/* * i/o functions */ /* Copyright 1990, 1991, 1998 The Open Group Permission to use, copy, modify, distribute, and sell this software and its documentation for any purpose is hereby granted without fee, provided that the above copyright notice appear in all copies and that both that copyright notice and this permission notice appear in supporting documentation. The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE OPEN GROUP BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. Except as contained in this notice, the name of The Open Group shall not be used in advertising or otherwise to promote the sale, use or other dealings in this Software without prior written authorization from The Open Group. * Copyright 1990, 1991 Network Computing Devices; * Portions Copyright 1987 by Digital Equipment Corporation * * Permission to use, copy, modify, distribute, and sell this software and * its documentation for any purpose is hereby granted without fee, provided * that the above copyright notice appear in all copies and that both that * copyright notice and this permission notice appear in supporting * documentation, and that the names of Network Computing Devices, or Digital * not be used in advertising or publicity pertaining to distribution * of the software without specific, written prior permission. * * NETWORK COMPUTING DEVICES, AND DIGITAL DISCLAIM ALL WARRANTIES WITH * REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS, IN NO EVENT SHALL NETWORK COMPUTING DEVICES, * OR DIGITAL BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL * DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR * PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS * ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF * THIS SOFTWARE. */ #include "config.h" #include #include #include #include #include #ifndef __UNIXOS2__ #include #endif #include #include "clientstr.h" #include "X11/Xpoll.h" #include "osdep.h" #include "globals.h" #include "dispatch.h" /* check for both EAGAIN and EWOULDBLOCK, because some supposedly POSIX * systems are broken and return EWOULDBLOCK when they should return EAGAIN */ #if defined(EAGAIN) && defined(EWOULDBLOCK) #define ETEST(err) (err == EAGAIN || err == EWOULDBLOCK) #else #ifdef EAGAIN #define ETEST(err) (err == EAGAIN) #else #define ETEST(err) (err == EWOULDBLOCK) #endif #endif static int timesThisConnection = 0; static ConnectionInputPtr FreeInputs = (ConnectionInputPtr) NULL; static ConnectionOutputPtr FreeOutputs = (ConnectionOutputPtr) NULL; static OsCommPtr AvailableInput = (OsCommPtr) NULL; extern int xfd_ffs(fd_mask); static ConnectionInputPtr AllocateInputBuffer(void); static ConnectionOutputPtr AllocateOutputBuffer(void); #define MAX_TIMES_PER 10 #define yield_control() \ { isItTimeToYield = TRUE; \ timesThisConnection = 0; } #define yield_control_no_input() \ { yield_control(); \ FD_CLR(fd, &ClientsWithInput); } #define yield_control_death() \ { timesThisConnection = 0; } #define request_length(req, client) \ ((int)((client)->swapped ? lswaps((req)->length) : (req)->length) << 2) int ReadRequest(ClientPtr client) { OsCommPtr oc; ConnectionInputPtr oci; fsReq *request; int fd, result, gotnow, needed = 0; if (client == NULL) return -1; oc = (OsCommPtr) client->osPrivate; if (oc == NULL) return -1; oci = oc->input; fd = oc->fd; if (oci != NULL && fd < 0) return -1; if (AvailableInput) { if (AvailableInput != oc) { ConnectionInputPtr aci = AvailableInput->input; if (aci->size > BUFWATERMARK) { fsfree(aci->buffer); fsfree(aci); } else { aci->next = FreeInputs; FreeInputs = aci; } AvailableInput->input = (ConnectionInputPtr) NULL; } AvailableInput = (OsCommPtr) NULL; } if (!oci) { if ((oci = FreeInputs ) != (ConnectionInputPtr) 0) { FreeInputs = oci->next; } else if (!