gecko/netwerk/protocol/http/Http2Compression.cpp

1220 lines
36 KiB
C++

/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set sw=2 ts=8 et tw=80 : */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
// HttpLog.h should generally be included first
#include "HttpLog.h"
// Log on level :5, instead of default :4.
#undef LOG
#define LOG(args) LOG5(args)
#undef LOG_ENABLED
#define LOG_ENABLED() LOG5_ENABLED()
#include "Http2Compression.h"
#include "Http2HuffmanIncoming.h"
#include "Http2HuffmanOutgoing.h"
extern PRThread *gSocketThread;
namespace mozilla {
namespace net {
static nsDeque *gStaticHeaders = nullptr;
void
Http2CompressionCleanup()
{
// this happens after the socket thread has been destroyed
delete gStaticHeaders;
gStaticHeaders = nullptr;
}
static void
AddStaticElement(const nsCString &name, const nsCString &value)
{
nvPair *pair = new nvPair(name, value);
gStaticHeaders->Push(pair);
}
static void
AddStaticElement(const nsCString &name)
{
AddStaticElement(name, EmptyCString());
}
static void
InitializeStaticHeaders()
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
if (!gStaticHeaders) {
gStaticHeaders = new nsDeque();
AddStaticElement(NS_LITERAL_CSTRING(":authority"));
AddStaticElement(NS_LITERAL_CSTRING(":method"), NS_LITERAL_CSTRING("GET"));
AddStaticElement(NS_LITERAL_CSTRING(":method"), NS_LITERAL_CSTRING("POST"));
AddStaticElement(NS_LITERAL_CSTRING(":path"), NS_LITERAL_CSTRING("/"));
AddStaticElement(NS_LITERAL_CSTRING(":path"), NS_LITERAL_CSTRING("/index.html"));
AddStaticElement(NS_LITERAL_CSTRING(":scheme"), NS_LITERAL_CSTRING("http"));
AddStaticElement(NS_LITERAL_CSTRING(":scheme"), NS_LITERAL_CSTRING("https"));
AddStaticElement(NS_LITERAL_CSTRING(":status"), NS_LITERAL_CSTRING("200"));
AddStaticElement(NS_LITERAL_CSTRING(":status"), NS_LITERAL_CSTRING("204"));
AddStaticElement(NS_LITERAL_CSTRING(":status"), NS_LITERAL_CSTRING("206"));
AddStaticElement(NS_LITERAL_CSTRING(":status"), NS_LITERAL_CSTRING("304"));
AddStaticElement(NS_LITERAL_CSTRING(":status"), NS_LITERAL_CSTRING("400"));
AddStaticElement(NS_LITERAL_CSTRING(":status"), NS_LITERAL_CSTRING("404"));
AddStaticElement(NS_LITERAL_CSTRING(":status"), NS_LITERAL_CSTRING("500"));
AddStaticElement(NS_LITERAL_CSTRING("accept-charset"));
AddStaticElement(NS_LITERAL_CSTRING("accept-encoding"), NS_LITERAL_CSTRING("gzip, deflate"));
AddStaticElement(NS_LITERAL_CSTRING("accept-language"));
AddStaticElement(NS_LITERAL_CSTRING("accept-ranges"));
AddStaticElement(NS_LITERAL_CSTRING("accept"));
AddStaticElement(NS_LITERAL_CSTRING("access-control-allow-origin"));
AddStaticElement(NS_LITERAL_CSTRING("age"));
AddStaticElement(NS_LITERAL_CSTRING("allow"));
AddStaticElement(NS_LITERAL_CSTRING("authorization"));
AddStaticElement(NS_LITERAL_CSTRING("cache-control"));
AddStaticElement(NS_LITERAL_CSTRING("content-disposition"));
AddStaticElement(NS_LITERAL_CSTRING("content-encoding"));
AddStaticElement(NS_LITERAL_CSTRING("content-language"));
AddStaticElement(NS_LITERAL_CSTRING("content-length"));
AddStaticElement(NS_LITERAL_CSTRING("content-location"));
AddStaticElement(NS_LITERAL_CSTRING("content-range"));
AddStaticElement(NS_LITERAL_CSTRING("content-type"));
AddStaticElement(NS_LITERAL_CSTRING("cookie"));
AddStaticElement(NS_LITERAL_CSTRING("date"));
AddStaticElement(NS_LITERAL_CSTRING("etag"));
AddStaticElement(NS_LITERAL_CSTRING("expect"));
AddStaticElement(NS_LITERAL_CSTRING("expires"));
AddStaticElement(NS_LITERAL_CSTRING("from"));
AddStaticElement(NS_LITERAL_CSTRING("host"));
AddStaticElement(NS_LITERAL_CSTRING("if-match"));
AddStaticElement(NS_LITERAL_CSTRING("if-modified-since"));
AddStaticElement(NS_LITERAL_CSTRING("if-none-match"));
AddStaticElement(NS_LITERAL_CSTRING("if-range"));
AddStaticElement(NS_LITERAL_CSTRING("if-unmodified-since"));
AddStaticElement(NS_LITERAL_CSTRING("last-modified"));
AddStaticElement(NS_LITERAL_CSTRING("link"));
AddStaticElement(NS_LITERAL_CSTRING("location"));
AddStaticElement(NS_LITERAL_CSTRING("max-forwards"));
AddStaticElement(NS_LITERAL_CSTRING("proxy-authenticate"));
AddStaticElement(NS_LITERAL_CSTRING("proxy-authorization"));
AddStaticElement(NS_LITERAL_CSTRING("range"));
AddStaticElement(NS_LITERAL_CSTRING("referer"));
AddStaticElement(NS_LITERAL_CSTRING("refresh"));
AddStaticElement(NS_LITERAL_CSTRING("retry-after"));
