/* * tclIO.c -- * * This file provides the generic portions (those that are the same on * all platforms and for all channel types) of Tcl's IO facilities. * * Copyright (c) 1998-2000 Ajuba Solutions * Copyright (c) 1995-1997 Sun Microsystems, Inc. * Contributions from Don Porter, NIST, 2014. (not subject to US copyright) * * See the file "license.terms" for information on usage and redistribution of * this file, and for a DISCLAIMER OF ALL WARRANTIES. */ #include "tclInt.h" #include "tclIO.h" #include /* * For each channel handler registered in a call to Tcl_CreateChannelHandler, * there is one record of the following type. All of records for a specific * channel are chained together in a singly linked list which is stored in * the channel structure. */ typedef struct ChannelHandler { Channel *chanPtr; /* The channel structure for this channel. */ int mask; /* Mask of desired events. */ Tcl_ChannelProc *proc; /* Procedure to call in the type of * Tcl_CreateChannelHandler. */ ClientData clientData; /* Argument to pass to procedure. */ struct ChannelHandler *nextPtr; /* Next one in list of registered handlers. */ } ChannelHandler; /* * This structure keeps track of the current ChannelHandler being invoked in * the current invocation of Tcl_NotifyChannel. There is a potential * problem if a ChannelHandler is deleted while it is the current one, since * Tcl_NotifyChannel needs to look at the nextPtr field. To handle this * problem, structures of the type below indicate the next handler to be * processed for any (recursively nested) dispatches in progress. The * nextHandlerPtr field is updated if the handler being pointed to is deleted. * The nestedHandlerPtr field is used to chain together all recursive * invocations, so that Tcl_DeleteChannelHandler can find all the recursively * nested invocations of Tcl_NotifyChannel and compare the handler being * deleted against the NEXT handler to be invoked in that invocation; when it * finds such a situation, Tcl_DeleteChannelHandler updates the nextHandlerPtr * field of the structure to the next handler. */ typedef struct NextChannelHandler { ChannelHandler *nextHandlerPtr; /* The next handler to be invoked in * this invocation. */ struct NextChannelHandler *nestedHandlerPtr; /* Next nested invocation of * Tcl_NotifyChannel. */ } NextChannelHandler; /* * The following structure is used by Tcl_GetsObj() to encapsulates the * state for a "gets" operation. */ typedef struct GetsState { Tcl_Obj *objPtr; /* The object to which UTF-8 characters * will be appended. */ char **dstPtr; /* Pointer into objPtr's string rep where * next character should be stored. */ Tcl_Encoding encoding; /* The encoding to use to convert raw bytes * to UTF-8. */ ChannelBuffer *bufPtr; /* The current buffer of raw bytes being * emptied. */ Tcl_EncodingState state; /* The encoding state just before the last * external to UTF-8 conversion in * FilterInputBytes(). */ int rawRead; /* The number of bytes removed from bufPtr * in the last call to FilterInputBytes(). */ int bytesWrote; /* The number of bytes of UTF-8 data * appended to objPtr during the last call to * FilterInputBytes(). */ int charsWrote; /* The corresponding number of UTF-8 * characters appended to objPtr during the * last call to FilterInputBytes(). */ int totalChars; /* The total number of UTF-8 characters * appended to objPtr so far, just before the * last call to FilterInputBytes(). */ } GetsState; /* * The following structure encapsulates the state for a background channel * copy. Note that the data buffer for the copy will be appended to this * structure. */ typedef struct CopyState { struct Channel *readPtr; /* Pointer to input channel. */ struct Channel *writePtr; /* Pointer to output channel. */ int readFlags; /* Original read channel flags. */ int writeFlags; /* Original write channel flags. */ Tcl_WideInt toRead; /* Number of bytes to copy, or -1. */ Tcl_WideInt total; /* Total bytes transferred (written). */ Tcl_Interp *interp; /* Interp that started the copy. */ Tcl_Obj *cmdPtr; /* Command to be invoked at completion. */ int bufSize; /* Size of appended buffer. */ char buffer[1]; /* Copy buffer, this must be the last * field. */ } CopyState; /* * All static variables used in this file are collected into a single instance * of the following structure. For multi-threaded implementations, there is * one instance of this structure for each thread. * * Notice that different structures with the same name appear in other files. * The structure defined below is used in this file only. */ typedef struct { NextChannelHandler *nestedHandlerPtr; /* This variable holds the list of nested * Tcl_NotifyChannel invocations. */ ChannelState *firstCSPtr; /* List of all channels currently open, * indexed by ChannelState, as only one * ChannelState exists per set of stacked * channels. */ Tcl_Channel stdinChannel; /* Static variable for the stdin channel. */ int stdinInitialized; Tcl_Channel stdoutChannel; /* Static variable for the stdout channel. */ int stdoutInitialized; Tcl_Channel stderrChannel; /* Static variable for the stderr channel. */ int stderrInitialized; Tcl_Encoding binaryEncoding; } ThreadSpecificData; static Tcl_ThreadDataKey dataKey; /* * Structure to record a close callback. One such record exists for * each close callback registered for a channel. */ typedef struct CloseCallback { Tcl_CloseProc *proc; /* The procedure to call. */ ClientData clientData; /* Arbitrary one-word data to pass * to the callback. */ struct CloseCallback *nextPtr; /* For chaining close callbacks. */ } CloseCallback; /* * Static functions in this file: */ static ChannelBuffer * AllocChannelBuffer(int length); static void PreserveChannelBuffer(ChannelBuffer *bufPtr); static void ReleaseChannelBuffer(ChannelBuffer *bufPtr); static int IsShared(ChannelBuffer *bufPtr); static void ChannelFree(Channel *chanPtr); static void ChannelTimerProc(ClientData clientData); static int ChanRead(Channel *chanPtr, char *dst, int dstSize); static int CheckChannelErrors(ChannelState *statePtr, int direction); static int CheckForDeadChannel(Tcl_Interp *interp, ChannelState *statePtr); static void CheckForStdChannelsBeingClosed(Tcl_Channel chan); static void CleanupChannelHandlers(Tcl_Interp *interp, Channel *chanPtr); static int CloseChannel(Tcl_Interp *interp, Channel *chanPtr, int errorCode); static int CloseChannelPart(Tcl_Interp *interp, Channel *chanPtr, int errorCode, int flags); static int CloseWrite(Tcl_Interp *interp, Channel *chanPtr); static void CommonGetsCleanup(Channel *chanPtr); static int CopyData(CopyState *csPtr, int mask); static int MoveBytes(CopyState *csPtr); static void MBCallback(CopyState *csPtr, Tcl_Obj *errObj); static void MBError(CopyState *csPtr, int mask, int errorCode); static int MBRead(CopyState *csPtr); static int MBWrite(CopyState *csPtr); static void MBEvent(ClientData clientData, int mask); static void CopyEventProc(ClientData clientData, int mask); static void CreateScriptRecord(Tcl_Interp *interp, Channel *chanPtr, int mask, Tcl_Obj *scriptPtr); static void DeleteChannelTable(ClientData clientData, Tcl_Interp *interp); static void DeleteScriptRecord(Tcl_Interp *interp, Channel *chanPtr, int mask); static int DetachChannel(Tcl_Interp *interp, Tcl_Channel chan); static void DiscardInputQueued(ChannelState *statePtr, int discardSavedBuffers); static void DiscardOutputQueued(ChannelState *chanPtr); static int DoRead(Channel *chanPtr, char *dst, int bytesToRead, int allowShortReads); static int DoReadChars(Channel *chan, Tcl_Obj *objPtr, int toRead, int appendFlag); static int FilterInputBytes(Channel *chanPtr, GetsState *statePtr); static int FlushChannel(Tcl_Interp *interp, Channel *chanPtr, int calledFromAsyncFlush); static int TclGetsObjBinary(Tcl_Channel chan, Tcl_Obj *objPtr); static Tcl_Encoding GetBinaryEncoding(); static void FreeBinaryEncoding(ClientData clientData); static Tcl_HashTable * GetChannelTable(Tcl_Interp *interp); static int GetInput(Channel *chanPtr); static int HaveVersion(const Tcl_ChannelType *typePtr, Tcl_ChannelTypeVersion minimumVersion); static void PeekAhead(Channel *chanPtr, char **dstEndPtr, GetsState *gsPtr); static int ReadBytes(ChannelState *statePtr, Tcl_Obj *objPtr, int charsLeft); static int ReadChars(ChannelState *statePtr, Tcl_Obj *objPtr, int charsLeft, int *factorPtr); static void RecycleBuffer(ChannelState *statePtr, ChannelBuffer *bufPtr, int mustDiscard); static int StackSetBlockMode(Channel *chanPtr, int mode); static int SetBlockMode(Tcl_Interp *interp, Channel *chanPtr, int mode); static void StopCopy(CopyState *csPtr); static void TranslateInputEOL(ChannelState *statePtr, char *dst, const char *src, int *dstLenPtr, int *srcLenPtr); static void UpdateInterest(Channel *chanPtr); static int Write(Channel *chanPtr, const char *src, int srcLen, Tcl_Encoding encoding); static Tcl_Obj * FixLevelCode(Tcl_Obj *msg); static void SpliceChannel(Tcl_Channel chan); static void CutChannel(Tcl_Channel chan); static int WillRead(Channel *chanPtr); #define WriteChars(chanPtr, src, srcLen) \ Write(chanPtr, src, srcLen, chanPtr->state->encoding) #define WriteBytes(chanPtr, src, srcLen) \ Write(chanPtr, src, srcLen, tclIdentityEncoding) /* * Simplifying helper macros. All may use their argument(s) multiple times. * The ANSI C "prototypes" for the macros are listed below, together with a * short description of what the macro