false)) {
return false;
}
}
int pos = byteBuffer.position();
prevChr = chr;
chr = byteBuffer.get();
if (prevChr == Constants.CR && chr != Constants.LF) {
// CR not followed by LF so not an HTTP/0.9 request and
// therefore invalid. Trigger error handling.
// Avoid unknown protocol triggering an additional error
request.protocol().setString(Constants.HTTP_11);
String invalidRequestTarget = parseInvalid(parsingRequestLineStart, byteBuffer);
throw new IllegalArgumentException(sm.getString("iib.invalidRequestTarget", invalidRequestTarget));
}
if (chr == Constants.SP || chr == Constants.HT) {
space = true;
end = pos;
} else if (chr == Constants.CR) {
// HTTP/0.9 style request. CR is optional. LF is not.
} else if (chr == Constants.LF) {
// HTTP/0.9 style request
// Stop this processing loop
space = true;
// Set blank protocol (indicates HTTP/0.9)
request.protocol().setString("");
// Skip the protocol processing
parsingRequestLinePhase = 7;
if (prevChr == Constants.CR) {
end = pos - 1;
} else {
end = pos;
}
} else if (chr == Constants.QUESTION && parsingRequestLineQPos == -1) {
parsingRequestLineQPos = pos;
} else if (parsingRequestLineQPos != -1 && !httpParser.isQueryRelaxed(chr)) {
// Avoid unknown protocol triggering an additional error
request.protocol().setString(Constants.HTTP_11);
// %nn decoding will be checked at the point of decoding
String invalidRequestTarget = parseInvalid(parsingRequestLineStart, byteBuffer);
throw new IllegalArgumentException(sm.getString("iib.invalidRequestTarget", invalidRequestTarget));
} else if (httpParser.isNotRequestTargetRelaxed(chr)) {
// Avoid unknown protocol triggering an additional error
request.protocol().setString(Constants.HTTP_11);
// This is a general check that aims to catch problems early
// Detailed checking of each part of the request target will
// happen in Http11Processor#prepareRequest()
String invalidRequestTarget = parseInvalid(parsingRequestLineStart, byteBuffer);
throw new IllegalArgumentException(sm.getString("iib.invalidRequestTarget", invalidRequestTarget));
}
}
if (parsingRequestLineQPos >= 0) {
request.queryString().setBytes(byteBuffer.array(), parsingRequestLineQPos + 1,
end - parsingRequestLineQPos - 1);
request.requestURI().setBytes(byteBuffer.array(), parsingRequestLineStart,
parsingRequestLineQPos - parsingRequestLineStart);
} else {
request.requestURI().setBytes(byteBuffer.array(), parsingRequestLineStart,
end - parsingRequestLineStart);
}
// HTTP/0.9 processing jumps to stage 7.
// Don't want to overwrite that here.
if (parsingRequestLinePhase == 4) {
parsingRequestLinePhase = 5;
}
}
if (parsingRequestLinePhase == 5) {
// Spec says single SP but also be tolerant of multiple and/or HT
boolean space = true;
while (space) {
// Read new bytes if needed
if (byteBuffer.position() >= byteBuffer.limit()) {
if (!fill(false)) {
return false;
}
}
byte chr = byteBuffer.get();
if (chr != Constants.SP && chr != Constants.HT) {
space = false;
byteBuffer.position(byteBuffer.position() - 1);
}
}
parsingRequestLineStart = byteBuffer.position();
parsingRequestLinePhase = 6;
// Mark the current buffer position
end = 0;
}
if (parsingRequestLinePhase == 6) {
//
// Reading the protocol
// Protocol is always "HTTP/" DIGIT "." DIGIT
//
while (!parsingRequestLineEol) {
// Read new bytes if needed
if (byteBuffer.position() >= byteBuffer.limit()) {
if (!fill(false)) {
return false;
}
}
int pos = byteBuffer.position();
prevChr = chr;
chr = byteBuffer.get();
if (chr == Constants.CR) {
// Possible end of request line. Need LF next else invalid.