AddStaticElement(NS_LITERAL_CSTRING("server"));
AddStaticElement(NS_LITERAL_CSTRING("set-cookie"));
AddStaticElement(NS_LITERAL_CSTRING("strict-transport-security"));
AddStaticElement(NS_LITERAL_CSTRING("transfer-encoding"));
AddStaticElement(NS_LITERAL_CSTRING("user-agent"));
AddStaticElement(NS_LITERAL_CSTRING("vary"));
AddStaticElement(NS_LITERAL_CSTRING("via"));
AddStaticElement(NS_LITERAL_CSTRING("www-authenticate"));
}
}
nvFIFO::nvFIFO()
: mByteCount(0)
, mTable()
{
InitializeStaticHeaders();
}
nvFIFO::~nvFIFO()
{
Clear();
}
void
nvFIFO::AddElement(const nsCString &name, const nsCString &value)
{
mByteCount += name.Length() + value.Length() + 32;
nvPair *pair = new nvPair(name, value);
mTable.PushFront(pair);
}
void
nvFIFO::AddElement(const nsCString &name)
{
AddElement(name, EmptyCString());
}
void
nvFIFO::RemoveElement()
{
nvPair *pair = static_cast<nvPair *>(mTable.Pop());
if (pair) {
mByteCount -= pair->Size();
delete pair;
}
}
uint32_t
nvFIFO::ByteCount() const
{
return mByteCount;
}
uint32_t
nvFIFO::Length() const
{
return mTable.GetSize() + gStaticHeaders->GetSize();
}
uint32_t
nvFIFO::VariableLength() const
{
return mTable.GetSize();
}
uint32_t
nvFIFO::StaticLength() const
{
return gStaticHeaders->GetSize();
}
void
nvFIFO::Clear()
{
mByteCount = 0;
while (mTable.GetSize())
delete static_cast<nvPair *>(mTable.Pop());
}
const nvPair *
nvFIFO::operator[] (int32_t index) const
{
// NWGH - ensure index > 0
// NWGH - subtract 1 from index here
if (index >= (mTable.GetSize() + gStaticHeaders->GetSize())) {
MOZ_ASSERT(false);
NS_WARNING("nvFIFO Table Out of Range");
return nullptr;
}
if (index >= gStaticHeaders->GetSize()) {
return static_cast<nvPair *>(mTable.ObjectAt(index - gStaticHeaders->GetSize()));
}
return static_cast<nvPair *>(gStaticHeaders->ObjectAt(index));
}
Http2BaseCompressor::Http2BaseCompressor()
: mOutput(nullptr)
, mMaxBuffer(kDefaultMaxBuffer)
{
}
void
Http2BaseCompressor::ClearHeaderTable()
{
mHeaderTable.Clear();
}
void
Http2BaseCompressor::MakeRoom(uint32_t amount, const char *direction)
{
// make room in the header table
while (mHeaderTable.VariableLength() && ((mHeaderTable.ByteCount() + amount) > mMaxBuffer)) {
// NWGH - remove the "- 1" here
uint32_t index = mHeaderTable.Length() - 1;
LOG(("HTTP %s header table index %u %s %s removed for size.\n",
direction, index, mHeaderTable[index]->mName.get(),
mHeaderTable[index]->mValue.get()));
mHeaderTable.RemoveElement();
}
}
void
Http2BaseCompressor::DumpState()
{
LOG(("Header Table"));
uint32_t i;
uint32_t length = mHeaderTable.Length();
uint32_t staticLength = mHeaderTable.StaticLength();
// NWGH - make i = 1; i <= length; ++i
for (i = 0; i < length; ++i) {
const nvPair *pair = mHeaderTable[i];
// NWGH - make this <= staticLength
LOG(("%sindex %u: %s %s", i < staticLength ? "static " : "", i,
pair->mName.get(), pair->mValue.get()));
}
}
nsresult
Http2Decompressor::DecodeHeaderBlock(const uint8_t *data, uint32_t datalen,
nsACString &output, bool isPush)
{
mOffset = 0;
mData = data;
mDataLen = datalen;
mOutput = &output;
mOutput->Truncate();
mHeaderStatus.Truncate();
mHeaderHost.Truncate();
mHeaderScheme.Truncate();
mHeaderPath.Truncate();
mHeaderMethod.Truncate();
mSeenNonColonHeader = false;
mIsPush = isPush;
nsresult rv = NS_OK;
while (NS_SUCCEEDED(rv) && (mOffset < datalen)) {
if (mData[mOffset] & 0x80) {
rv = DoIndexed();
LOG(("Decompressor state after indexed"));
} else if (mData[mOffset] & 0x40) {
rv = DoLiteralWithIncremental();
LOG(("Decompressor state after literal with incremental"));
} else if (mData[mOffset] & 0x20) {
rv = DoContextUpdate();
LOG(("Decompressor state after context update"));
} else if (mData[mOffset] & 0x10) {
rv = DoLiteralNeverIndexed();
LOG(("Decompressor state after literal never index"));
} else {
rv = DoLiteralWithoutIndex();
LOG(("Decompressor state after literal without index"));
}
DumpState();
}
return rv;
}
nsresult
Http2Decompressor::DecodeInteger(uint32_t prefixLen, uint32_t &accum)
{
accum = 0;
if (prefixLen) {
uint32_t mask = (1 << prefixLen) - 1;
accum = mData[mOffset] & mask;
++mOffset;
if (accum != mask) {
// the simple case for small values
return NS_OK;
}
}
uint32_t factor = 1; // 128 ^ 0
// we need a series of bytes. The high bit signifies if we need another one.
