blob: 339593e8f82fcefdea73d1ecba14f2c474b58c24 [file] [log] [blame]
// Copyright 2012 The Chromium Authors
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "ipc/ipc_message_utils.h"
#include <stddef.h>
#include <stdint.h>
#include <type_traits>
#include "base/files/file_path.h"
#include "base/json/json_writer.h"
#include "base/logging.h"
#include "base/memory/ptr_util.h"
#include "base/notreached.h"
#include "base/strings/string_number_conversions.h"
#include "base/strings/stringprintf.h"
#include "base/strings/utf_string_conversions.h"
#include "base/time/time.h"
#include "base/unguessable_token.h"
#include "build/build_config.h"
#include "ipc/ipc_channel_handle.h"
#include "ipc/ipc_message.h"
#include "ipc/ipc_message_attachment.h"
#include "ipc/ipc_message_attachment_set.h"
#include "ipc/ipc_mojo_param_traits.h"
#if BUILDFLAG(IS_APPLE)
#include "ipc/mach_port_mac.h"
#endif
#if BUILDFLAG(IS_WIN)
#include <tchar.h>
#include "ipc/handle_win.h"
#include "ipc/ipc_platform_file.h"
#elif BUILDFLAG(IS_POSIX) || BUILDFLAG(IS_FUCHSIA)
#include "base/file_descriptor_posix.h"
#include "ipc/ipc_platform_file_attachment_posix.h"
#endif
#if BUILDFLAG(IS_FUCHSIA)
#include "base/fuchsia/fuchsia_logging.h"
#include "ipc/handle_attachment_fuchsia.h"
#endif
#if BUILDFLAG(IS_ANDROID)
#include "base/android/scoped_hardware_buffer_handle.h"
#include "ipc/ipc_mojo_handle_attachment.h"
#include "mojo/public/cpp/system/message_pipe.h"
#include "mojo/public/cpp/system/scope_to_message_pipe.h"
#endif
namespace IPC {
namespace {
const int kMaxRecursionDepth = 200;
template<typename CharType>
void LogBytes(const std::vector<CharType>& data, std::string* out) {
#if BUILDFLAG(IS_WIN)
// Windows has a GUI for logging, which can handle arbitrary binary data.
for (size_t i = 0; i < data.size(); ++i)
out->push_back(data[i]);
#elif BUILDFLAG(IS_POSIX) || BUILDFLAG(IS_FUCHSIA)
// On POSIX, we log to stdout, which we assume can display ASCII.
static const size_t kMaxBytesToLog = 100;
for (size_t i = 0; i < std::min(data.size(), kMaxBytesToLog); ++i) {
if (isprint(data[i]))
out->push_back(data[i]);
else
out->append(
base::StringPrintf("[%02X]", static_cast<unsigned char>(data[i])));
}
if (data.size() > kMaxBytesToLog) {
out->append(base::StringPrintf(
" and %u more bytes",
static_cast<unsigned>(data.size() - kMaxBytesToLog)));
}
#endif
}
template <typename CharType>
void WriteCharVector(base::Pickle* m, const std::vector<CharType>& p) {
static_assert(sizeof(CharType) == 1);
static_assert(std::is_integral_v<CharType>);
if (p.empty()) {
m->WriteData(nullptr, 0);
} else {
const char* data = reinterpret_cast<const char*>(p.data());
m->WriteData(data, p.size());
}
}
template <typename CharType>
bool ReadCharVector(const base::Pickle* m,
base::PickleIterator* iter,
std::vector<CharType>* r) {
static_assert(sizeof(CharType) == 1);
static_assert(std::is_integral_v<CharType>);
const char* data;
size_t data_size = 0;
if (!iter->ReadData(&data, &data_size)) {
return false;
}
const CharType* begin = reinterpret_cast<const CharType*>(data);
const CharType* end = begin + data_size;
r->assign(begin, end);
return true;
}
void WriteValue(const base::Value& value, int recursion, base::Pickle* pickle);
void WriteDictValue(const base::Value::Dict& value,
int recursion,
base::Pickle* pickle) {
WriteParam(pickle, base::checked_cast<int>(value.size()));
for (const auto entry : value) {
WriteParam(pickle, entry.first);
WriteValue(entry.second, recursion + 1, pickle);
}
}
void WriteListValue(const base::Value::List& value,
int recursion,
base::Pickle* pickle) {
WriteParam(pickle, base::checked_cast<int>(value.size()));
for (const auto& entry : value) {
WriteValue(entry, recursion + 1, pickle);
}
}
void WriteValue(const base::Value& value, int recursion, base::Pickle* pickle) {
bool result;
if (recursion > kMaxRecursionDepth) {
LOG(ERROR) << "Max recursion depth hit in WriteValue.";
return;
}
pickle->WriteInt(static_cast<int>(value.type()));
switch (value.type()) {
case base::Value::Type::NONE:
break;
case base::Value::Type::BOOLEAN: {
WriteParam(pickle, value.GetBool());
break;
}
case base::Value::Type::INTEGER: {
DCHECK(value.is_int());
WriteParam(pickle, value.GetInt());
break;
}
case base::Value::Type::DOUBLE: {
DCHECK(value.is_int() || value.is_double());
WriteParam(pickle, value.GetDouble());
break;
}
case base::Value::Type::STRING: {
const std::string* val = value.GetIfString();
result = !!val;
DCHECK(result);
WriteParam(pickle, *val);
break;
}
case base::Value::Type::BINARY: {
pickle->WriteData(reinterpret_cast<const char*>(value.GetBlob().data()),
value.GetBlob().size());
break;
}
case base::Value::Type::DICT: {
DCHECK(value.is_dict());
WriteDictValue(value.GetDict(), recursion, pickle);
break;
}
case base::Value::Type::LIST: {
DCHECK(value.is_list());
WriteListValue(value.GetList(), recursion, pickle);
break;
}
}
}
bool ReadValue(const base::Pickle* pickle,
base::PickleIterator* iter,
int recursion,
base::Value* value);
// Helper for ReadValue that reads a Value::Dict into a pre-allocated object.