} else if (prevChr == Constants.CR && chr == Constants.LF) {
// CRLF is the standard line terminator
end = pos - 1;
parsingRequestLineEol = true;
} else if (chr == Constants.LF) {
// LF is an optional line terminator
end = pos;
parsingRequestLineEol = true;
} else if (prevChr == Constants.CR || !HttpParser.isHttpProtocol(chr)) {
String invalidProtocol = parseInvalid(parsingRequestLineStart, byteBuffer);
throw new IllegalArgumentException(sm.getString("iib.invalidHttpProtocol", invalidProtocol));
}
}
if (end - parsingRequestLineStart > 0) {
request.protocol().setBytes(byteBuffer.array(), parsingRequestLineStart, end - parsingRequestLineStart);
parsingRequestLinePhase = 7;
}
// If no protocol is found, the ISE below will be triggered.
}
if (parsingRequestLinePhase == 7) {
// Parsing is complete. Return and clean-up.
parsingRequestLine = false;
parsingRequestLinePhase = 0;
parsingRequestLineEol = false;
parsingRequestLineStart = 0;
return true;
}
throw new IllegalStateException(sm.getString("iib.invalidPhase", Integer.valueOf(parsingRequestLinePhase)));
}
/**
* Parse the HTTP headers.
*
* @throws IOException an underlying I/O error occurred
*/
boolean parseHeaders() throws IOException {
if (!parsingHeader) {
throw new IllegalStateException(sm.getString("iib.parseheaders.ise.error"));
}
HeaderParseStatus status = HeaderParseStatus.HAVE_MORE_HEADERS;
do {
status = parseHeader();
// Checking that
// (1) Headers plus request line size does not exceed its limit
// (2) There are enough bytes to avoid expanding the buffer when
// reading body
// Technically, (2) is technical limitation, (1) is logical
// limitation to enforce the meaning of headerBufferSize
// From the way how buf is allocated and how blank lines are being
// read, it should be enough to check (1) only.
if (byteBuffer.position() > headerBufferSize ||
byteBuffer.capacity() - byteBuffer.position() < socketReadBufferSize) {
throw new IllegalArgumentException(sm.getString("iib.requestheadertoolarge.error"));
}
} while (status == HeaderParseStatus.HAVE_MORE_HEADERS);
if (status == HeaderParseStatus.DONE) {
parsingHeader = false;
end = byteBuffer.position();
return true;
} else {
return false;
}
}
int getParsingRequestLinePhase() {
return parsingRequestLinePhase;
}
private String parseInvalid(int startPos, ByteBuffer buffer) {
// Look for the next space
byte b = 0;
while (buffer.hasRemaining() && b != 0x20) {
b = buffer.get();
}
String result = HeaderUtil.toPrintableString(buffer.array(), buffer.arrayOffset() + startPos,
buffer.position() - startPos);
if (b != 0x20) {
// Ran out of buffer rather than found a space
result = result + "...";
}
return result;
}
/**
* End request (consumes leftover bytes).
*
* @throws IOException an underlying I/O error occurred
*/
void endRequest() throws IOException {
if (swallowInput && (lastActiveFilter != -1)) {
int extraBytes = (int) activeFilters[lastActiveFilter].end();
byteBuffer.position(byteBuffer.position() - extraBytes);
}
}
@Override
public int available() {
return available(false);
}
/**
* Available bytes in the buffers for the current request. Note that when requests are pipelined, the data in
* byteBuffer may relate to the next request rather than this one.
*
* @return the amount of bytes available, 0 if none, and 1 if there was an IO error to trigger a read
*/
int available(boolean read) {
int available;
if (lastActiveFilter == -1) {
available = inputStreamInputBuffer.available();
} else {
available = activeFilters[lastActiveFilter].available();
}
// Only try a non-blocking read if:
// - there is no data in the filters
// - the caller requested a read
// - there is no data in byteBuffer
// - the socket wrapper indicates a read is allowed
//
// Notes: 1. When pipelined requests are being used available may be
// zero even when byteBuffer has data. This is because the data
// in byteBuffer is for the next request. We don't want to
// attempt a read in this case.
// 2. wrapper.hasDataToRead() is present to handle the NIO2 case
try {
if (available == 0 && read && !byteBuffer.hasRemaining() && wrapper.hasDataToRead()) {
fill(false);
available = byteBuffer.remaining();
}
} catch (IOException ioe) {
if (log.isDebugEnabled()) {
log.debug(sm.getString("iib.available.readFail"), ioe);
}
// Not ideal. This will indicate that data is available which should
// trigger a read which in turn will trigger another IOException and
// that one can be thrown.
available = 1;
}
return available;
}
/**
* Has all of the request body been read? There are subtle differences between this and available() > 0 primarily
* because of having to handle faking non-blocking reads with the blocking IO connector.