// The first one is a a factor of 128 ^ 0, the next 128 ^1, the next 128 ^2, ..
if (mOffset >= mDataLen) {
NS_WARNING("Ran out of data to decode integer");
return NS_ERROR_ILLEGAL_VALUE;
}
bool chainBit = mData[mOffset] & 0x80;
accum += (mData[mOffset] & 0x7f) * factor;
++mOffset;
factor = factor * 128;
while (chainBit) {
// really big offsets are just trawling for overflows
if (accum >= 0x800000) {
NS_WARNING("Decoding integer >= 0x800000");
return NS_ERROR_ILLEGAL_VALUE;
}
if (mOffset >= mDataLen) {
NS_WARNING("Ran out of data to decode integer");
return NS_ERROR_ILLEGAL_VALUE;
}
chainBit = mData[mOffset] & 0x80;
accum += (mData[mOffset] & 0x7f) * factor;
++mOffset;
factor = factor * 128;
}
return NS_OK;
}
nsresult
Http2Decompressor::OutputHeader(const nsACString &name, const nsACString &value)
{
// exclusions
if (!mIsPush &&
(name.EqualsLiteral("connection") ||
name.EqualsLiteral("host") ||
name.EqualsLiteral("keep-alive") ||
name.EqualsLiteral("proxy-connection") ||
name.EqualsLiteral("te") ||
name.EqualsLiteral("transfer-encoding") ||
name.EqualsLiteral("upgrade") ||
name.Equals(("accept-encoding")))) {
nsCString toLog(name);
LOG(("HTTP Decompressor illegal response header found, not gatewaying: %s",
toLog.get()));
return NS_OK;
}
// Look for upper case characters in the name.
for (const char *cPtr = name.BeginReading();
cPtr && cPtr < name.EndReading();
++cPtr) {
if (*cPtr <= 'Z' && *cPtr >= 'A') {
nsCString toLog(name);
LOG(("HTTP Decompressor upper case response header found. [%s]\n",
toLog.get()));
return NS_ERROR_ILLEGAL_VALUE;
}
}
// Look for CR OR LF in value - could be smuggling Sec 10.3
// can map to space safely
for (const char *cPtr = value.BeginReading();
cPtr && cPtr < value.EndReading();
++cPtr) {
if (*cPtr == '\r' || *cPtr== '\n') {
char *wPtr = const_cast<char *>(cPtr);
*wPtr = ' ';
}
}
// Status comes first
if (name.EqualsLiteral(":status")) {
nsAutoCString status(NS_LITERAL_CSTRING("HTTP/2.0 "));
status.Append(value);
status.AppendLiteral("\r\n");
mOutput->Insert(status, 0);
mHeaderStatus = value;
} else if (name.EqualsLiteral(":authority")) {
mHeaderHost = value;
} else if (name.EqualsLiteral(":scheme")) {
mHeaderScheme = value;
} else if (name.EqualsLiteral(":path")) {
mHeaderPath = value;
} else if (name.EqualsLiteral(":method")) {
mHeaderMethod = value;
}
// http/2 transport level headers shouldn't be gatewayed into http/1
bool isColonHeader = false;
for (const char *cPtr = name.BeginReading();
cPtr && cPtr < name.EndReading();
++cPtr) {
if (*cPtr == ':') {
isColonHeader = true;
break;
} else if (*cPtr != ' ' && *cPtr != '\t') {
isColonHeader = false;
break;
}
}
if(isColonHeader) {
if (mSeenNonColonHeader) {
LOG(("HTTP Decompressor found illegal : header %s", name.BeginReading()));
return NS_ERROR_ILLEGAL_VALUE;
}
LOG(("HTTP Decompressor not gatewaying %s into http/1",
name.BeginReading()));
return NS_OK;
}
LOG(("Http2Decompressor::OutputHeader %s %s", name.BeginReading(),
value.BeginReading()));
mSeenNonColonHeader = true;
mOutput->Append(name);
mOutput->AppendLiteral(": ");
mOutput->Append(value);
mOutput->AppendLiteral("\r\n");
return NS_OK;
}
nsresult
Http2Decompressor::OutputHeader(uint32_t index)
{
// NWGH - make this < index
// bounds check
if (mHeaderTable.Length() <= index) {
LOG(("Http2Decompressor::OutputHeader index too large %u", index));
return NS_ERROR_ILLEGAL_VALUE;
}
return OutputHeader(mHeaderTable[index]->mName,
mHeaderTable[index]->mValue);
}
nsresult
Http2Decompressor::CopyHeaderString(uint32_t index, nsACString &name)
{
// NWGH - make this < index
// bounds check
if (mHeaderTable.Length() <= index)
return NS_ERROR_ILLEGAL_VALUE;
name = mHeaderTable[index]->mName;
return NS_OK;
}
nsresult
Http2Decompressor::CopyStringFromInput(uint32_t bytes, nsACString &val)
{
if (mOffset + bytes > mDataLen)
return NS_ERROR_ILLEGAL_VALUE;
val.Assign(reinterpret_cast<const char *>(mData) + mOffset, bytes);
mOffset += bytes;
return NS_OK;
}
nsresult
Http2Decompressor::DecodeFinalHuffmanCharacter(HuffmanIncomingTable *table,
uint8_t &c, uint8_t &bitsLeft)
{
uint8_t mask = (1 << bitsLeft) - 1;
uint8_t idx = mData[mOffset - 1] & mask;
idx <<= (8 - bitsLeft);
// Don't update bitsLeft yet, because we need to check that value against the
// number of bits used by our encoding later on. We'll update when we are sure
// how many bits we've actually used.
