// Copyright 2016 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "mojo/edk/system/channel.h"
#include <string.h>
#include <algorithm>
#include <limits>
#include <utility>
#include "base/macros.h"
#include "base/memory/aligned_memory.h"
#include "base/process/process_handle.h"
#include "mojo/edk/embedder/platform_handle.h"
#if defined(OS_MACOSX) && !defined(OS_IOS)
#include "base/mac/mach_logging.h"
#elif defined(OS_WIN)
#include "base/win/win_util.h"
#endif
namespace mojo {
namespace edk {
namespace {
static_assert(sizeof(Channel::Message::Header) % kChannelMessageAlignment == 0,
"Invalid Header size.");
#if defined(MOJO_EDK_LEGACY_PROTOCOL)
static_assert(sizeof(Channel::Message::Header) == 8,
"Header must be 8 bytes on ChromeOS and Android");
#endif
} // namespace
const size_t kReadBufferSize = 4096;
const size_t kMaxUnusedReadBufferCapacity = 64 * 1024;
const size_t kMaxChannelMessageSize = 256 * 1024 * 1024;
const size_t kMaxAttachedHandles = 128;
Channel::Message::Message(size_t payload_size,
size_t max_handles,
Header::MessageType message_type)
: max_handles_(max_handles) {
DCHECK_LE(max_handles_, kMaxAttachedHandles);
size_t extra_header_size = 0;
#if defined(OS_WIN)
// On Windows we serialize HANDLEs into the extra header space.
extra_header_size = max_handles_ * sizeof(HandleEntry);
#elif defined(OS_MACOSX) && !defined(OS_IOS)
// On OSX, some of the platform handles may be mach ports, which are
// serialised into the message buffer. Since there could be a mix of fds and
// mach ports, we store the mach ports as an <index, port> pair (of uint32_t),
// so that the original ordering of handles can be re-created.
if (max_handles) {
extra_header_size =
sizeof(MachPortsExtraHeader) + (max_handles * sizeof(MachPortsEntry));
}
#endif
// Pad extra header data to be aliged to |kChannelMessageAlignment| bytes.
if (extra_header_size % kChannelMessageAlignment) {
extra_header_size += kChannelMessageAlignment -
(extra_header_size % kChannelMessageAlignment);
}
DCHECK_EQ(0u, extra_header_size % kChannelMessageAlignment);
#if defined(MOJO_EDK_LEGACY_PROTOCOL)
DCHECK_EQ(0u, extra_header_size);
#endif
size_ = sizeof(Header) + extra_header_size + payload_size;
data_ = static_cast<char*>(base::AlignedAlloc(size_,
kChannelMessageAlignment));
// Only zero out the header and not the payload. Since the payload is going to
// be memcpy'd, zeroing the payload is unnecessary work and a significant
// performance issue when dealing with large messages. Any sanitizer errors
// complaining about an uninitialized read in the payload area should be
// treated as an error and fixed.
memset(data_, 0, sizeof(Header) + extra_header_size);
header_ = reinterpret_cast<Header*>(data_);
DCHECK_LE(size_, std::numeric_limits<uint32_t>::max());
header_->num_bytes = static_cast<uint32_t>(size_);
DCHECK_LE(sizeof(Header) + extra_header_size,
std::numeric_limits<uint16_t>::max());
header_->message_type = message_type;
#if defined(MOJO_EDK_LEGACY_PROTOCOL)
header_->num_handles = static_cast<uint16_t>(max_handles);
#else
header_->num_header_bytes =
static_cast<uint16_t>(sizeof(Header) + extra_header_size);
#endif
if (max_handles_ > 0) {
#if defined(OS_WIN)
handles_ = reinterpret_cast<HandleEntry*>(mutable_extra_header());
// Initialize all handles to invalid values.
for (size_t i = 0; i < max_handles_; ++i)
handles_[i].handle = base::win::HandleToUint32(INVALID_HANDLE_VALUE);
#elif defined(OS_MACOSX) && !defined(OS_IOS)
mach_ports_header_ =
reinterpret_cast<MachPortsExtraHeader*>(mutable_extra_header());
mach_ports_header_->num_ports = 0;
// Initialize all handles to invalid values.