does. * * -------------------------------------------------------------------------- * int BytesLeft(ChannelBuffer *bufPtr) * * Returns the number of bytes of data remaining in the buffer. * * int SpaceLeft(ChannelBuffer *bufPtr) * * Returns the number of bytes of space remaining at the end of the * buffer. * * int IsBufferReady(ChannelBuffer *bufPtr) * * Returns whether a buffer has bytes available within it. * * int IsBufferEmpty(ChannelBuffer *bufPtr) * * Returns whether a buffer is entirely empty. Note that this is not the * inverse of the above operation; trying to merge the two seems to lead * to occasional crashes... * * int IsBufferFull(ChannelBuffer *bufPtr) * * Returns whether more data can be added to a buffer. * * int IsBufferOverflowing(ChannelBuffer *bufPtr) * * Returns whether a buffer has more data in it than it should. * * char *InsertPoint(ChannelBuffer *bufPtr) * * Returns a pointer to where characters should be added to the buffer. * * char *RemovePoint(ChannelBuffer *bufPtr) * * Returns a pointer to where characters should be removed from the * buffer. * -------------------------------------------------------------------------- */ #define BytesLeft(bufPtr) ((bufPtr)->nextAdded - (bufPtr)->nextRemoved) #define SpaceLeft(bufPtr) ((bufPtr)->bufLength - (bufPtr)->nextAdded) #define IsBufferReady(bufPtr) ((bufPtr)->nextAdded > (bufPtr)->nextRemoved) #define IsBufferEmpty(bufPtr) ((bufPtr)->nextAdded == (bufPtr)->nextRemoved) #define IsBufferFull(bufPtr) ((bufPtr) && (bufPtr)->nextAdded >= (bufPtr)->bufLength) #define IsBufferOverflowing(bufPtr) ((bufPtr)->nextAdded>(bufPtr)->bufLength) #define InsertPoint(bufPtr) ((bufPtr)->buf + (bufPtr)->nextAdded) #define RemovePoint(bufPtr) ((bufPtr)->buf + (bufPtr)->nextRemoved) /* * For working with channel state flag bits. */ #define SetFlag(statePtr, flag) ((statePtr)->flags |= (flag)) #define ResetFlag(statePtr, flag) ((statePtr)->flags &= ~(flag)) #define GotFlag(statePtr, flag) ((statePtr)->flags & (flag)) /* * Macro for testing whether a string (in optionName, length len) matches a * value (prefix matching rules). Arguments are the minimum length to match * and the value to match against. (Can't use Tcl_GetIndexFromObj as this is * used in a situation where no objects are available.) */ #define HaveOpt(minLength, nameString) \ ((len > (minLength)) && (optionName[1] == (nameString)[1]) \ && (strncmp(optionName, (nameString), len) == 0)) /* * The ChannelObjType type. Used to store the result of looking up * a channel name in the context of an interp. Saves the lookup * result and values needed to check its continued validity. */ typedef struct ResolvedChanName { ChannelState *statePtr; /* The saved lookup result */ Tcl_Interp *interp; /* The interp in which the lookup was done. */ size_t epoch; /* The epoch of the channel when the lookup * was done. Use to verify validity. */ size_t refCount; /* Share this struct among many Tcl_Obj. */ } ResolvedChanName; static void DupChannelIntRep(Tcl_Obj *objPtr, Tcl_Obj *copyPtr); static void FreeChannelIntRep(Tcl_Obj *objPtr); static const Tcl_ObjType chanObjType = { "channel", /* name for this type */ FreeChannelIntRep, /* freeIntRepProc */ DupChannelIntRep, /* dupIntRepProc */ NULL, /* updateStringProc */ NULL /* setFromAnyProc */ }; #define BUSY_STATE(st, fl) \ ((((st)->csPtrR) && ((fl) & TCL_READABLE)) || \ (((st)->csPtrW) && ((fl) & TCL_WRITABLE))) #define MAX_CHANNEL_BUFFER_SIZE (1024*1024) /* *--------------------------------------------------------------------------- * * ChanClose, ChanRead, ChanSeek, ChanThreadAction, ChanWatch, ChanWrite -- * * Simplify the access to selected channel driver "methods" that are used * in multiple places in a stereotypical fashion. These are just thin * wrappers around the driver functions. * *--------------------------------------------------------------------------- */ static inline int ChanClose( Channel *chanPtr, Tcl_Interp *interp) { if (chanPtr->typePtr->closeProc != TCL_CLOSE2PROC) { return chanPtr->typePtr->closeProc(chanPtr->instanceData, interp); } else { return chanPtr->typePtr->close2Proc(chanPtr->instanceData, interp, 0); } } static inline int ChanCloseHalf( Channel *chanPtr, Tcl_Interp *interp, int flags) { return chanPtr->typePtr->close2Proc(chanPtr->instanceData, interp, flags); } /* *--------------------------------------------------------------------------- * * ChanRead -- * * Read up to dstSize bytes using the inputProc of chanPtr, store them at * dst, and return the number of bytes stored. * * Results: * The return value of the driver inputProc, * - number of bytes stored at dst, ot * - -1 on error, with a Posix error code available to the caller by * calling Tcl_GetErrno(). * * Side effects: * The CHANNEL_BLOCKED and CHANNEL_EOF flags of the channel state are set * as appropriate. On EOF, the inputEncodingFlags are set to perform * ending operations on decoding. * * TODO - Is this really the right place for that? * *--------------------------------------------------------------------------- */ static int ChanRead( Channel *chanPtr, char *dst, int dstSize) { int bytesRead, result; /* * If the caller asked for zero bytes, we'd force the inputProc to return * zero bytes, and then misinterpret that as EOF. */ assert(dstSize > 0); /* * Each read op must set the blocked and eof states anew, not let * the effect of prior reads leak through. */ if (GotFlag(chanPtr->state, CHANNEL_EOF)) { chanPtr->state->inputEncodingFlags |= TCL_ENCODING_START; } ResetFlag(chanPtr->state, CHANNEL_BLOCKED | CHANNEL_EOF); chanPtr->state->inputEncodingFlags &= ~TCL_ENCODING_END; if (WillRead(chanPtr) < 0) { return -1; } bytesRead = chanPtr->typePtr->inputProc(chanPtr->instanceData, dst, dstSize, &result); /* * Stop any flag leakage through stacked channel levels. */ if (GotFlag(chanPtr->state, CHANNEL_EOF)) { chanPtr->state->inputEncodingFlags |= TCL_ENCODING_START; } ResetFlag(chanPtr->state, CHANNEL_BLOCKED | CHANNEL_EOF); chanPtr->state->inputEncodingFlags &= ~TCL_ENCODING_END; if (bytesRead > 0) { /* * If we get a short read, signal up that we may be BLOCKED. We should * avoid calling the driver because on some platforms we will block in * the low level reading code even though the channel is set into * nonblocking mode. */ if (bytesRead < dstSize) { SetFlag(chanPtr->state, CHANNEL_BLOCKED); } } else if (bytesRead == 0) { SetFlag(chanPtr->state, CHANNEL_EOF); chanPtr->state->inputEncodingFlags |= TCL_ENCODING_END; } else if (bytesRead < 0) { if ((result == EWOULDBLOCK) || (result == EAGAIN)) { SetFlag(chanPtr->state, CHANNEL_BLOCKED); result = EAGAIN; } Tcl_SetErrno(result); } return bytesRead; } static inline Tcl_WideInt ChanSeek( Channel *chanPtr, Tcl_WideInt offset, int mode, int *errnoPtr) { /* * Note that we prefer the wideSeekProc if that field is available in the * type and non-NULL. */ if (HaveVersion(chanPtr->typePtr, TCL_CHANNEL_VERSION_3) && chanPtr->typePtr->wideSeekProc != NULL) { return chanPtr->typePtr->wideSeekProc(chanPtr->instanceData, offset, mode, errnoPtr); } if (offsetTcl_LongAsWide(LONG_MAX)) { *errnoPtr = EOVERFLOW; return Tcl_LongAsWide(-1); } return Tcl_LongAsWide(chanPtr->typePtr->seekProc(chanPtr->instanceData, Tcl_WideAsLong(offset), mode, errnoPtr)); } static inline void ChanThreadAction( Channel *chanPtr, int action) { Tcl_DriverThreadActionProc *threadActionProc = Tcl_ChannelThreadActionProc(chanPtr->typePtr); if (threadActionProc != NULL) { threadActionProc(chanPtr->instanceData, action); } } static inline void ChanWatch( Channel *chanPtr, int mask) { chanPtr->typePtr->watchProc(chanPtr->instanceData, mask); } static inline int ChanWrite( Channel *chanPtr, const char *src, int srcLen, int *errnoPtr) { return chanPtr->typePtr->outputProc(chanPtr->instanceData, src, srcLen, errnoPtr); } /* *--------------------------------------------------------------------------- * * TclInitIOSubsystem -- * * Initialize all resources used by this subsystem on a per-process * basis. * * Results: * None. * * Side effects: * Depends on the memory subsystems. * *--------------------------------------------------------------------------- */ void TclInitIOSubsystem(void) { /* * By fetching thread local storage we take care of allocating it for each * thread. */ (void) TCL_TSD_INIT(&dataKey); } /* *------------------------------------------------------------------------- * * TclFinalizeIOSubsystem -- * * Releases all resources used by this subsystem on a per-process basis. * Closes all extant channels that have not already been closed because * they were not owned by any interp. * * Results: * None. * * Side effects: * Depends on encoding and memory subsystems. * *------------------------------------------------------------------------- */ /* ARGSUSED */ void TclFinalizeIOSubsystem(void) { ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); Channel *chanPtr = NULL; /* Iterates over open channels. */ ChannelState *statePtr; /* State of channel stack */ int active = 1; /* Flag == 1 while there's still work to do */ int doflushnb; /* * Fetch the pre-TIP#398 compatibility flag. */ { const char *s; Tcl_DString ds; s = TclGetEnv("TCL_FLUSH_NONBLOCKING_ON_EXIT", &ds); doflushnb = ((s != NULL) && strcmp(s, "0")); if (s != NULL) { Tcl_DStringFree(&ds); } } /* * Walk all channel state structures known to this thread and close * corresponding channels. */ while (active) { /* * Iterate through the open channel list, and find the first channel * that isn't dead. We start