HuffmanIncomingEntry *entry = &(table->mEntries[idx]);
if (entry->mPtr) {
// Can't chain to another table when we're all out of bits in the encoding
LOG(("DecodeFinalHuffmanCharacter trying to chain when we're out of bits"));
return NS_ERROR_ILLEGAL_VALUE;
}
if (bitsLeft < entry->mPrefixLen) {
// We don't have enough bits to actually make a match, this is some sort of
// invalid coding
LOG(("DecodeFinalHuffmanCharacter does't have enough bits to match"));
return NS_ERROR_ILLEGAL_VALUE;
}
// This is a character!
if (entry->mValue == 256) {
// EOS
LOG(("DecodeFinalHuffmanCharacter actually decoded an EOS"));
return NS_ERROR_ILLEGAL_VALUE;
}
c = static_cast<uint8_t>(entry->mValue & 0xFF);
bitsLeft -= entry->mPrefixLen;
return NS_OK;
}
uint8_t
Http2Decompressor::ExtractByte(uint8_t bitsLeft, uint32_t &bytesConsumed)
{
uint8_t rv;
if (bitsLeft) {
// Need to extract bitsLeft bits from the previous byte, and 8 - bitsLeft
// bits from the current byte
uint8_t mask = (1 << bitsLeft) - 1;
rv = (mData[mOffset - 1] & mask) << (8 - bitsLeft);
rv |= (mData[mOffset] & ~mask) >> bitsLeft;
} else {
rv = mData[mOffset];
}
// We always update these here, under the assumption that all 8 bits we got
// here will be used. These may be re-adjusted later in the case that we don't
// use up all 8 bits of the byte.
++mOffset;
++bytesConsumed;
return rv;
}
nsresult
Http2Decompressor::DecodeHuffmanCharacter(HuffmanIncomingTable *table,
uint8_t &c, uint32_t &bytesConsumed,
uint8_t &bitsLeft)
{
uint8_t idx = ExtractByte(bitsLeft, bytesConsumed);
HuffmanIncomingEntry *entry = &(table->mEntries[idx]);
if (entry->mPtr) {
if (bytesConsumed >= mDataLen) {
if (!bitsLeft || (bytesConsumed > mDataLen)) {
// TODO - does this get me into trouble in the new world?
// No info left in input to try to consume, we're done
LOG(("DecodeHuffmanCharacter all out of bits to consume, can't chain"));
return NS_ERROR_ILLEGAL_VALUE;
}
// We might get lucky here!
return DecodeFinalHuffmanCharacter(entry->mPtr, c, bitsLeft);
}
// We're sorry, Mario, but your princess is in another castle
return DecodeHuffmanCharacter(entry->mPtr, c, bytesConsumed, bitsLeft);
}
if (entry->mValue == 256) {
LOG(("DecodeHuffmanCharacter found an actual EOS"));
return NS_ERROR_ILLEGAL_VALUE;
}
c = static_cast<uint8_t>(entry->mValue & 0xFF);
// Need to adjust bitsLeft (and possibly other values) because we may not have
// consumed all of the bits of the byte we extracted.