*
* @return {@code true} if the request has been fully read
*/
boolean isFinished() {
// The active filters have the definitive information on whether or not
// the current request body has been read. Note that byteBuffer may
// contain pipelined data so is not a good indicator.
if (lastActiveFilter >= 0) {
return activeFilters[lastActiveFilter].isFinished();
} else {
// No filters. Assume request is not finished. EOF will signal end of
// request.
return false;
}
}
ByteBuffer getLeftover() {
int available = byteBuffer.remaining();
if (available > 0) {
return ByteBuffer.wrap(byteBuffer.array(), byteBuffer.position(), available);
} else {
return null;
}
}
boolean isChunking() {
for (int i = 0; i < lastActiveFilter; i++) {
if (activeFilters[i] == filterLibrary[Constants.CHUNKED_FILTER]) {
return true;
}
}
return false;
}
void init(SocketWrapperBase> socketWrapper) {
wrapper = socketWrapper;
wrapper.setAppReadBufHandler(this);
int bufLength = headerBufferSize + wrapper.getSocketBufferHandler().getReadBuffer().capacity();
if (byteBuffer == null || byteBuffer.capacity() < bufLength) {
byteBuffer = ByteBuffer.allocate(bufLength);
byteBuffer.position(0).limit(0);
}
}
/**
* Attempts to read some data into the input buffer.
*
* @param block Should blocking IO be used when filling the input buffer
*
* @return true
if more data was added to the input buffer otherwise false
*
* @throws IOException if an IO error occurs while filling the input buffer
*/
private boolean fill(boolean block) throws IOException {
if (log.isTraceEnabled()) {
log.trace("Before fill(): parsingHeader: [" + parsingHeader + "], parsingRequestLine: [" +
parsingRequestLine + "], parsingRequestLinePhase: [" + parsingRequestLinePhase +
"], parsingRequestLineStart: [" + parsingRequestLineStart + "], byteBuffer.position(): [" +
byteBuffer.position() + "], byteBuffer.limit(): [" + byteBuffer.limit() + "], end: [" + end + "]");
}
if (parsingHeader) {
if (byteBuffer.limit() >= headerBufferSize) {
if (parsingRequestLine) {
// Avoid unknown protocol triggering an additional error
request.protocol().setString(Constants.HTTP_11);
}
throw new IllegalArgumentException(sm.getString("iib.requestheadertoolarge.error"));
}
} else {
byteBuffer.limit(end).position(end);
}
int nRead = -1;
int mark = byteBuffer.position();
try {
if (byteBuffer.position() < byteBuffer.limit()) {
byteBuffer.position(byteBuffer.limit());
}
byteBuffer.limit(byteBuffer.capacity());
SocketWrapperBase> socketWrapper = this.wrapper;
if (socketWrapper != null) {
nRead = socketWrapper.read(block, byteBuffer);
} else {
throw new CloseNowException(sm.getString("iib.eof.error"));
}
} finally {
// Ensure that the buffer limit and position are returned to a
// consistent "ready for read" state if an error occurs during in
// the above code block.
// Some error conditions can result in the position being reset to
// zero which also invalidates the mark.
// https://bz.apache.org/bugzilla/show_bug.cgi?id=65677
if (byteBuffer.position() >= mark) {
// // Position and mark are consistent. Assume a read (possibly
// of zero bytes) has occurred.
byteBuffer.limit(byteBuffer.position());
byteBuffer.position(mark);
} else {
// Position and mark are inconsistent. Set position and limit to
// zero so effectively no data is reported as read.
byteBuffer.position(0);
byteBuffer.limit(0);
}
}
if (log.isTraceEnabled()) {
log.trace("Received [" + new String(byteBuffer.array(), byteBuffer.position(), byteBuffer.remaining(),
StandardCharsets.ISO_8859_1) + "]");
}
if (nRead > 0) {
return true;
} else if (nRead == -1) {
throw new EOFException(sm.getString("iib.eof.error"));
} else {
return false;
}
}
/**
* Parse an HTTP header.