from the head of the list each time, * because the close action on one channel can close others. */ active = 0; for (statePtr = tsdPtr->firstCSPtr; statePtr != NULL; statePtr = statePtr->nextCSPtr) { chanPtr = statePtr->topChanPtr; if (GotFlag(statePtr, CHANNEL_DEAD)) { continue; } if (!GotFlag(statePtr, CHANNEL_INCLOSE | CHANNEL_CLOSED ) || GotFlag(statePtr, BG_FLUSH_SCHEDULED)) { ResetFlag(statePtr, BG_FLUSH_SCHEDULED); active = 1; break; } } /* * We've found a live (or bg-closing) channel. Close it. */ if (active) { TclChannelPreserve((Tcl_Channel)chanPtr); /* * TIP #398: by default, we no longer set the channel back into * blocking mode. To restore the old blocking behavior, the * environment variable TCL_FLUSH_NONBLOCKING_ON_EXIT must be set * and not be "0". */ if (doflushnb) { /* * Set the channel back into blocking mode to ensure that we * wait for all data to flush out. */ (void) Tcl_SetChannelOption(NULL, (Tcl_Channel) chanPtr, "-blocking", "on"); } if ((chanPtr == (Channel *) tsdPtr->stdinChannel) || (chanPtr == (Channel *) tsdPtr->stdoutChannel) || (chanPtr == (Channel *) tsdPtr->stderrChannel)) { /* * Decrement the refcount which was earlier artificially * bumped up to keep the channel from being closed. */ statePtr->refCount--; } if (statePtr->refCount <= 0) { /* * Close it only if the refcount indicates that the channel is * not referenced from any interpreter. If it is, that * interpreter will close the channel when it gets destroyed. */ (void) Tcl_Close(NULL, (Tcl_Channel) chanPtr); } else { /* * The refcount is greater than zero, so flush the channel. */ Tcl_Flush((Tcl_Channel) chanPtr); /* * Call the device driver to actually close the underlying * device for this channel. */ (void) ChanClose(chanPtr, NULL); /* * Finally, we clean up the fields in the channel data * structure since all of them have been deleted already. We * mark the channel with CHANNEL_DEAD to prevent any further * IO operations on it. */ chanPtr->instanceData = NULL; SetFlag(statePtr, CHANNEL_DEAD); } TclChannelRelease((Tcl_Channel)chanPtr); } } TclpFinalizeSockets(); TclpFinalizePipes(); } /* *---------------------------------------------------------------------- * * Tcl_SetStdChannel -- * * This function is used to change the channels that are used for * stdin/stdout/stderr in new interpreters. * * Results: * None * * Side effects: * None. * *---------------------------------------------------------------------- */ void Tcl_SetStdChannel( Tcl_Channel channel, int type) /* One of TCL_STDIN, TCL_STDOUT, TCL_STDERR. */ { ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); switch (type) { case TCL_STDIN: tsdPtr->stdinInitialized = 1; tsdPtr->stdinChannel = channel; break; case TCL_STDOUT: tsdPtr->stdoutInitialized = 1; tsdPtr->stdoutChannel = channel; break; case TCL_STDERR: tsdPtr->stderrInitialized = 1; tsdPtr->stderrChannel = channel; break; } } /* *---------------------------------------------------------------------- * * Tcl_GetStdChannel -- * * Returns the specified standard channel. * * Results: * Returns the specified standard channel, or NULL. * * Side effects: * May cause the creation of a standard channel and the underlying file. * *---------------------------------------------------------------------- */ Tcl_Channel Tcl_GetStdChannel( int type) /* One of TCL_STDIN, TCL_STDOUT, TCL_STDERR. */ { Tcl_Channel channel = NULL; ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); /* * If the channels were not created yet, create them now and store them in * the static variables. */ switch (type) { case TCL_STDIN: if (!tsdPtr->stdinInitialized) { tsdPtr->stdinChannel = TclpGetDefaultStdChannel(TCL_STDIN); tsdPtr->stdinInitialized = 1; /* * Artificially bump the refcount to ensure that the channel is * only closed on exit. * * NOTE: Must only do this if stdinChannel is not NULL. It can be * NULL in situations where Tcl is unable to connect to the * standard input. */ if (tsdPtr->stdinChannel != NULL) { Tcl_RegisterChannel(NULL, tsdPtr->stdinChannel); } } channel = tsdPtr->stdinChannel; break; case TCL_STDOUT: if (!tsdPtr->stdoutInitialized) { tsdPtr->stdoutChannel = TclpGetDefaultStdChannel(TCL_STDOUT); tsdPtr->stdoutInitialized = 1; if (tsdPtr->stdoutChannel != NULL) { Tcl_RegisterChannel(NULL, tsdPtr->stdoutChannel); } } channel = tsdPtr->stdoutChannel; break; case TCL_STDERR: if (!tsdPtr->stderrInitialized) { tsdPtr->stderrChannel = TclpGetDefaultStdChannel(TCL_STDERR); tsdPtr->stderrInitialized = 1; if (tsdPtr->stderrChannel != NULL) { Tcl_RegisterChannel(NULL, tsdPtr->stderrChannel); } } channel = tsdPtr->stderrChannel; break; } return channel; } /* *---------------------------------------------------------------------- * * Tcl_CreateCloseHandler * * Creates a close callback which will be called when the channel is * closed. * * Results: * None. * * Side effects: * Causes the callback to be called in the future when the channel will * be closed. * *---------------------------------------------------------------------- */ void Tcl_CreateCloseHandler( Tcl_Channel chan, /* The channel for which to create the close * callback. */ Tcl_CloseProc *proc, /* The callback routine to call when the * channel will be closed. */ ClientData clientData) /* Arbitrary data to pass to the close * callback. */ { ChannelState *statePtr = ((Channel *) chan)->state; CloseCallback *cbPtr; cbPtr = ckalloc(sizeof(CloseCallback)); cbPtr->proc = proc; cbPtr->clientData = clientData; cbPtr->nextPtr = statePtr->closeCbPtr; statePtr->closeCbPtr = cbPtr; } /* *---------------------------------------------------------------------- * * Tcl_DeleteCloseHandler -- * * Removes a callback that would have been called on closing the channel. * If there is no matching callback then this function has no effect. * * Results: * None. * * Side effects: * The callback will not be called in the future when the channel is * eventually closed. * *---------------------------------------------------------------------- */ void Tcl_DeleteCloseHandler( Tcl_Channel chan, /* The channel for which to cancel the close * callback. */ Tcl_CloseProc *proc, /* The procedure for the callback to * remove. */ ClientData clientData) /* The callback data for the callback to * remove. */ { ChannelState *statePtr = ((Channel *) chan)->state; CloseCallback *cbPtr, *cbPrevPtr; for (cbPtr = statePtr->closeCbPtr, cbPrevPtr = NULL; cbPtr != NULL; cbPtr = cbPtr->nextPtr) { if ((cbPtr->proc == proc) && (cbPtr->clientData == clientData)) { if (cbPrevPtr == NULL) { statePtr->closeCbPtr = cbPtr->nextPtr; } else { cbPrevPtr->nextPtr = cbPtr->nextPtr; } ckfree(cbPtr); break; } cbPrevPtr = cbPtr; } } /* *---------------------------------------------------------------------- * * GetChannelTable -- * * Gets and potentially initializes the channel table for an interpreter. * If it is initializing the table it also inserts channels for stdin, * stdout and stderr if the interpreter is trusted. * * Results: * A pointer to the hash table created, for use by the caller. * * Side effects: * Initializes the channel table for an interpreter. May create channels * for stdin, stdout and stderr. * *---------------------------------------------------------------------- */ static Tcl_HashTable * GetChannelTable( Tcl_Interp *interp) { Tcl_HashTable *hTblPtr; /* Hash table of channels. */ Tcl_Channel stdinChan, stdoutChan, stderrChan; hTblPtr = Tcl_GetAssocData(interp, "tclIO", NULL); if (hTblPtr == NULL) { hTblPtr = ckalloc(sizeof(Tcl_HashTable)); Tcl_InitHashTable(hTblPtr, TCL_STRING_KEYS); Tcl_SetAssocData(interp, "tclIO", (Tcl_InterpDeleteProc *) DeleteChannelTable, hTblPtr); /* * If the interpreter is trusted (not "safe"), insert channels for * stdin, stdout and stderr (possibly creating them in the process). */ if (Tcl_IsSafe(interp) == 0) { stdinChan = Tcl_GetStdChannel(TCL_STDIN); if (stdinChan != NULL) { Tcl_RegisterChannel(interp, stdinChan); } stdoutChan = Tcl_GetStdChannel(TCL_STDOUT); if (stdoutChan != NULL) { Tcl_RegisterChannel(interp, stdoutChan); } stderrChan = Tcl_GetStdChannel(TCL_STDERR); if (stderrChan != NULL) { Tcl_RegisterChannel(interp, stderrChan); } } } return hTblPtr; } /* *---------------------------------------------------------------------- * * DeleteChannelTable -- * * Deletes the channel table for an interpreter, closing any open * channels whose refcount reaches zero. This procedure is invoked when * an interpreter is deleted, via the AssocData cleanup mechanism. * * Results: * None. * * Side effects: * Deletes the hash table of channels. May close channels. May flush * output on closed channels. Removes any channeEvent handlers that were * registered in this interpreter. * *---------------------------------------------------------------------- */ static void DeleteChannelTable( ClientData clientData, /* The per-interpreter data structure. */ Tcl_Interp *interp) /* The interpreter being deleted. */ { Tcl_HashTable *hTblPtr; /* The hash table. */ Tcl_HashSearch hSearch; /* Search variable. */ Tcl_HashEntry *hPtr; /* Search variable. */ Channel *chanPtr; /* Channel being deleted. */ ChannelState *statePtr; /* State of Channel being deleted. */ EventScriptRecord *sPtr, *prevPtr, *nextPtr; /* Variables to loop over all channel events * registered, to delete the ones that refer * to the interpreter being deleted. */ /* * Delete all the registered channels - this will close channels whose * refcount reaches zero. */ hTblPtr = clientData; for (hPtr = Tcl_FirstHashEntry(hTblPtr, &hSearch); hPtr != NULL; hPtr = Tcl_FirstHashEntry(hTblPtr, &hSearch)) { chanPtr = Tcl_GetHashValue(hPtr); statePtr = chanPtr->state; /* * Remove any fileevents registered in this interpreter. */ for (sPtr = statePtr->scriptRecordPtr, prevPtr = NULL; sPtr != NULL; sPtr = nextPtr) { nextPtr = sPtr->nextPtr; if (sPtr->interp == interp) { if (prevPtr == NULL) { statePtr->scriptRecordPtr = nextPtr; } else { prevPtr->nextPtr = nextPtr; } Tcl_DeleteChannelHandler((Tcl_Channel) chanPtr, TclChannelEventScriptInvoker, sPtr); TclDecrRefCount(sPtr->scriptPtr); ckfree(sPtr); } else { prevPtr = sPtr; } } /* * Cannot call Tcl_UnregisterChannel because that procedure calls * Tcl_GetAssocData to get the channel table, which might already be * inaccessible from the interpreter structure. Instead, we emulate * the behavior of Tcl_UnregisterChannel directly here. */ Tcl_DeleteHashEntry(hPtr); statePtr->epoch++; if (statePtr->refCount-- <= 1) { if (!GotFlag(statePtr, BG_FLUSH_SCHEDULED)) { (void) Tcl_Close(interp, (Tcl_Channel) chanPtr); } } } Tcl_DeleteHashTable(hTblPtr); ckfree(hTblPtr); } /* *---------------------------------------------------------------------- * * CheckForStdChannelsBeingClosed -- * * Perform special handling for standard channels being closed. When * given a standard channel, if the refcount is now 1, it means that the * last reference to the standard channel is being explicitly closed. Now * bump the refcount artificially down to 0, to ensure the normal * handling of channels being closed will occur. Also reset the static * pointer to the channel to NULL, to avoid dangling references. * * Results: * None. * * Side effects: * Manipulates the refcount on standard channels. May smash the global * static pointer to a standard channel. * *---------------------------------------------------------------------- */ static void CheckForStdChannelsBeingClosed( Tcl_Channel chan) { ChannelState *statePtr = ((Channel *) chan)->state; ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); if (tsdPtr->stdinInitialized && tsdPtr->stdinChannel != NULL && statePtr == ((Channel *)tsdPtr->stdinChannel)->state) { if (statePtr->refCount < 2) { statePtr->refCount = 0; tsdPtr->stdinChannel = NULL; return; } } else if (tsdPtr->stdoutInitialized && tsdPtr->stdoutChannel != NULL && statePtr == ((Channel *)tsdPtr->stdoutChannel)->state) { if (statePtr->refCount < 2) { statePtr->refCount = 0; tsdPtr->stdoutChannel = NULL; return; } } else if (tsdPtr->stderrInitialized && tsdPtr->stderrChannel != NULL && statePtr == ((Channel *)tsdPtr->stderrChannel)->state) { if (statePtr->refCount < 2) { statePtr->refCount = 0; tsdPtr->stderrChannel = NULL; return; } } } /* *---------------------------------------------------------------------- * * Tcl_IsStandardChannel -- * * Test if the given channel is a standard channel. No attempt is made to * check if the channel or the standard channels are initialized or * otherwise valid. * * Results: * Returns 1 if true, 0 if false. * * Side effects: * None. * *---------------------------------------------------------------------- */ int Tcl_IsStandardChannel( Tcl_Channel chan) /* Channel to check. */ { ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); if ((chan == tsdPtr->stdinChannel) || (chan == tsdPtr->stdoutChannel) || (chan == tsdPtr->stderrChannel)) { return 1; } else { return 0; } } /* *---------------------------------------------------------------------- * * Tcl_RegisterChannel -- * * Adds an already-open channel to the channel table of an interpreter. * If the interpreter passed as argument is NULL, it only increments the * channel refCount. * * Results: * None. * * Side effects: * May increment the reference count of a channel. * *---------------------------------------------------------------------- */ void Tcl_RegisterChannel( Tcl_Interp *interp, /* Interpreter in which to add the channel. */ Tcl_Channel chan) /* The channel to add to this interpreter * channel table. */ { Tcl_HashTable *hTblPtr; /* Hash table of channels. */ Tcl_HashEntry *hPtr; /* Search variable. */ int isNew; /* Is the hash entry new or does it exist? */ Channel *chanPtr; /* The actual channel. */ ChannelState *statePtr; /* State of the actual channel. */ /* * Always (un)register bottom-most channel in the stack. This makes * management of the channel list easier because no manipulation is * necessary during (un)stack operation. */ chanPtr = ((Channel *) chan)->state->bottomChanPtr; statePtr = chanPtr->state; if (statePtr->channelName == NULL) { Tcl_Panic("Tcl_RegisterChannel: channel without name"); } if (interp != NULL) { hTblPtr = GetChannelTable(interp); hPtr = Tcl_CreateHashEntry(hTblPtr, statePtr->channelName, &isNew); if (!isNew) { if (chan == Tcl_GetHashValue(hPtr)) { return; } Tcl_Panic("Tcl_RegisterChannel: duplicate channel names"); } Tcl_SetHashValue(hPtr, chanPtr); } statePtr->refCount++; } /* *---------------------------------------------------------------------- * * Tcl_UnregisterChannel -- * * Deletes the hash entry for a channel associated with an interpreter. * If the interpreter given as argument is NULL, it only decrements the * reference count. (This all happens in the Tcl_DetachChannel helper * function). * * Finally, if the reference count of the channel drops to zero, it is * deleted. * * Results: * A standard Tcl result. * * Side effects: * Calls Tcl_DetachChannel which deletes the hash entry for a channel * associated with an interpreter. * * May delete the channel, which can have a variety of consequences, * especially if we are forced to close the channel. * *---------------------------------------------------------------------- */ int Tcl_UnregisterChannel( Tcl_Interp *interp, /* Interpreter in which channel is defined. */ Tcl_Channel chan) /* Channel to delete. */ { ChannelState *statePtr; /* State of the real channel. */ statePtr = ((Channel *) chan)->state->bottomChanPtr->state; if (GotFlag(statePtr, CHANNEL_INCLOSE)) { if (interp != NULL) { Tcl_SetObjResult(interp, Tcl_NewStringObj( "illegal recursive call to close through close-handler" " of channel", -1)); } return TCL_ERROR; } if (DetachChannel(interp, chan) != TCL_OK) { return TCL_OK; } statePtr = ((Channel *) chan)->state->bottomChanPtr->state; /* * Perform special handling for standard channels being closed. If the * refCount is now 1 it means that the last reference to the standard * channel is being explicitly closed, so bump the refCount down * artificially to 0. This will ensure that the channel is actually * closed, below. Also set the static pointer to NULL for the channel. */ CheckForStdChannelsBeingClosed(chan); /* * If the refCount reached zero, close the actual channel. */ if (statePtr->refCount <= 0) { Tcl_Preserve(statePtr); if (!GotFlag(statePtr, BG_FLUSH_SCHEDULED)) { /* * We don't want to re-enter Tcl_Close(). */ if (!GotFlag(statePtr, CHANNEL_CLOSED)) { if (Tcl_Close(interp, chan) != TCL_OK) { SetFlag(statePtr, CHANNEL_CLOSED); Tcl_Release(statePtr); return TCL_ERROR; } } } SetFlag(statePtr, CHANNEL_CLOSED); Tcl_Release(statePtr); } return TCL_OK; } /* *---------------------------------------------------------------------- * * Tcl_DetachChannel -- * * Deletes the hash entry for a channel associated with an interpreter. * If the interpreter given as argument is NULL, it only decrements the * reference count. Even if the ref count drops to zero, the channel is * NOT closed or cleaned up. This allows a channel to be detached from an * interpreter and left in the same state it was in when it was * originally returned by 'Tcl_OpenFileChannel', for example. * * This function cannot be used on the standard channels, and will return * TCL_ERROR if that is attempted. * * This function should only be necessary for special purposes in which * you need to generate a pristine channel from one that has already been * used. All ordinary purposes will almost always want to use * Tcl_UnregisterChannel instead. * * Provided the channel is not attached to any other interpreter, it can * then be closed with Tcl_Close, rather than with Tcl_UnregisterChannel. * * Results: * A standard Tcl result. If the channel is not currently registered with * the given interpreter, TCL_ERROR is returned, otherwise TCL_OK. * However no error messages are left in the interp's result. * * Side effects: * Deletes the hash entry for a channel associated with an interpreter. * *---------------------------------------------------------------------- */ int Tcl_DetachChannel( Tcl_Interp *interp, /* Interpreter in which channel is defined. */ Tcl_Channel chan) /* Channel to delete. */ { if (Tcl_IsStandardChannel(chan)) { return TCL_ERROR; } return DetachChannel(interp, chan); } /* *---------------------------------------------------------------------- * * DetachChannel -- * * Deletes the hash entry for a channel associated with an interpreter. * If the interpreter given as argument is NULL, it only decrements the * reference count. Even if the ref count drops to zero, the channel is * NOT closed or cleaned up. This allows a channel to be detached from an * interpreter and left in the same state it was in when it was * originally returned by 'Tcl_OpenFileChannel', for example. * * Results: * A standard Tcl result. If the channel is not currently registered with * the given interpreter, TCL_ERROR is returned, otherwise TCL_OK. * However no error messages are left in the interp's