(oci = AllocateInputBuffer())) { yield_control_death(); return -1; } oc->input = oci; } oci->bufptr += oci->lenLastReq; gotnow = oci->bufcnt + oci->buffer - oci->bufptr; #ifdef WORD64 /* need 8-byte alignment */ if ((oci->bufptr - oci->buffer) & 7 && gotnow > 0) { memmove( oci->buffer, oci->bufptr, gotnow); oci->bufptr = oci->buffer; oci->bufcnt = gotnow; } #endif request = (fsReq *) oci->bufptr; /* not enough for a request */ if ((gotnow < SIZEOF(fsReq)) || (gotnow < (needed = request_length(request, client)))) { oci->lenLastReq = 0; if ((gotnow < SIZEOF(fsReq)) || needed == 0) needed = SIZEOF(fsReq); else if (needed > MAXBUFSIZE) { yield_control_death(); return -1; } /* see if we need to shift up a partial request so the rest can fit */ if ((gotnow == 0) || ((oci->bufptr - oci->buffer + needed) > oci->size)) { if ((gotnow > 0) && (oci->bufptr != oci->buffer)) memmove( oci->buffer, oci->bufptr, gotnow); /* grow buffer if necessary */ if (needed > oci->size) { char *ibuf; ibuf = (char *) fsrealloc(oci->buffer, needed); if (!ibuf) { yield_control_death(); return -1; } oci->size = needed; oci->buffer = ibuf; } oci->bufptr = oci->buffer; oci->bufcnt = gotnow; } /* fill 'er up */ if (oc->trans_conn == NULL) { yield_control_death(); return -1; } result = _FontTransRead(oc->trans_conn, oci->buffer + oci->bufcnt, oci->size - oci->bufcnt); if (result <= 0) { #if !(defined(SVR4) && defined(i386) && !defined(sun)) if ((result < 0) && ETEST(errno)) { yield_control_no_input(); return 0; } else #endif { yield_control_death(); return -1; } } oci->bufcnt += result; gotnow += result; /* free up space after huge requests */ if ((oci->size > BUFWATERMARK) && (oci->bufcnt < BUFSIZE) && (needed < BUFSIZE)) { char *ibuf; ibuf = (char *) fsrealloc(oci->buffer, BUFSIZE); if (ibuf) { oci->size = BUFSIZE; oci->buffer = ibuf; oci->bufptr = ibuf + oci->bufcnt - gotnow; } } request = (fsReq *) oci->bufptr; if ((gotnow < SIZEOF(fsReq)) || (gotnow < (needed = request_length(request, client)))) { yield_control_no_input(); return 0; } } if (needed == 0) needed = SIZEOF(fsReq); oci->lenLastReq = needed; /* * Check to see if client has at least one whole request in the buffer. If * there is only a partial request, treat like buffer is empty so that * select() will be called again and other clients can get into the queue. */ if (gotnow >= needed + SIZEOF(fsReq)) { request = (fsReq *) (oci->bufptr + needed); if (gotnow >= needed + request_length(request, client)) FD_SET(fd, &ClientsWithInput); else yield_control_no_input(); } else { if (gotnow == needed) AvailableInput = oc; yield_control_no_input(); } if (++timesThisConnection >= MAX_TIMES_PER) yield_control(); client->requestBuffer = (pointer) oci->bufptr; return needed; } Bool InsertFakeRequest(ClientPtr client, char *data, int count) { OsCommPtr oc = (OsCommPtr) client->osPrivate; ConnectionInputPtr oci = oc->input; int fd = oc->fd; fsReq *request; int gotnow, moveup; if (AvailableInput) { if (AvailableInput != oc) { register ConnectionInputPtr aci = AvailableInput->input; if (aci->size > BUFWATERMARK) { fsfree(aci->buffer); fsfree(aci); } else { aci->next = FreeInputs; FreeInputs = aci; } AvailableInput->input = (ConnectionInputPtr) NULL; } AvailableInput = (OsCommPtr) NULL; } if (!oci) { if ((oci = FreeInputs) != (ConnectionInputPtr) 0) FreeInputs = oci->next; else if (!