blob: f779d6e446e12b1e57b077a772bdc37e388bb49e [file] [log] [blame]
/*
* Copyright (C) 2005 The Android Open Source Project
*
* Licensed 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.
*/
#define LOG_TAG "Parcel"
//#define LOG_NDEBUG 0
#include <errno.h>
#include <fcntl.h>
#include <inttypes.h>
#include <pthread.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <sys/mman.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <sys/resource.h>
#include <unistd.h>
#include <binder/Binder.h>
#include <binder/BpBinder.h>
#include <binder/IPCThreadState.h>
#include <binder/Parcel.h>
#include <binder/ProcessState.h>
#include <binder/Status.h>
#include <binder/TextOutput.h>
#include <binder/Value.h>
#include <cutils/ashmem.h>
#include <utils/Debug.h>
#include <utils/Flattenable.h>
#include <utils/Log.h>
#include <utils/misc.h>
#include <utils/String8.h>
#include <utils/String16.h>
#include <private/binder/binder_module.h>
#include <private/binder/Static.h>
#ifndef INT32_MAX
#define INT32_MAX ((int32_t)(2147483647))
#endif
#define LOG_REFS(...)
//#define LOG_REFS(...) ALOG(LOG_DEBUG, LOG_TAG, __VA_ARGS__)
#define LOG_ALLOC(...)
//#define LOG_ALLOC(...) ALOG(LOG_DEBUG, LOG_TAG, __VA_ARGS__)
// ---------------------------------------------------------------------------
// This macro should never be used at runtime, as a too large value
// of s could cause an integer overflow. Instead, you should always
// use the wrapper function pad_size()
#define PAD_SIZE_UNSAFE(s) (((s)+3)&~3)
static size_t pad_size(size_t s) {
if (s > (SIZE_T_MAX - 3)) {
abort();
}
return PAD_SIZE_UNSAFE(s);
}
// Note: must be kept in sync with android/os/StrictMode.java's PENALTY_GATHER
#define STRICT_MODE_PENALTY_GATHER (1 << 31)
// XXX This can be made public if we want to provide
// support for typed data.
struct small_flat_data
{
uint32_t type;
uint32_t data;
};
namespace android {
static pthread_mutex_t gParcelGlobalAllocSizeLock = PTHREAD_MUTEX_INITIALIZER;
static size_t gParcelGlobalAllocSize = 0;
static size_t gParcelGlobalAllocCount = 0;
static size_t gMaxFds = 0;
// Maximum size of a blob to transfer in-place.
static const size_t BLOB_INPLACE_LIMIT = 16 * 1024;
enum {
BLOB_INPLACE = 0,
BLOB_ASHMEM_IMMUTABLE = 1,
BLOB_ASHMEM_MUTABLE = 2,
};
void acquire_object(const sp<ProcessState>& proc,
const flat_binder_object& obj, const void* who, size_t* outAshmemSize)
{
switch (obj.hdr.type) {
case BINDER_TYPE_BINDER:
if (obj.binder) {
LOG_REFS("Parcel %p acquiring reference on local %p", who, obj.cookie);
reinterpret_cast<IBinder*>(obj.cookie)->incStrong(who);
}
return;
case BINDER_TYPE_WEAK_BINDER:
if (obj.binder)
reinterpret_cast<RefBase::weakref_type*>(obj.binder)->incWeak(who);
return;
case BINDER_TYPE_HANDLE: {
const sp<IBinder> b = proc->getStrongProxyForHandle(obj.handle);
if (b != nullptr) {
LOG_REFS("Parcel %p acquiring reference on remote %p", who, b.get());
b->incStrong(who);
}
return;
}
case BINDER_TYPE_WEAK_HANDLE: {
const wp<IBinder> b = proc->getWeakProxyForHandle(obj.handle);
if (b != nullptr) b.get_refs()->incWeak(who);
return;
}
case BINDER_TYPE_FD: {
if ((obj.cookie != 0) && (outAshmemSize != nullptr) && ashmem_valid(obj.handle)) {
// If we own an ashmem fd, keep track of how much memory it refers to.
int size = ashmem_get_size_region(obj.handle);
if (size > 0) {
*outAshmemSize += size;
}
}
return;
}
}
ALOGD("Invalid object type 0x%08x", obj.hdr.type);
}
void acquire_object(const sp<ProcessState>& proc,
const flat_binder_object& obj, const void* who)
{
acquire_object(proc, obj, who, nullptr);
}
static void release_object(const sp<ProcessState>& proc,
const flat_binder_object& obj, const void* who, size_t* outAshmemSize)
{
switch (obj.hdr.type) {
case BINDER_TYPE_BINDER:
if (obj.binder) {
LOG_REFS("Parcel %p releasing reference on local %p", who, obj.cookie);
reinterpret_cast<IBinder*>(obj.cookie)->decStrong(who);
}
return;
case BINDER_TYPE_WEAK_BINDER:
if (obj.binder)
reinterpret_cast<RefBase::weakref_type*>(obj.binder)->decWeak(who);
return;
case BINDER_TYPE_HANDLE: {
const sp<IBinder> b = proc->getStrongProxyForHandle(obj.handle);
if (b != nullptr) {
LOG_REFS("Parcel %p releasing reference on remote %p", who, b.get());
b->decStrong(who);
}
return;
}
case BINDER_TYPE_WEAK_HANDLE: {
const wp<IBinder> b = proc->getWeakProxyForHandle(obj.handle);
if (b != nullptr) b.get_refs()->decWeak(who);
return;
}
case BINDER_TYPE_FD: {
if (obj.cookie != 0) { // owned
if ((outAshmemSize != nullptr) && ashmem_valid(obj.handle)) {
int size = ashmem_get_size_region(obj.handle);
if (size > 0) {
*outAshmemSize -= size;
}
}
close(obj.handle);
}
return;
}
}
ALOGE("Invalid object type 0x%08x", obj.hdr.type);
}
void release_object(const sp<ProcessState>& proc,
const flat_binder_object& obj, const void* who)
{
release_object(proc, obj, who, nullptr);
}
inline static status_t finish_flatten_binder(
const sp<IBinder>& /*binder*/, const flat_binder_object& flat, Parcel* out)
{
return out->writeObject(flat, false);
}
status_t flatten_binder(const sp<ProcessState>& /*proc*/,
const sp<IBinder>& binder, Parcel* out)
{
flat_binder_object obj;
if (IPCThreadState::self()->backgroundSchedulingDisabled()) {
/* minimum priority for all nodes is nice 0 */
obj.flags = FLAT_BINDER_FLAG_ACCEPTS_FDS;
} else {
/* minimum priority for all nodes is MAX_NICE(19) */
obj.flags = 0x13 | FLAT_BINDER_FLAG_ACCEPTS_FDS;
}
if (binder != nullptr) {
BBinder *local = binder->localBinder();
if (!local) {
BpBinder *proxy = binder->remoteBinder();
if (proxy == nullptr) {
ALOGE("null proxy");
}
const int32_t handle = proxy ? proxy->handle() : 0;
obj.hdr.type = BINDER_TYPE_HANDLE;
obj.binder = 0; /* Don't pass uninitialized stack data to a remote process */
obj.handle = handle;
obj.cookie = 0;
} else {
if (local->isRequestingSid()) {
obj.flags |= FLAT_BINDER_FLAG_TXN_SECURITY_CTX;
}
obj.hdr.type = BINDER_TYPE_BINDER;
obj.binder = reinterpret_cast<uintptr_t>(local->getWeakRefs());
obj.cookie = reinterpret_cast<uintptr_t>(local);
}
} else {
obj.hdr.type = BINDER_TYPE_BINDER;
obj.binder = 0;
obj.cookie = 0;
}
return finish_flatten_binder(binder, obj, out);
}
status_t flatten_binder(const sp<ProcessState>& /*proc*/,
const wp<IBinder>& binder, Parcel* out)
{
flat_binder_object obj;
obj.flags = 0x7f | FLAT_BINDER_FLAG_ACCEPTS_FDS;
if (binder != nullptr) {
sp<IBinder> real = binder.promote();
if (real != nullptr) {
IBinder *local = real->localBinder();
if (!local) {
BpBinder *proxy = real->remoteBinder();
if (proxy == nullptr) {
ALOGE("null proxy");
}
const int32_t handle = proxy ? proxy->handle() : 0;
obj.hdr.type = BINDER_TYPE_WEAK_HANDLE;
obj.binder = 0; /* Don't pass uninitialized stack data to a remote process */
obj.handle = handle;
obj.cookie = 0;
} else {
obj.hdr.type = BINDER_TYPE_WEAK_BINDER;
obj.binder = reinterpret_cast<uintptr_t>(binder.get_refs());
obj.cookie = reinterpret_cast<uintptr_t>(binder.unsafe_get());
}
return finish_flatten_binder(real, obj, out);
}
// XXX How to deal? In order to flatten the given binder,
// we need to probe it for information, which requires a primary
// reference... but we don't have one.
//
// The OpenBinder implementation uses a dynamic_cast<> here,
// but we can't do that with the different reference counting
// implementation we are using.