*
* @return One of {@link HeaderParseStatus#NEED_MORE_DATA}, {@link HeaderParseStatus#HAVE_MORE_HEADERS} or
* {@link HeaderParseStatus#DONE}.
*/
private HeaderParseStatus parseHeader() throws IOException {
/*
* Implementation note: Any changes to this method probably need to be echoed in
* ChunkedInputFilter.parseHeader(). Why not use a common implementation? In short, this code uses non-blocking
* reads whereas ChunkedInputFilter using blocking reads. The code is just different enough that a common
* implementation wasn't viewed as practical.
*/
while (headerParsePos == HeaderParsePosition.HEADER_START) {
// Read new bytes if needed
if (byteBuffer.position() >= byteBuffer.limit()) {
if (!fill(false)) {
return HeaderParseStatus.NEED_MORE_DATA;
}
}
prevChr = chr;
chr = byteBuffer.get();
if (chr == Constants.CR && prevChr != Constants.CR) {
// Possible start of CRLF - process the next byte.
} else if (chr == Constants.LF) {
// CRLF or LF is an acceptable line terminator
return HeaderParseStatus.DONE;
} else {
if (prevChr == Constants.CR) {
// Must have read two bytes (first was CR, second was not LF)
byteBuffer.position(byteBuffer.position() - 2);
} else {
// Must have only read one byte
byteBuffer.position(byteBuffer.position() - 1);
}
break;
}
}
if (headerParsePos == HeaderParsePosition.HEADER_START) {
// Mark the current buffer position
headerData.start = byteBuffer.position();
headerData.lineStart = headerData.start;
headerParsePos = HeaderParsePosition.HEADER_NAME;
}
//
// Reading the header name
// Header name is always US-ASCII
//
while (headerParsePos == HeaderParsePosition.HEADER_NAME) {
// Read new bytes if needed
if (byteBuffer.position() >= byteBuffer.limit()) {
if (!fill(false)) { // parse header
return HeaderParseStatus.NEED_MORE_DATA;
}
}
int pos = byteBuffer.position();
chr = byteBuffer.get();
if (chr == Constants.COLON) {
if (headerData.start == pos) {
// Zero length header name - not valid.
// skipLine() will handle the error
return skipLine(false);
}
headerParsePos = HeaderParsePosition.HEADER_VALUE_START;
headerData.headerValue = headers.addValue(byteBuffer.array(), headerData.start, pos - headerData.start);
pos = byteBuffer.position();
// Mark the current buffer position
headerData.start = pos;
headerData.realPos = pos;
headerData.lastSignificantChar = pos;
break;
} else if (!HttpParser.isToken(chr)) {
// Non-token characters are illegal in header names
// Parsing continues so the error can be reported in context
headerData.lastSignificantChar = pos;
byteBuffer.position(byteBuffer.position() - 1);
// skipLine() will handle the error
return skipLine(false);
}
// chr is next byte of header name. Convert to lowercase.
if (chr >= Constants.A && chr <= Constants.Z) {
byteBuffer.put(pos, (byte) (chr - Constants.LC_OFFSET));
}
}
// Skip the line and ignore the header
if (headerParsePos == HeaderParsePosition.HEADER_SKIPLINE) {
return skipLine(false);
}
//
// Reading the header value (which can be spanned over multiple lines)
//
while (headerParsePos == HeaderParsePosition.HEADER_VALUE_START ||
headerParsePos == HeaderParsePosition.HEADER_VALUE ||
headerParsePos == HeaderParsePosition.HEADER_MULTI_LINE) {
if (headerParsePos == HeaderParsePosition.HEADER_VALUE_START) {
// Skipping spaces
while (true) {
// Read new bytes if needed
if (byteBuffer.position() >= byteBuffer.limit()) {
if (!fill(false)) {// parse header
// HEADER_VALUE_START
return HeaderParseStatus.NEED_MORE_DATA;
}
}
chr = byteBuffer.get();
if (chr != Constants.SP && chr != Constants.HT) {
headerParsePos = HeaderParsePosition.HEADER_VALUE;
byteBuffer.position(byteBuffer.position() - 1);
// Avoids prevChr = chr at start of header value
// parsing which causes problems when chr is CR
// (in the case of an empty header value)
chr = 0;
break;
}
}
}
if (headerParsePos == HeaderParsePosition.HEADER_VALUE) {
// Reading bytes until the end of the line
boolean eol = false;
while (!eol) {
// Read new bytes if needed
if (byteBuffer.position() >= byteBuffer.limit()) {
if (!fill(false)) {// parse header
// HEADER_VALUE
return HeaderParseStatus.NEED_MORE_DATA;
}
}
prevChr = chr;
chr = byteBuffer.get();
if (chr == Constants.CR && prevChr != Constants.CR) {
// CR is only permitted at the start of a CRLF sequence.