for (size_t i = 0; i < max_handles_; ++i) {
mach_ports_header_->entries[i] =
{0, static_cast<uint32_t>(MACH_PORT_NULL)};
}
#endif
}
}
Channel::Message::~Message() {
base::AlignedFree(data_);
}
// static
Channel::MessagePtr Channel::Message::Deserialize(const void* data,
size_t data_num_bytes) {
if (data_num_bytes < sizeof(Header))
return nullptr;
const Header* header = reinterpret_cast<const Header*>(data);
if (header->num_bytes != data_num_bytes) {
DLOG(ERROR) << "Decoding invalid message: " << header->num_bytes
<< " != " << data_num_bytes;
return nullptr;
}
#if defined(MOJO_EDK_LEGACY_PROTOCOL)
size_t payload_size = data_num_bytes - sizeof(Header);
const char* payload = static_cast<const char*>(data) + sizeof(Header);
#else
if (header->num_bytes < header->num_header_bytes ||
header->num_header_bytes < sizeof(Header)) {
DLOG(ERROR) << "Decoding invalid message: " << header->num_bytes << " < "
<< header->num_header_bytes;
return nullptr;
}
uint32_t extra_header_size = header->num_header_bytes - sizeof(Header);
size_t payload_size = data_num_bytes - header->num_header_bytes;
const char* payload =
static_cast<const char*>(data) + header->num_header_bytes;
#endif // defined(MOJO_EDK_LEGACY_PROTOCOL)
#if defined(OS_WIN)
uint32_t max_handles = extra_header_size / sizeof(HandleEntry);
#elif defined(OS_MACOSX) && !defined(OS_IOS)
if (extra_header_size < sizeof(MachPortsExtraHeader)) {
DLOG(ERROR) << "Decoding invalid message: " << extra_header_size << " < "
<< sizeof(MachPortsExtraHeader);
return nullptr;
}
uint32_t max_handles = (extra_header_size - sizeof(MachPortsExtraHeader)) /
sizeof(MachPortsEntry);
#else
const uint32_t max_handles = 0;
#endif // defined(OS_WIN)
if (header->num_handles > max_handles || max_handles > kMaxAttachedHandles) {
DLOG(ERROR) << "Decoding invalid message:" << header->num_handles
<< " > " << max_handles;
return nullptr;
}
MessagePtr message(new Message(payload_size, max_handles));
DCHECK_EQ(message->data_num_bytes(), data_num_bytes);
// Copy all payload bytes.
if (payload_size)
memcpy(message->mutable_payload(), payload, payload_size);
#if !defined(MOJO_EDK_LEGACY_PROTOCOL)
DCHECK_EQ(message->extra_header_size(), extra_header_size);
DCHECK_EQ(message->header_->num_header_bytes, header->num_header_bytes);
if (message->extra_header_size()) {
// Copy extra header bytes.
memcpy(message->mutable_extra_header(),
static_cast<const char*>(data) + sizeof(Header),
message->extra_header_size());
}
#endif
message->header_->num_handles = header->num_handles;
#if defined(OS_WIN)
ScopedPlatformHandleVectorPtr handles(
new PlatformHandleVector(header->num_handles));
for (size_t i = 0; i < header->num_handles; i++) {
(*handles)[i].handle = reinterpret_cast<HANDLE>(
static_cast<uintptr_t>(message->handles_[i].handle));
}
message->SetHandles(std::move(handles));
#endif
return message;
}
size_t Channel::Message::payload_size() const {
#if defined(MOJO_EDK_LEGACY_PROTOCOL)
return header_->num_bytes - sizeof(Header);
#else
return size_ - header_->num_header_bytes;
#endif
}
#if defined(OS_MACOSX) && !defined(OS_IOS)
bool Channel::Message::has_mach_ports() const {
if (!has_handles())
return false;
for (const auto& handle : (*handle_vector_)) {
if (handle.type == PlatformHandle::Type::MACH ||
handle.type == PlatformHandle::Type::MACH_NAME) {
return true;
}
}
return false;
}
#endif
void Channel::Message::SetHandles(ScopedPlatformHandleVectorPtr new_handles) {