result. * * Side effects: * Deletes the hash entry for a channel associated with an interpreter. * *---------------------------------------------------------------------- */ static int DetachChannel( Tcl_Interp *interp, /* Interpreter in which channel is defined. */ Tcl_Channel chan) /* Channel to delete. */ { Tcl_HashTable *hTblPtr; /* Hash table of channels. */ Tcl_HashEntry *hPtr; /* Search variable. */ Channel *chanPtr; /* The real IO channel. */ ChannelState *statePtr; /* State of the real channel. */ /* * Always (un)register bottom-most channel in the stack. This makes * management of the channel list easier because no manipulation is * necessary during (un)stack operation. */ chanPtr = ((Channel *) chan)->state->bottomChanPtr; statePtr = chanPtr->state; if (interp != NULL) { hTblPtr = Tcl_GetAssocData(interp, "tclIO", NULL); if (hTblPtr == NULL) { return TCL_ERROR; } hPtr = Tcl_FindHashEntry(hTblPtr, statePtr->channelName); if (hPtr == NULL) { return TCL_ERROR; } if ((Channel *) Tcl_GetHashValue(hPtr) != chanPtr) { return TCL_ERROR; } Tcl_DeleteHashEntry(hPtr); statePtr->epoch++; /* * Remove channel handlers that refer to this interpreter, so that * they will not be present if the actual close is delayed and more * events happen on the channel. This may occur if the channel is * shared between several interpreters, or if the channel has async * flushing active. */ CleanupChannelHandlers(interp, chanPtr); } statePtr->refCount--; return TCL_OK; } /* *--------------------------------------------------------------------------- * * Tcl_GetChannel -- * * Finds an existing Tcl_Channel structure by name in a given * interpreter. This function is public because it is used by * channel-type-specific functions. * * Results: * A Tcl_Channel or NULL on failure. If failed, interp's result object * contains an error message. *modePtr is filled with the modes in which * the channel was opened. * * Side effects: * None. * *--------------------------------------------------------------------------- */ Tcl_Channel Tcl_GetChannel( Tcl_Interp *interp, /* Interpreter in which to find or create the * channel. */ const char *chanName, /* The name of the channel. */ int *modePtr) /* Where to store the mode in which the * channel was opened? Will contain an ORed * combination of TCL_READABLE and * TCL_WRITABLE, if non-NULL. */ { Channel *chanPtr; /* The actual channel. */ Tcl_HashTable *hTblPtr; /* Hash table of channels. */ Tcl_HashEntry *hPtr; /* Search variable. */ const char *name; /* Translated name. */ /* * Substitute "stdin", etc. Note that even though we immediately find the * channel using Tcl_GetStdChannel, we still need to look it up in the * specified interpreter to ensure that it is present in the channel * table. Otherwise, safe interpreters would always have access to the * standard channels. */ name = chanName; if ((chanName[0] == 's') && (chanName[1] == 't')) { chanPtr = NULL; if (strcmp(chanName, "stdin") == 0) { chanPtr = (Channel *) Tcl_GetStdChannel(TCL_STDIN); } else if (strcmp(chanName, "stdout") == 0) { chanPtr = (Channel *) Tcl_GetStdChannel(TCL_STDOUT); } else if (strcmp(chanName, "stderr") == 0) { chanPtr = (Channel *) Tcl_GetStdChannel(TCL_STDERR); } if (chanPtr != NULL) { name = chanPtr->state->channelName; } } hTblPtr = GetChannelTable(interp); hPtr = Tcl_FindHashEntry(hTblPtr, name); if (hPtr == NULL) { Tcl_SetObjResult(interp, Tcl_ObjPrintf( "can not find channel named \"%s\"", chanName)); Tcl_SetErrorCode(interp, "TCL", "LOOKUP", "CHANNEL", chanName, NULL); return NULL; } /* * Always return bottom-most channel in the stack. This one lives the * longest - other channels may go away unnoticed. The other APIs * compensate where necessary to retrieve the topmost channel again. */ chanPtr = Tcl_GetHashValue(hPtr); chanPtr = chanPtr->state->bottomChanPtr; if (modePtr != NULL) { *modePtr = chanPtr->state->flags & (TCL_READABLE|TCL_WRITABLE); } return (Tcl_Channel) chanPtr; } /* *--------------------------------------------------------------------------- * * TclGetChannelFromObj -- * * Finds an existing Tcl_Channel structure by name in a given * interpreter. This function is public because it is used by * channel-type-specific functions. * * Results: * A Tcl_Channel or NULL on failure. If failed, interp's result object * contains an error message. *modePtr is filled with the modes in which * the channel was opened. * * Side effects: * None. * *--------------------------------------------------------------------------- */ int TclGetChannelFromObj( Tcl_Interp *interp, /* Interpreter in which to find or create the * channel. */ Tcl_Obj *objPtr, Tcl_Channel *channelPtr, int *modePtr, /* Where to store the mode in which the * channel was opened? Will contain an ORed * combination of TCL_READABLE and * TCL_WRITABLE, if non-NULL. */ int flags) { ChannelState *statePtr; ResolvedChanName *resPtr = NULL; Tcl_Channel chan; if (interp == NULL) { return TCL_ERROR; } if (objPtr->typePtr == &chanObjType) { /* * Confirm validity of saved lookup results. */ resPtr = (ResolvedChanName *) objPtr->internalRep.twoPtrValue.ptr1; statePtr = resPtr->statePtr; if ((resPtr->interp == interp) /* Same interp context */ /* No epoch change in channel since lookup */ && (resPtr->epoch == statePtr->epoch)) { /* * Have a valid saved lookup. Jump to end to return it. */ goto valid; } } chan = Tcl_GetChannel(interp, TclGetString(objPtr), NULL); if (chan == NULL) { if (resPtr) { FreeChannelIntRep(objPtr); } return TCL_ERROR; } if (resPtr && resPtr->refCount == 1) { /* * Re-use the ResolvedCmdName struct. */ Tcl_Release((ClientData) resPtr->statePtr); } else { TclFreeIntRep(objPtr); resPtr = (ResolvedChanName *) ckalloc(sizeof(ResolvedChanName)); resPtr->refCount = 1; objPtr->internalRep.twoPtrValue.ptr1 = (ClientData) resPtr; objPtr->typePtr = &chanObjType; } statePtr = ((Channel *)chan)->state; resPtr->statePtr = statePtr; Tcl_Preserve((ClientData) statePtr); resPtr->interp = interp; resPtr->epoch = statePtr->epoch; valid: *channelPtr = (Tcl_Channel) statePtr->bottomChanPtr; if (modePtr != NULL) { *modePtr = statePtr->flags & (TCL_READABLE|TCL_WRITABLE); } return TCL_OK; } /* *---------------------------------------------------------------------- * * Tcl_CreateChannel -- * * Creates a new entry in the hash table for a Tcl_Channel record. * * Results: * Returns the new Tcl_Channel. * * Side effects: * Creates a new Tcl_Channel instance and inserts it into the hash table. * *---------------------------------------------------------------------- */ Tcl_Channel Tcl_CreateChannel( const Tcl_ChannelType *typePtr, /* The channel type record. */ const char *chanName, /* Name of channel to record. */ ClientData instanceData, /* Instance specific data. */ int mask) /* TCL_READABLE & TCL_WRITABLE to indicate if * the channel is readable, writable. */ { Channel *chanPtr; /* The channel structure newly created. */ ChannelState *statePtr; /* The stack-level independent state info for * the channel. */ const char *name; char *tmp; ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); /* * With the change of the Tcl_ChannelType structure to use a version in * 8.3.2+, we have to make sure that our assumption that the structure * remains a binary compatible size is true. * * If this assertion fails on some system, then it can be removed only if * the user recompiles code with older channel drivers in the new system * as well. */ assert(sizeof(Tcl_ChannelTypeVersion) == sizeof(Tcl_DriverBlockModeProc *)); assert(typePtr->typeName != NULL); if (NULL == typePtr->closeProc) { Tcl_Panic("channel type %s must define closeProc", typePtr->typeName); } if ((TCL_READABLE & mask) && (NULL == typePtr->inputProc)) { Tcl_Panic("channel type %s must define inputProc when used for reader channel", typePtr->typeName); } if ((TCL_WRITABLE & mask) && (NULL == typePtr->outputProc)) { Tcl_Panic("channel type %s must define outputProc when used for writer channel", typePtr->typeName); } if (NULL == typePtr->watchProc) { Tcl_Panic("channel type %s must define watchProc", typePtr->typeName); } if ((NULL!=typePtr->wideSeekProc) && (NULL == typePtr->seekProc)) { Tcl_Panic("channel type %s must define seekProc if defining wideSeekProc", typePtr->typeName); } /* * JH: We could subsequently memset these to 0 to avoid the numerous * assignments to 0/NULL below. */ chanPtr = ckalloc(sizeof(Channel)); statePtr = ckalloc(sizeof(ChannelState)); chanPtr->state = statePtr; chanPtr->instanceData = instanceData; chanPtr->typePtr = typePtr; /* * Set all the bits that are part of the stack-independent state * information for the channel. */ if (chanName != NULL) { unsigned len = strlen(chanName) + 1; /* * Make sure we allocate at least 7 bytes, so it fits for "stdout" * later. */ tmp = ckalloc((len < 7) ? 