/* * Copyright (C) 1996-2023 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 05 Socket Functions */ #include "squid.h" #include "comm.h" #include "comm/IoCallback.h" #include "comm/Loops.h" #include "comm/Read.h" #include "comm_internal.h" #include "CommCalls.h" #include "debug/Stream.h" #include "fd.h" #include "fde.h" #include "sbuf/SBuf.h" #include "SquidConfig.h" #include "StatCounters.h" // Does comm check this fd for read readiness? // Note that when comm is not monitoring, there can be a pending callback // call, which may resume comm monitoring once fired. bool Comm::MonitorsRead(int fd) { assert(isOpen(fd) && COMMIO_FD_READCB(fd) != nullptr); // Being active is usually the same as monitoring because we always // start monitoring the FD when we configure Comm::IoCallback for I/O // and we usually configure Comm::IoCallback for I/O when we starting // monitoring a FD for reading. return COMMIO_FD_READCB(fd)->active(); } void Comm::Read(const Comm::ConnectionPointer &conn, AsyncCall::Pointer &callback) { // TODO: move comm_read_base() internals into here // when comm_read() char* API is no longer needed comm_read_base(conn, nullptr, 0, callback); } /** * Queue a read. * If a buffer is given the callback is scheduled when the read * completes, on error, or on file descriptor close. * * If no buffer (NULL) is given the callback is scheduled when * the socket FD is ready for a read(2)/recv(2). */ void comm_read_base(const Comm::ConnectionPointer &conn, char *buf, int size, AsyncCall::Pointer &callback) { debugs(5, 5, "comm_read, queueing read for " << conn << "; asynCall " << callback); /* Make sure we are open and not closing */ assert(Comm::IsConnOpen(conn)); assert(!fd_table[conn->fd].closing()); Comm::IoCallback *ccb = COMMIO_FD_READCB(conn->fd); // Make sure we are either not reading or just passively monitoring. // Active/passive conflicts are OK and simply cancel passive monitoring. if (ccb->active()) { // if the assertion below fails, we have an active comm_read conflict assert(fd_table[conn->fd].halfClosedReader != nullptr); commStopHalfClosedMonitor(conn->fd); assert(!ccb->active()); } ccb->conn = conn; /* Queue the read */ ccb->setCallback(Comm::IOCB_READ, callback, (char *)buf, nullptr, size); Comm::SetSelect(conn->fd, COMM_SELECT_READ, Comm::HandleRead, ccb, 0); } Comm::Flag Comm::ReadNow(CommIoCbParams ¶ms, SBuf &buf) { /* Attempt a read */ ++ statCounter.syscalls.sock.reads; SBuf::size_type sz = buf.spaceSize(); if (params.size > 0 && params.size < sz) sz = params.size; char *inbuf = buf.rawAppendStart(sz); errno = 0; const int retval = FD_READ_METHOD(params.conn->fd, inbuf, sz); params.xerrno = errno; debugs(5, 3, params.conn << ", size " << sz << ", retval " << retval << ", errno " << params.xerrno); if (retval > 0) { // data read most common case buf.rawAppendFinish(inbuf, retval); fd_bytes(params.conn->fd, retval, IoDirection::Read); params.flag = Comm::OK; params.size = retval; } else if (retval == 0) { // remote closure (somewhat less) common // Note - read 0 == socket EOF, which is a valid read. params.flag = Comm::ENDFILE; params.size = 0; } else if (retval < 0) { // connection errors are worst-case debugs(5, 3, params.conn << " Comm::COMM_ERROR: " << xstrerr(params.xerrno)); if (ignoreErrno(params.xerrno)) params.flag = Comm::INPROGRESS; else params.flag = Comm::COMM_ERROR; params.size = 0; } return params.flag; } /** * Handle an FD which is ready for read(2). * * If there is no provided buffer to fill call the