if (entry->mPrefixLen <= bitsLeft) {
bitsLeft -= entry->mPrefixLen;
--mOffset;
--bytesConsumed;
} else {
bitsLeft = 8 - (entry->mPrefixLen - bitsLeft);
}
MOZ_ASSERT(bitsLeft < 8);
return NS_OK;
}
nsresult
Http2Decompressor::CopyHuffmanStringFromInput(uint32_t bytes, nsACString &val)
{
if (mOffset + bytes > mDataLen) {
LOG(("CopyHuffmanStringFromInput not enough data"));
return NS_ERROR_ILLEGAL_VALUE;
}
uint32_t bytesRead = 0;
uint8_t bitsLeft = 0;
nsAutoCString buf;
nsresult rv;
uint8_t c;
while (bytesRead < bytes) {
uint32_t bytesConsumed = 0;
rv = DecodeHuffmanCharacter(&HuffmanIncomingRoot, c, bytesConsumed,
bitsLeft);
if (NS_FAILED(rv)) {
LOG(("CopyHuffmanStringFromInput failed to decode a character"));
return rv;
}
bytesRead += bytesConsumed;
buf.Append(c);
}
if (bytesRead > bytes) {
LOG(("CopyHuffmanStringFromInput read more bytes than was allowed!"));
return NS_ERROR_ILLEGAL_VALUE;
}
if (bitsLeft) {
// The shortest valid code is 4 bits, so we know there can be at most one
// character left that our loop didn't decode. Check to see if that's the
// case, and if so, add it to our output.
rv = DecodeFinalHuffmanCharacter(&HuffmanIncomingRoot, c, bitsLeft);
if (NS_SUCCEEDED(rv)) {
buf.Append(c);
}
}
if (bitsLeft > 7) {
LOG(("CopyHuffmanStringFromInput more than 7 bits of padding"));
return NS_ERROR_ILLEGAL_VALUE;
}
if (bitsLeft) {
// Any bits left at this point must belong to the EOS symbol, so make sure
// they make sense (ie, are all ones)
uint8_t mask = (1 << bitsLeft) - 1;
uint8_t bits = mData[mOffset - 1] & mask;
if (bits != mask) {
LOG(("CopyHuffmanStringFromInput ran out of data but found possible "
"non-EOS symbol"));
return NS_ERROR_ILLEGAL_VALUE;
}
}
val = buf;
LOG(("CopyHuffmanStringFromInput decoded a full string!"));
return NS_OK;
}
nsresult
Http2Decompressor::DoIndexed()
{
// this starts with a 1 bit pattern
MOZ_ASSERT(mData[mOffset] & 0x80);
// This is a 7 bit prefix
uint32_t index;
nsresult rv = DecodeInteger(7, index);
if (NS_FAILED(rv))
return rv;
LOG(("HTTP decompressor indexed entry %u\n", index));
if (index == 0) {
return NS_ERROR_ILLEGAL_VALUE;
}
// NWGH - remove this line, since we'll keep everything 1-indexed
index--; // Internally, we 0-index everything, since this is, y'know, C++
return OutputHeader(index);
}
nsresult
Http2Decompressor::DoLiteralInternal(nsACString &name, nsACString &value,
uint32_t namePrefixLen)
{
// guts of doliteralwithoutindex and doliteralwithincremental
MOZ_ASSERT(((mData[mOffset] & 0xF0) == 0x00) || // withoutindex
((mData[mOffset] & 0xF0) == 0x10) || // neverindexed
((mData[mOffset] & 0xC0) == 0x40)); // withincremental
// first let's get the name
uint32_t index;
nsresult rv = DecodeInteger(namePrefixLen, index);
if (NS_FAILED(rv))
return rv;
bool isHuffmanEncoded;
if (!index) {
// name is embedded as a literal
uint32_t nameLen;
isHuffmanEncoded = mData[mOffset] & (1 << 7);
rv = DecodeInteger(7, nameLen);
if (NS_SUCCEEDED(rv)) {
if (isHuffmanEncoded) {
rv = CopyHuffmanStringFromInput(nameLen, name);
} else {
rv = CopyStringFromInput(nameLen, name);
}
}
LOG(("Http2Decompressor::DoLiteralInternal literal name %s",
name.BeginReading()));
} else {
// NWGH - make this index, not index - 1
// name is from headertable
rv = CopyHeaderString(index - 1, name);
LOG(("Http2Decompressor::DoLiteralInternal indexed name %d %s",
index, name.BeginReading()));
}
if (NS_FAILED(rv))
return rv;
// now the value
uint32_t valueLen;
isHuffmanEncoded = mData[mOffset] & (1 << 7);
rv = DecodeInteger(7, valueLen);
if (NS_SUCCEEDED(rv)) {
if (isHuffmanEncoded) {
rv = CopyHuffmanStringFromInput(valueLen, value);
} else {
rv = CopyStringFromInput(valueLen, value);
}
}
if (NS_FAILED(rv))
return rv;
LOG(("Http2Decompressor::DoLiteralInternal value %s", value.BeginReading()));
return NS_OK;
}
nsresult
Http2Decompressor::DoLiteralWithoutIndex()
{
// this starts with 0000 bit pattern
MOZ_ASSERT((mData[mOffset] & 0xF0) == 0x00);
nsAutoCString name, value;
nsresult rv = DoLiteralInternal(name, value, 4);
LOG(("HTTP decompressor literal without index %s %s\n",
name.get(), value.get()));
if (NS_SUCCEEDED(rv))
rv = OutputHeader(name, value);
return rv;
}
nsresult
Http2Decompressor::DoLiteralWithIncremental()
{
// this starts with 01 bit pattern
MOZ_ASSERT((mData[mOffset] & 0xC0) == 0x40);
nsAutoCString name, value;
nsresult rv = DoLiteralInternal(name, value, 6);
if (NS_SUCCEEDED(rv))
rv = OutputHeader(name, value);
if (NS_FAILED(rv))
return rv;
uint32_t room = nvPair(name, value).Size();
if (room > mMaxBuffer) {
ClearHeaderTable();
LOG(("HTTP decompressor literal with index not inserted due to size %u %s %s\n",
room, name.get(), value.get()));
LOG(("Decompressor state after ClearHeaderTable"));
DumpState();
return NS_OK;
}
MakeRoom(room, "decompressor");
// Incremental Indexing implicitly adds a row to the header table.