ALOGE("Unable to unflatten Binder weak reference!");
obj.hdr.type = BINDER_TYPE_BINDER;
obj.binder = 0;
obj.cookie = 0;
return finish_flatten_binder(nullptr, obj, out);
} else {
obj.hdr.type = BINDER_TYPE_BINDER;
obj.binder = 0;
obj.cookie = 0;
return finish_flatten_binder(nullptr, obj, out);
}
}
inline static status_t finish_unflatten_binder(
BpBinder* /*proxy*/, const flat_binder_object& /*flat*/,
const Parcel& /*in*/)
{
return NO_ERROR;
}
status_t unflatten_binder(const sp<ProcessState>& proc,
const Parcel& in, sp<IBinder>* out)
{
const flat_binder_object* flat = in.readObject(false);
if (flat) {
switch (flat->hdr.type) {
case BINDER_TYPE_BINDER:
*out = reinterpret_cast<IBinder*>(flat->cookie);
return finish_unflatten_binder(nullptr, *flat, in);
case BINDER_TYPE_HANDLE:
*out = proc->getStrongProxyForHandle(flat->handle);
return finish_unflatten_binder(
static_cast<BpBinder*>(out->get()), *flat, in);
}
}
return BAD_TYPE;
}
status_t unflatten_binder(const sp<ProcessState>& proc,
const Parcel& in, wp<IBinder>* out)
{
const flat_binder_object* flat = in.readObject(false);
if (flat) {
switch (flat->hdr.type) {
case BINDER_TYPE_BINDER:
*out = reinterpret_cast<IBinder*>(flat->cookie);
return finish_unflatten_binder(nullptr, *flat, in);
case BINDER_TYPE_WEAK_BINDER:
if (flat->binder != 0) {
out->set_object_and_refs(
reinterpret_cast<IBinder*>(flat->cookie),
reinterpret_cast<RefBase::weakref_type*>(flat->binder));
} else {
*out = nullptr;
}
return finish_unflatten_binder(nullptr, *flat, in);
case BINDER_TYPE_HANDLE:
case BINDER_TYPE_WEAK_HANDLE:
*out = proc->getWeakProxyForHandle(flat->handle);
return finish_unflatten_binder(
static_cast<BpBinder*>(out->unsafe_get()), *flat, in);
}
}
return BAD_TYPE;
}
// ---------------------------------------------------------------------------
Parcel::Parcel()
{
LOG_ALLOC("Parcel %p: constructing", this);
initState();
}
Parcel::~Parcel()
{
freeDataNoInit();
LOG_ALLOC("Parcel %p: destroyed", this);
}
size_t Parcel::getGlobalAllocSize() {
pthread_mutex_lock(&gParcelGlobalAllocSizeLock);
size_t size = gParcelGlobalAllocSize;
pthread_mutex_unlock(&gParcelGlobalAllocSizeLock);
return size;
}
size_t Parcel::getGlobalAllocCount() {
pthread_mutex_lock(&gParcelGlobalAllocSizeLock);
size_t count = gParcelGlobalAllocCount;
pthread_mutex_unlock(&gParcelGlobalAllocSizeLock);
return count;
}
const uint8_t* Parcel::data() const
{
return mData;
}
size_t Parcel::dataSize() const
{
return (mDataSize > mDataPos ? mDataSize : mDataPos);
}
size_t Parcel::dataAvail() const
{
size_t result = dataSize() - dataPosition();
if (result > INT32_MAX) {
abort();
}
return result;
}
size_t Parcel::dataPosition() const
{
return mDataPos;
}
size_t Parcel::dataCapacity() const
{
return mDataCapacity;
}
status_t Parcel::setDataSize(size_t size)
{
if (size > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return BAD_VALUE;
}
status_t err;
err = continueWrite(size);
if (err == NO_ERROR) {
mDataSize = size;
ALOGV("setDataSize Setting data size of %p to %zu", this, mDataSize);
}
return err;
}
void Parcel::setDataPosition(size_t pos) const
{
if (pos > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
abort();
}
mDataPos = pos;
mNextObjectHint = 0;
mObjectsSorted = false;
}
status_t Parcel::setDataCapacity(size_t size)
{
if (size > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return BAD_VALUE;
}
if (size > mDataCapacity) return continueWrite(size);
return NO_ERROR;
}
status_t Parcel::setData(const uint8_t* buffer, size_t len)
{
if (len > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return BAD_VALUE;
}
status_t err = restartWrite(len);
if (err == NO_ERROR) {
memcpy(const_cast<uint8_t*>(data()), buffer, len);
mDataSize = len;
mFdsKnown = false;
}
return err;
}
status_t Parcel::appendFrom(const Parcel *parcel, size_t offset, size_t len)
{
status_t err;
const uint8_t *data = parcel->mData;
const binder_size_t *objects = parcel->mObjects;
size_t size = parcel->mObjectsSize;
int startPos = mDataPos;
int firstIndex = -1, lastIndex = -2;
if (len == 0) {
return NO_ERROR;
}
if (len > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return BAD_VALUE;
}
// range checks against the source parcel size
if ((offset > parcel->mDataSize)
|| (len > parcel->mDataSize)
|| (offset + len > parcel->mDataSize)) {
return BAD_VALUE;
}
// Count objects in range
for (int i = 0; i < (int) size; i++) {
size_t off = objects[i];
if ((off >= offset) && (off + sizeof(flat_binder_object) <= offset + len)) {
if (firstIndex == -1) {
firstIndex = i;
}
lastIndex = i;
}
}
int numObjects = lastIndex - firstIndex + 1;
if ((mDataSize+len) > mDataCapacity) {
// grow data
err = growData(len);
if (err != NO_ERROR) {
return err;
}
}
// append data
memcpy(mData + mDataPos, data + offset, len);
mDataPos += len;
mDataSize += len;
err = NO_ERROR;
if (numObjects > 0) {
const sp<ProcessState> proc(ProcessState::self());
// grow objects
if (mObjectsCapacity < mObjectsSize + numObjects) {
size_t newSize = ((mObjectsSize + numObjects)*3)/2;
if (newSize*sizeof(binder_size_t) < mObjectsSize) return NO_MEMORY; // overflow
binder_size_t *objects =
(binder_size_t*)realloc(mObjects, newSize*sizeof(binder_size_t));
if (objects == (binder_size_t*)nullptr) {
return NO_MEMORY;
}
mObjects = objects;
mObjectsCapacity = newSize;
}
// append and acquire objects
int idx = mObjectsSize;
for (int i = firstIndex; i <= lastIndex; i++) {
size_t off = objects[i] - offset + startPos;
mObjects[idx++] = off;
mObjectsSize++;
flat_binder_object* flat
= reinterpret_cast<flat_binder_object*>(mData + off);
acquire_object(proc, *flat, this, &mOpenAshmemSize);
if (flat->hdr.type == BINDER_TYPE_FD) {
// If this is a file descriptor, we need to dup it so the
// new Parcel now owns its own fd, and can declare that we
// officially know we have fds.
flat->handle = fcntl(flat->handle, F_DUPFD_CLOEXEC, 0);
flat->cookie = 1;
mHasFds = mFdsKnown = true;
if (!mAllowFds) {
err = FDS_NOT_ALLOWED;
}
}
}
}
return err;
}
int Parcel::compareData(const Parcel& other) {
size_t size = dataSize();
if (size != other.dataSize()) {
return size < other.dataSize() ? -1 : 1;
}
return memcmp(data(), other.data(), size);
}
bool Parcel::allowFds() const
{
return mAllowFds;
}
bool Parcel::pushAllowFds(bool allowFds)
{
const bool origValue = mAllowFds;
if (!allowFds) {
mAllowFds = false;
}
return origValue;
}
void Parcel::restoreAllowFds(bool lastValue)
{
mAllowFds = lastValue;
}
bool Parcel::hasFileDescriptors() const
{
if (!mFdsKnown) {
scanForFds();
}
return mHasFds;
}
// Write RPC headers. (previously just the interface token)
status_t Parcel::writeInterfaceToken(const String16& interface)
{
const IPCThreadState* threadState = IPCThreadState::self();
writeInt32(threadState->getStrictModePolicy() | STRICT_MODE_PENALTY_GATHER);
writeInt32(threadState->shouldPropagateWorkSource() ?
threadState->getCallingWorkSourceUid() : IPCThreadState::kUnsetWorkSource);
// currently the interface identification token is just its name as a string
return writeString16(interface);
}
bool Parcel::checkInterface(IBinder* binder) const
{
return enforceInterface(binder->getInterfaceDescriptor());
}
bool Parcel::enforceInterface(const String16& interface,
IPCThreadState* threadState) const
{
// StrictModePolicy.
int32_t strictPolicy = readInt32();
if (threadState == nullptr) {
threadState = IPCThreadState::self();
}
if ((threadState->getLastTransactionBinderFlags() &
IBinder::FLAG_ONEWAY) != 0) {
// For one-way calls, the callee is running entirely
// disconnected from the caller, so disable StrictMode entirely.
// Not only does disk/network usage not impact the caller, but
// there's no way to commuicate back any violations anyway.
threadState->setStrictModePolicy(0);
} else {
threadState->setStrictModePolicy(strictPolicy);
}
// WorkSource.
int32_t workSource = readInt32();
threadState->setCallingWorkSourceUidWithoutPropagation(workSource);
// Interface descriptor.
const String16 str(readString16());
if (str == interface) {
return true;
} else {
ALOGW("**** enforceInterface() expected '%s' but read '%s'",
String8(interface).string(), String8(str).string());
return false;
}
}
const binder_size_t* Parcel::objects() const
{
return mObjects;
}
size_t Parcel::objectsCount() const
{
return mObjectsSize;
}
status_t Parcel::errorCheck() const
{
return mError;
}
void Parcel::setError(status_t err)
{
mError = err;
}
status_t Parcel::finishWrite(size_t len)
{
if (len > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return BAD_VALUE;
}
//printf("Finish write of %d\n", len);
mDataPos += len;
ALOGV("finishWrite Setting data pos of %p to %zu", this, mDataPos);
if (mDataPos > mDataSize) {
mDataSize = mDataPos;
ALOGV("finishWrite Setting data size of %p to %zu", this, mDataSize);
}
//printf("New pos=%d, size=%d\n", mDataPos, mDataSize);
return NO_ERROR;
}
status_t Parcel::writeUnpadded(const void* data, size_t len)
{
if (len > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return BAD_VALUE;
}
size_t end = mDataPos + len;
if (end < mDataPos) {
// integer overflow
return BAD_VALUE;
}
if (end <= mDataCapacity) {
restart_write:
memcpy(mData+mDataPos, data, len);
return finishWrite(len);
}
status_t err = growData(len);
if (err == NO_ERROR) goto restart_write;
return err;
}
status_t Parcel::write(const void* data, size_t len)
{
if (len > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return BAD_VALUE;
}
void* const d = writeInplace(len);
if (d) {
memcpy(d, data, len);
return NO_ERROR;
}
return mError;
}
void* Parcel::writeInplace(size_t len)
{
if (len > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return nullptr;
}
const size_t padded = pad_size(len);
// sanity check for integer overflow
if (mDataPos+padded < mDataPos) {
return nullptr;
}
if ((mDataPos+padded) <= mDataCapacity) {
restart_write:
//printf("Writing %ld bytes, padded to %ld\n", len, padded);
uint8_t* const data = mData+mDataPos;
// Need to pad at end?
