/* * Copyright (C) 1996-2018 The Squid Software Foundation and contributors * * Squid software is distributed under GPLv2+ license and includes * contributions from numerous individuals and organizations. * Please see the COPYING and CONTRIBUTORS files for details. */ /* DEBUG: section 54 Interprocess Communication */ #include "squid.h" #include "base/TextException.h" #include "Debug.h" #include "globals.h" #include "ipc/Queue.h" #include /// constructs Metadata ID from parent queue ID static String MetadataId(String id) { id.append("__metadata"); return id; } /// constructs one-to-one queues ID from parent queue ID static String QueuesId(String id) { id.append("__queues"); return id; } /// constructs QueueReaders ID from parent queue ID static String ReadersId(String id) { id.append("__readers"); return id; } /* QueueReader */ InstanceIdDefinitions(Ipc::QueueReader, "ipcQR"); Ipc::QueueReader::QueueReader(): popBlocked(1), popSignal(0), rateLimit(0), balance(0) { debugs(54, 7, HERE << "constructed " << id); } /* QueueReaders */ Ipc::QueueReaders::QueueReaders(const int aCapacity): theCapacity(aCapacity), theReaders(theCapacity) { Must(theCapacity > 0); } size_t Ipc::QueueReaders::sharedMemorySize() const { return SharedMemorySize(theCapacity); } size_t Ipc::QueueReaders::SharedMemorySize(const int capacity) { return sizeof(QueueReaders) + sizeof(QueueReader) * capacity; } // OneToOneUniQueue Ipc::OneToOneUniQueue::OneToOneUniQueue(const unsigned int aMaxItemSize, const int aCapacity): theIn(0), theOut(0), theSize(0), theMaxItemSize(aMaxItemSize), theCapacity(aCapacity) { Must(theMaxItemSize > 0); Must(theCapacity > 0); } int Ipc::OneToOneUniQueue::Bytes2Items(const unsigned int maxItemSize, int size) { assert(maxItemSize > 0); size -= sizeof(OneToOneUniQueue); return size >= 0 ? size / maxItemSize : 0; } int Ipc::OneToOneUniQueue::Items2Bytes(const unsigned int maxItemSize, const int size) { assert(size >= 0); return sizeof(OneToOneUniQueue) + maxItemSize * size; } /* OneToOneUniQueues */ Ipc::OneToOneUniQueues::OneToOneUniQueues(const int aCapacity, const unsigned int maxItemSize, const int queueCapacity): theCapacity(aCapacity) { Must(theCapacity > 0); for (int i = 0; i < theCapacity; ++i) new (&(*this)[i]) OneToOneUniQueue(maxItemSize, queueCapacity); } size_t Ipc::OneToOneUniQueues::sharedMemorySize() const { return sizeof(*this) + theCapacity * front().sharedMemorySize(); } size_t Ipc::OneToOneUniQueues::SharedMemorySize(const int capacity, const unsigned int maxItemSize, const int queueCapacity) { const int queueSize = OneToOneUniQueue::Items2Bytes(maxItemSize, queueCapacity); return sizeof(OneToOneUniQueues) + queueSize * capacity; } const Ipc::OneToOneUniQueue & Ipc::OneToOneUniQueues::operator [](const int index) const { Must(0 <= index && index < theCapacity); const size_t queueSize = index ? front().sharedMemorySize() : 0; const char *const queue = reinterpret_cast(this) + sizeof(*this) + index * queueSize; return *reinterpret_cast(queue); } // BaseMultiQueue Ipc::BaseMultiQueue::BaseMultiQueue(const int aLocalProcessId): theLocalProcessId(aLocalProcessId), theLastPopProcessId(std::numeric_limits::max() - 1) { } void Ipc::BaseMultiQueue::clearReaderSignal(const int remoteProcessId) { QueueReader &reader = localReader(); debugs(54, 7, "reader: " << reader.id); reader.clearSignal(); // we got a hint; we could reposition iteration to try popping from the // remoteProcessId queue first; but it does not seem to help much and might // introduce some bias so we do not do that for now: // theLastPopProcessId = remoteProcessId; } const Ipc::QueueReader::Balance & Ipc::BaseMultiQueue::balance(const int remoteProcessId) const { const QueueReader &r = remoteReader(remoteProcessId); return r.balance; } const Ipc::QueueReader::Rate & Ipc::BaseMultiQueue::rateLimit(const int remoteProcessId) const { const QueueReader &r = remoteReader(remoteProcessId); return r.rateLimit; } Ipc::OneToOneUniQueue & Ipc::BaseMultiQueue::inQueue(const int remoteProcessId) { const OneToOneUniQueue &queue = const_cast(this)->inQueue(remoteProcessId); return const_cast(queue); } Ipc::OneToOneUniQueue & Ipc::BaseMultiQueue::outQueue(const int remoteProcessId) { const OneToOneUniQueue &queue = const_cast(this)->outQueue(remoteProcessId); return const_cast(queue); } Ipc::QueueReader & Ipc::BaseMultiQueue::localReader() { const QueueReader &reader = const_cast(this)->localReader(); return const_cast(reader); } Ipc::QueueReader & Ipc::BaseMultiQueue::remoteReader(const int remoteProcessId) { const QueueReader &reader = const_cast(this)->remoteReader(remoteProcessId); return const_cast(reader); } // FewToFewBiQueue Ipc::FewToFewBiQueue::Owner * Ipc::FewToFewBiQueue::Init(const String &id, const int groupASize, const int groupAIdOffset, const int groupBSize, const int groupBIdOffset, const unsigned int maxItemSize, const int capacity) { return new Owner(id, groupASize, groupAIdOffset, groupBSize, groupBIdOffset, maxItemSize, capacity); } Ipc::FewToFewBiQueue::FewToFewBiQueue(const String &id, const Group aLocalGroup, const int aLocalProcessId): BaseMultiQueue(aLocalProcessId), metadata(shm_old(Metadata)(MetadataId(id).termedBuf())), queues(shm_old(OneToOneUniQueues)(QueuesId(id).termedBuf())), readers(shm_old(QueueReaders)(ReadersId(id).termedBuf())), theLocalGroup(aLocalGroup) { Must(queues->theCapacity == metadata->theGroupASize * metadata->theGroupBSize * 2); Must(readers->theCapacity == metadata->theGroupASize + metadata->theGroupBSize); debugs(54, 7, "queue " << id << " reader: " << localReader().id); } int Ipc::FewToFewBiQueue::MaxItemsCount(const int groupASize, const int groupBSize, const int capacity) { return capacity * groupASize * groupBSize * 2; } bool Ipc::FewToFewBiQueue::validProcessId(const Group group, const int processId) const { switch (group) { case groupA: return metadata->theGroupAIdOffset <= processId && processId < metadata->theGroupAIdOffset + metadata->theGroupASize; case groupB: return metadata->theGroupBIdOffset <= processId && processId < metadata->theGroupBIdOffset + metadata->theGroupBSize; } return false; } int Ipc::FewToFewBiQueue::oneToOneQueueIndex(const Group fromGroup, const int fromProcessId, const Group toGroup, const int toProcessId) const { Must(fromGroup != toGroup); assert(validProcessId(fromGroup, fromProcessId)); assert(validProcessId(toGroup, toProcessId)); int index1; int index2; int offset; if (fromGroup == groupA) { index1 = fromProcessId - metadata->theGroupAIdOffset; index2 = toProcessId - metadata->theGroupBIdOffset; offset = 0; } else { index1 = toProcessId - metadata->theGroupAIdOffset; index2 = fromProcessId - metadata->theGroupBIdOffset; offset = metadata->theGroupASize * metadata->theGroupBSize; } const int index = offset + index1 * metadata->theGroupBSize + index2; return index; } const Ipc::OneToOneUniQueue & Ipc::FewToFewBiQueue::oneToOneQueue(const Group fromGroup, const int fromProcessId, const Group toGroup, const int toProcessId) const { return (*queues)[oneToOneQueueIndex(fromGroup, fromProcessId, toGroup, toProcessId)]; } const Ipc::OneToOneUniQueue & Ipc::FewToFewBiQueue::inQueue(const int remoteProcessId) const { return oneToOneQueue(remoteGroup(), remoteProcessId, theLocalGroup, theLocalProcessId); } const Ipc::OneToOneUniQueue & Ipc::FewToFewBiQueue::outQueue(const int remoteProcessId) const { return oneToOneQueue(theLocalGroup, theLocalProcessId, remoteGroup(), remoteProcessId); } int Ipc::FewToFewBiQueue::readerIndex(const Group group, const int processId) const { Must(validProcessId(group, processId)); return group == groupA ? processId - metadata->theGroupAIdOffset : metadata->theGroupASize + processId - metadata->theGroupBIdOffset; } const Ipc::QueueReader & Ipc::FewToFewBiQueue::localReader() const { return readers->theReaders[readerIndex(theLocalGroup, theLocalProcessId)]; } const Ipc::QueueReader & Ipc::FewToFewBiQueue::remoteReader(const int processId) const { return readers->theReaders[readerIndex(remoteGroup(), processId)]; } int Ipc::FewToFewBiQueue::remotesCount() const { return theLocalGroup == groupA ? metadata->theGroupBSize : metadata->theGroupASize; } int