bool ReadDictValue(const base::Pickle* pickle,
base::PickleIterator* iter,
int recursion,
base::Value::Dict* value) {
int size;
if (!ReadParam(pickle, iter, &size))
return false;
for (int i = 0; i < size; i++) {
std::string key;
base::Value subvalue;
if (!ReadParam(pickle, iter, &key) ||
!ReadValue(pickle, iter, recursion + 1, &subvalue)) {
return false;
}
value->Set(key, std::move(subvalue));
}
return true;
}
// Helper for ReadValue that reads a Value::List into a pre-allocated object.
bool ReadListValue(const base::Pickle* pickle,
base::PickleIterator* iter,
int recursion,
base::Value::List* value) {
int size;
if (!ReadParam(pickle, iter, &size))
return false;
value->reserve(size);
for (int i = 0; i < size; i++) {
base::Value subval;
if (!ReadValue(pickle, iter, recursion + 1, &subval))
return false;
value->Append(std::move(subval));
}
return true;
}
bool ReadValue(const base::Pickle* pickle,
base::PickleIterator* iter,
int recursion,
base::Value* value) {
if (recursion > kMaxRecursionDepth) {
LOG(ERROR) << "Max recursion depth hit in ReadValue.";
return false;
}
int type;
if (!ReadParam(pickle, iter, &type))
return false;
constexpr int kMinValueType = static_cast<int>(base::Value::Type::NONE);
constexpr int kMaxValueType = static_cast<int>(base::Value::Type::LIST);
if (type > kMaxValueType || type < kMinValueType)
return false;
switch (static_cast<base::Value::Type>(type)) {
case base::Value::Type::NONE:
*value = base::Value();
break;
case base::Value::Type::BOOLEAN: {
bool val;
if (!ReadParam(pickle, iter, &val))
return false;
*value = base::Value(val);
break;
}
case base::Value::Type::INTEGER: {
int val;
if (!ReadParam(pickle, iter, &val))
return false;
*value = base::Value(val);
break;
}
case base::Value::Type::DOUBLE: {
double val;
if (!ReadParam(pickle, iter, &val))
return false;
*value = base::Value(val);
break;
}
case base::Value::Type::STRING: {
std::string val;
if (!ReadParam(pickle, iter, &val))
return false;
*value = base::Value(std::move(val));
break;
}
case base::Value::Type::BINARY: {
absl::optional<base::span<const uint8_t>> data = iter->ReadData();
if (!data) {
return false;
}
*value = base::Value(*data);
break;
}
case base::Value::Type::DICT: {
base::Value::Dict val;
if (!ReadDictValue(pickle, iter, recursion, &val))
return false;
*value = base::Value(std::move(val));
break;
}
case base::Value::Type::LIST: {
base::Value::List val;
if (!ReadListValue(pickle, iter, recursion, &val))
return false;
*value = base::Value(std::move(val));
break;
}
default:
NOTREACHED();
return false;
}
return true;
}
} // namespace
// -----------------------------------------------------------------------------
LogData::LogData()
: routing_id(0),
type(0),
sent(0),
receive(0),
dispatch(0) {
}
LogData::LogData(const LogData& other) = default;
LogData::~LogData() = default;
void ParamTraits<bool>::Log(const param_type& p, std::string* l) {
l->append(p ? "true" : "false");
}
void ParamTraits<signed char>::Write(base::Pickle* m, const param_type& p) {
m->WriteBytes(&p, sizeof(param_type));
}
bool ParamTraits<signed char>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
const char* data;
if (!iter->ReadBytes(&data, sizeof(param_type)))
return false;
memcpy(r, data, sizeof(param_type));
return true;
}
void ParamTraits<signed char>::Log(const param_type& p, std::string* l) {
l->append(base::NumberToString(p));
}
void ParamTraits<unsigned char>::Write(base::Pickle* m, const param_type& p) {
m->WriteBytes(&p, sizeof(param_type));
}
bool ParamTraits<unsigned char>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
const char* data;
if (!iter->ReadBytes(&data, sizeof(param_type)))
return false;
memcpy(r, data, sizeof(param_type));
return true;
}
void ParamTraits<unsigned char>::Log(const param_type& p, std::string* l) {
l->append(base::NumberToString(p));
}
void ParamTraits<unsigned short>::Write(base::Pickle* m, const param_type& p) {
m->WriteBytes(&p, sizeof(param_type));
}
bool ParamTraits<unsigned short>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
const char* data;
if (!iter->ReadBytes(&data, sizeof(param_type)))
return false;
memcpy(r, data, sizeof(param_type));
return true;
}
void ParamTraits<unsigned short>::Log(const param_type& p, std::string* l) {
l->append(base::NumberToString(p));
}
void ParamTraits<int>::Log(const param_type& p, std::string* l) {
l->append(base::NumberToString(p));
}
void ParamTraits<unsigned int>::Log(const param_type& p, std::string* l) {
l->append(base::NumberToString(p));
}
#if BUILDFLAG(IS_WIN) || BUILDFLAG(IS_LINUX) || BUILDFLAG(IS_CHROMEOS) || \
BUILDFLAG(IS_FUCHSIA) || \
(BUILDFLAG(IS_ANDROID) && defined(ARCH_CPU_64_BITS))
void ParamTraits<long>::Log(const param_type& p, std::string* l) {
l->append(base::NumberToString(p));
}
void ParamTraits<unsigned long>::Log(const param_type& p, std::string* l) {