if (padded != len) {
#if BYTE_ORDER == BIG_ENDIAN
static const uint32_t mask[4] = {
0x00000000, 0xffffff00, 0xffff0000, 0xff000000
};
#endif
#if BYTE_ORDER == LITTLE_ENDIAN
static const uint32_t mask[4] = {
0x00000000, 0x00ffffff, 0x0000ffff, 0x000000ff
};
#endif
//printf("Applying pad mask: %p to %p\n", (void*)mask[padded-len],
// *reinterpret_cast<void**>(data+padded-4));
*reinterpret_cast<uint32_t*>(data+padded-4) &= mask[padded-len];
}
finishWrite(padded);
return data;
}
status_t err = growData(padded);
if (err == NO_ERROR) goto restart_write;
return nullptr;
}
status_t Parcel::writeUtf8AsUtf16(const std::string& str) {
const uint8_t* strData = (uint8_t*)str.data();
const size_t strLen= str.length();
const ssize_t utf16Len = utf8_to_utf16_length(strData, strLen);
if (utf16Len < 0 || utf16Len > std::numeric_limits<int32_t>::max()) {
return BAD_VALUE;
}
status_t err = writeInt32(utf16Len);
if (err) {
return err;
}
// Allocate enough bytes to hold our converted string and its terminating NULL.
void* dst = writeInplace((utf16Len + 1) * sizeof(char16_t));
if (!dst) {
return NO_MEMORY;
}
utf8_to_utf16(strData, strLen, (char16_t*)dst, (size_t) utf16Len + 1);
return NO_ERROR;
}
status_t Parcel::writeUtf8AsUtf16(const std::unique_ptr<std::string>& str) {
if (!str) {
return writeInt32(-1);
}
return writeUtf8AsUtf16(*str);
}
namespace {
template<typename T>
status_t writeByteVectorInternal(Parcel* parcel, const std::vector<T>& val)
{
status_t status;
if (val.size() > std::numeric_limits<int32_t>::max()) {
status = BAD_VALUE;
return status;
}
status = parcel->writeInt32(val.size());
if (status != OK) {
return status;
}
void* data = parcel->writeInplace(val.size());
if (!data) {
status = BAD_VALUE;
return status;
}
memcpy(data, val.data(), val.size());
return status;
}
template<typename T>
status_t writeByteVectorInternalPtr(Parcel* parcel,
const std::unique_ptr<std::vector<T>>& val)
{
if (!val) {
return parcel->writeInt32(-1);
}
return writeByteVectorInternal(parcel, *val);
}
} // namespace
status_t Parcel::writeByteVector(const std::vector<int8_t>& val) {
return writeByteVectorInternal(this, val);
}
status_t Parcel::writeByteVector(const std::unique_ptr<std::vector<int8_t>>& val)
{
return writeByteVectorInternalPtr(this, val);
}
status_t Parcel::writeByteVector(const std::vector<uint8_t>& val) {
return writeByteVectorInternal(this, val);
}
status_t Parcel::writeByteVector(const std::unique_ptr<std::vector<uint8_t>>& val)
{
return writeByteVectorInternalPtr(this, val);
}
status_t Parcel::writeInt32Vector(const std::vector<int32_t>& val)
{
return writeTypedVector(val, &Parcel::writeInt32);
}
status_t Parcel::writeInt32Vector(const std::unique_ptr<std::vector<int32_t>>& val)
{
return writeNullableTypedVector(val, &Parcel::writeInt32);
}
status_t Parcel::writeInt64Vector(const std::vector<int64_t>& val)
{
return writeTypedVector(val, &Parcel::writeInt64);
}
status_t Parcel::writeInt64Vector(const std::unique_ptr<std::vector<int64_t>>& val)
{
return writeNullableTypedVector(val, &Parcel::writeInt64);
}
status_t Parcel::writeUint64Vector(const std::vector<uint64_t>& val)
{
return writeTypedVector(val, &Parcel::writeUint64);
}
status_t Parcel::writeUint64Vector(const std::unique_ptr<std::vector<uint64_t>>& val)
{
return writeNullableTypedVector(val, &Parcel::writeUint64);
}
status_t Parcel::writeFloatVector(const std::vector<float>& val)
{
return writeTypedVector(val, &Parcel::writeFloat);
}
status_t Parcel::writeFloatVector(const std::unique_ptr<std::vector<float>>& val)
{
return writeNullableTypedVector(val, &Parcel::writeFloat);
}
status_t Parcel::writeDoubleVector(const std::vector<double>& val)
{
return writeTypedVector(val, &Parcel::writeDouble);
}
status_t Parcel::writeDoubleVector(const std::unique_ptr<std::vector<double>>& val)
{
return writeNullableTypedVector(val, &Parcel::writeDouble);
}
status_t Parcel::writeBoolVector(const std::vector<bool>& val)
{
return writeTypedVector(val, &Parcel::writeBool);
}
status_t Parcel::writeBoolVector(const std::unique_ptr<std::vector<bool>>& val)
{
return writeNullableTypedVector(val, &Parcel::writeBool);
}
status_t Parcel::writeCharVector(const std::vector<char16_t>& val)
{
return writeTypedVector(val, &Parcel::writeChar);
}
status_t Parcel::writeCharVector(const std::unique_ptr<std::vector<char16_t>>& val)
{
return writeNullableTypedVector(val, &Parcel::writeChar);
}
status_t Parcel::writeString16Vector(const std::vector<String16>& val)
{
return writeTypedVector(val, &Parcel::writeString16);
}
status_t Parcel::writeString16Vector(
const std::unique_ptr<std::vector<std::unique_ptr<String16>>>& val)
{
return writeNullableTypedVector(val, &Parcel::writeString16);
}
status_t Parcel::writeUtf8VectorAsUtf16Vector(
const std::unique_ptr<std::vector<std::unique_ptr<std::string>>>& val) {
return writeNullableTypedVector(val, &Parcel::writeUtf8AsUtf16);
}
status_t Parcel::writeUtf8VectorAsUtf16Vector(const std::vector<std::string>& val) {
return writeTypedVector(val, &Parcel::writeUtf8AsUtf16);
}
status_t Parcel::writeInt32(int32_t val)
{
return writeAligned(val);
}
status_t Parcel::writeUint32(uint32_t val)
{
return writeAligned(val);
}
status_t Parcel::writeInt32Array(size_t len, const int32_t *val) {
if (len > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return BAD_VALUE;
}
if (!val) {
return writeInt32(-1);
}
status_t ret = writeInt32(static_cast<uint32_t>(len));
if (ret == NO_ERROR) {
ret = write(val, len * sizeof(*val));
}
return ret;
}
status_t Parcel::writeByteArray(size_t len, const uint8_t *val) {
if (len > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return BAD_VALUE;
}
if (!val) {
return writeInt32(-1);
}
status_t ret = writeInt32(static_cast<uint32_t>(len));
if (ret == NO_ERROR) {
ret = write(val, len * sizeof(*val));
}
return ret;
}
status_t Parcel::writeBool(bool val)
{
return writeInt32(int32_t(val));
}
status_t Parcel::writeChar(char16_t val)
{
return writeInt32(int32_t(val));
}
status_t Parcel::writeByte(int8_t val)
{
return writeInt32(int32_t(val));
}
status_t Parcel::writeInt64(int64_t val)
{
return writeAligned(val);
}
status_t Parcel::writeUint64(uint64_t val)
{
return writeAligned(val);
}
status_t Parcel::writePointer(uintptr_t val)
{
return writeAligned<binder_uintptr_t>(val);
}
status_t Parcel::writeFloat(float val)
{
return writeAligned(val);
}
#if defined(__mips__) && defined(__mips_hard_float)
status_t Parcel::writeDouble(double val)
{
union {
double d;
unsigned long long ll;
} u;
u.d = val;
return writeAligned(u.ll);
}
#else
status_t Parcel::writeDouble(double val)
{
return writeAligned(val);
}
#endif
status_t Parcel::writeCString(const char* str)
{
return write(str, strlen(str)+1);
}
status_t Parcel::writeString8(const String8& str)
{
status_t err = writeInt32(str.bytes());
// only write string if its length is more than zero characters,
// as readString8 will only read if the length field is non-zero.
