/* * Copyright (C) 2016 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. */ #ifndef _FMSGQ_DESCRIPTOR_H #define _FMSGQ_DESCRIPTOR_H #include #include #include #include namespace android { namespace hardware { typedef uint64_t RingBufferPosition; struct GrantorDescriptor { uint32_t flags __attribute__ ((aligned(4))); uint32_t fdIndex __attribute__ ((aligned(4))); uint32_t offset __attribute__ ((aligned(4))); uint64_t extent __attribute__ ((aligned(8))); }; static_assert(offsetof(GrantorDescriptor, flags) == 0, "wrong offset"); static_assert(offsetof(GrantorDescriptor, fdIndex) == 4, "wrong offset"); static_assert(offsetof(GrantorDescriptor, offset) == 8, "wrong offset"); static_assert(offsetof(GrantorDescriptor, extent) == 16, "wrong offset"); static_assert(sizeof(GrantorDescriptor) == 24, "wrong size"); static_assert(__alignof(GrantorDescriptor) == 8, "wrong alignment"); enum MQFlavor : uint32_t { /* * kSynchronizedReadWrite represents the wait-free synchronized flavor of the * FMQ. It is intended to be have a single reader and single writer. * Attempts to overflow/underflow returns a failure. */ kSynchronizedReadWrite = 0x01, /* * kUnsynchronizedWrite represents the flavor of FMQ where writes always * succeed. This flavor allows one writer and many readers. A read operation * can detect an overwrite and reset the read counter. */ kUnsynchronizedWrite = 0x02 }; template struct MQDescriptor { MQDescriptor( const std::vector& grantors, native_handle_t* nHandle, size_t size); MQDescriptor(size_t bufferSize, native_handle_t* nHandle, size_t messageSize, bool configureEventFlag = false); MQDescriptor(); ~MQDescriptor(); explicit MQDescriptor(const MQDescriptor &other); MQDescriptor &operator=(const MQDescriptor &other) = delete; size_t getSize() const; size_t getQuantum() const; int32_t getFlags() const; bool isHandleValid() const { return mHandle != nullptr; } size_t countGrantors() const { return mGrantors.size(); } inline const ::android::hardware::hidl_vec &grantors() const { return mGrantors; } inline ::android::hardware::hidl_vec &grantors() { return mGrantors; } inline const ::native_handle_t *handle() const { return mHandle; } inline ::native_handle_t *handle() { return mHandle; } static const size_t kOffsetOfGrantors; static const size_t kOffsetOfHandle; enum GrantorType : int { READPTRPOS = 0, WRITEPTRPOS, DATAPTRPOS, EVFLAGWORDPOS }; /* * There should at least be GrantorDescriptors for the read counter, write * counter and data buffer. A GrantorDescriptor for an EventFlag word is * not required if there is no need for blocking FMQ operations. */ static constexpr int32_t kMinGrantorCount = DATAPTRPOS + 1; /* * Minimum number of GrantorDescriptors required if EventFlag support is * needed for blocking FMQ operations. */ static constexpr int32_t kMinGrantorCountForEvFlagSupport = EVFLAGWORDPOS + 1; //TODO(b/34160777) Identify a better solution that supports remoting. static inline size_t alignToWordBoundary(size_t length) { constexpr size_t kAlignmentSize = 64; if (kAlignmentSize % __WORDSIZE != 0) { details::logAlwaysFatal("Incompatible word size"); } /* * Check if alignment to word boundary would cause an overflow. */ if (length > SIZE_MAX - kAlignmentSize/8 + 1) { details::logAlwaysFatal("Queue size too large"); } return (length + kAlignmentSize/8 - 1) & ~(kAlignmentSize/8 - 1U); } static inline size_t isAlignedToWordBoundary(size_t offset) { constexpr size_t kAlignmentSize = 64; return (offset & (kAlignmentSize/8 - 1)) == 0; } private: ::android::hardware::hidl_vec