l->append(base::NumberToString(p));
}
#endif
void ParamTraits<long long>::Log(const param_type& p, std::string* l) {
l->append(base::NumberToString(p));
}
void ParamTraits<unsigned long long>::Log(const param_type& p, std::string* l) {
l->append(base::NumberToString(p));
}
void ParamTraits<float>::Log(const param_type& p, std::string* l) {
l->append(base::StringPrintf("%e", p));
}
void ParamTraits<double>::Write(base::Pickle* m, const param_type& p) {
m->WriteBytes(reinterpret_cast<const char*>(&p), sizeof(param_type));
}
bool ParamTraits<double>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
const char *data;
if (!iter->ReadBytes(&data, sizeof(*r))) {
NOTREACHED();
return false;
}
memcpy(r, data, sizeof(param_type));
return true;
}
void ParamTraits<double>::Log(const param_type& p, std::string* l) {
l->append(base::StringPrintf("%e", p));
}
void ParamTraits<std::string>::Log(const param_type& p, std::string* l) {
l->append(p);
}
void ParamTraits<std::u16string>::Log(const param_type& p, std::string* l) {
l->append(base::UTF16ToUTF8(p));
}
#if BUILDFLAG(IS_WIN)
bool ParamTraits<std::wstring>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
base::StringPiece16 piece16;
if (!iter->ReadStringPiece16(&piece16))
return false;
*r = base::AsWString(piece16);
return true;
}
void ParamTraits<std::wstring>::Log(const param_type& p, std::string* l) {
l->append(base::WideToUTF8(p));
}
#endif
void ParamTraits<std::vector<char>>::Write(base::Pickle* m,
const param_type& p) {
WriteCharVector(m, p);
}
bool ParamTraits<std::vector<char>>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
return ReadCharVector(m, iter, r);
}
void ParamTraits<std::vector<char> >::Log(const param_type& p, std::string* l) {
LogBytes(p, l);
}
void ParamTraits<std::vector<unsigned char>>::Write(base::Pickle* m,
const param_type& p) {
WriteCharVector(m, p);
}
bool ParamTraits<std::vector<unsigned char>>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
return ReadCharVector(m, iter, r);
}
void ParamTraits<std::vector<unsigned char> >::Log(const param_type& p,
std::string* l) {
LogBytes(p, l);
}
void ParamTraits<std::vector<bool>>::Write(base::Pickle* m,
const param_type& p) {
WriteParam(m, base::checked_cast<int>(p.size()));
// Cast to bool below is required because libc++'s
// vector<bool>::const_reference is different from bool, and we want to avoid
// writing an extra specialization of ParamTraits for it.
for (size_t i = 0; i < p.size(); i++)
WriteParam(m, static_cast<bool>(p[i]));
}
bool ParamTraits<std::vector<bool>>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
size_t size;
if (!iter->ReadLength(&size))
return false;
r->resize(size);
for (size_t i = 0; i < size; i++) {
bool value;
if (!ReadParam(m, iter, &value))
return false;
(*r)[i] = value;
}
return true;
}
void ParamTraits<std::vector<bool> >::Log(const param_type& p, std::string* l) {
for (size_t i = 0; i < p.size(); ++i) {
if (i != 0)
l->push_back(' ');
LogParam(static_cast<bool>(p[i]), l);
}
}
void ParamTraits<base::Value::Dict>::Write(base::Pickle* m,
const param_type& p) {
WriteDictValue(p, 0, m);
}
bool ParamTraits<base::Value::Dict>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
return ReadDictValue(m, iter, 0, r);
}
void ParamTraits<base::Value::Dict>::Log(const param_type& p, std::string* l) {
std::string json;
base::JSONWriter::Write(p, &json);
l->append(json);
}
#if BUILDFLAG(IS_POSIX) || BUILDFLAG(IS_FUCHSIA)
void ParamTraits<base::FileDescriptor>::Write(base::Pickle* m,
const param_type& p) {
// This serialization must be kept in sync with
// nacl_message_scanner.cc:WriteHandle().
const bool valid = p.fd >= 0;
WriteParam(m, valid);
if (!valid)
return;
if (p.auto_close) {
if (!m->WriteAttachment(
new internal::PlatformFileAttachment(base::ScopedFD(p.fd))))
NOTREACHED();
} else {
if (!m->WriteAttachment(new internal::PlatformFileAttachment(p.fd)))
NOTREACHED();
}
}
bool ParamTraits<base::FileDescriptor>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
*r = base::FileDescriptor();
bool valid;
if (!ReadParam(m, iter, &valid))
return false;
if (!valid)
return true;
scoped_refptr<base::Pickle::Attachment> attachment;
if (!m->ReadAttachment(iter, &attachment))
return false;
if (static_cast<MessageAttachment*>(attachment.get())->GetType() !=
MessageAttachment::Type::PLATFORM_FILE) {
return false;
}
*r = base::FileDescriptor(
static_cast<internal::PlatformFileAttachment*>(attachment.get())
->TakePlatformFile(),
true);
return true;
}
void ParamTraits<base::FileDescriptor>::Log(const param_type& p,
std::string* l) {
if (p.auto_close) {
l->append(base::StringPrintf("FD(%d auto-close)", p.fd));
} else {
l->append(base::StringPrintf("FD(%d)", p.fd));
}
}
void ParamTraits<base::ScopedFD>::Write(base::Pickle* m, const param_type& p) {
// This serialization must be kept in sync with
// nacl_message_scanner.cc:WriteHandle().