#if defined(MOJO_EDK_LEGACY_PROTOCOL)
// Old semantics for ChromeOS and Android
if (header_->num_handles == 0) {
CHECK(!new_handles || new_handles->size() == 0);
return;
}
CHECK(new_handles && new_handles->size() == header_->num_handles);
std::swap(handle_vector_, new_handles);
#else
if (max_handles_ == 0) {
CHECK(!new_handles || new_handles->size() == 0);
return;
}
CHECK(new_handles && new_handles->size() <= max_handles_);
header_->num_handles = static_cast<uint16_t>(new_handles->size());
std::swap(handle_vector_, new_handles);
#if defined(OS_WIN)
memset(handles_, 0, extra_header_size());
for (size_t i = 0; i < handle_vector_->size(); i++)
handles_[i].handle = base::win::HandleToUint32((*handle_vector_)[i].handle);
#endif // defined(OS_WIN)
#endif // defined(MOJO_EDK_LEGACY_PROTOCOL)
#if defined(OS_MACOSX) && !defined(OS_IOS)
size_t mach_port_index = 0;
if (mach_ports_header_) {
for (size_t i = 0; i < max_handles_; ++i) {
mach_ports_header_->entries[i] =
{0, static_cast<uint32_t>(MACH_PORT_NULL)};
}
for (size_t i = 0; i < handle_vector_->size(); i++) {
if ((*handle_vector_)[i].type == PlatformHandle::Type::MACH ||
(*handle_vector_)[i].type == PlatformHandle::Type::MACH_NAME) {
mach_port_t port = (*handle_vector_)[i].port;
mach_ports_header_->entries[mach_port_index].index = i;
mach_ports_header_->entries[mach_port_index].mach_port = port;
mach_port_index++;
}
}
mach_ports_header_->num_ports = static_cast<uint16_t>(mach_port_index);
}
#endif
}
ScopedPlatformHandleVectorPtr Channel::Message::TakeHandles() {
#if defined(OS_MACOSX) && !defined(OS_IOS)
if (mach_ports_header_) {
for (size_t i = 0; i < max_handles_; ++i) {
mach_ports_header_->entries[i] =
{0, static_cast<uint32_t>(MACH_PORT_NULL)};
}
mach_ports_header_->num_ports = 0;
}
header_->num_handles = 0;
return std::move(handle_vector_);
#else
header_->num_handles = 0;
return std::move(handle_vector_);
#endif
}
ScopedPlatformHandleVectorPtr Channel::Message::TakeHandlesForTransport() {
#if defined(OS_WIN)
// Not necessary on Windows.
NOTREACHED();
return nullptr;
#elif defined(OS_MACOSX) && !defined(OS_IOS)
if (handle_vector_) {
for (auto it = handle_vector_->begin(); it != handle_vector_->end(); ) {
if (it->type == PlatformHandle::Type::MACH ||
it->type == PlatformHandle::Type::MACH_NAME) {
// For Mach port names, we can can just leak them. They're not real
// ports anyways. For real ports, they're leaked because this is a child
// process and the remote process will take ownership.
it = handle_vector_->erase(it);
} else {
++it;
}
}
}
return std::move(handle_vector_);
#else
return std::move(handle_vector_);
#endif
}
#if defined(OS_WIN)
// static
bool Channel::Message::RewriteHandles(base::ProcessHandle from_process,
base::ProcessHandle to_process,
PlatformHandleVector* handles) {
bool success = true;
for (size_t i = 0; i < handles->size(); ++i) {
if (!(*handles)[i].is_valid()) {
DLOG(ERROR) << "Refusing to duplicate invalid handle.";
continue;
}
DCHECK_EQ((*handles)[i].owning_process, from_process);
BOOL result = DuplicateHandle(
from_process, (*handles)[i].handle, to_process,
&(*handles)[i].handle, 0, FALSE,
DUPLICATE_SAME_ACCESS | DUPLICATE_CLOSE_SOURCE);
if (result) {
(*handles)[i].owning_process = to_process;
} else {
success = false;
// If handle duplication fails, the source handle will already be closed
// due to DUPLICATE_CLOSE_SOURCE. Replace the handle in the message with
// an invalid handle.