// Possible start of CRLF - process the next byte.
} else if (chr == Constants.LF) {
// CRLF or LF is an acceptable line terminator
eol = true;
} else if (prevChr == Constants.CR) {
// Invalid value - also need to delete header
return skipLine(true);
} else if (HttpParser.isControl(chr) && chr != Constants.HT) {
// Invalid value - also need to delete header
return skipLine(true);
} else if (chr == Constants.SP || chr == Constants.HT) {
byteBuffer.put(headerData.realPos, chr);
headerData.realPos++;
} else {
byteBuffer.put(headerData.realPos, chr);
headerData.realPos++;
headerData.lastSignificantChar = headerData.realPos;
}
}
// Ignore whitespaces at the end of the line
headerData.realPos = headerData.lastSignificantChar;
// Checking the first character of the new line. If the character
// is a LWS, then it's a multiline header
headerParsePos = HeaderParsePosition.HEADER_MULTI_LINE;
}
// Read new bytes if needed
if (byteBuffer.position() >= byteBuffer.limit()) {
if (!fill(false)) {// parse header
// HEADER_MULTI_LINE
return HeaderParseStatus.NEED_MORE_DATA;
}
}
byte peek = byteBuffer.get(byteBuffer.position());
if (headerParsePos == HeaderParsePosition.HEADER_MULTI_LINE) {
if (peek != Constants.SP && peek != Constants.HT) {
headerParsePos = HeaderParsePosition.HEADER_START;
break;
} else {
// Copying one extra space in the buffer (since there must
// be at least one space inserted between the lines)
byteBuffer.put(headerData.realPos, peek);
headerData.realPos++;
headerParsePos = HeaderParsePosition.HEADER_VALUE_START;
}
}
}
// Set the header value
headerData.headerValue.setBytes(byteBuffer.array(), headerData.start,
headerData.lastSignificantChar - headerData.start);
headerData.recycle();
return HeaderParseStatus.HAVE_MORE_HEADERS;
}
private HeaderParseStatus skipLine(boolean deleteHeader) throws IOException {
boolean rejectThisHeader = rejectIllegalHeader;
// Check if rejectIllegalHeader is disabled and needs to be overridden
// for this header. The header name is required to determine if this
// override is required. The header name is only available once the
// header has been created. If the header has been created then
// deleteHeader will be true.
if (!rejectThisHeader && deleteHeader) {
if (headers.getName(headers.size() - 1).equalsIgnoreCase("content-length")) {
// Malformed content-length headers must always be rejected
// RFC 9112, section 6.3, bullet 5.
rejectThisHeader = true;
} else {
// Only need to delete the header if the request isn't going to
// be rejected (it will be the most recent one)
headers.removeHeader(headers.size() - 1);
}
}
// Parse the rest of the invalid header so we can construct a useful
// exception and/or debug message.
headerParsePos = HeaderParsePosition.HEADER_SKIPLINE;
boolean eol = false;
// Reading bytes until the end of the line
while (!eol) {
// Read new bytes if needed
if (byteBuffer.position() >= byteBuffer.limit()) {
if (!fill(false)) {
return HeaderParseStatus.NEED_MORE_DATA;
}
}
int pos = byteBuffer.position();
prevChr = chr;
chr = byteBuffer.get();
if (chr == Constants.CR) {
// Skip
} else if (chr == Constants.LF) {
// CRLF or LF is an acceptable line terminator
eol = true;
} else {
headerData.lastSignificantChar = pos;
}
}
if (rejectThisHeader || log.isDebugEnabled()) {
if (rejectThisHeader) {
throw new IllegalArgumentException(
sm.getString("iib.invalidheader.reject", HeaderUtil.toPrintableString(byteBuffer.array(),
headerData.lineStart, headerData.lastSignificantChar - headerData.lineStart + 1)));
}
log.debug(sm.getString("iib.invalidheader", HeaderUtil.toPrintableString(byteBuffer.array(),
headerData.lineStart, headerData.lastSignificantChar - headerData.lineStart + 1)));
}
headerParsePos = HeaderParsePosition.HEADER_START;
return HeaderParseStatus.HAVE_MORE_HEADERS;
}
// ----------------------------------------------------------- Inner classes
private enum HeaderParseStatus {
DONE,
HAVE_MORE_HEADERS,
NEED_MORE_DATA
}
private enum HeaderParsePosition {
/**
* Start of a new header. A CRLF here means that there are no more headers. Any other character starts a header
* name.