const bool valid = p.is_valid();
WriteParam(m, valid);
if (!valid)
return;
if (!m->WriteAttachment(new internal::PlatformFileAttachment(
std::move(const_cast<param_type&>(p))))) {
NOTREACHED();
}
}
bool ParamTraits<base::ScopedFD>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
r->reset();
bool valid;
if (!ReadParam(m, iter, &valid))
return false;
if (!valid)
return true;
scoped_refptr<base::Pickle::Attachment> attachment;
if (!m->ReadAttachment(iter, &attachment))
return false;
if (static_cast<MessageAttachment*>(attachment.get())->GetType() !=
MessageAttachment::Type::PLATFORM_FILE) {
return false;
}
*r = base::ScopedFD(
static_cast<internal::PlatformFileAttachment*>(attachment.get())
->TakePlatformFile());
return true;
}
void ParamTraits<base::ScopedFD>::Log(const param_type& p, std::string* l) {
l->append(base::StringPrintf("ScopedFD(%d)", p.get()));
}
#endif // BUILDFLAG(IS_POSIX) || BUILDFLAG(IS_FUCHSIA)
#if BUILDFLAG(IS_WIN)
void ParamTraits<base::win::ScopedHandle>::Write(base::Pickle* m,
const param_type& p) {
const bool valid = p.IsValid();
WriteParam(m, valid);
if (!valid)
return;
HandleWin handle(p.Get());
WriteParam(m, handle);
}
bool ParamTraits<base::win::ScopedHandle>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
r->Close();
bool valid;
if (!ReadParam(m, iter, &valid))
return false;
if (!valid)
return true;
HandleWin handle;
if (!ReadParam(m, iter, &handle))
return false;
r->Set(handle.get_handle());
return true;
}
void ParamTraits<base::win::ScopedHandle>::Log(const param_type& p,
std::string* l) {
l->append(base::StringPrintf("ScopedHandle(%p)", p.Get()));
}
#endif // BUILDFLAG(IS_WIN)
#if BUILDFLAG(IS_FUCHSIA)
void ParamTraits<zx::vmo>::Write(base::Pickle* m, const param_type& p) {
// This serialization must be kept in sync with
// nacl_message_scanner.cc:WriteHandle().
const bool valid = p.is_valid();
WriteParam(m, valid);
if (!valid)
return;
if (!m->WriteAttachment(new internal::HandleAttachmentFuchsia(
std::move(const_cast<param_type&>(p))))) {
NOTREACHED();
}
}
bool ParamTraits<zx::vmo>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
r->reset();
bool valid;
if (!ReadParam(m, iter, &valid))
return false;
if (!valid)
return true;
scoped_refptr<base::Pickle::Attachment> attachment;
if (!m->ReadAttachment(iter, &attachment))
return false;
if (static_cast<MessageAttachment*>(attachment.get())->GetType() !=
MessageAttachment::Type::FUCHSIA_HANDLE) {
return false;
}
*r = zx::vmo(static_cast<internal::HandleAttachmentFuchsia*>(attachment.get())
->Take());
return true;
}
void ParamTraits<zx::vmo>::Log(const param_type& p, std::string* l) {
l->append("ZirconVMO");
}
void ParamTraits<zx::channel>::Write(base::Pickle* m, const param_type& p) {
// This serialization must be kept in sync with
// nacl_message_scanner.cc:WriteHandle().
const bool valid = p.is_valid();
WriteParam(m, valid);
if (!valid)
return;
if (!m->WriteAttachment(new internal::HandleAttachmentFuchsia(
std::move(const_cast<param_type&>(p))))) {
NOTREACHED();
}
}
bool ParamTraits<zx::channel>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
r->reset();
bool valid;
if (!ReadParam(m, iter, &valid))
return false;
if (!valid)
return true;
scoped_refptr<base::Pickle::Attachment> attachment;
if (!m->ReadAttachment(iter, &attachment))
return false;
if (static_cast<MessageAttachment*>(attachment.get())->GetType() !=
MessageAttachment::Type::FUCHSIA_HANDLE) {
return false;
}
*r = zx::channel(
static_cast<internal::HandleAttachmentFuchsia*>(attachment.get())
->Take());
return true;
}
void ParamTraits<zx::channel>::Log(const param_type& p, std::string* l) {
l->append("ZirconChannel");
}
#endif // BUILDFLAG(IS_FUCHSIA)
#if BUILDFLAG(IS_ANDROID)
void ParamTraits<base::android::ScopedHardwareBufferHandle>::Write(
base::Pickle* m,
const param_type& p) {
const bool is_valid = p.is_valid();
WriteParam(m, is_valid);
if (!is_valid)
return;
// We must keep a ref to the AHardwareBuffer alive until the receiver has
// acquired its own reference. We do this by sending a message pipe handle
// along with the buffer. When the receiver deserializes (or even if they
// die without ever reading the message) their end of the pipe will be
// closed. We will eventually detect this and release the AHB reference.
mojo::MessagePipe tracking_pipe;
m->WriteAttachment(new internal::MojoHandleAttachment(
mojo::ScopedHandle::From(std::move(tracking_pipe.handle0))));
WriteParam(m, base::FileDescriptor(p.SerializeAsFileDescriptor().release(),
true /* auto_close */));
// Pass ownership of the input handle to our tracking pipe to keep the AHB
// alive long enough to be deserialized by the receiver.