7 : len); strcpy(tmp, chanName); } else { tmp = ckalloc(7); tmp[0] = '\0'; } statePtr->channelName = tmp; statePtr->flags = mask; /* * Set the channel to system default encoding. * * Note the strange bit of protection taking place here. If the system * encoding name is reported back as "binary", something weird is * happening. Tcl provides no "binary" encoding, so someone else has * provided one. We ignore it so as not to interfere with the "magic" * interpretation that Tcl_Channels give to the "-encoding binary" option. */ statePtr->encoding = NULL; name = Tcl_GetEncodingName(NULL); if (strcmp(name, "binary") != 0) { statePtr->encoding = Tcl_GetEncoding(NULL, name); } statePtr->inputEncodingState = NULL; statePtr->inputEncodingFlags = TCL_ENCODING_START; statePtr->outputEncodingState = NULL; statePtr->outputEncodingFlags = TCL_ENCODING_START; /* * Set the channel up initially in AUTO input translation mode to accept * "\n", "\r" and "\r\n". Output translation mode is set to a platform * specific default value. The eofChar is set to 0 for both input and * output, so that Tcl does not look for an in-file EOF indicator (e.g., * ^Z) and does not append an EOF indicator to files. */ statePtr->inputTranslation = TCL_TRANSLATE_AUTO; statePtr->outputTranslation = TCL_PLATFORM_TRANSLATION; statePtr->inEofChar = 0; statePtr->outEofChar = 0; statePtr->unreportedError = 0; statePtr->refCount = 0; statePtr->closeCbPtr = NULL; statePtr->curOutPtr = NULL; statePtr->outQueueHead = NULL; statePtr->outQueueTail = NULL; statePtr->saveInBufPtr = NULL; statePtr->inQueueHead = NULL; statePtr->inQueueTail = NULL; statePtr->chPtr = NULL; statePtr->interestMask = 0; statePtr->scriptRecordPtr = NULL; statePtr->bufSize = CHANNELBUFFER_DEFAULT_SIZE; statePtr->timer = NULL; statePtr->csPtrR = NULL; statePtr->csPtrW = NULL; statePtr->outputStage = NULL; /* * As we are creating the channel, it is obviously the top for now. */ statePtr->topChanPtr = chanPtr; statePtr->bottomChanPtr = chanPtr; chanPtr->downChanPtr = NULL; chanPtr->upChanPtr = NULL; chanPtr->inQueueHead = NULL; chanPtr->inQueueTail = NULL; chanPtr->refCount = 0; /* * TIP #219, Tcl Channel Reflection API */ statePtr->chanMsg = NULL; statePtr->unreportedMsg = NULL; statePtr->epoch = 0; /* * Link the channel into the list of all channels; create an on-exit * handler if there is not one already, to close off all the channels in * the list on exit. * * JH: Could call Tcl_SpliceChannel, but need to avoid NULL check. * * TIP #218. * AK: Just initialize the field to NULL before invoking Tcl_SpliceChannel * We need Tcl_SpliceChannel, for the threadAction calls. There is no * real reason to duplicate all of this. * NOTE: All drivers using thread actions now have to perform their TSD * manipulation only in their thread action proc. Doing it when * creating their instance structures will collide with the thread * action activity and lead to damaged lists. */ statePtr->nextCSPtr = NULL; SpliceChannel((Tcl_Channel) chanPtr); /* * Install this channel in the first empty standard channel slot, if the * channel was previously closed explicitly. */ if ((tsdPtr->stdinChannel == NULL) && (tsdPtr->stdinInitialized == 1)) { strcpy(tmp, "stdin"); Tcl_SetStdChannel((Tcl_Channel) chanPtr, TCL_STDIN); Tcl_RegisterChannel(NULL, (Tcl_Channel) chanPtr); } else if ((tsdPtr->stdoutChannel == NULL) && (tsdPtr->stdoutInitialized == 1)) { strcpy(tmp, "stdout"); Tcl_SetStdChannel((Tcl_Channel) chanPtr, TCL_STDOUT); Tcl_RegisterChannel(NULL, (Tcl_Channel) chanPtr); } else if ((tsdPtr->stderrChannel == NULL) && (tsdPtr->stderrInitialized == 1)) { strcpy(tmp, "stderr"); Tcl_SetStdChannel((Tcl_Channel) chanPtr, TCL_STDERR); Tcl_RegisterChannel(NULL, (Tcl_Channel) chanPtr); } return (Tcl_Channel) chanPtr; } /* *---------------------------------------------------------------------- * * Tcl_StackChannel -- * * Replaces an entry in the hash table for a Tcl_Channel record. The * replacement is a new channel with same name, it supercedes the * replaced channel. Input and output of the superceded channel is now * going through the newly created channel and allows the arbitrary * filtering/manipulation of the dataflow. * * Andreas Kupries , 12/13/1998 "Trf-Patch for * filtering channels" * * Results: * Returns the new Tcl_Channel, which actually contains the saved * information about prevChan. * * Side effects: * A new channel structure is allocated and linked below the existing * channel. The channel operations and client data of the existing * channel are copied down to the newly created channel, and the current * channel has its operations replaced by the new typePtr. * *---------------------------------------------------------------------- */ Tcl_Channel Tcl_StackChannel( Tcl_Interp *interp, /* The interpreter we are working in */ const Tcl_ChannelType *typePtr, /* The channel type record for the new * channel. */ ClientData instanceData, /* Instance specific data for the new * channel. */ int mask, /* TCL_READABLE & TCL_WRITABLE to indicate if * the channel is readable, writable. */ Tcl_Channel prevChan) /* The channel structure to replace */ { ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); Channel *chanPtr, *prevChanPtr; ChannelState *statePtr; /* * Find the given channel (prevChan) in the list of all channels. If we do * not find it, then it was never registered correctly. * * This operation should occur at the top of a channel stack. */ statePtr = (ChannelState *) tsdPtr->firstCSPtr; prevChanPtr = ((Channel *) prevChan)->state->topChanPtr; while ((statePtr != NULL) && (statePtr->topChanPtr != prevChanPtr)) { statePtr = statePtr->nextCSPtr; } if (statePtr == NULL) { if (interp) { Tcl_SetObjResult(interp, Tcl_ObjPrintf( "couldn't find state for channel \"%s\"", Tcl_GetChannelName(prevChan))); } return NULL; } /* * Here we check if the given "mask" matches the "flags" of the already * existing channel. * * | - | R | W | RW | * --+---+---+---+----+ <=> 0 != (chan->mask & prevChan->mask) * - | | | | | * R | | + | | + | The superceding channel is allowed to restrict * W | | | + | + | the capabilities of the superceded one! * RW| | + | + | + | * --+---+---+---+----+ */ if ((mask & (statePtr->flags & (TCL_READABLE | TCL_WRITABLE))) == 0) { if (interp) { Tcl_SetObjResult(interp, Tcl_ObjPrintf( "reading and writing both disallowed for channel \"%s\"", Tcl_GetChannelName(prevChan))); } return NULL; } /* * Flush the buffers. This ensures that any data still in them at this * time is not handled by the new transformation. Restrict this to * writable channels. Take care to hide a possible bg-copy in progress * from Tcl_Flush and the CheckForChannelErrors inside. */ if ((mask & TCL_WRITABLE) != 0) { CopyState *csPtrR = statePtr->csPtrR; CopyState *csPtrW = statePtr->csPtrW; statePtr->csPtrR = NULL; statePtr->csPtrW = NULL; /* * TODO: Examine what can go wrong if Tcl_Flush() call disturbs * the stacking state of this channel during its operations. */ if (Tcl_Flush((Tcl_Channel) prevChanPtr) != TCL_OK) { statePtr->csPtrR = csPtrR; statePtr->csPtrW = csPtrW; if (interp) { Tcl_SetObjResult(interp, Tcl_ObjPrintf( "could not flush channel \"%s\"", Tcl_GetChannelName(prevChan))); } return NULL; } statePtr->csPtrR = csPtrR; statePtr->csPtrW = csPtrW; } /* * Discard any input in the buffers. They are not yet read by the user of * the channel, so they have to go through the new transformation before * reading. As the buffers contain the untransformed form their contents * are not only useless but actually distorts our view of the system. * * To preserve the information without having to read them again and to * avoid problems with the location in the channel (seeking might be * impossible) we move the buffers from the common state structure into * the channel itself. We use the buffers in the channel below the new * transformation to hold the data. In the future this allows us to write * transformations which pre-read data and push the unused part back when * they are going away. */ if (((mask & TCL_READABLE) != 0) && (statePtr->inQueueHead != NULL)) { /* * When statePtr->inQueueHead is not NULL, we know * prevChanPtr->inQueueHead must be NULL. */ assert(prevChanPtr->inQueueHead == NULL); assert(prevChanPtr->inQueueTail == NULL); prevChanPtr->inQueueHead = statePtr->inQueueHead; prevChanPtr->inQueueTail = statePtr->inQueueTail; statePtr->inQueueHead = NULL; statePtr->inQueueTail = NULL; } chanPtr = ckalloc(sizeof(Channel)); /* * Save some of the current state into the new structure, reinitialize the * parts which will stay with the transformation. * * Remarks: */ chanPtr->state = statePtr; chanPtr->instanceData = instanceData; chanPtr->typePtr = typePtr; chanPtr->downChanPtr = prevChanPtr; chanPtr->upChanPtr = NULL; chanPtr->inQueueHead = NULL; chanPtr->inQueueTail = NULL; chanPtr->refCount = 0; /* * Place new block at the head of a possibly existing list of previously * stacked channels. */ prevChanPtr->upChanPtr = chanPtr; statePtr->topChanPtr = chanPtr; /* * TIP #218, Channel Thread Actions. * * We call the thread actions for the new channel directly. We _cannot_ * use SpliceChannel, because the (thread-)global list of all channels * always contains the _ChannelState_ for a stack of channels, not the * individual channels. And SpliceChannel would not only call the thread * actions, but also add the shared ChannelState to this list a second * time, mangling it. */ ChanThreadAction(chanPtr, TCL_CHANNEL_THREAD_INSERT); return (Tcl_Channel) chanPtr; } void TclChannelPreserve( Tcl_Channel chan) { ((Channel *)chan)->refCount++; } void TclChannelRelease( Tcl_Channel chan) { Channel *chanPtr = (Channel *) chan; if (chanPtr->refCount == 0) { Tcl_Panic("Channel released more than preserved"); } if (--chanPtr->refCount) { return; } if (chanPtr->typePtr == NULL) { ckfree(chanPtr); } } static void ChannelFree( Channel *chanPtr) { if (chanPtr->refCount == 0) { ckfree(chanPtr); return; } chanPtr->typePtr = NULL; } /* *---------------------------------------------------------------------- * * Tcl_UnstackChannel -- * * Unstacks an entry in