// this is slightly different from how writeString16 works.
if (str.bytes() > 0 && err == NO_ERROR) {
err = write(str.string(), str.bytes()+1);
}
return err;
}
status_t Parcel::writeString16(const std::unique_ptr<String16>& str)
{
if (!str) {
return writeInt32(-1);
}
return writeString16(*str);
}
status_t Parcel::writeString16(const String16& str)
{
return writeString16(str.string(), str.size());
}
status_t Parcel::writeString16(const char16_t* str, size_t len)
{
if (str == nullptr) return writeInt32(-1);
status_t err = writeInt32(len);
if (err == NO_ERROR) {
len *= sizeof(char16_t);
uint8_t* data = (uint8_t*)writeInplace(len+sizeof(char16_t));
if (data) {
memcpy(data, str, len);
*reinterpret_cast<char16_t*>(data+len) = 0;
return NO_ERROR;
}
err = mError;
}
return err;
}
status_t Parcel::writeStrongBinder(const sp<IBinder>& val)
{
return flatten_binder(ProcessState::self(), val, this);
}
status_t Parcel::writeStrongBinderVector(const std::vector<sp<IBinder>>& val)
{
return writeTypedVector(val, &Parcel::writeStrongBinder);
}
status_t Parcel::writeStrongBinderVector(const std::unique_ptr<std::vector<sp<IBinder>>>& val)
{
return writeNullableTypedVector(val, &Parcel::writeStrongBinder);
}
status_t Parcel::readStrongBinderVector(std::unique_ptr<std::vector<sp<IBinder>>>* val) const {
return readNullableTypedVector(val, &Parcel::readNullableStrongBinder);
}
status_t Parcel::readStrongBinderVector(std::vector<sp<IBinder>>* val) const {
return readTypedVector(val, &Parcel::readStrongBinder);
}
status_t Parcel::writeWeakBinder(const wp<IBinder>& val)
{
return flatten_binder(ProcessState::self(), val, this);
}
status_t Parcel::writeRawNullableParcelable(const Parcelable* parcelable) {
if (!parcelable) {
return writeInt32(0);
}
return writeParcelable(*parcelable);
}
status_t Parcel::writeParcelable(const Parcelable& parcelable) {
status_t status = writeInt32(1); // parcelable is not null.
if (status != OK) {
return status;
}
return parcelable.writeToParcel(this);
}
status_t Parcel::writeValue(const binder::Value& value) {
return value.writeToParcel(this);
}
status_t Parcel::writeNativeHandle(const native_handle* handle)
{
if (!handle || handle->version != sizeof(native_handle))
return BAD_TYPE;
status_t err;
err = writeInt32(handle->numFds);
if (err != NO_ERROR) return err;
err = writeInt32(handle->numInts);
if (err != NO_ERROR) return err;
for (int i=0 ; err==NO_ERROR && i<handle->numFds ; i++)
err = writeDupFileDescriptor(handle->data[i]);
if (err != NO_ERROR) {
ALOGD("write native handle, write dup fd failed");
return err;
}
err = write(handle->data + handle->numFds, sizeof(int)*handle->numInts);
return err;
}
status_t Parcel::writeFileDescriptor(int fd, bool takeOwnership)
{
flat_binder_object obj;
obj.hdr.type = BINDER_TYPE_FD;
obj.flags = 0x7f | FLAT_BINDER_FLAG_ACCEPTS_FDS;
obj.binder = 0; /* Don't pass uninitialized stack data to a remote process */
obj.handle = fd;
obj.cookie = takeOwnership ? 1 : 0;
return writeObject(obj, true);
}
status_t Parcel::writeDupFileDescriptor(int fd)
{
int dupFd = fcntl(fd, F_DUPFD_CLOEXEC, 0);
if (dupFd < 0) {
return -errno;
}
status_t err = writeFileDescriptor(dupFd, true /*takeOwnership*/);
if (err != OK) {
close(dupFd);
}
return err;
}
status_t Parcel::writeParcelFileDescriptor(int fd, bool takeOwnership)
{
writeInt32(0);
return writeFileDescriptor(fd, takeOwnership);
}
status_t Parcel::writeDupParcelFileDescriptor(int fd)
{
int dupFd = fcntl(fd, F_DUPFD_CLOEXEC, 0);
if (dupFd < 0) {
return -errno;
}
status_t err = writeParcelFileDescriptor(dupFd, true /*takeOwnership*/);
if (err != OK) {
close(dupFd);
}
return err;
}
status_t Parcel::writeUniqueFileDescriptor(const base::unique_fd& fd) {
return writeDupFileDescriptor(fd.get());
}
status_t Parcel::writeUniqueFileDescriptorVector(const std::vector<base::unique_fd>& val) {
return writeTypedVector(val, &Parcel::writeUniqueFileDescriptor);
}
status_t Parcel::writeUniqueFileDescriptorVector(const std::unique_ptr<std::vector<base::unique_fd>>& val) {
return writeNullableTypedVector(val, &Parcel::writeUniqueFileDescriptor);
}
status_t Parcel::writeBlob(size_t len, bool mutableCopy, WritableBlob* outBlob)
{
if (len > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return BAD_VALUE;
}
status_t status;
if (!mAllowFds || len <= BLOB_INPLACE_LIMIT) {
ALOGV("writeBlob: write in place");
status = writeInt32(BLOB_INPLACE);
if (status) return status;
void* ptr = writeInplace(len);
if (!ptr) return NO_MEMORY;
outBlob->init(-1, ptr, len, false);
return NO_ERROR;
}
ALOGV("writeBlob: write to ashmem");
int fd = ashmem_create_region("Parcel Blob", len);
if (fd < 0) return NO_MEMORY;
int result = ashmem_set_prot_region(fd, PROT_READ | PROT_WRITE);
if (result < 0) {
status = result;
} else {
void* ptr = ::mmap(nullptr, len, PROT_READ | PROT_WRITE, MAP_SHARED, fd, 0);
if (ptr == MAP_FAILED) {
status = -errno;
} else {
if (!mutableCopy) {
result = ashmem_set_prot_region(fd, PROT_READ);
}
if (result < 0) {
status = result;
} else {
status = writeInt32(mutableCopy ? BLOB_ASHMEM_MUTABLE : BLOB_ASHMEM_IMMUTABLE);
if (!status) {
status = writeFileDescriptor(fd, true /*takeOwnership*/);
if (!status) {
outBlob->init(fd, ptr, len, mutableCopy);
return NO_ERROR;
}
}
}
}
::munmap(ptr, len);
}
::close(fd);
return status;
}
status_t Parcel::writeDupImmutableBlobFileDescriptor(int fd)
{
// Must match up with what's done in writeBlob.
if (!mAllowFds) return FDS_NOT_ALLOWED;
status_t status = writeInt32(BLOB_ASHMEM_IMMUTABLE);
if (status) return status;
return writeDupFileDescriptor(fd);
}
status_t Parcel::write(const FlattenableHelperInterface& val)
{
status_t err;
// size if needed
const size_t len = val.getFlattenedSize();
const size_t fd_count = val.getFdCount();
if ((len > INT32_MAX) || (fd_count >= gMaxFds)) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return BAD_VALUE;
}
err = this->writeInt32(len);
if (err) return err;
err = this->writeInt32(fd_count);
if (err) return err;
// payload
void* const buf = this->writeInplace(len);
if (buf == nullptr)
return BAD_VALUE;
int* fds = nullptr;
if (fd_count) {
fds = new (std::nothrow) int[fd_count];
if (fds == nullptr) {
ALOGE("write: failed to allocate requested %zu fds", fd_count);
return BAD_VALUE;
}
}
err = val.flatten(buf, len, fds, fd_count);
for (size_t i=0 ; i<fd_count && err==NO_ERROR ; i++) {
err = this->writeDupFileDescriptor( fds[i] );
}
if (fd_count) {
delete [] fds;
}
return err;
}
status_t Parcel::writeObject(const flat_binder_object& val, bool nullMetaData)
{
const bool enoughData = (mDataPos+sizeof(val)) <= mDataCapacity;
const bool enoughObjects = mObjectsSize < mObjectsCapacity;
if (enoughData && enoughObjects) {
restart_write:
*reinterpret_cast<flat_binder_object*>(mData+mDataPos) = val;
// remember if it's a file descriptor
if (val.hdr.type == BINDER_TYPE_FD) {
if (!mAllowFds) {
// fail before modifying our object index
return FDS_NOT_ALLOWED;
}
mHasFds = mFdsKnown = true;
}
// Need to write meta-data?
if (nullMetaData || val.binder != 0) {
mObjects[mObjectsSize] = mDataPos;
acquire_object(ProcessState::self(), val, this, &mOpenAshmemSize);
mObjectsSize++;
}
return finishWrite(sizeof(flat_binder_object));
}
if (!enoughData) {
const status_t err = growData(sizeof(val));
if (err != NO_ERROR) return err;
}
if (!enoughObjects) {
size_t newSize = ((mObjectsSize+2)*3)/2;
if (newSize*sizeof(binder_size_t) < mObjectsSize) return NO_MEMORY; // overflow
binder_size_t* objects = (binder_size_t*)realloc(mObjects, newSize*sizeof(binder_size_t));
if (objects == nullptr) return NO_MEMORY;
mObjects = objects;
mObjectsCapacity = newSize;
}
goto restart_write;
}
status_t Parcel::writeNoException()
{
binder::Status status;
return status.writeToParcel(this);
}
status_t Parcel::writeMap(const ::android::binder::Map& map_in)
{
using ::std::map;
using ::android::binder::Value;
using ::android::binder::Map;
Map::const_iterator iter;
status_t ret;
ret = writeInt32(map_in.size());
if (ret != NO_ERROR) {
return ret;
}
for (iter = map_in.begin(); iter != map_in.end(); ++iter) {
ret = writeValue(Value(iter->first));
if (ret != NO_ERROR) {
return ret;
}
ret = writeValue(iter->second);
if (ret != NO_ERROR) {
return ret;
}
}
return ret;
}
status_t Parcel::writeNullableMap(const std::unique_ptr<binder::Map>& map)
{
if (map == nullptr) {
return writeInt32(-1);
}
return writeMap(*map.get());
}
status_t Parcel::readMap(::android::binder::Map* map_out)const
{
using ::std::map;
using ::android::String16;
using ::android::String8;
using ::android::binder::Value;
using ::android::binder::Map;
status_t ret = NO_ERROR;
int32_t count;
ret = readInt32(&count);
if (ret != NO_ERROR) {
return ret;
}
if (count < 0) {
ALOGE("readMap: Unexpected count: %d", count);
return (count == -1)
? UNEXPECTED_NULL
: BAD_VALUE;
}
map_out->clear();
while (count--) {
Map::key_type key;
Value value;
ret = readValue(&value);
if (ret != NO_ERROR) {
return ret;
}
if (!value.getString(&key)) {
ALOGE("readMap: Key type not a string (parcelType = %d)", value.parcelType());
return BAD_VALUE;
}
ret = readValue(&value);
if (ret != NO_ERROR) {
return ret;
}
(*map_out)[key] = value;
}
return ret;
}
status_t Parcel::readNullableMap(std::unique_ptr<binder::Map>* map) const
{
const size_t start = dataPosition();
int32_t count;
status_t status = readInt32(&count);
map->reset();
if (status != OK || count == -1) {
return status;
}
setDataPosition(start);
map->reset(new binder::Map());
status = readMap(map->get());
if (status != OK) {
map->reset();
}
return status;
}
void Parcel::remove(size_t /*start*/, size_t /*amt*/)
{
LOG_ALWAYS_FATAL("Parcel::remove() not yet implemented!");
}
status_t Parcel::validateReadData(size_t upperBound) const
{
// Don't allow non-object reads on object data
if (mObjectsSorted || mObjectsSize <= 1) {
data_sorted:
// Expect to check only against the next object
if (mNextObjectHint < mObjectsSize && upperBound > mObjects[mNextObjectHint]) {
// For some reason the current read position is greater than the next object
// hint. Iterate until we find the right object
size_t nextObject = mNextObjectHint;
do {
if (mDataPos < mObjects[nextObject] + sizeof(flat_binder_object)) {
// Requested info overlaps with an object
ALOGE("Attempt to read from protected data in Parcel %p", this);
return PERMISSION_DENIED;
}
nextObject++;
} while (nextObject < mObjectsSize && upperBound > mObjects[nextObject]);
mNextObjectHint = nextObject;
}
return NO_ERROR;
}
// Quickly determine if mObjects is sorted.