mHeaderTable.AddElement(name, value);
LOG(("HTTP decompressor literal with index 0 %s %s\n",
name.get(), value.get()));
return NS_OK;
}
nsresult
Http2Decompressor::DoLiteralNeverIndexed()
{
// This starts with 0001 bit pattern
MOZ_ASSERT((mData[mOffset] & 0xF0) == 0x10);
nsAutoCString name, value;
nsresult rv = DoLiteralInternal(name, value, 4);
LOG(("HTTP decompressor literal never indexed %s %s\n",
name.get(), value.get()));
if (NS_SUCCEEDED(rv))
rv = OutputHeader(name, value);
return rv;
}
nsresult
Http2Decompressor::DoContextUpdate()
{
// This starts with 001 bit pattern
MOZ_ASSERT((mData[mOffset] & 0xE0) == 0x20);
// Getting here means we have to adjust the max table size
uint32_t newMaxSize;
nsresult rv = DecodeInteger(5, newMaxSize);
LOG(("Http2Decompressor::DoContextUpdate new maximum size %u", newMaxSize));
if (NS_FAILED(rv))
return rv;
return mCompressor->SetMaxBufferSizeInternal(newMaxSize);
}
/////////////////////////////////////////////////////////////////
nsresult
Http2Compressor::EncodeHeaderBlock(const nsCString &nvInput,
const nsACString &method, const nsACString &path,
const nsACString &host, const nsACString &scheme,
bool connectForm, nsACString &output)
{
mOutput = &output;
output.SetCapacity(1024);
output.Truncate();
mParsedContentLength = -1;
// first thing's first - context size updates (if necessary)
if (mBufferSizeChangeWaiting) {
if (mLowestBufferSizeWaiting < mMaxBufferSetting) {
EncodeTableSizeChange(mLowestBufferSizeWaiting);
}
EncodeTableSizeChange(mMaxBufferSetting);
mBufferSizeChangeWaiting = false;
}
// colon headers first
if (!connectForm) {
ProcessHeader(nvPair(NS_LITERAL_CSTRING(":method"), method), false, false);
ProcessHeader(nvPair(NS_LITERAL_CSTRING(":path"), path), true, false);
ProcessHeader(nvPair(NS_LITERAL_CSTRING(":authority"), host), false, false);
ProcessHeader(nvPair(NS_LITERAL_CSTRING(":scheme"), scheme), false, false);
} else {
ProcessHeader(nvPair(NS_LITERAL_CSTRING(":method"), method), false, false);
ProcessHeader(nvPair(NS_LITERAL_CSTRING(":authority"), host), false, false);
}
// now the non colon headers
const char *beginBuffer = nvInput.BeginReading();
// This strips off the HTTP/1 method+path+version
int32_t crlfIndex = nvInput.Find("\r\n");
while (true) {
int32_t startIndex = crlfIndex + 2;
crlfIndex = nvInput.Find("\r\n", false, startIndex);
if (crlfIndex == -1)
break;
int32_t colonIndex = nvInput.Find(":", false, startIndex,
crlfIndex - startIndex);
if (colonIndex == -1)
break;
nsDependentCSubstring name = Substring(beginBuffer + startIndex,
beginBuffer + colonIndex);
// all header names are lower case in http/2
ToLowerCase(name);
// exclusions
if (name.EqualsLiteral("connection") ||
name.EqualsLiteral("host") ||
name.EqualsLiteral("keep-alive") ||
name.EqualsLiteral("proxy-connection") ||
name.EqualsLiteral("te") ||
name.EqualsLiteral("transfer-encoding") ||
name.EqualsLiteral("upgrade")) {
continue;
}
// colon headers are for http/2 and this is http/1 input, so that
// is probably a smuggling attack of some kind
bool isColonHeader = false;
for (const char *cPtr = name.BeginReading();
cPtr && cPtr < name.EndReading();
++cPtr) {
if (*cPtr == ':') {
isColonHeader = true;
break;
} else if (*cPtr != ' ' && *cPtr != '\t') {
isColonHeader = false;
break;
}
}
if(isColonHeader) {
continue;
}
int32_t valueIndex = colonIndex + 1;
while (valueIndex < crlfIndex && beginBuffer[valueIndex] == ' ')
++valueIndex;
nsDependentCSubstring value = Substring(beginBuffer + valueIndex,
beginBuffer + crlfIndex);
if (name.EqualsLiteral("content-length")) {
int64_t len;
nsCString tmp(value);
if (nsHttp::ParseInt64(tmp.get(), nullptr, &len))
mParsedContentLength = len;
}
if (name.EqualsLiteral("cookie")) {
// cookie crumbling
bool haveMoreCookies = true;
int32_t nextCookie = valueIndex;
while (haveMoreCookies) {
int32_t semiSpaceIndex = nvInput.Find("; ", false, nextCookie,
crlfIndex - nextCookie);
if (semiSpaceIndex == -1) {
haveMoreCookies = false;
semiSpaceIndex = crlfIndex;
}
nsDependentCSubstring cookie = Substring(beginBuffer + nextCookie,
beginBuffer + semiSpaceIndex);
// cookies less than 20 bytes are not indexed
ProcessHeader(nvPair(name, cookie), false, cookie.Length() < 20);
nextCookie = semiSpaceIndex + 2;
}
} else {
// allow indexing of every non-cookie except authorization
ProcessHeader(nvPair(name, value), false,
name.EqualsLiteral("authorization"));
}
}
mOutput = nullptr;
LOG(("Compressor state after EncodeHeaderBlock"));
DumpState();
return NS_OK;
}
void
Http2Compressor::DoOutput(Http2Compressor::outputCode code,
const class nvPair *pair, uint32_t index)
{
// start Byte needs to be calculated from the offset after
// the opcode has been written out in case the output stream
// buffer gets resized/relocated
uint32_t offset = mOutput->Length();
uint8_t *startByte;
switch (code) {
case kNeverIndexedLiteral:
LOG(("HTTP compressor %p neverindex literal with name reference %u %s %s\n",
this, index, pair->mName.get(), pair->mValue.get()));
// In this case, the index will have already been adjusted to be 1-based
// instead of 0-based.