Ipc::FewToFewBiQueue::remotesIdOffset() const { return theLocalGroup == groupA ? metadata->theGroupBIdOffset : metadata->theGroupAIdOffset; } Ipc::FewToFewBiQueue::Metadata::Metadata(const int aGroupASize, const int aGroupAIdOffset, const int aGroupBSize, const int aGroupBIdOffset): theGroupASize(aGroupASize), theGroupAIdOffset(aGroupAIdOffset), theGroupBSize(aGroupBSize), theGroupBIdOffset(aGroupBIdOffset) { Must(theGroupASize > 0); Must(theGroupBSize > 0); } Ipc::FewToFewBiQueue::Owner::Owner(const String &id, const int groupASize, const int groupAIdOffset, const int groupBSize, const int groupBIdOffset, const unsigned int maxItemSize, const int capacity): metadataOwner(shm_new(Metadata)(MetadataId(id).termedBuf(), groupASize, groupAIdOffset, groupBSize, groupBIdOffset)), queuesOwner(shm_new(OneToOneUniQueues)(QueuesId(id).termedBuf(), groupASize*groupBSize*2, maxItemSize, capacity)), readersOwner(shm_new(QueueReaders)(ReadersId(id).termedBuf(), groupASize+groupBSize)) { } Ipc::FewToFewBiQueue::Owner::~Owner() { delete metadataOwner; delete queuesOwner; delete readersOwner; } // MultiQueue Ipc::MultiQueue::Owner * Ipc::MultiQueue::Init(const String &id, const int processCount, const int processIdOffset, const unsigned int maxItemSize, const int capacity) { return new Owner(id, processCount, processIdOffset, maxItemSize, capacity); } Ipc::MultiQueue::MultiQueue(const String &id, const int localProcessId): BaseMultiQueue(localProcessId), metadata(shm_old(Metadata)(MetadataId(id).termedBuf())), queues(shm_old(OneToOneUniQueues)(QueuesId(id).termedBuf())), readers(shm_old(QueueReaders)(ReadersId(id).termedBuf())) { Must(queues->theCapacity == metadata->theProcessCount * metadata->theProcessCount); Must(readers->theCapacity == metadata->theProcessCount); debugs(54, 7, "queue " << id << " reader: " << localReader().id); } bool Ipc::MultiQueue::validProcessId(const int processId) const { return metadata->theProcessIdOffset <= processId && processId < metadata->theProcessIdOffset + metadata->theProcessCount; } const Ipc::OneToOneUniQueue & Ipc::MultiQueue::oneToOneQueue(const int fromProcessId, const int toProcessId) const { assert(validProcessId(fromProcessId)); assert(validProcessId(toProcessId)); const int fromIndex = fromProcessId - metadata->theProcessIdOffset; const int toIndex = toProcessId - metadata->theProcessIdOffset; const int index = fromIndex * metadata->theProcessCount + toIndex; return (*queues)[index]; } const Ipc::QueueReader & Ipc::MultiQueue::reader(const int processId) const { assert(validProcessId(processId)); const int index = processId - metadata->theProcessIdOffset; return readers->theReaders[index]; } const Ipc::OneToOneUniQueue & Ipc::MultiQueue::inQueue(const int remoteProcessId) const { return oneToOneQueue(remoteProcessId, theLocalProcessId); } const Ipc::OneToOneUniQueue & Ipc::MultiQueue::outQueue(const int remoteProcessId) const { return oneToOneQueue(theLocalProcessId, remoteProcessId); } const Ipc::QueueReader & Ipc::MultiQueue::localReader() const { return reader(theLocalProcessId); } const Ipc::QueueReader & Ipc::MultiQueue::remoteReader(const int processId) const { return reader(processId); } int Ipc::MultiQueue::remotesCount() const { return metadata->theProcessCount; } int Ipc::MultiQueue::remotesIdOffset() const { return metadata->theProcessIdOffset; } Ipc::MultiQueue::Metadata::Metadata(const int aProcessCount, const int aProcessIdOffset): theProcessCount(aProcessCount), theProcessIdOffset(aProcessIdOffset) { Must(theProcessCount > 0); } Ipc::MultiQueue::Owner::Owner(const String &id, const int processCount, const int processIdOffset, const unsigned int maxItemSize, const int capacity): metadataOwner(shm_new(Metadata)(MetadataId(id).termedBuf(), processCount, processIdOffset)), queuesOwner(shm_new(OneToOneUniQueues)(QueuesId(id).termedBuf(), processCount*processCount, maxItemSize, capacity)), readersOwner(shm_new(QueueReaders)(ReadersId(id).termedBuf(), processCount)) { } Ipc::MultiQueue::Owner::~Owner() { delete metadataOwner; delete queuesOwner; delete readersOwner; }