binder_size_t* currObj = mObjects + mObjectsSize - 1;
binder_size_t* prevObj = currObj;
while (currObj > mObjects) {
prevObj--;
if(*prevObj > *currObj) {
goto data_unsorted;
}
currObj--;
}
mObjectsSorted = true;
goto data_sorted;
data_unsorted:
// Insertion Sort mObjects
// Great for mostly sorted lists. If randomly sorted or reverse ordered mObjects become common,
// switch to std::sort(mObjects, mObjects + mObjectsSize);
for (binder_size_t* iter0 = mObjects + 1; iter0 < mObjects + mObjectsSize; iter0++) {
binder_size_t temp = *iter0;
binder_size_t* iter1 = iter0 - 1;
while (iter1 >= mObjects && *iter1 > temp) {
*(iter1 + 1) = *iter1;
iter1--;
}
*(iter1 + 1) = temp;
}
mNextObjectHint = 0;
mObjectsSorted = true;
goto data_sorted;
}
status_t Parcel::read(void* outData, size_t len) const
{
if (len > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return BAD_VALUE;
}
if ((mDataPos+pad_size(len)) >= mDataPos && (mDataPos+pad_size(len)) <= mDataSize
&& len <= pad_size(len)) {
if (mObjectsSize > 0) {
status_t err = validateReadData(mDataPos + pad_size(len));
if(err != NO_ERROR) {
// Still increment the data position by the expected length
mDataPos += pad_size(len);
ALOGV("read Setting data pos of %p to %zu", this, mDataPos);
return err;
}
}
memcpy(outData, mData+mDataPos, len);
mDataPos += pad_size(len);
ALOGV("read Setting data pos of %p to %zu", this, mDataPos);
return NO_ERROR;
}
return NOT_ENOUGH_DATA;
}
const void* Parcel::readInplace(size_t len) const
{
if (len > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return nullptr;
}
if ((mDataPos+pad_size(len)) >= mDataPos && (mDataPos+pad_size(len)) <= mDataSize
&& len <= pad_size(len)) {
if (mObjectsSize > 0) {
status_t err = validateReadData(mDataPos + pad_size(len));
if(err != NO_ERROR) {
// Still increment the data position by the expected length
mDataPos += pad_size(len);
ALOGV("readInplace Setting data pos of %p to %zu", this, mDataPos);
return nullptr;
}
}
const void* data = mData+mDataPos;
mDataPos += pad_size(len);
ALOGV("readInplace Setting data pos of %p to %zu", this, mDataPos);
return data;
}
return nullptr;
}
template<class T>
status_t Parcel::readAligned(T *pArg) const {
COMPILE_TIME_ASSERT_FUNCTION_SCOPE(PAD_SIZE_UNSAFE(sizeof(T)) == sizeof(T));
if ((mDataPos+sizeof(T)) <= mDataSize) {
if (mObjectsSize > 0) {
status_t err = validateReadData(mDataPos + sizeof(T));
if(err != NO_ERROR) {
// Still increment the data position by the expected length
mDataPos += sizeof(T);
return err;
}
}
const void* data = mData+mDataPos;
mDataPos += sizeof(T);
*pArg = *reinterpret_cast<const T*>(data);
return NO_ERROR;
} else {
return NOT_ENOUGH_DATA;
}
}
template<class T>
T Parcel::readAligned() const {
T result;
if (readAligned(&result) != NO_ERROR) {
result = 0;
}
return result;
}
template<class T>
status_t Parcel::writeAligned(T val) {
COMPILE_TIME_ASSERT_FUNCTION_SCOPE(PAD_SIZE_UNSAFE(sizeof(T)) == sizeof(T));
if ((mDataPos+sizeof(val)) <= mDataCapacity) {
restart_write:
*reinterpret_cast<T*>(mData+mDataPos) = val;
return finishWrite(sizeof(val));
}
status_t err = growData(sizeof(val));
if (err == NO_ERROR) goto restart_write;
return err;
}
namespace {
template<typename T>
status_t readByteVectorInternal(const Parcel* parcel,
std::vector<T>* val) {
val->clear();
int32_t size;
status_t status = parcel->readInt32(&size);
if (status != OK) {
return status;
}
if (size < 0) {
status = UNEXPECTED_NULL;
return status;
}
if (size_t(size) > parcel->dataAvail()) {
status = BAD_VALUE;
return status;
}
T* data = const_cast<T*>(reinterpret_cast<const T*>(parcel->readInplace(size)));
if (!data) {
status = BAD_VALUE;
return status;
}
val->reserve(size);
val->insert(val->end(), data, data + size);
return status;
}
template<typename T>
status_t readByteVectorInternalPtr(
const Parcel* parcel,
std::unique_ptr<std::vector<T>>* val) {
const int32_t start = parcel->dataPosition();
int32_t size;
status_t status = parcel->readInt32(&size);
val->reset();
if (status != OK || size < 0) {
return status;
}
parcel->setDataPosition(start);
val->reset(new (std::nothrow) std::vector<T>());
status = readByteVectorInternal(parcel, val->get());
if (status != OK) {
val->reset();
}
return status;
}
} // namespace
status_t Parcel::readByteVector(std::vector<int8_t>* val) const {
return readByteVectorInternal(this, val);
}
status_t Parcel::readByteVector(std::vector<uint8_t>* val) const {
return readByteVectorInternal(this, val);
}
status_t Parcel::readByteVector(std::unique_ptr<std::vector<int8_t>>* val) const {
return readByteVectorInternalPtr(this, val);
}
status_t Parcel::readByteVector(std::unique_ptr<std::vector<uint8_t>>* val) const {
return readByteVectorInternalPtr(this, val);
}
status_t Parcel::readInt32Vector(std::unique_ptr<std::vector<int32_t>>* val) const {
return readNullableTypedVector(val, &Parcel::readInt32);
}
status_t Parcel::readInt32Vector(std::vector<int32_t>* val) const {
return readTypedVector(val, &Parcel::readInt32);
}
status_t Parcel::readInt64Vector(std::unique_ptr<std::vector<int64_t>>* val) const {
return readNullableTypedVector(val, &Parcel::readInt64);
}
status_t Parcel::readInt64Vector(std::vector<int64_t>* val) const {
return readTypedVector(val, &Parcel::readInt64);
}
status_t Parcel::readUint64Vector(std::unique_ptr<std::vector<uint64_t>>* val) const {
return readNullableTypedVector(val, &Parcel::readUint64);
}
status_t Parcel::readUint64Vector(std::vector<uint64_t>* val) const {
return readTypedVector(val, &Parcel::readUint64);
}
status_t Parcel::readFloatVector(std::unique_ptr<std::vector<float>>* val) const {
return readNullableTypedVector(val, &Parcel::readFloat);
}
status_t Parcel::readFloatVector(std::vector<float>* val) const {
return readTypedVector(val, &Parcel::readFloat);
}
status_t Parcel::readDoubleVector(std::unique_ptr<std::vector<double>>* val) const {
return readNullableTypedVector(val, &Parcel::readDouble);
}
status_t Parcel::readDoubleVector(std::vector<double>* val) const {
return readTypedVector(val, &Parcel::readDouble);
}
status_t Parcel::readBoolVector(std::unique_ptr<std::vector<bool>>* val) const {
const int32_t start = dataPosition();
int32_t size;
status_t status = readInt32(&size);
val->reset();
if (status != OK || size < 0) {
return status;
}
setDataPosition(start);
val->reset(new (std::nothrow) std::vector<bool>());
status = readBoolVector(val->get());
if (status != OK) {
val->reset();
}
return status;
}
status_t Parcel::readBoolVector(std::vector<bool>* val) const {
int32_t size;
status_t status = readInt32(&size);
if (status != OK) {
return status;
}
if (size < 0) {
return UNEXPECTED_NULL;
}
val->resize(size);
/* C++ bool handling means a vector of bools isn't necessarily addressable
* (we might use individual bits)
*/
bool data;
for (int32_t i = 0; i < size; ++i) {
status = readBool(&data);
(*val)[i] = data;
if (status != OK) {
return status;
}
}
return OK;
}
status_t Parcel::readCharVector(std::unique_ptr<std::vector<char16_t>>* val) const {