*/
HEADER_START,
/**
* Reading a header name. All characters of header are HTTP_TOKEN_CHAR. Header name is followed by ':'. No
* whitespace is allowed.
* Any non-HTTP_TOKEN_CHAR (this includes any whitespace) encountered before ':' will result in the whole line
* being ignored.
*/
HEADER_NAME,
/**
* Skipping whitespace before text of header value starts, either on the first line of header value (just after
* ':') or on subsequent lines when it is known that subsequent line starts with SP or HT.
*/
HEADER_VALUE_START,
/**
* Reading the header value. We are inside the value. Either on the first line or on any subsequent line. We
* come into this state from HEADER_VALUE_START after the first non-SP/non-HT byte is encountered on the line.
*/
HEADER_VALUE,
/**
* Before reading a new line of a header. Once the next byte is peeked, the state changes without advancing our
* position. The state becomes either HEADER_VALUE_START (if that first byte is SP or HT), or HEADER_START
* (otherwise).
*/
HEADER_MULTI_LINE,
/**
* Reading all bytes until the next CRLF. The line is being ignored.
*/
HEADER_SKIPLINE
}
private static class HeaderParseData {
/**
* The first character of the header line.
*/
int lineStart = 0;
/**
* When parsing header name: first character of the header.
* When skipping broken header line: first character of the header.
* When parsing header value: first character after ':'.
*/
int start = 0;
/**
* When parsing header name: not used (stays as 0).
* When skipping broken header line: not used (stays as 0).
* When parsing header value: starts as the first character after ':'. Then is increased as far as more bytes of
* the header are harvested. Bytes from buf[pos] are copied to buf[realPos]. Thus the string from [start] to
* [realPos-1] is the prepared value of the header, with whitespaces removed as needed.
*/
int realPos = 0;
/**
* When parsing header name: not used (stays as 0).
* When skipping broken header line: last non-CR/non-LF character.
* When parsing header value: position after the last not-LWS character.
*/
int lastSignificantChar = 0;
/**
* MB that will store the value of the header. It is null while parsing header name and is created after the
* name has been parsed.
*/
MessageBytes headerValue = null;
public void recycle() {
lineStart = 0;
start = 0;
realPos = 0;
lastSignificantChar = 0;
headerValue = null;
}
}
// ------------------------------------- InputStreamInputBuffer Inner Class
/**
* This class is an input buffer which will read its data from an input stream.
*/
private class SocketInputBuffer implements InputBuffer {
@Override
public int doRead(ApplicationBufferHandler handler) throws IOException {
if (byteBuffer.position() >= byteBuffer.limit()) {
// The application is reading the HTTP request body
boolean block = (request.getReadListener() == null);
if (!fill(block)) {
if (block) {
return -1;
} else {
return 0;
}
}
}
int length = byteBuffer.remaining();
handler.setByteBuffer(byteBuffer.duplicate());
byteBuffer.position(byteBuffer.limit());
return length;
}
@Override
public int available() {
return byteBuffer.remaining();
}
}
@Override
public void setByteBuffer(ByteBuffer buffer) {
byteBuffer = buffer;
}
@Override
public ByteBuffer getByteBuffer() {
return byteBuffer;
}
@Override
public void expand(int size) {
if (byteBuffer.capacity() >= size) {
byteBuffer.limit(size);
}
ByteBuffer temp = ByteBuffer.allocate(size);
temp.put(byteBuffer);
byteBuffer = temp;
byteBuffer.mark();
temp = null;
}
}
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