mojo::ScopeToMessagePipe(std::move(const_cast<param_type&>(p)),
std::move(tracking_pipe.handle1));
}
bool ParamTraits<base::android::ScopedHardwareBufferHandle>::Read(
const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
*r = base::android::ScopedHardwareBufferHandle();
bool is_valid;
if (!ReadParam(m, iter, &is_valid))
return false;
if (!is_valid)
return true;
scoped_refptr<base::Pickle::Attachment> tracking_pipe_attachment;
if (!m->ReadAttachment(iter, &tracking_pipe_attachment))
return false;
// We keep this alive until the AHB is safely deserialized below. When this
// goes out of scope, the sender holding the other end of this pipe will treat
// this handle closure as a signal that it's safe to release their AHB
// keepalive ref.
mojo::ScopedHandle tracking_pipe =
static_cast<MessageAttachment*>(tracking_pipe_attachment.get())
->TakeMojoHandle();
base::FileDescriptor descriptor;
if (!ReadParam(m, iter, &descriptor))
return false;
// NOTE: It is valid to deserialize an invalid FileDescriptor, so the success
// of |ReadParam()| above does not imply that |descriptor| is valid.
base::ScopedFD scoped_fd(descriptor.fd);
if (!scoped_fd.is_valid())
return false;
*r = base::android::ScopedHardwareBufferHandle::DeserializeFromFileDescriptor(
std::move(scoped_fd));
return true;
}
void ParamTraits<base::android::ScopedHardwareBufferHandle>::Log(
const param_type& p,
std::string* l) {
l->append(base::StringPrintf("base::android::ScopedHardwareBufferHandle(%p)",
p.get()));
}
#endif // BUILDFLAG(IS_ANDROID)
void ParamTraits<base::ReadOnlySharedMemoryRegion>::Write(base::Pickle* m,
const param_type& p) {
base::subtle::PlatformSharedMemoryRegion handle =
base::ReadOnlySharedMemoryRegion::TakeHandleForSerialization(
std::move(const_cast<param_type&>(p)));
WriteParam(m, std::move(handle));
}
bool ParamTraits<base::ReadOnlySharedMemoryRegion>::Read(
const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
base::subtle::PlatformSharedMemoryRegion handle;
if (!ReadParam(m, iter, &handle))
return false;
*r = base::ReadOnlySharedMemoryRegion::Deserialize(std::move(handle));
return true;
}
void ParamTraits<base::ReadOnlySharedMemoryRegion>::Log(const param_type& p,
std::string* l) {
*l = "<base::ReadOnlySharedMemoryRegion>";
// TODO(alexilin): currently there is no way to access underlying handle
// without destructing a ReadOnlySharedMemoryRegion instance.
}
void ParamTraits<base::WritableSharedMemoryRegion>::Write(base::Pickle* m,
const param_type& p) {
base::subtle::PlatformSharedMemoryRegion handle =
base::WritableSharedMemoryRegion::TakeHandleForSerialization(
std::move(const_cast<param_type&>(p)));
WriteParam(m, std::move(handle));
}
bool ParamTraits<base::WritableSharedMemoryRegion>::Read(
const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
base::subtle::PlatformSharedMemoryRegion handle;
if (!ReadParam(m, iter, &handle))
return false;
*r = base::WritableSharedMemoryRegion::Deserialize(std::move(handle));
return true;
}
void ParamTraits<base::WritableSharedMemoryRegion>::Log(const param_type& p,
std::string* l) {
*l = "<base::WritableSharedMemoryRegion>";
// TODO(alexilin): currently there is no way to access underlying handle
// without destructing a ReadOnlySharedMemoryRegion instance.
}
void ParamTraits<base::UnsafeSharedMemoryRegion>::Write(base::Pickle* m,
const param_type& p) {
base::subtle::PlatformSharedMemoryRegion handle =
base::UnsafeSharedMemoryRegion::TakeHandleForSerialization(
std::move(const_cast<param_type&>(p)));
WriteParam(m, std::move(handle));
}
bool ParamTraits<base::UnsafeSharedMemoryRegion>::Read(
const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
base::subtle::PlatformSharedMemoryRegion handle;
if (!ReadParam(m, iter, &handle))
return false;
*r = base::UnsafeSharedMemoryRegion::Deserialize(std::move(handle));
return true;
}
void ParamTraits<base::UnsafeSharedMemoryRegion>::Log(const param_type& p,
std::string* l) {
*l = "<base::UnsafeSharedMemoryRegion>";
// TODO(alexilin): currently there is no way to access underlying handle
// without destructing a ReadOnlySharedMemoryRegion instance.
}
void ParamTraits<base::subtle::PlatformSharedMemoryRegion>::Write(
base::Pickle* m,
const param_type& p) {
// This serialization must be kept in sync with
// nacl_message_scanner.cc::WriteHandle().