(*handles)[i].handle = INVALID_HANDLE_VALUE;
(*handles)[i].owning_process = base::GetCurrentProcessHandle();
}
}
return success;
}
#endif
// Helper class for managing a Channel's read buffer allocations. This maintains
// a single contiguous buffer with the layout:
//
// [discarded bytes][occupied bytes][unoccupied bytes]
//
// The Reserve() method ensures that a certain capacity of unoccupied bytes are
// available. It does not claim that capacity and only allocates new capacity
// when strictly necessary.
//
// Claim() marks unoccupied bytes as occupied.
//
// Discard() marks occupied bytes as discarded, signifying that their contents
// can be forgotten or overwritten.
//
// Realign() moves occupied bytes to the front of the buffer so that those
// occupied bytes are properly aligned.
//
// The most common Channel behavior in practice should result in very few
// allocations and copies, as memory is claimed and discarded shortly after
// being reserved, and future reservations will immediately reuse discarded
// memory.
class Channel::ReadBuffer {
public:
ReadBuffer() {
size_ = kReadBufferSize;
data_ = static_cast<char*>(base::AlignedAlloc(size_,
kChannelMessageAlignment));
}
~ReadBuffer() {
DCHECK(data_);
base::AlignedFree(data_);
}
const char* occupied_bytes() const { return data_ + num_discarded_bytes_; }
size_t num_occupied_bytes() const {
return num_occupied_bytes_ - num_discarded_bytes_;
}
// Ensures the ReadBuffer has enough contiguous space allocated to hold
// |num_bytes| more bytes; returns the address of the first available byte.
char* Reserve(size_t num_bytes) {
if (num_occupied_bytes_ + num_bytes > size_) {
size_ = std::max(size_ * 2, num_occupied_bytes_ + num_bytes);
void* new_data = base::AlignedAlloc(size_, kChannelMessageAlignment);
memcpy(new_data, data_, num_occupied_bytes_);
base::AlignedFree(data_);
data_ = static_cast<char*>(new_data);
}
return data_ + num_occupied_bytes_;
}
// Marks the first |num_bytes| unoccupied bytes as occupied.
void Claim(size_t num_bytes) {
DCHECK_LE(num_occupied_bytes_ + num_bytes, size_);
num_occupied_bytes_ += num_bytes;
}
// Marks the first |num_bytes| occupied bytes as discarded. This may result in
// shrinkage of the internal buffer, and it is not safe to assume the result
// of a previous Reserve() call is still valid after this.
void Discard(size_t num_bytes) {
DCHECK_LE(num_discarded_bytes_ + num_bytes, num_occupied_bytes_);
num_discarded_bytes_ += num_bytes;
if (num_discarded_bytes_ == num_occupied_bytes_) {
// We can just reuse the buffer from the beginning in this common case.
num_discarded_bytes_ = 0;
num_occupied_bytes_ = 0;
}
if (num_discarded_bytes_ > kMaxUnusedReadBufferCapacity) {
// In the uncommon case that we have a lot of discarded data at the
// front of the buffer, simply move remaining data to a smaller buffer.
size_t num_preserved_bytes = num_occupied_bytes_ - num_discarded_bytes_;
size_ = std::max(num_preserved_bytes, kReadBufferSize);
char* new_data = static_cast<char*>(
base::AlignedAlloc(size_, kChannelMessageAlignment));
memcpy(new_data, data_ + num_discarded_bytes_, num_preserved_bytes);
base::AlignedFree(data_);
data_ = new_data;
num_discarded_bytes_ = 0;
num_occupied_bytes_ = num_preserved_bytes;
}
if (num_occupied_bytes_ == 0 && size_ > kMaxUnusedReadBufferCapacity) {
// Opportunistically shrink the read buffer back down to a small size if
// it's grown very large. We only do this if there are no remaining
// unconsumed bytes in the buffer to avoid copies in most the common
// cases.
size_ = kMaxUnusedReadBufferCapacity;
base::AlignedFree(data_);
data_ = static_cast<char*>(
base::AlignedAlloc(size_, kChannelMessageAlignment));
}
}
void Realign() {
size_t num_bytes = num_occupied_bytes();
memmove(data_, occupied_bytes(), num_bytes);
num_discarded_bytes_ = 0;
num_occupied_bytes_ = num_bytes;
}
private:
char* data_ = nullptr;
// The total size of the allocated buffer.
size_t size_ = 0;
// The number of discarded bytes at the beginning of the allocated buffer.