return readNullableTypedVector(val, &Parcel::readChar);
}
status_t Parcel::readCharVector(std::vector<char16_t>* val) const {
return readTypedVector(val, &Parcel::readChar);
}
status_t Parcel::readString16Vector(
std::unique_ptr<std::vector<std::unique_ptr<String16>>>* val) const {
return readNullableTypedVector(val, &Parcel::readString16);
}
status_t Parcel::readString16Vector(std::vector<String16>* val) const {
return readTypedVector(val, &Parcel::readString16);
}
status_t Parcel::readUtf8VectorFromUtf16Vector(
std::unique_ptr<std::vector<std::unique_ptr<std::string>>>* val) const {
return readNullableTypedVector(val, &Parcel::readUtf8FromUtf16);
}
status_t Parcel::readUtf8VectorFromUtf16Vector(std::vector<std::string>* val) const {
return readTypedVector(val, &Parcel::readUtf8FromUtf16);
}
status_t Parcel::readInt32(int32_t *pArg) const
{
return readAligned(pArg);
}
int32_t Parcel::readInt32() const
{
return readAligned<int32_t>();
}
status_t Parcel::readUint32(uint32_t *pArg) const
{
return readAligned(pArg);
}
uint32_t Parcel::readUint32() const
{
return readAligned<uint32_t>();
}
status_t Parcel::readInt64(int64_t *pArg) const
{
return readAligned(pArg);
}
int64_t Parcel::readInt64() const
{
return readAligned<int64_t>();
}
status_t Parcel::readUint64(uint64_t *pArg) const
{
return readAligned(pArg);
}
uint64_t Parcel::readUint64() const
{
return readAligned<uint64_t>();
}
status_t Parcel::readPointer(uintptr_t *pArg) const
{
status_t ret;
binder_uintptr_t ptr;
ret = readAligned(&ptr);
if (!ret)
*pArg = ptr;
return ret;
}
uintptr_t Parcel::readPointer() const
{
return readAligned<binder_uintptr_t>();
}
status_t Parcel::readFloat(float *pArg) const
{
return readAligned(pArg);
}
float Parcel::readFloat() const
{
return readAligned<float>();
}
#if defined(__mips__) && defined(__mips_hard_float)
status_t Parcel::readDouble(double *pArg) const
{
union {
double d;
unsigned long long ll;
} u;
u.d = 0;
status_t status;
status = readAligned(&u.ll);
*pArg = u.d;
return status;
}
double Parcel::readDouble() const
{
union {
double d;
unsigned long long ll;
} u;
u.ll = readAligned<unsigned long long>();
return u.d;
}
#else
status_t Parcel::readDouble(double *pArg) const
{
return readAligned(pArg);
}
double Parcel::readDouble() const
{
return readAligned<double>();
}
#endif
status_t Parcel::readIntPtr(intptr_t *pArg) const
{
return readAligned(pArg);
}
intptr_t Parcel::readIntPtr() const
{
return readAligned<intptr_t>();
}
status_t Parcel::readBool(bool *pArg) const
{
int32_t tmp = 0;
status_t ret = readInt32(&tmp);
*pArg = (tmp != 0);
return ret;
}
bool Parcel::readBool() const
{
return readInt32() != 0;
}
status_t Parcel::readChar(char16_t *pArg) const
{
int32_t tmp = 0;
status_t ret = readInt32(&tmp);
*pArg = char16_t(tmp);
return ret;
}
char16_t Parcel::readChar() const
{
return char16_t(readInt32());
}
status_t Parcel::readByte(int8_t *pArg) const
{
int32_t tmp = 0;
status_t ret = readInt32(&tmp);
*pArg = int8_t(tmp);
return ret;
}
int8_t Parcel::readByte() const
{
return int8_t(readInt32());
}
status_t Parcel::readUtf8FromUtf16(std::string* str) const {
size_t utf16Size = 0;
const char16_t* src = readString16Inplace(&utf16Size);
if (!src) {
return UNEXPECTED_NULL;
}
// Save ourselves the trouble, we're done.
if (utf16Size == 0u) {
str->clear();
return NO_ERROR;
}
// Allow for closing '\0'
ssize_t utf8Size = utf16_to_utf8_length(src, utf16Size) + 1;
if (utf8Size < 1) {
return BAD_VALUE;
}
// Note that while it is probably safe to assume string::resize keeps a
// spare byte around for the trailing null, we still pass the size including the trailing null
str->resize(utf8Size);
utf16_to_utf8(src, utf16Size, &((*str)[0]), utf8Size);
str->resize(utf8Size - 1);
return NO_ERROR;
}
status_t Parcel::readUtf8FromUtf16(std::unique_ptr<std::string>* str) const {
const int32_t start = dataPosition();
int32_t size;
status_t status = readInt32(&size);
str->reset();
if (status != OK || size < 0) {
return status;
}
setDataPosition(start);
str->reset(new (std::nothrow) std::string());
return readUtf8FromUtf16(str->get());
}
const char* Parcel::readCString() const
{
const size_t avail = mDataSize-mDataPos;
if (avail > 0) {
const char* str = reinterpret_cast<const char*>(mData+mDataPos);
// is the string's trailing NUL within the parcel's valid bounds?
const char* eos = reinterpret_cast<const char*>(memchr(str, 0, avail));
if (eos) {
const size_t len = eos - str;
mDataPos += pad_size(len+1);
ALOGV("readCString Setting data pos of %p to %zu", this, mDataPos);
return str;
}
}
return nullptr;
}
String8 Parcel::readString8() const
{
String8 retString;
status_t status = readString8(&retString);
if (status != OK) {
// We don't care about errors here, so just return an empty string.
return String8();
}
return retString;
}
status_t Parcel::readString8(String8* pArg) const
{
int32_t size;
status_t status = readInt32(&size);
if (status != OK) {
return status;
}
// watch for potential int overflow from size+1
if (size < 0 || size >= INT32_MAX) {
return BAD_VALUE;
}
// |writeString8| writes nothing for empty string.
if (size == 0) {
*pArg = String8();
return OK;
}
const char* str = (const char*)readInplace(size + 1);
if (str == nullptr) {
return BAD_VALUE;
}
pArg->setTo(str, size);
return OK;
}
String16 Parcel::readString16() const
{
size_t len;
const char16_t* str = readString16Inplace(&len);
if (str) return String16(str, len);
ALOGE("Reading a NULL string not supported here.");
return String16();
}
status_t Parcel::readString16(std::unique_ptr<String16>* pArg) const
{
const int32_t start = dataPosition();
int32_t size;
status_t status = readInt32(&size);
pArg->reset();
if (status != OK || size < 0) {
return status;
}
setDataPosition(start);
pArg->reset(new (std::nothrow) String16());
status = readString16(pArg->get());
if (status != OK) {
pArg->reset();
}
return status;
}
status_t Parcel::readString16(String16* pArg) const
{
size_t len;
const char16_t* str = readString16Inplace(&len);
if (str) {
pArg->setTo(str, len);
return 0;
} else {
*pArg = String16();
return UNEXPECTED_NULL;
}
}
const char16_t* Parcel::readString16Inplace(size_t* outLen) const
{
int32_t size = readInt32();
// watch for potential int overflow from size+1
if (size >= 0 && size < INT32_MAX) {
*outLen = size;
const char16_t* str = (const char16_t*)readInplace((size+1)*sizeof(char16_t));
if (str != nullptr) {
return str;
}
}
*outLen = 0;
return nullptr;
}
status_t Parcel::readStrongBinder(sp<IBinder>* val) const
{
status_t status = readNullableStrongBinder(val);
if (status == OK && !val->get()) {
status = UNEXPECTED_NULL;
}
return status;
}
status_t Parcel::readNullableStrongBinder(sp<IBinder>* val) const
{
return unflatten_binder(ProcessState::self(), *this, val);
}
sp<IBinder> Parcel::readStrongBinder() const
{
sp<IBinder> val;
// Note that a lot of code in Android reads binders by hand with this
// method, and that code has historically been ok with getting nullptr
// back (while ignoring error codes).