const bool valid = p.IsValid();
WriteParam(m, valid);
if (!valid)
return;
WriteParam(m, p.GetMode());
WriteParam(m, static_cast<uint64_t>(p.GetSize()));
WriteParam(m, p.GetGUID());
#if BUILDFLAG(IS_WIN)
base::win::ScopedHandle h = const_cast<param_type&>(p).PassPlatformHandle();
HandleWin handle_win(h.Get());
WriteParam(m, handle_win);
#elif BUILDFLAG(IS_FUCHSIA)
zx::vmo vmo = const_cast<param_type&>(p).PassPlatformHandle();
WriteParam(m, vmo);
#elif BUILDFLAG(IS_APPLE)
base::mac::ScopedMachSendRight h =
const_cast<param_type&>(p).PassPlatformHandle();
MachPortMac mach_port_mac(h.get());
WriteParam(m, mach_port_mac);
#elif BUILDFLAG(IS_ANDROID)
m->WriteAttachment(new internal::PlatformFileAttachment(
base::ScopedFD(const_cast<param_type&>(p).PassPlatformHandle())));
#elif BUILDFLAG(IS_POSIX)
base::subtle::ScopedFDPair h =
const_cast<param_type&>(p).PassPlatformHandle();
m->WriteAttachment(new internal::PlatformFileAttachment(std::move(h.fd)));
if (p.GetMode() ==
base::subtle::PlatformSharedMemoryRegion::Mode::kWritable) {
m->WriteAttachment(
new internal::PlatformFileAttachment(std::move(h.readonly_fd)));
}
#endif
}
bool ParamTraits<base::subtle::PlatformSharedMemoryRegion>::Read(
const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
bool valid;
if (!ReadParam(m, iter, &valid))
return false;
if (!valid) {
*r = base::subtle::PlatformSharedMemoryRegion();
return true;
}
base::subtle::PlatformSharedMemoryRegion::Mode mode;
uint64_t shm_size;
base::UnguessableToken guid;
if (!ReadParam(m, iter, &mode) || !ReadParam(m, iter, &shm_size) ||
!base::IsValueInRangeForNumericType<size_t>(shm_size) ||
!ReadParam(m, iter, &guid)) {
return false;
}
size_t size = static_cast<size_t>(shm_size);
#if BUILDFLAG(IS_WIN)
HandleWin handle_win;
if (!ReadParam(m, iter, &handle_win))
return false;
*r = base::subtle::PlatformSharedMemoryRegion::Take(
base::win::ScopedHandle(handle_win.get_handle()), mode, size, guid);
#elif BUILDFLAG(IS_FUCHSIA)
zx::vmo vmo;
if (!ReadParam(m, iter, &vmo))
return false;
*r = base::subtle::PlatformSharedMemoryRegion::Take(std::move(vmo), mode,
size, guid);
#elif BUILDFLAG(IS_APPLE)
MachPortMac mach_port_mac;
if (!ReadParam(m, iter, &mach_port_mac))
return false;
*r = base::subtle::PlatformSharedMemoryRegion::Take(
base::mac::ScopedMachSendRight(mach_port_mac.get_mach_port()), mode, size,
guid);
#elif BUILDFLAG(IS_POSIX)
scoped_refptr<base::Pickle::Attachment> attachment;
if (!m->ReadAttachment(iter, &attachment))
return false;
if (static_cast<MessageAttachment*>(attachment.get())->GetType() !=
MessageAttachment::Type::PLATFORM_FILE) {
return false;
}
#if BUILDFLAG(IS_ANDROID)
*r = base::subtle::PlatformSharedMemoryRegion::Take(
base::ScopedFD(
static_cast<internal::PlatformFileAttachment*>(attachment.get())
->TakePlatformFile()),
mode, size, guid);
#else
scoped_refptr<base::Pickle::Attachment> readonly_attachment;
if (mode == base::subtle::PlatformSharedMemoryRegion::Mode::kWritable) {
if (!m->ReadAttachment(iter, &readonly_attachment))
return false;
if (static_cast<MessageAttachment*>(readonly_attachment.get())->GetType() !=
MessageAttachment::Type::PLATFORM_FILE) {
return false;
}
}
*r = base::subtle::PlatformSharedMemoryRegion::Take(
base::subtle::ScopedFDPair(
base::ScopedFD(
static_cast<internal::PlatformFileAttachment*>(attachment.get())
->TakePlatformFile()),
readonly_attachment
? base::ScopedFD(static_cast<internal::PlatformFileAttachment*>(
readonly_attachment.get())
->TakePlatformFile())
: base::ScopedFD()),
mode, size, guid);
#endif // BUILDFLAG(IS_ANDROID)
#endif
return true;
}
void ParamTraits<base::subtle::PlatformSharedMemoryRegion>::Log(
const param_type& p,
std::string* l) {
#if BUILDFLAG(IS_FUCHSIA)
l->append("Handle: ");
LogParam(p.GetPlatformHandle()->get(), l);
#elif BUILDFLAG(IS_WIN)
l->append("Handle: ");
LogParam(p.GetPlatformHandle(), l);
#elif BUILDFLAG(IS_APPLE)
l->append("Mach port: ");
LogParam(p.GetPlatformHandle(), l);
#elif BUILDFLAG(IS_ANDROID)
l->append("FD: ");
LogParam(p.GetPlatformHandle(), l);
#elif BUILDFLAG(IS_POSIX)
base::subtle::FDPair h = p.GetPlatformHandle();
l->append("FD: ");
LogParam(h.fd, l);
l->append("Read-only FD: ");
LogParam(h.readonly_fd, l);
#endif
l->append("Mode: ");
LogParam(p.GetMode(), l);
l->append("size: ");
LogParam(static_cast<uint64_t>(p.GetSize()), l);
l->append("GUID: ");
LogParam(p.GetGUID(), l);
}
void ParamTraits<base::subtle::PlatformSharedMemoryRegion::Mode>::Write(
base::Pickle* m,
const param_type& value) {
DCHECK(static_cast<int>(value) >= 0 &&
static_cast<int>(value) <= static_cast<int>(param_type::kMaxValue));
m->WriteInt(static_cast<int>(value));
}
bool ParamTraits<base::subtle::PlatformSharedMemoryRegion::Mode>::Read(
const base::Pickle* m,
base::PickleIterator* iter,
param_type* p) {
int value;
if (!iter->ReadInt(&value))
return false;
if (!(static_cast<int>(value) >= 0 &&
static_cast<int>(value) <= static_cast<int>(param_type::kMaxValue))) {
return false;
}
*p = static_cast<param_type>(value);
return true;
}
void ParamTraits<base::subtle::PlatformSharedMemoryRegion::Mode>::Log(
const param_type& p,
std::string* l) {
LogParam(static_cast<int>(p), l);
}
#if BUILDFLAG(IS_WIN)
void ParamTraits<PlatformFileForTransit>::Write(base::Pickle* m,
const param_type& p) {
m->WriteBool(p.IsValid());