callback. * * Otherwise attempt a read into the provided buffer. * If the read attempt succeeds or fails, call the callback. * Else, wait for another IO notification. */ void Comm::HandleRead(int fd, void *data) { Comm::IoCallback *ccb = (Comm::IoCallback *) data; assert(data == COMMIO_FD_READCB(fd)); assert(ccb->active()); // Without a buffer, just call back. // The callee may ReadMore() to get the data. if (!ccb->buf) { ccb->finish(Comm::OK, 0); return; } /* For legacy callers : Attempt a read */ // Keep in sync with Comm::ReadNow()! ++ statCounter.syscalls.sock.reads; int xerrno = errno = 0; int retval = FD_READ_METHOD(fd, ccb->buf, ccb->size); xerrno = errno; debugs(5, 3, "FD " << fd << ", size " << ccb->size << ", retval " << retval << ", errno " << xerrno); /* See if we read anything */ /* Note - read 0 == socket EOF, which is a valid read */ if (retval >= 0) { fd_bytes(fd, retval, IoDirection::Read); ccb->offset = retval; ccb->finish(Comm::OK, 0); return; } else if (retval < 0 && !ignoreErrno(xerrno)) { debugs(5, 3, "comm_read_try: scheduling Comm::COMM_ERROR"); ccb->offset = 0; ccb->finish(Comm::COMM_ERROR, xerrno); return; }; /* Nope, register for some more IO */ Comm::SetSelect(fd, COMM_SELECT_READ, Comm::HandleRead, data, 0); } /** * Cancel a pending read. Assert that we have the right parameters, * and that there are no pending read events! * * XXX: We do not assert that there are no pending read events and * with async calls it becomes even more difficult. * The whole interface should be reworked to do callback->cancel() * instead of searching for places where the callback may be stored and * updating the state of those places. * * AHC Don't call the comm handlers? */ void comm_read_cancel(int fd, IOCB *callback, void *data) { if (!isOpen(fd)) { debugs(5, 4, "fails: FD " << fd << " closed"); return; } Comm::IoCallback *cb = COMMIO_FD_READCB(fd); // TODO: is "active" == "monitors FD"? if (!cb->active()) { debugs(5, 4, "fails: FD " << fd << " inactive"); return; } typedef CommCbFunPtrCallT Call; Call *call = dynamic_cast(cb->callback.getRaw()); if (!call) { debugs(5, 4, "fails: FD " << fd << " lacks callback"); return; } call->cancel("old comm_read_cancel"); typedef CommIoCbParams Params; const Params ¶ms = GetCommParams(cb->callback); /* Ok, we can be reasonably sure we won't lose any data here! */ assert(call->dialer.handler == callback); assert(params.data == data); /* Delete the callback */ cb->cancel("old comm_read_cancel"); /* And the IO event */ Comm::SetSelect(fd, COMM_SELECT_READ, nullptr, nullptr, 0); } void Comm::ReadCancel(int fd, AsyncCall::Pointer &callback) { callback->cancel("comm_read_cancel"); if (!isOpen(fd)) { debugs(5, 4, "fails: FD " << fd << " closed"); return; } Comm::IoCallback *cb = COMMIO_FD_READCB(fd); if (!cb->active()) { debugs(5, 4, "fails: FD " << fd << " inactive"); return; } AsyncCall::Pointer call = cb->callback; /* Ok, we can be reasonably sure we won't lose any data here! */ assert(call == callback); /* Delete the callback */ cb->cancel("comm_read_cancel"); /* And the IO event */ Comm::SetSelect(fd, COMM_SELECT_READ, nullptr, nullptr, 0); } time_t Comm::MortalReadTimeout(const time_t startTime, const time_t lifetimeLimit) { if (lifetimeLimit > 0) { const time_t timeUsed = (squid_curtime > startTime) ? (squid_curtime - startTime) : 0; const time_t timeLeft = (lifetimeLimit > timeUsed) ? (lifetimeLimit - timeUsed) : 0; return min(::Config.Timeout.read, timeLeft); } else return ::Config.Timeout.read; }