EncodeInteger(4, index); // 0001 4 bit prefix
startByte = reinterpret_cast<unsigned char *>(mOutput->BeginWriting()) + offset;
*startByte = (*startByte & 0x0f) | 0x10;
if (!index) {
HuffmanAppend(pair->mName);
}
HuffmanAppend(pair->mValue);
break;
case kPlainLiteral:
LOG(("HTTP compressor %p noindex literal with name reference %u %s %s\n",
this, index, pair->mName.get(), pair->mValue.get()));
// In this case, the index will have already been adjusted to be 1-based
// instead of 0-based.
EncodeInteger(4, index); // 0000 4 bit prefix
startByte = reinterpret_cast<unsigned char *>(mOutput->BeginWriting()) + offset;
*startByte = *startByte & 0x0f;
if (!index) {
HuffmanAppend(pair->mName);
}
HuffmanAppend(pair->mValue);
break;
case kIndexedLiteral:
LOG(("HTTP compressor %p literal with name reference %u %s %s\n",
this, index, pair->mName.get(), pair->mValue.get()));
// In this case, the index will have already been adjusted to be 1-based
// instead of 0-based.
EncodeInteger(6, index); // 01 2 bit prefix
startByte = reinterpret_cast<unsigned char *>(mOutput->BeginWriting()) + offset;
*startByte = (*startByte & 0x3f) | 0x40;
if (!index) {
HuffmanAppend(pair->mName);
}
HuffmanAppend(pair->mValue);
break;
case kIndex:
LOG(("HTTP compressor %p index %u %s %s\n",
this, index, pair->mName.get(), pair->mValue.get()));
// NWGH - make this plain old index instead of index + 1
// In this case, we are passed the raw 0-based C index, and need to
// increment to make it 1-based and comply with the spec
EncodeInteger(7, index + 1);
startByte = reinterpret_cast<unsigned char *>(mOutput->BeginWriting()) + offset;
*startByte = *startByte | 0x80; // 1 1 bit prefix
break;
}
}
// writes the encoded integer onto the output
void
Http2Compressor::EncodeInteger(uint32_t prefixLen, uint32_t val)
{
uint32_t mask = (1 << prefixLen) - 1;
uint8_t tmp;
if (val < mask) {
// 1 byte encoding!