if (p.IsValid()) {
HandleWin handle_win(p.GetHandle());
ParamTraits<HandleWin>::Write(m, handle_win);
::CloseHandle(p.GetHandle());
}
}
bool ParamTraits<PlatformFileForTransit>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
bool is_valid;
if (!iter->ReadBool(&is_valid))
return false;
if (!is_valid) {
*r = PlatformFileForTransit();
return true;
}
HandleWin handle_win;
if (!ParamTraits<HandleWin>::Read(m, iter, &handle_win))
return false;
*r = PlatformFileForTransit(handle_win.get_handle());
return true;
}
void ParamTraits<PlatformFileForTransit>::Log(const param_type& p,
std::string* l) {
LogParam(p.GetHandle(), l);
}
#endif // BUILDFLAG(IS_WIN)
void ParamTraits<base::FilePath>::Write(base::Pickle* m, const param_type& p) {
p.WriteToPickle(m);
}
bool ParamTraits<base::FilePath>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
return r->ReadFromPickle(iter);
}
void ParamTraits<base::FilePath>::Log(const param_type& p, std::string* l) {
ParamTraits<base::FilePath::StringType>::Log(p.value(), l);
}
void ParamTraits<base::Value::List>::Write(base::Pickle* m,
const param_type& p) {
WriteListValue(p, 0, m);
}
bool ParamTraits<base::Value::List>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
return ReadListValue(m, iter, 0, r);
}
void ParamTraits<base::Value::List>::Log(const param_type& p, std::string* l) {
std::string json;
base::JSONWriter::Write(p, &json);
l->append(json);
}
void ParamTraits<base::Value>::Write(base::Pickle* m, const param_type& p) {
WriteValue(p, 0, m);
}
bool ParamTraits<base::Value>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
return ReadValue(m, iter, 0, r);
}
void ParamTraits<base::Value>::Log(const param_type& p, std::string* l) {
std::string json;
base::JSONWriter::Write(p, &json);
l->append(json);
}
void ParamTraits<base::File::Info>::Write(base::Pickle* m,
const param_type& p) {
WriteParam(m, p.size);
WriteParam(m, p.is_directory);
WriteParam(m, p.last_modified.ToDoubleT());
WriteParam(m, p.last_accessed.ToDoubleT());
WriteParam(m, p.creation_time.ToDoubleT());
}
bool ParamTraits<base::File::Info>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* p) {
double last_modified, last_accessed, creation_time;
if (!ReadParam(m, iter, &p->size) ||
!ReadParam(m, iter, &p->is_directory) ||
!ReadParam(m, iter, &last_modified) ||
!ReadParam(m, iter, &last_accessed) ||
!ReadParam(m, iter, &creation_time))
return false;
p->last_modified = base::Time::FromDoubleT(last_modified);
p->last_accessed = base::Time::FromDoubleT(last_accessed);
p->creation_time = base::Time::FromDoubleT(creation_time);
return true;
}
void ParamTraits<base::File::Info>::Log(const param_type& p,
std::string* l) {
l->append("(");
LogParam(p.size, l);
l->append(",");
LogParam(p.is_directory, l);
l->append(",");
LogParam(p.last_modified.ToDoubleT(), l);
l->append(",");
LogParam(p.last_accessed.ToDoubleT(), l);
l->append(",");
LogParam(p.creation_time.ToDoubleT(), l);
l->append(")");
}
void ParamTraits<base::Time>::Write(base::Pickle* m, const param_type& p) {
ParamTraits<int64_t>::Write(m, p.ToInternalValue());
}
bool ParamTraits<base::Time>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
int64_t value;
if (!ParamTraits<int64_t>::Read(m, iter, &value))
return false;
*r = base::Time::FromInternalValue(value);
return true;
}
void ParamTraits<base::Time>::Log(const param_type& p, std::string* l) {
ParamTraits<int64_t>::Log(p.ToInternalValue(), l);
}
void ParamTraits<base::TimeDelta>::Write(base::Pickle* m, const param_type& p) {
ParamTraits<int64_t>::Write(m, p.ToInternalValue());
}
bool ParamTraits<base::TimeDelta>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
int64_t value;
bool ret = ParamTraits<int64_t>::Read(m, iter, &value);
if (ret)
*r = base::TimeDelta::FromInternalValue(value);
return ret;
}
void ParamTraits<base::TimeDelta>::Log(const param_type& p, std::string* l) {
ParamTraits<int64_t>::Log(p.ToInternalValue(), l);
}
void ParamTraits<base::TimeTicks>::Write(base::Pickle* m, const param_type& p) {
ParamTraits<int64_t>::Write(m, p.ToInternalValue());
}
bool ParamTraits<base::TimeTicks>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
int64_t value;
bool ret = ParamTraits<int64_t>::Read(m, iter, &value);
if (ret)
*r = base::TimeTicks::FromInternalValue(value);
return ret;
}
void ParamTraits<base::TimeTicks>::Log(const param_type& p, std::string* l) {
ParamTraits<int64_t>::Log(p.ToInternalValue(), l);
}
// If base::UnguessableToken is no longer 128 bits, the IPC serialization logic
// below should be updated.
static_assert(sizeof(base::UnguessableToken) == 2 * sizeof(uint64_t),
"base::UnguessableToken should be of size 2 * sizeof(uint64_t).");
void ParamTraits<base::UnguessableToken>::Write(base::Pickle* m,
const param_type& p) {
DCHECK(!p.is_empty());
ParamTraits<uint64_t>::Write(m, p.GetHighForSerialization());
ParamTraits<uint64_t>::Write(m, p.GetLowForSerialization());
}
bool ParamTraits<base::UnguessableToken>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
uint64_t high, low;
if (!ParamTraits<uint64_t>::Read(m, iter, &high) ||
!ParamTraits<uint64_t>::Read(m, iter, &low))
return false;
// This is not mapped as nullable_is_same_type, so any UnguessableToken
// deserialized by the traits should always yield a non-empty token.