mGrantors; ::android::hardware::details::hidl_pointer mHandle; uint32_t mQuantum; uint32_t mFlags; }; template const size_t MQDescriptor::kOffsetOfGrantors = offsetof(MQDescriptor, mGrantors); template const size_t MQDescriptor::kOffsetOfHandle = offsetof(MQDescriptor, mHandle); /* * MQDescriptorSync will describe the wait-free synchronized * flavor of FMQ. */ template using MQDescriptorSync = MQDescriptor; /* * MQDescriptorUnsync will describe the unsynchronized write * flavor of FMQ. */ template using MQDescriptorUnsync = MQDescriptor; template MQDescriptor::MQDescriptor( const std::vector& grantors, native_handle_t* nhandle, size_t size) : mHandle(nhandle), mQuantum(size), mFlags(flavor) { mGrantors.resize(grantors.size()); for (size_t i = 0; i < grantors.size(); ++i) { if (isAlignedToWordBoundary(grantors[i].offset) == false) { details::logAlwaysFatal("Grantor offsets need to be aligned"); } mGrantors[i] = grantors[i]; } } template MQDescriptor::MQDescriptor(size_t bufferSize, native_handle_t *nHandle, size_t messageSize, bool configureEventFlag) : mHandle(nHandle), mQuantum(messageSize), mFlags(flavor) { /* * If configureEventFlag is true, allocate an additional spot in mGrantor * for containing the fd and offset for mmapping the EventFlag word. */ mGrantors.resize(configureEventFlag? kMinGrantorCountForEvFlagSupport : kMinGrantorCount); size_t memSize[] = { sizeof(RingBufferPosition), /* memory to be allocated for read pointer counter */ sizeof(RingBufferPosition), /* memory to be allocated for write pointer counter */ bufferSize, /* memory to be allocated for data buffer */ sizeof(std::atomic)/* memory to be allocated for EventFlag word */ }; /* * Create a default grantor descriptor for read, write pointers and * the data buffer. fdIndex parameter is set to 0 by default and * the offset for each grantor is contiguous. */ for (size_t grantorPos = 0, offset = 0; grantorPos < mGrantors.size(); offset += memSize[grantorPos++]) { mGrantors[grantorPos] = { 0 /* grantor flags */, 0 /* fdIndex */, static_cast(alignToWordBoundary(offset)), memSize[grantorPos] }; } } template MQDescriptor::MQDescriptor(const MQDescriptor &other) : mGrantors(other.mGrantors), mHandle(nullptr), mQuantum(other.mQuantum), mFlags(other.mFlags) { if (other.mHandle != nullptr) { mHandle = native_handle_create( other.mHandle->numFds, other.mHandle->numInts); for (int i = 0; i < other.mHandle->numFds; ++i) { mHandle->data[i] = dup(other.mHandle->data[i]); } memcpy(&mHandle->data[other.mHandle->numFds], &other.mHandle->data[other.mHandle->numFds], other.mHandle->numInts * sizeof(int)); } } template MQDescriptor::MQDescriptor() : MQDescriptor( std::vector(), nullptr /* nHandle */, 0 /* size */) {} template MQDescriptor::~MQDescriptor() { if (mHandle != nullptr) { native_handle_close(mHandle); native_handle_delete(mHandle); } } template size_t MQDescriptor::getSize() const { return mGrantors[DATAPTRPOS].extent; } template size_t MQDescriptor::getQuantum() const { return mQuantum; } template int32_t MQDescriptor::getFlags() const { return mFlags; } template std::string toString(const MQDescriptor &q) { std::string os; if (flavor & kSynchronizedReadWrite) { os += "fmq_sync"; } if (flavor & kUnsynchronizedWrite) { os += "fmq_unsync"; } os += " {" + toString(q.grantors().size()) + " grantor(s), " + "size = " + toString(q.getSize()) + ", .handle = " + toString(q.handle()) + ", .quantum = " + toString(q.getQuantum()) + "}"; return os; } } // namespace hardware } // namespace android #endif // FMSGQ_DESCRIPTOR_H