tmp = val;
mOutput->Append(reinterpret_cast<char *>(&tmp), 1);
return;
}
if (mask) {
val -= mask;
tmp = mask;
mOutput->Append(reinterpret_cast<char *>(&tmp), 1);
}
uint32_t q, r;
do {
q = val / 128;
r = val % 128;
tmp = r;
if (q)
tmp |= 0x80; // chain bit
val = q;
mOutput->Append(reinterpret_cast<char *>(&tmp), 1);
} while (q);
}
void
Http2Compressor::HuffmanAppend(const nsCString &value)
{
nsAutoCString buf;
uint8_t bitsLeft = 8;
uint32_t length = value.Length();
uint32_t offset;
uint8_t *startByte;
for (uint32_t i = 0; i < length; ++i) {
uint8_t idx = static_cast<uint8_t>(value[i]);
uint8_t huffLength = HuffmanOutgoing[idx].mLength;
uint32_t huffValue = HuffmanOutgoing[idx].mValue;
if (bitsLeft < 8) {
// Fill in the least significant <bitsLeft> bits of the previous byte
// first
uint32_t val;
if (huffLength >= bitsLeft) {
val = huffValue & ~((1 << (huffLength - bitsLeft)) - 1);
val >>= (huffLength - bitsLeft);
} else {
val = huffValue << (bitsLeft - huffLength);
}
val &= ((1 << bitsLeft) - 1);
offset = buf.Length() - 1;
startByte = reinterpret_cast<unsigned char *>(buf.BeginWriting()) + offset;
*startByte = *startByte | static_cast<uint8_t>(val & 0xFF);
if (huffLength >= bitsLeft) {
huffLength -= bitsLeft;
bitsLeft = 8;
} else {
bitsLeft -= huffLength;
huffLength = 0;
}
}
while (huffLength >= 8) {
uint32_t mask = ~((1 << (huffLength - 8)) - 1);
uint8_t val = ((huffValue & mask) >> (huffLength - 8)) & 0xFF;
buf.Append(reinterpret_cast<char *>(&val), 1);
huffLength -= 8;
}
if (huffLength) {
// Fill in the most significant <huffLength> bits of the next byte
bitsLeft = 8 - huffLength;
uint8_t val = (huffValue & ((1 << huffLength) - 1)) << bitsLeft;
buf.Append(reinterpret_cast<char *>(&val), 1);
}
}
if (bitsLeft != 8) {
// Pad the last <bitsLeft> bits with ones, which corresponds to the EOS
// encoding
uint8_t val = (1 << bitsLeft) - 1;
offset = buf.Length() - 1;
startByte = reinterpret_cast<unsigned char *>(buf.BeginWriting()) + offset;
*startByte = *startByte | val;
}
// Now we know how long our encoded string is, we can fill in our length
uint32_t bufLength = buf.Length();
offset = mOutput->Length();
EncodeInteger(7, bufLength);
startByte = reinterpret_cast<unsigned char *>(mOutput->BeginWriting()) + offset;
*startByte = *startByte | 0x80;
// Finally, we can add our REAL data!
mOutput->Append(buf);
LOG(("Http2Compressor::HuffmanAppend %p encoded %d byte original on %d "
"bytes.\n", this, length, bufLength));
}
void
Http2Compressor::ProcessHeader(const nvPair inputPair, bool noLocalIndex,
bool neverIndex)
{
uint32_t newSize = inputPair.Size();
uint32_t headerTableSize = mHeaderTable.Length();
uint32_t matchedIndex;
uint32_t nameReference = 0;
bool match = false;
LOG(("Http2Compressor::ProcessHeader %s %s", inputPair.mName.get(),
inputPair.mValue.get()));
// NWGH - make this index = 1; index <= headerTableSize; ++index
for (uint32_t index = 0; index < headerTableSize; ++index) {
if (mHeaderTable[index]->mName.Equals(inputPair.mName)) {
// NWGH - make this nameReference = index
nameReference = index + 1;
if (mHeaderTable[index]->mValue.Equals(inputPair.mValue)) {
match = true;
matchedIndex = index;
break;
}
}
}
// We need to emit a new literal
if (!match || noLocalIndex || neverIndex) {
if (neverIndex) {
DoOutput(kNeverIndexedLiteral, &inputPair, nameReference);
LOG(("Compressor state after literal never index"));
DumpState();
return;
}
if (noLocalIndex || (newSize > (mMaxBuffer / 2)) || (mMaxBuffer < 128)) {
DoOutput(kPlainLiteral, &inputPair, nameReference);
LOG(("Compressor state after literal without index"));
DumpState();
return;
}
// make sure to makeroom() first so that any implied items
// get preserved.
MakeRoom(newSize, "compressor");
DoOutput(kIndexedLiteral, &inputPair, nameReference);
mHeaderTable.AddElement(inputPair.mName, inputPair.mValue);
LOG(("HTTP compressor %p new literal placed at index 0\n",
this));
LOG(("Compressor state after literal with index"));
DumpState();
return;
}
// emit an index
DoOutput(kIndex, &inputPair, matchedIndex);
LOG(("Compressor state after index"));
DumpState();
return;
}
void
Http2Compressor::EncodeTableSizeChange(uint32_t newMaxSize)
{
uint32_t offset = mOutput->Length();
EncodeInteger(5, newMaxSize);
uint8_t *startByte = reinterpret_cast<uint8_t *>(mOutput->BeginWriting()) + offset;
*startByte = *startByte | 0x20;
}
void
Http2Compressor::SetMaxBufferSize(uint32_t maxBufferSize)
{
mMaxBufferSetting = maxBufferSize;
SetMaxBufferSizeInternal(maxBufferSize);
if (!mBufferSizeChangeWaiting) {
mBufferSizeChangeWaiting = true;
mLowestBufferSizeWaiting = maxBufferSize;
} else if (maxBufferSize < mLowestBufferSizeWaiting) {
mLowestBufferSizeWaiting = maxBufferSize;
}
}
nsresult
Http2Compressor::SetMaxBufferSizeInternal(uint32_t maxBufferSize)
{
if (maxBufferSize > mMaxBufferSetting) {
return NS_ERROR_ILLEGAL_VALUE;
}
uint32_t removedCount = 0;
LOG(("Http2Compressor::SetMaxBufferSizeInternal %u called", maxBufferSize));
while (mHeaderTable.VariableLength() && (mHeaderTable.ByteCount() > maxBufferSize)) {
mHeaderTable.RemoveElement();
++removedCount;
}
mMaxBuffer = maxBufferSize;
return NS_OK;
}
} // namespace mozilla::net
} // namespace mozilla