readNullableStrongBinder(&val);
return val;
}
wp<IBinder> Parcel::readWeakBinder() const
{
wp<IBinder> val;
unflatten_binder(ProcessState::self(), *this, &val);
return val;
}
status_t Parcel::readParcelable(Parcelable* parcelable) const {
int32_t have_parcelable = 0;
status_t status = readInt32(&have_parcelable);
if (status != OK) {
return status;
}
if (!have_parcelable) {
return UNEXPECTED_NULL;
}
return parcelable->readFromParcel(this);
}
status_t Parcel::readValue(binder::Value* value) const {
return value->readFromParcel(this);
}
int32_t Parcel::readExceptionCode() const
{
binder::Status status;
status.readFromParcel(*this);
return status.exceptionCode();
}
native_handle* Parcel::readNativeHandle() const
{
int numFds, numInts;
status_t err;
err = readInt32(&numFds);
if (err != NO_ERROR) return nullptr;
err = readInt32(&numInts);
if (err != NO_ERROR) return nullptr;
native_handle* h = native_handle_create(numFds, numInts);
if (!h) {
return nullptr;
}
for (int i=0 ; err==NO_ERROR && i<numFds ; i++) {
h->data[i] = fcntl(readFileDescriptor(), F_DUPFD_CLOEXEC, 0);
if (h->data[i] < 0) {
for (int j = 0; j < i; j++) {
close(h->data[j]);
}
native_handle_delete(h);
return nullptr;
}
}
err = read(h->data + numFds, sizeof(int)*numInts);
if (err != NO_ERROR) {
native_handle_close(h);
native_handle_delete(h);
h = nullptr;
}
return h;
}
int Parcel::readFileDescriptor() const
{
const flat_binder_object* flat = readObject(true);
if (flat && flat->hdr.type == BINDER_TYPE_FD) {
return flat->handle;
}
return BAD_TYPE;
}
int Parcel::readParcelFileDescriptor() const
{
int32_t hasComm = readInt32();
int fd = readFileDescriptor();
if (hasComm != 0) {
// detach (owned by the binder driver)
int comm = readFileDescriptor();
// warning: this must be kept in sync with:
// frameworks/base/core/java/android/os/ParcelFileDescriptor.java
enum ParcelFileDescriptorStatus {
DETACHED = 2,
};
#if BYTE_ORDER == BIG_ENDIAN
const int32_t message = ParcelFileDescriptorStatus::DETACHED;
#endif
#if BYTE_ORDER == LITTLE_ENDIAN
const int32_t message = __builtin_bswap32(ParcelFileDescriptorStatus::DETACHED);
#endif
ssize_t written = TEMP_FAILURE_RETRY(
::write(comm, &message, sizeof(message)));
if (written == -1 || written != sizeof(message)) {
ALOGW("Failed to detach ParcelFileDescriptor written: %zd err: %s",
written, strerror(errno));
return BAD_TYPE;
}
}
return fd;
}
status_t Parcel::readUniqueFileDescriptor(base::unique_fd* val) const
{
int got = readFileDescriptor();
if (got == BAD_TYPE) {
return BAD_TYPE;
}
val->reset(fcntl(got, F_DUPFD_CLOEXEC, 0));
if (val->get() < 0) {
return BAD_VALUE;
}
return OK;
}
status_t Parcel::readUniqueParcelFileDescriptor(base::unique_fd* val) const
{
int got = readParcelFileDescriptor();
if (got == BAD_TYPE) {
return BAD_TYPE;
}
val->reset(fcntl(got, F_DUPFD_CLOEXEC, 0));
if (val->get() < 0) {
return BAD_VALUE;
}
return OK;
}
status_t Parcel::readUniqueFileDescriptorVector(std::unique_ptr<std::vector<base::unique_fd>>* val) const {
return readNullableTypedVector(val, &Parcel::readUniqueFileDescriptor);
}
status_t Parcel::readUniqueFileDescriptorVector(std::vector<base::unique_fd>* val) const {
return readTypedVector(val, &Parcel::readUniqueFileDescriptor);
}
status_t Parcel::readBlob(size_t len, ReadableBlob* outBlob) const
{
int32_t blobType;
status_t status = readInt32(&blobType);
if (status) return status;
if (blobType == BLOB_INPLACE) {
ALOGV("readBlob: read in place");
const void* ptr = readInplace(len);
if (!ptr) return BAD_VALUE;
outBlob->init(-1, const_cast<void*>(ptr), len, false);
return NO_ERROR;
}
ALOGV("readBlob: read from ashmem");
bool isMutable = (blobType == BLOB_ASHMEM_MUTABLE);
int fd = readFileDescriptor();
if (fd == int(BAD_TYPE)) return BAD_VALUE;
if (!ashmem_valid(fd)) {
ALOGE("invalid fd");
return BAD_VALUE;
}
int size = ashmem_get_size_region(fd);
if (size < 0 || size_t(size) < len) {
ALOGE("request size %zu does not match fd size %d", len, size);
return BAD_VALUE;
}
void* ptr = ::mmap(nullptr, len, isMutable ? PROT_READ | PROT_WRITE : PROT_READ,
MAP_SHARED, fd, 0);
if (ptr == MAP_FAILED) return NO_MEMORY;
outBlob->init(fd, ptr, len, isMutable);
return NO_ERROR;
}
status_t Parcel::read(FlattenableHelperInterface& val) const
{
// size
const size_t len = this->readInt32();
const size_t fd_count = this->readInt32();
if ((len > INT32_MAX) || (fd_count >= gMaxFds)) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return BAD_VALUE;
}
// payload
void const* const buf = this->readInplace(pad_size(len));
if (buf == nullptr)
return BAD_VALUE;
int* fds = nullptr;
if (fd_count) {
fds = new (std::nothrow) int[fd_count];
if (fds == nullptr) {
ALOGE("read: failed to allocate requested %zu fds", fd_count);
return BAD_VALUE;
}
}
status_t err = NO_ERROR;
for (size_t i=0 ; i<fd_count && err==NO_ERROR ; i++) {
int fd = this->readFileDescriptor();
if (fd < 0 || ((fds[i] = fcntl(fd, F_DUPFD_CLOEXEC, 0)) < 0)) {
err = BAD_VALUE;
ALOGE("fcntl(F_DUPFD_CLOEXEC) failed in Parcel::read, i is %zu, fds[i] is %d, fd_count is %zu, error: %s",
i, fds[i], fd_count, strerror(fd < 0 ? -fd : errno));
// Close all the file descriptors that were dup-ed.
for (size_t j=0; j<i ;j++) {
close(fds[j]);
}
}
}
if (err == NO_ERROR) {
err = val.unflatten(buf, len, fds, fd_count);
}
if (fd_count) {
delete [] fds;
}
return err;
}
const flat_binder_object* Parcel::readObject(bool nullMetaData) const
{
const size_t DPOS = mDataPos;
if ((DPOS+sizeof(flat_binder_object)) <= mDataSize) {
const flat_binder_object* obj
= reinterpret_cast<const flat_binder_object*>(mData+DPOS);
mDataPos = DPOS + sizeof(flat_binder_object);
if (!nullMetaData && (obj->cookie == 0 && obj->binder == 0)) {
// When transferring a NULL object, we don't write it into
// the object list, so we don't want to check for it when
// reading.
ALOGV("readObject Setting data pos of %p to %zu", this, mDataPos);
return obj;
}
// Ensure that this object is valid...
binder_size_t* const OBJS = mObjects;
const size_t N = mObjectsSize;
size_t opos = mNextObjectHint;
if (N > 0) {
ALOGV("Parcel %p looking for obj at %zu, hint=%zu",
this, DPOS, opos);
// Start at the current hint position, looking for an object at
// the current data position.
if (opos < N) {
while (opos < (N-1) && OBJS[opos] < DPOS) {
opos++;
}
} else {
opos = N-1;
}
if (OBJS[opos] == DPOS) {
// Found it!
ALOGV("Parcel %p found obj %zu at index %zu with forward search",
this, DPOS, opos);
mNextObjectHint = opos+1;
ALOGV("readObject Setting data pos of %p to %zu", this, mDataPos);
return obj;
}
// Look backwards for it...
while (opos > 0 && OBJS[opos] > DPOS) {
opos--;
}
if (OBJS[opos] == DPOS) {
// Found it!
ALOGV("Parcel %p found obj %zu at index %zu with backward search",
this, DPOS, opos);
mNextObjectHint = opos+1;
ALOGV("readObject Setting data pos of %p to %zu", this, mDataPos);
return obj;
}
}
ALOGW("Attempt to read object from Parcel %p at offset %zu that is not in the object list",
this, DPOS);
}
return nullptr;
}
void Parcel::closeFileDescriptors()
{
size_t i = mObjectsSize;
if (i > 0) {
//ALOGI("Closing file descriptors for %zu objects...", i);
}
while (i > 0) {
i--;
const flat_binder_object* flat
= reinterpret_cast<flat_binder_object*>(mData+mObjects[i]);
if (flat->hdr.type == BINDER_TYPE_FD) {
//ALOGI("Closing fd: %ld", flat->handle);
close(flat->handle);
}
}
}
uintptr_t Parcel::ipcData() const
{
return reinterpret_cast<uintptr_t>(mData);
}
size_t Parcel::ipcDataSize() const
{
return (mDataSize > mDataPos ? mDataSize : mDataPos);
}
uintptr_t Parcel::ipcObjects() const
{
return reinterpret_cast<uintptr_t>(mObjects);
}
size_t Parcel::ipcObjectsCount() const
{
return mObjectsSize;
}
void Parcel::ipcSetDataReference(const uint8_t* data, size_t dataSize,
const binder_size_t* objects, size_t objectsCount, release_func relFunc, void* relCookie)
{
binder_size_t minOffset = 0;
freeDataNoInit();
mError = NO_ERROR;
mData = const_cast<uint8_t*>(data);
mDataSize = mDataCapacity = dataSize;
//ALOGI("setDataReference Setting data size of %p to %lu (pid=%d)", this, mDataSize, getpid());
mDataPos = 0;
ALOGV("setDataReference Setting data pos of %p to %zu", this, mDataPos);
mObjects = const_cast<binder_size_t*>(objects);
mObjectsSize = mObjectsCapacity = objectsCount;
mNextObjectHint = 0;
mObjectsSorted = false;
mOwner = relFunc;
mOwnerCookie = relCookie;
for (size_t i = 0; i < mObjectsSize; i++) {
binder_size_t offset = mObjects[i];
if (offset < minOffset) {
ALOGE("%s: bad object offset %" PRIu64 " < %" PRIu64 "\n",
__func__, (uint64_t)offset, (uint64_t)minOffset);
mObjectsSize = 0;
break;
}
minOffset = offset + sizeof(flat_binder_object);
}
scanForFds();
}
void Parcel::print(TextOutput& to, uint32_t /*flags*/) const
{
to << "Parcel(";
if (errorCheck() != NO_ERROR) {
const status_t err = errorCheck();
to << "Error: " << (void*)(intptr_t)err << " \"" << strerror(-err) << "\"";
} else if (dataSize() > 0) {
const uint8_t* DATA = data();
to << indent << HexDump(DATA, dataSize()) << dedent;
const binder_size_t* OBJS = objects();
const size_t N = objectsCount();
for (size_t i=0; i<N; i++) {
const flat_binder_object* flat
= reinterpret_cast<const flat_binder_object*>(DATA+OBJS[i]);
to << endl << "Object #" << i << " @ " << (void*)OBJS[i] << ": "
<< TypeCode(flat->hdr.type & 0x7f7f7f00)
<< " = " << flat->binder;
}
} else {
to << "NULL";
}
to << ")";
}
void Parcel::releaseObjects()
{
size_t i = mObjectsSize;
if (i == 0) {
return;
}
sp<ProcessState> proc(ProcessState::self());
uint8_t* const data = mData;
binder_size_t* const objects = mObjects;
while (i > 0) {
i--;
const flat_binder_object* flat
= reinterpret_cast<flat_binder_object*>(data+objects[i]);
release_object(proc, *flat, this, &mOpenAshmemSize);
}
}
void Parcel::acquireObjects()
{
size_t i = mObjectsSize;
if (i == 0) {
return;
}
const sp<ProcessState> proc(ProcessState::self());
uint8_t* const data = mData;
binder_size_t* const objects = mObjects;
while (i > 0) {
i--;
const flat_binder_object* flat
= reinterpret_cast<flat_binder_object*>(data+objects[i]);
acquire_object(proc, *flat, this, &mOpenAshmemSize);
}
}
void Parcel::freeData()
{
freeDataNoInit();
initState();
}
void Parcel::freeDataNoInit()
{
if (mOwner) {
LOG_ALLOC("Parcel %p: freeing other owner data", this);
//ALOGI("Freeing data ref of %p (pid=%d)", this, getpid());
mOwner(this, mData, mDataSize, mObjects, mObjectsSize, mOwnerCookie);
} else {
LOG_ALLOC("Parcel %p: freeing allocated data", this);
releaseObjects();
if (mData) {
LOG_ALLOC("Parcel %p: freeing with %zu capacity", this, mDataCapacity);
pthread_mutex_lock(&gParcelGlobalAllocSizeLock);
if (mDataCapacity <= gParcelGlobalAllocSize) {
gParcelGlobalAllocSize = gParcelGlobalAllocSize - mDataCapacity;
} else {
gParcelGlobalAllocSize = 0;
}
if (gParcelGlobalAllocCount > 0) {
gParcelGlobalAllocCount--;
}
pthread_mutex_unlock(&gParcelGlobalAllocSizeLock);
free(mData);
}
if (mObjects) free(mObjects);
}
}
status_t Parcel::growData(size_t len)
{
if (len > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return BAD_VALUE;
}
size_t newSize = ((mDataSize+len)*3)/2;
return (newSize <= mDataSize)
? (status_t) NO_MEMORY
: continueWrite(newSize);
}
status_t Parcel::restartWrite(size_t desired)
{
if (desired > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return BAD_VALUE;
}
if (mOwner) {
freeData();
return continueWrite(desired);
}
uint8_t* data = (uint8_t*)realloc(mData, desired);
if (!data && desired > mDataCapacity) {
mError = NO_MEMORY;
return NO_MEMORY;
}
releaseObjects();
if (data) {
LOG_ALLOC("Parcel %p: restart from %zu to %zu capacity", this, mDataCapacity, desired);
pthread_mutex_lock(&gParcelGlobalAllocSizeLock);
gParcelGlobalAllocSize += desired;
gParcelGlobalAllocSize -= mDataCapacity;
if (!mData) {
gParcelGlobalAllocCount++;
}
pthread_mutex_unlock(&gParcelGlobalAllocSizeLock);
mData = data;
mDataCapacity = desired;
}
mDataSize = mDataPos = 0;
ALOGV("restartWrite Setting data size of %p to %zu", this, mDataSize);
ALOGV("restartWrite Setting data pos of %p to %zu", this, mDataPos);
free(mObjects);
mObjects = nullptr;
mObjectsSize = mObjectsCapacity = 0;
mNextObjectHint = 0;
mObjectsSorted = false;
mHasFds = false;
mFdsKnown = true;
mAllowFds = true;
return NO_ERROR;
}
status_t Parcel::continueWrite(size_t desired)
{
if (desired > INT32_MAX) {
// don't accept size_t values which may have come from an
// inadvertent conversion from a negative int.