// If deserialization results in an empty token, the data is malformed.
absl::optional<base::UnguessableToken> token =
base::UnguessableToken::Deserialize(high, low);
if (!token.has_value()) {
return false;
}
*r = token.value();
return true;
}
void ParamTraits<base::UnguessableToken>::Log(const param_type& p,
std::string* l) {
l->append(p.ToString());
}
void ParamTraits<IPC::ChannelHandle>::Write(base::Pickle* m,
const param_type& p) {
#if BUILDFLAG(IS_NACL)
WriteParam(m, p.socket);
#else
WriteParam(m, p.mojo_handle);
#endif
}
bool ParamTraits<IPC::ChannelHandle>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
#if BUILDFLAG(IS_NACL)
return ReadParam(m, iter, &r->socket);
#else
return ReadParam(m, iter, &r->mojo_handle);
#endif
}
void ParamTraits<IPC::ChannelHandle>::Log(const param_type& p,
std::string* l) {
l->append("ChannelHandle(");
#if BUILDFLAG(IS_NACL)
ParamTraits<base::FileDescriptor>::Log(p.socket, l);
#else
LogParam(p.mojo_handle, l);
#endif
l->append(")");
}
void ParamTraits<LogData>::Write(base::Pickle* m, const param_type& p) {
WriteParam(m, p.channel);
WriteParam(m, p.routing_id);
WriteParam(m, p.type);
WriteParam(m, p.flags);
WriteParam(m, p.sent);
WriteParam(m, p.receive);
WriteParam(m, p.dispatch);
WriteParam(m, p.message_name);
WriteParam(m, p.params);
}
bool ParamTraits<LogData>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
return
ReadParam(m, iter, &r->channel) &&
ReadParam(m, iter, &r->routing_id) &&
ReadParam(m, iter, &r->type) &&
ReadParam(m, iter, &r->flags) &&
ReadParam(m, iter, &r->sent) &&
ReadParam(m, iter, &r->receive) &&
ReadParam(m, iter, &r->dispatch) &&
ReadParam(m, iter, &r->message_name) &&
ReadParam(m, iter, &r->params);
}
void ParamTraits<LogData>::Log(const param_type& p, std::string* l) {
// Doesn't make sense to implement this!
}
void ParamTraits<Message>::Write(base::Pickle* m, const Message& p) {
#if BUILDFLAG(IS_POSIX) || BUILDFLAG(IS_FUCHSIA)
// We don't serialize the file descriptors in the nested message, so there
// better not be any.
DCHECK(!p.HasAttachments());
#endif
// Don't just write out the message. This is used to send messages between
// NaCl (Posix environment) and the browser (could be on Windows). The message
// header formats differ between these systems (so does handle sharing, but
// we already asserted we don't have any handles). So just write out the
// parts of the header we use.
//
// Be careful also to use only explicitly-sized types. The NaCl environment
// could be 64-bit and the host browser could be 32-bits. The nested message
// may or may not be safe to send between 32-bit and 64-bit systems, but we
// leave that up to the code sending the message to ensure.
m->WriteUInt32(static_cast<uint32_t>(p.routing_id()));
m->WriteUInt32(p.type());
m->WriteUInt32(p.flags());
m->WriteData(p.payload(), p.payload_size());
}
bool ParamTraits<Message>::Read(const base::Pickle* m,
base::PickleIterator* iter,
Message* r) {
uint32_t routing_id, type, flags;
if (!iter->ReadUInt32(&routing_id) ||
!iter->ReadUInt32(&type) ||
!iter->ReadUInt32(&flags))
return false;
size_t payload_size;
const char* payload;
if (!iter->ReadData(&payload, &payload_size))
return false;
r->SetHeaderValues(static_cast<int32_t>(routing_id), type, flags);
r->WriteBytes(payload, payload_size);
return true;
}
void ParamTraits<Message>::Log(const Message& p, std::string* l) {
l->append("<IPC::Message>");
}
#if BUILDFLAG(IS_WIN)
// Note that HWNDs/HANDLE/HCURSOR/HACCEL etc are always 32 bits, even on 64
// bit systems. That's why we use the Windows macros to convert to 32 bits.
void ParamTraits<HANDLE>::Write(base::Pickle* m, const param_type& p) {
m->WriteInt(HandleToLong(p));
}
bool ParamTraits<HANDLE>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
int32_t temp;
if (!iter->ReadInt(&temp))
return false;
*r = LongToHandle(temp);
return true;
}
void ParamTraits<HANDLE>::Log(const param_type& p, std::string* l) {
l->append(base::StringPrintf("0x%p", p));
}
void ParamTraits<MSG>::Write(base::Pickle* m, const param_type& p) {
m->WriteData(reinterpret_cast<const char*>(&p), sizeof(MSG));
}
bool ParamTraits<MSG>::Read(const base::Pickle* m,
base::PickleIterator* iter,
param_type* r) {
const char *data;
size_t data_size = 0;
bool result = iter->ReadData(&data, &data_size);
if (result && data_size == sizeof(MSG)) {
memcpy(r, data, sizeof(MSG));
} else {
result = false;
NOTREACHED();
}
return result;
}
void ParamTraits<MSG>::Log(const param_type& p, std::string* l) {
l->append("<MSG>");
}
#endif // BUILDFLAG(IS_WIN)
} // namespace IPC