(oci = AllocateInputBuffer())) return FALSE; oc->input = oci; } oci->bufptr += oci->lenLastReq; oci->lenLastReq = 0; gotnow = oci->bufcnt + oci->buffer - oci->bufptr; if ((gotnow + count) > oci->size) { char *ibuf; ibuf = (char *) fsrealloc(oci->buffer, gotnow + count); if (!ibuf) return FALSE; oci->size = gotnow + count; oci->buffer = ibuf; oci->bufptr = ibuf + oci->bufcnt - gotnow; } moveup = count - (oci->bufptr - oci->buffer); if (moveup > 0) { if (gotnow > 0) memmove( oci->bufptr + moveup, oci->bufptr, gotnow); oci->bufptr += moveup; oci->bufcnt += moveup; } memmove( oci->bufptr - count, data, count); oci->bufptr -= count; request = (fsReq *) oci->bufptr; gotnow += count; if ((gotnow >= SIZEOF(fsReq)) && (gotnow >= request_length(request, client))) FD_SET(fd, &ClientsWithInput); else yield_control_no_input(); return TRUE; } void ResetCurrentRequest(ClientPtr client) { OsCommPtr oc = (OsCommPtr) client->osPrivate; ConnectionInputPtr oci = oc->input; int fd = oc->fd; fsReq *request; int gotnow; if (AvailableInput == oc) AvailableInput = (OsCommPtr) NULL; oci->lenLastReq = 0; request = (fsReq *) oci->bufptr; gotnow = oci->bufcnt + oci->buffer - oci->bufptr; if ((gotnow >= SIZEOF(fsReq)) && (gotnow >= request_length(request, client))) { FD_SET(fd, &ClientsWithInput); yield_control(); } else { yield_control_no_input(); } } int FlushClient( ClientPtr client, OsCommPtr oc, char *extraBuf, int extraCount, int padsize) { ConnectionOutputPtr oco = oc->output; int fd = oc->fd; struct iovec iov[3]; char padBuffer[3]; long written; long notWritten; long todo; if (!oco) return 0; written = 0; notWritten = oco->count + extraCount + padsize; todo = notWritten; while (notWritten) { long before = written; long remain = todo; int i = 0; long len; /*- * You could be very general here and have "in" and "out" iovecs and * write a loop without using a macro, but what the heck. This * translates to: * * how much of this piece is new? * if more new then we are trying this time, clamp * if nothing new * then bump down amount already written, for next piece * else put new stuff in iovec, will need all of next piece * * Note that todo had better be at least 1 or else we'll end up * writing 0 iovecs. */ #define InsertIOV(pointer, length) \ len = (length) - before; \ if (len > remain) \ len = remain; \ if (len <= 0) { \ before = (-len); \ } else { \ iov[i].iov_len = len; \ iov[i].iov_base = (pointer) + before; \ i++; \ remain -= len; \ before = 0; \ } InsertIOV((char *) oco->buf, oco->count); InsertIOV(extraBuf, extraCount); InsertIOV(padBuffer, padsize); errno = 0; if (oc->trans_conn && (len = _FontTransWritev(oc->trans_conn, iov, i)) >= 0) { written += len; notWritten -= len; todo = notWritten; } else if (ETEST(errno) #ifdef SUNSYSV /* check for another brain-damaged OS bug */ || (errno == 0) #endif #ifdef EMSGSIZE /* check for another brain-damaged OS bug */ || ((errno == EMSGSIZE) && (todo == 1)) #endif ) { FD_SET(fd, &ClientsWriteBlocked); AnyClientsWriteBlocked = TRUE; if (written < oco->count) { if (written > 0) { oco->count -= written; memmove( (char *) oco->buf, (char *) oco->buf + written, oco->count); written = 0; } } else { written -= oco->count; oco->count = 0; } /* grow buffer if necessary */ if (notWritten > oco->size) { unsigned char *obuf; obuf = (unsigned char *) fsrealloc(oco->buf, notWritten + OutputBufferSize); if (!obuf) { if (oc->trans_conn) _FontTransClose(oc->trans_conn); oc->trans_conn = NULL; MarkClientException(client); oco->count = 0; return -1; } oco->size = notWritten + OutputBufferSize; oco->buf = obuf; } if ((len = extraCount - written) > 0) { memmove( (char *) oco->buf + oco->count, extraBuf + written, len); } oco->count = notWritten; return extraCount; } #ifdef EMSGSIZE /* check for another brain-damaged OS bug */ else if (errno == EMSGSIZE) { todo >>= 1; } #endif else { if (oc->trans_conn) _FontTransClose(oc->trans_conn); oc->trans_conn = NULL; MarkClientException(client); oco->count = 0; return -1; } } /* everything was flushed */ oco->count = 0; /* clear the write block if it was set */ if (AnyClientsWriteBlocked) { FD_CLR(fd, &ClientsWriteBlocked); if (!XFD_ANYSET(&ClientsWriteBlocked)) AnyClientsWriteBlocked = FALSE; } if (oco->size > BUFWATERMARK) { fsfree(oco->buf); fsfree(oco); } else { oco->next = FreeOutputs; FreeOutputs = oco; } oc->output = (ConnectionOutputPtr) NULL; return extraCount; } void FlushAllOutput(void) { int index, base; fd_mask mask; OsCommPtr oc; ClientPtr client; if (!NewOutputPending) return; NewOutputPending = FALSE; for (base = 0; base < howmany(XFD_SETSIZE, NFDBITS); base++) { mask = OutputPending.fds_bits[base]; OutputPending.fds_bits[base] = 0; while (mask) { index = xfd_ffs(mask) - 1; mask &= ~lowbit(mask); if ((index = ConnectionTranslation[(base * (sizeof(fd_mask) * 8)) + index]) == 0) continue; client = clients[index]; if (client->clientGone == CLIENT_GONE) continue; oc = (OsCommPtr) client->osPrivate; if (FD_ISSET(oc->fd, &ClientsWithInput)) { FD_SET(oc->fd, &OutputPending); NewOutputPending = TRUE; } else { (void) FlushClient(client, oc, (char *) NULL, 0, 0); } } } } /* * returns number of bytes written */ static int write_to_client_internal(ClientPtr client, int count, char *buf, int padBytes) { OsCommPtr oc = (OsCommPtr) client->osPrivate; ConnectionOutputPtr oco = oc->output; if (!count) return 0; if (!oco) { if ((oco = FreeOutputs) != (ConnectionOutputPtr) 0) { FreeOutputs = oco->next; } else if (!(oco = AllocateOutputBuffer())) { _FontTransClose(oc->trans_conn); oc->trans_conn = NULL; MarkClientException(client); return -1; } oc->output = oco; } if (oco->count + count + padBytes > oco->size) { FD_CLR(oc->fd, &OutputPending); NewOutputPending = FALSE; return FlushClient(client, oc, buf, count, padBytes); } NewOutputPending = TRUE; FD_SET(oc->fd, &OutputPending); memmove( (char *) oco->buf + oco->count, buf, count); oco->count += count + padBytes; return count; } void WriteToClientUnpadded(ClientPtr client, int count, char *buf) { write_to_client_internal(client, count, buf, 0); } static int padlength[4] = {0, 3, 2, 1}; void WriteToClient(ClientPtr client, int count, char *buf) { int flag = 0; if (NULL == buf) { flag = -1; buf = (char *)fsalloc(count); memset(buf, 0, count); } write_to_client_internal(client, count, buf, padlength[count & 3]); if (flag) fsfree(buf); } static ConnectionInputPtr AllocateInputBuffer(void) { register ConnectionInputPtr oci; oci = (ConnectionInputPtr) fsalloc(sizeof(ConnectionInput)); if (!oci) return (ConnectionInputPtr) NULL; oci->buffer = (char *) fsalloc(BUFSIZE); if (!oci->buffer) { fsfree(oci); return (ConnectionInputPtr) NULL; } oci->next = NULL; oci->size = BUFSIZE; oci->bufptr = oci->buffer; oci->bufcnt = 0; oci->lenLastReq = 0; return oci; } static ConnectionOutputPtr AllocateOutputBuffer(void) { register ConnectionOutputPtr oco; oco = (ConnectionOutputPtr) fsalloc(sizeof(ConnectionOutput)); if (!oco) return (ConnectionOutputPtr) NULL; oco->buf = (unsigned char *) fsalloc(BUFSIZE); if (!oco->buf) { fsfree(oco); return (ConnectionOutputPtr) NULL; } oco->size = BUFSIZE; oco->count = 0; return oco; } void FreeOsBuffers(OsCommPtr oc) { register ConnectionInputPtr oci; register ConnectionOutputPtr oco; if (AvailableInput == oc) AvailableInput = (OsCommPtr) NULL; if ((oci = oc->input) != (ConnectionInputPtr) 0) { if (FreeInputs) { fsfree(oci->buffer); fsfree(oci); } else { FreeInputs = oci; oci->next = (ConnectionInputPtr) NULL; oci->bufptr = oci->buffer; oci->bufcnt = 0; oci->lenLastReq = 0; } } if ((oco = oc->output) != (ConnectionOutputPtr) 0) { if (FreeOutputs) { fsfree(oco->buf); fsfree(oco); } else { FreeOutputs = oco; oco->next = (ConnectionOutputPtr) NULL; oco->count = 0; } } } void ResetOsBuffers(void) { register ConnectionInputPtr oci; register ConnectionOutputPtr oco; while ((oci = FreeInputs) != (ConnectionInputPtr) 0) { FreeInputs = oci->next; fsfree(oci->buffer); fsfree(oci); } while ((oco = FreeOutputs) != (ConnectionOutputPtr) 0) { FreeOutputs = oco->next; fsfree(oco->buf); fsfree(oco); } }