size_t num_discarded_bytes_ = 0;
// The total number of occupied bytes, including discarded bytes.
size_t num_occupied_bytes_ = 0;
DISALLOW_COPY_AND_ASSIGN(ReadBuffer);
};
Channel::Channel(Delegate* delegate)
: delegate_(delegate), read_buffer_(new ReadBuffer) {
}
Channel::~Channel() {
}
void Channel::ShutDown() {
delegate_ = nullptr;
ShutDownImpl();
}
char* Channel::GetReadBuffer(size_t *buffer_capacity) {
DCHECK(read_buffer_);
size_t required_capacity = *buffer_capacity;
if (!required_capacity)
required_capacity = kReadBufferSize;
*buffer_capacity = required_capacity;
return read_buffer_->Reserve(required_capacity);
}
bool Channel::OnReadComplete(size_t bytes_read, size_t *next_read_size_hint) {
bool did_dispatch_message = false;
read_buffer_->Claim(bytes_read);
while (read_buffer_->num_occupied_bytes() >= sizeof(Message::Header)) {
// Ensure the occupied data is properly aligned. If it isn't, a SIGBUS could
// happen on architectures that don't allow misaligned words access (i.e.
// anything other than x86). Only re-align when necessary to avoid copies.
if (reinterpret_cast<uintptr_t>(read_buffer_->occupied_bytes()) %
kChannelMessageAlignment != 0)
read_buffer_->Realign();
// We have at least enough data available for a MessageHeader.
const Message::Header* header = reinterpret_cast<const Message::Header*>(
read_buffer_->occupied_bytes());
if (header->num_bytes < sizeof(Message::Header) ||
header->num_bytes > kMaxChannelMessageSize) {
LOG(ERROR) << "Invalid message size: " << header->num_bytes;
return false;
}
if (read_buffer_->num_occupied_bytes() < header->num_bytes) {
// Not enough data available to read the full message. Hint to the
// implementation that it should try reading the full size of the message.
*next_read_size_hint =
header->num_bytes - read_buffer_->num_occupied_bytes();
return true;
}
#if defined(MOJO_EDK_LEGACY_PROTOCOL)
size_t extra_header_size = 0;
const void* extra_header = nullptr;
size_t payload_size = header->num_bytes - sizeof(Message::Header);
void* payload = payload_size ? const_cast<Message::Header*>(&header[1])
: nullptr;
#else
if (header->num_header_bytes < sizeof(Message::Header) ||
header->num_header_bytes > header->num_bytes) {
LOG(ERROR) << "Invalid message header size: " << header->num_header_bytes;
return false;
}
size_t extra_header_size =
header->num_header_bytes - sizeof(Message::Header);
const void* extra_header = extra_header_size ? header + 1 : nullptr;
size_t payload_size = header->num_bytes - header->num_header_bytes;
void* payload =
payload_size ? reinterpret_cast<Message::Header*>(
const_cast<char*>(read_buffer_->occupied_bytes()) +
header->num_header_bytes)
: nullptr;
#endif // defined(MOJO_EDK_LEGACY_PROTOCOL)
ScopedPlatformHandleVectorPtr handles;
if (header->num_handles > 0) {
if (!GetReadPlatformHandles(header->num_handles, extra_header,
extra_header_size, &handles)) {
return false;
}
if (!handles) {
// Not enough handles available for this message.
break;
}
}
// We've got a complete message! Dispatch it and try another.
if (header->message_type != Message::Header::MessageType::NORMAL) {
if (!OnControlMessage(header->message_type, payload, payload_size,
std::move(handles))) {
return false;
}
did_dispatch_message = true;
} else if (delegate_) {
delegate_->OnChannelMessage(payload, payload_size, std::move(handles));
did_dispatch_message = true;
}
read_buffer_->Discard(header->num_bytes);
}
*next_read_size_hint = did_dispatch_message ? 0 : kReadBufferSize;
return true;
}
void Channel::OnError() {
if (delegate_)
delegate_->OnChannelError();
}
bool Channel::OnControlMessage(Message::Header::MessageType message_type,
const void* payload,
size_t payload_size,
ScopedPlatformHandleVectorPtr handles) {
return false;
}
} // namespace edk
} // namespace mojo