return BAD_VALUE;
}
// If shrinking, first adjust for any objects that appear
// after the new data size.
size_t objectsSize = mObjectsSize;
if (desired < mDataSize) {
if (desired == 0) {
objectsSize = 0;
} else {
while (objectsSize > 0) {
if (mObjects[objectsSize-1] < desired)
break;
objectsSize--;
}
}
}
if (mOwner) {
// If the size is going to zero, just release the owner's data.
if (desired == 0) {
freeData();
return NO_ERROR;
}
// If there is a different owner, we need to take
// posession.
uint8_t* data = (uint8_t*)malloc(desired);
if (!data) {
mError = NO_MEMORY;
return NO_MEMORY;
}
binder_size_t* objects = nullptr;
if (objectsSize) {
objects = (binder_size_t*)calloc(objectsSize, sizeof(binder_size_t));
if (!objects) {
free(data);
mError = NO_MEMORY;
return NO_MEMORY;
}
// Little hack to only acquire references on objects
// we will be keeping.
size_t oldObjectsSize = mObjectsSize;
mObjectsSize = objectsSize;
acquireObjects();
mObjectsSize = oldObjectsSize;
}
if (mData) {
memcpy(data, mData, mDataSize < desired ? mDataSize : desired);
}
if (objects && mObjects) {
memcpy(objects, mObjects, objectsSize*sizeof(binder_size_t));
}
//ALOGI("Freeing data ref of %p (pid=%d)", this, getpid());
mOwner(this, mData, mDataSize, mObjects, mObjectsSize, mOwnerCookie);
mOwner = nullptr;
LOG_ALLOC("Parcel %p: taking ownership of %zu capacity", this, desired);
pthread_mutex_lock(&gParcelGlobalAllocSizeLock);
gParcelGlobalAllocSize += desired;
gParcelGlobalAllocCount++;
pthread_mutex_unlock(&gParcelGlobalAllocSizeLock);
mData = data;
mObjects = objects;
mDataSize = (mDataSize < desired) ? mDataSize : desired;
ALOGV("continueWrite Setting data size of %p to %zu", this, mDataSize);
mDataCapacity = desired;
mObjectsSize = mObjectsCapacity = objectsSize;
mNextObjectHint = 0;
mObjectsSorted = false;
} else if (mData) {
if (objectsSize < mObjectsSize) {
// Need to release refs on any objects we are dropping.
const sp<ProcessState> proc(ProcessState::self());
for (size_t i=objectsSize; i<mObjectsSize; i++) {
const flat_binder_object* flat
= reinterpret_cast<flat_binder_object*>(mData+mObjects[i]);
if (flat->hdr.type == BINDER_TYPE_FD) {
// will need to rescan because we may have lopped off the only FDs
mFdsKnown = false;
}
release_object(proc, *flat, this, &mOpenAshmemSize);
}
binder_size_t* objects =
(binder_size_t*)realloc(mObjects, objectsSize*sizeof(binder_size_t));
if (objects) {
mObjects = objects;
}
mObjectsSize = objectsSize;
mNextObjectHint = 0;
mObjectsSorted = false;
}
// We own the data, so we can just do a realloc().
if (desired > mDataCapacity) {
uint8_t* data = (uint8_t*)realloc(mData, desired);
if (data) {
LOG_ALLOC("Parcel %p: continue from %zu to %zu capacity", this, mDataCapacity,
desired);
pthread_mutex_lock(&gParcelGlobalAllocSizeLock);
gParcelGlobalAllocSize += desired;
gParcelGlobalAllocSize -= mDataCapacity;
pthread_mutex_unlock(&gParcelGlobalAllocSizeLock);
mData = data;
mDataCapacity = desired;
} else {
mError = NO_MEMORY;
return NO_MEMORY;
}
} else {
if (mDataSize > desired) {
mDataSize = desired;
ALOGV("continueWrite Setting data size of %p to %zu", this, mDataSize);
}
if (mDataPos > desired) {
mDataPos = desired;
ALOGV("continueWrite Setting data pos of %p to %zu", this, mDataPos);
}
}
} else {
// This is the first data. Easy!
uint8_t* data = (uint8_t*)malloc(desired);
if (!data) {
mError = NO_MEMORY;
return NO_MEMORY;
}
if(!(mDataCapacity == 0 && mObjects == nullptr
&& mObjectsCapacity == 0)) {
ALOGE("continueWrite: %zu/%p/%zu/%zu", mDataCapacity, mObjects, mObjectsCapacity, desired);
}
LOG_ALLOC("Parcel %p: allocating with %zu capacity", this, desired);
pthread_mutex_lock(&gParcelGlobalAllocSizeLock);
gParcelGlobalAllocSize += desired;
gParcelGlobalAllocCount++;
pthread_mutex_unlock(&gParcelGlobalAllocSizeLock);
mData = data;
mDataSize = mDataPos = 0;
ALOGV("continueWrite Setting data size of %p to %zu", this, mDataSize);
ALOGV("continueWrite Setting data pos of %p to %zu", this, mDataPos);
mDataCapacity = desired;
}
return NO_ERROR;
}
void Parcel::initState()
{
LOG_ALLOC("Parcel %p: initState", this);
mError = NO_ERROR;
mData = nullptr;
mDataSize = 0;
mDataCapacity = 0;
mDataPos = 0;
ALOGV("initState Setting data size of %p to %zu", this, mDataSize);
ALOGV("initState Setting data pos of %p to %zu", this, mDataPos);
mObjects = nullptr;
mObjectsSize = 0;
mObjectsCapacity = 0;
mNextObjectHint = 0;
mObjectsSorted = false;
mHasFds = false;
mFdsKnown = true;
mAllowFds = true;
mOwner = nullptr;
mOpenAshmemSize = 0;
// racing multiple init leads only to multiple identical write
if (gMaxFds == 0) {
struct rlimit result;
if (!getrlimit(RLIMIT_NOFILE, &result)) {
gMaxFds = (size_t)result.rlim_cur;
//ALOGI("parcel fd limit set to %zu", gMaxFds);
} else {
ALOGW("Unable to getrlimit: %s", strerror(errno));
gMaxFds = 1024;
}
}
}
void Parcel::scanForFds() const
{
bool hasFds = false;
for (size_t i=0; i<mObjectsSize; i++) {
const flat_binder_object* flat
= reinterpret_cast<const flat_binder_object*>(mData + mObjects[i]);
if (flat->hdr.type == BINDER_TYPE_FD) {
hasFds = true;
break;
}
}
mHasFds = hasFds;
mFdsKnown = true;
}
size_t Parcel::getBlobAshmemSize() const
{
// This used to return the size of all blobs that were written to ashmem, now we're returning
// the ashmem currently referenced by this Parcel, which should be equivalent.
// TODO: Remove method once ABI can be changed.
return mOpenAshmemSize;
}
size_t Parcel::getOpenAshmemSize() const
{
return mOpenAshmemSize;
}
// --- Parcel::Blob ---
Parcel::Blob::Blob() :
mFd(-1), mData(nullptr), mSize(0), mMutable(false) {
}
Parcel::Blob::~Blob() {
release();
}
void Parcel::Blob::release() {
if (mFd != -1 && mData) {
::munmap(mData, mSize);
}
clear();
}
void Parcel::Blob::init(int fd, void* data, size_t size, bool isMutable) {
mFd = fd;
mData = data;
mSize = size;
mMutable = isMutable;
}
void Parcel::Blob::clear() {
mFd = -1;
mData = nullptr;
mSize = 0;
mMutable = false;
}
}; // namespace android