the hash table for a Tcl_Channel record. This is * the reverse to 'Tcl_StackChannel'. * * Results: * A standard Tcl result. * * Side effects: * If TCL_ERROR is returned, the posix error code will be set with * Tcl_SetErrno. May leave a message in interp result as well. * *---------------------------------------------------------------------- */ int Tcl_UnstackChannel( Tcl_Interp *interp, /* The interpreter we are working in */ Tcl_Channel chan) /* The channel to unstack */ { Channel *chanPtr = (Channel *) chan; ChannelState *statePtr = chanPtr->state; int result = 0; /* * This operation should occur at the top of a channel stack. */ chanPtr = statePtr->topChanPtr; if (chanPtr->downChanPtr != NULL) { /* * Instead of manipulating the per-thread / per-interp list/hashtable * of registered channels we wind down the state of the * transformation, and then restore the state of underlying channel * into the old structure. * * TODO: Figure out how to handle the situation where the chan * operations called below by this unstacking operation cause * another unstacking recursively. In that case the downChanPtr * value we're holding on to will not be the right thing. */ Channel *downChanPtr = chanPtr->downChanPtr; /* * Flush the buffers. This ensures that any data still in them at this * time _is_ handled by the transformation we are unstacking right * now. Restrict this to writable channels. Take care to hide a * possible bg-copy in progress from Tcl_Flush and the * CheckForChannelErrors inside. */ if (GotFlag(statePtr, TCL_WRITABLE)) { CopyState *csPtrR = statePtr->csPtrR; CopyState *csPtrW = statePtr->csPtrW; statePtr->csPtrR = NULL; statePtr->csPtrW = NULL; if (Tcl_Flush((Tcl_Channel) chanPtr) != TCL_OK) { statePtr->csPtrR = csPtrR; statePtr->csPtrW = csPtrW; /* * TIP #219, Tcl Channel Reflection API. * Move error messages put by the driver into the chan/ip * bypass area into the regular interpreter result. Fall back * to the regular message if nothing was found in the * bypasses. */ if (!TclChanCaughtErrorBypass(interp, chan) && interp) { Tcl_SetObjResult(interp, Tcl_ObjPrintf( "could not flush channel \"%s\"", Tcl_GetChannelName((Tcl_Channel) chanPtr))); } return TCL_ERROR; } statePtr->csPtrR = csPtrR; statePtr->csPtrW = csPtrW; } /* * Anything in the input queue and the push-back buffers of the * transformation going away is transformed data, but not yet read. As * unstacking means that the caller does not want to see transformed * data any more we have to discard these bytes. To avoid writing an * analogue to 'DiscardInputQueued' we move the information in the * push back buffers to the input queue and then call * 'DiscardInputQueued' on that. */ if (GotFlag(statePtr, TCL_READABLE) && ((statePtr->inQueueHead != NULL) || (chanPtr->inQueueHead != NULL))) { if ((statePtr->inQueueHead != NULL) && (chanPtr->inQueueHead != NULL)) { statePtr->inQueueTail->nextPtr = chanPtr->inQueueHead; statePtr->inQueueTail = chanPtr->inQueueTail; statePtr->inQueueHead = statePtr->inQueueTail; } else if (chanPtr->inQueueHead != NULL) { statePtr->inQueueHead = chanPtr->inQueueHead; statePtr->inQueueTail = chanPtr->inQueueTail; } chanPtr->inQueueHead = NULL; chanPtr->inQueueTail = NULL; DiscardInputQueued(statePtr, 0); } /* * TIP #218, Channel Thread Actions. * * We call the thread actions for the new channel directly. We * _cannot_ use CutChannel, because the (thread-)global list of all * channels always contains the _ChannelState_ for a stack of * channels, not the individual channels. And SpliceChannel would not * only call the thread actions, but also remove the shared * ChannelState from this list despite there being more channels for * the state which are still active. */ ChanThreadAction(chanPtr, TCL_CHANNEL_THREAD_REMOVE); statePtr->topChanPtr = downChanPtr; downChanPtr->upChanPtr = NULL; /* * Leave this link intact for closeproc * chanPtr->downChanPtr = NULL; */ /* * Close and free the channel driver state. */ result = ChanClose(chanPtr, interp); ChannelFree(chanPtr); UpdateInterest(statePtr->topChanPtr); if (result != 0) { Tcl_SetErrno(result); /* * TIP #219, Tcl Channel Reflection API. * Move error messages put by the driver into the chan/ip bypass * area into the regular interpreter result. */ TclChanCaughtErrorBypass(interp, chan); return TCL_ERROR; } } else { /* * This channel does not cover another one. Simply do a close, if * necessary. */ if (statePtr->refCount <= 0) { if (Tcl_Close(interp, chan) != TCL_OK) { /* * TIP #219, Tcl Channel Reflection API. * "TclChanCaughtErrorBypass" is not required here, it was * done already by "Tcl_Close". */ return TCL_ERROR; } } /* * TIP #218, Channel Thread Actions. * Not required in this branch, this is done by Tcl_Close. If * Tcl_Close is not called then the ChannelState is still active in * the thread and no action has to be taken either. */ } return TCL_OK; } /* *---------------------------------------------------------------------- * * Tcl_GetStackedChannel -- * * Determines whether the specified channel is stacked upon another. * * Results: * NULL if the channel is not stacked upon another one, or a reference to * the channel it is stacked upon. This reference can be used in queries, * but modification is not allowed. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_Channel Tcl_GetStackedChannel( Tcl_Channel chan) { Channel *chanPtr = (Channel *) chan; /* The actual channel. */ return (Tcl_Channel) chanPtr->downChanPtr; } /* *---------------------------------------------------------------------- * * Tcl_GetTopChannel -- * * Returns the top channel of a channel stack. * * Results: * NULL if the channel is not stacked upon another one, or a reference to * the channel it is stacked upon. This reference can be used in queries, * but modification is not allowed. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_Channel Tcl_GetTopChannel( Tcl_Channel chan) { Channel *chanPtr = (Channel *) chan; /* The actual channel. */ return (Tcl_Channel) chanPtr->state->topChanPtr; } /* *---------------------------------------------------------------------- * * Tcl_GetChannelInstanceData -- * * Returns the client data associated with a channel. * * Results: * The client data. * * Side effects: * None. * *---------------------------------------------------------------------- */ ClientData Tcl_GetChannelInstanceData( Tcl_Channel chan) /* Channel for which to return client data. */ { Channel *chanPtr = (Channel *) chan; /* The actual channel. */ return chanPtr->instanceData; } /* *---------------------------------------------------------------------- * * Tcl_GetChannelThread -- * * Given a channel structure, returns the thread managing it. TIP #10 * * Results: * Returns the id of the thread managing the channel. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_ThreadId Tcl_GetChannelThread( Tcl_Channel chan) /* The channel to return the managing thread * for. */ { Channel *chanPtr = (Channel *) chan; /* The actual channel. */ return chanPtr->state->managingThread; } /* *---------------------------------------------------------------------- * * Tcl_GetChannelType -- * * Given a channel structure, returns the channel type structure. * * Results: * Returns a pointer to the channel type structure. * * Side effects: * None. * *---------------------------------------------------------------------- */ const Tcl_ChannelType * Tcl_GetChannelType( Tcl_Channel chan) /* The channel to return type for. */ { Channel *chanPtr = (Channel *) chan; /* The actual channel. */ return chanPtr->typePtr; } /* *---------------------------------------------------------------------- * * Tcl_GetChannelMode -- * * Computes a mask indicating whether the channel is open for reading and * writing. * * Results: * An OR-ed combination of TCL_READABLE and TCL_WRITABLE. * * Side effects: * None. * *---------------------------------------------------------------------- */ int Tcl_GetChannelMode( Tcl_Channel chan) /* The channel for which the mode is being * computed. */ { ChannelState *statePtr = ((Channel *) chan)->state; /* State of actual channel. */ return (statePtr->flags & (TCL_READABLE | TCL_WRITABLE)); } /* *---------------------------------------------------------------------- * * Tcl_GetChannelName -- * * Returns the string identifying the channel name. * * Results: * The string containing the channel name. This memory is owned by the * generic layer and should not be modified by the caller. * * Side effects: * None. * *---------------------------------------------------------------------- */ const char * Tcl_GetChannelName( Tcl_Channel chan) /* The channel for which to return the name. */ { ChannelState *statePtr = ((Channel *) chan)->state; /* State of actual channel. */ return statePtr->channelName; } /* *---------------------------------------------------------------------- * * Tcl_GetChannelHandle -- * * Returns an OS handle associated with a channel. * * Results: * Returns TCL_OK and places the handle in handlePtr, or returns * TCL_ERROR on failure. * * Side effects: * None. * *---------------------------------------------------------------------- */ int Tcl_GetChannelHandle( Tcl_Channel chan, /* The channel to get file from. */ int direction, /* TCL_WRITABLE or TCL_READABLE. */ ClientData *handlePtr) /* Where to store handle */ { Channel *chanPtr; /* The actual channel. */ ClientData handle; int result; chanPtr = ((Channel *) chan)->state->bottomChanPtr; if (!chanPtr->typePtr->getHandleProc) { Tcl_SetChannelError(chan, Tcl_ObjPrintf( "channel \"%s\" does not support OS handles", Tcl_GetChannelName(chan))); return TCL_ERROR; } result = chanPtr->typePtr->getHandleProc(chanPtr->instanceData, direction, &handle); if (handlePtr) { *handlePtr = handle; } return result; } /* *--------------------------------------------------------------------------- * * AllocChannelBuffer -- * * A channel buffer has BUFFER_PADDING bytes extra at beginning to hold * any bytes of a native-encoding character that got split by the end of * the previous buffer and need to be moved to the beginning of the next * buffer to make a contiguous string so it can be converted to UTF-8. * * A channel buffer has BUFFER_PADDING bytes extra at the end to hold any * bytes of a native-encoding character (generated from a UTF-8 * character) that overflow past the end of the buffer and need to be * moved to the next buffer. * * Results: * A newly allocated channel buffer. * * Side effects: * None. * *--------------------------------------------------------------------------- */ static ChannelBuffer * AllocChannelBuffer( int length) /* Desired length of channel buffer. */ { ChannelBuffer *bufPtr; int n; n = length + CHANNELBUFFER_HEADER_SIZE + BUFFER_PADDING + BUFFER_PADDING; bufPtr = ckalloc(n); bufPtr->nextAdded = BUFFER_PADDING; bufPtr->nextRemoved = BUFFER_PADDING; bufPtr->bufLength = length + BUFFER_PADDING; bufPtr->nextPtr = NULL; bufPtr->refCount = 1; return bufPtr; } static void PreserveChannelBuffer( ChannelBuffer *bufPtr) { if (bufPtr->refCount == 0) { Tcl_Panic("Reuse of ChannelBuffer! %p", bufPtr); } bufPtr->refCount++; } static void ReleaseChannelBuffer( ChannelBuffer *bufPtr) { if (--bufPtr->refCount) { return; } ckfree(bufPtr); } static int IsShared( ChannelBuffer *bufPtr) { return bufPtr->refCount > 1; } /* *---------------------------------------------------------------------- * * RecycleBuffer -- * * Helper function to recycle input and output buffers. Ensures that two * input buffers are saved (one in the input queue and another in the * saveInBufPtr field) and that curOutPtr is set to a buffer. Only if * these conditions are met is the buffer freed to the OS. * * Results: * None. * * Side effects: * May free a buffer to the OS. * *---------------------------------------------------------------------- */ static void RecycleBuffer( ChannelState *statePtr, /* ChannelState in which to recycle buffers. */ ChannelBuffer *bufPtr, /* The buffer to recycle. */ int mustDiscard) /* If nonzero, free the buffer to the OS, * always. */ { /* * Do we have to free the buffer to the OS? */ if (IsShared(bufPtr)) { mustDiscard = 1; } if (mustDiscard) { ReleaseChannelBuffer(bufPtr); return; } /* * Only save buffers which have the requested buffersize for the channel. * This is to honor dynamic changes of the buffersize made by the user. */ if ((bufPtr->bufLength - BUFFER_PADDING) != statePtr->bufSize) { ReleaseChannelBuffer(bufPtr); return; } /* * Only save buffers for the input queue if the channel is readable. */ if (GotFlag(statePtr, TCL_READABLE)) { if (statePtr->inQueueHead == NULL) { statePtr->inQueueHead = bufPtr; statePtr->inQueueTail = bufPtr; goto keepBuffer; } if (statePtr->saveInBufPtr == NULL) { statePtr->saveInBufPtr = bufPtr; goto keepBuffer; } } /* * Only save buffers for the output queue if the channel is writable. */ if (GotFlag(statePtr, TCL_WRITABLE)) { if (statePtr->curOutPtr == NULL) { statePtr->curOutPtr = bufPtr; goto keepBuffer; } } /* * If we reached this code we return the buffer to the OS. */ ReleaseChannelBuffer(bufPtr); return; keepBuffer: bufPtr->nextRemoved = BUFFER_PADDING; bufPtr->nextAdded = BUFFER_PADDING; bufPtr->nextPtr = NULL; } /* *---------------------------------------------------------------------- * * DiscardOutputQueued -- * * Discards all output queued in the output queue of a channel. * * Results: * None. * * Side effects: * Recycles buffers. * *---------------------------------------------------------------------- */ static void DiscardOutputQueued( ChannelState *statePtr) /* ChannelState for which to discard output. */ { ChannelBuffer *bufPtr; while (statePtr->outQueueHead != NULL) { bufPtr = statePtr->outQueueHead; statePtr->outQueueHead = bufPtr->nextPtr; RecycleBuffer(statePtr, bufPtr, 0); } statePtr->outQueueHead = NULL; statePtr->outQueueTail = NULL; bufPtr = statePtr->curOutPtr; if (bufPtr && BytesLeft(bufPtr)) { statePtr->curOutPtr = NULL; RecycleBuffer(statePtr, bufPtr, 0); } } /* *---------------------------------------------------------------------- * * CheckForDeadChannel -- * * This function checks is a given channel is Dead (a channel that has * been closed but not yet deallocated.) * * Results: * True (1) if channel is Dead, False (0) if channel is Ok * * Side effects: * None * *---------------------------------------------------------------------- */ static int CheckForDeadChannel( Tcl_Interp *interp, /* For error reporting (can be NULL) */ ChannelState *statePtr) /* The channel state to check. */ { if (!GotFlag(statePtr, CHANNEL_DEAD)) { return 0; } Tcl_SetErrno(EINVAL); if (interp) { Tcl_SetObjResult(interp, Tcl_NewStringObj( "unable to access channel: invalid channel", -1)); } return 1; } /* *---------------------------------------------------------------------- * * FlushChannel -- * * This function flushes as much of the queued output as is possible now. * If calledFromAsyncFlush is nonzero, it is being called in an event * handler to flush channel output asynchronously. * * Results: * 0 if successful, else the error code that was returned by the channel * type operation. May leave a message in the interp result. * * Side effects: * May produce output on a channel. May block indefinitely if the channel * is synchronous. May schedule an async flush on the channel. May * recycle memory for buffers in the output queue. * *---------------------------------------------------------------------- */ static int FlushChannel( Tcl_Interp *interp, /* For error reporting during close. */ Channel *chanPtr, /* The channel to flush on. */ int calledFromAsyncFlush) /* If nonzero then we are being called from an * asynchronous flush callback. */ { ChannelState *statePtr = chanPtr->state; /* State of the channel stack. */ ChannelBuffer *bufPtr; /* Iterates over buffered output queue. */ int written; /* Amount of output data actually written in * current round. */ int errorCode = 0; /* Stores POSIX error codes from channel * driver operations. */ int wroteSome = 0; /* Set to one if any data was written to the * driver. */ /* * Prevent writing on a dead channel -- a channel that has been closed but * not yet deallocated. This can occur if the exit handler for the channel * deallocation runs before all channels are deregistered in all * interpreters. */ if (CheckForDeadChannel(interp, statePtr)) { return -1; } /* * Should we shift the current output buffer over to the output queue? * First check that there are bytes in it. If so then... * * If the output queue is empty, then yes, trusting the caller called us * only when written bytes ought to be flushed. * * If the current output buffer is full, then yes, so we can meet the * post-condition that on a successful return to caller we've left space * in the current output buffer for more writing (the flush call was to * make new room). * * If the channel is blocking, then yes, so we guarantee that blocking * flushes actually flush all pending data. * * Otherwise, no. Keep the current output buffer where it is so more * can be written to it, possibly filling it, to promote more efficient * buffer usage. */ bufPtr = statePtr->curOutPtr; if (bufPtr && BytesLeft(bufPtr) && /* Keep empties off queue */ (statePtr->outQueueHead == NULL || IsBufferFull(bufPtr) || !GotFlag(statePtr, CHANNEL_NONBLOCKING))) { if (statePtr->outQueueHead == NULL) { statePtr->outQueueHead = bufPtr; } else { statePtr->outQueueTail->nextPtr = bufPtr; } statePtr->outQueueTail = bufPtr; statePtr->curOutPtr = NULL; } assert(!IsBufferFull(statePtr->curOutPtr)); /* * If we are not being called from an async flush and an async flush * is active, we just return without producing any output. */ if (!calledFromAsyncFlush && GotFlag(statePtr, BG_FLUSH_SCHEDULED)) { return 0; } /* * Loop over the queued buffers and attempt to flush as much as possible * of the queued output to the channel. */ TclChannelPreserve((Tcl_Channel)chanPtr); while (statePtr->outQueueHead) { bufPtr = statePtr->outQueueHead; /* * Produce the output on the channel. */ PreserveChannelBuffer(bufPtr); written = ChanWrite(chanPtr, RemovePoint(bufPtr), BytesLeft(bufPtr), &errorCode); /* * If the write failed completely attempt to start the asynchronous * flush mechanism and break out of this loop - do not attempt to * write any more output at this time. */ if (written < 0) { /* * If the last attempt to write was interrupted, simply retry. */ if (errorCode == EINTR) { errorCode = 0; ReleaseChannelBuffer(bufPtr); continue; } /* * If the channel is non-blocking and we would have blocked, start * a background flushing handler and break out of the loop. */ if ((errorCode == EWOULDBLOCK) || (errorCode == EAGAIN)) { /* * This used to check for CHANNEL_NONBLOCKING, and panic if * the channel was blocking. However, it appears that setting * stdin to -blocking 0 has some effect on the stdout when * it's a tty channel (dup'ed underneath) */ if (!GotFlag(statePtr, BG_FLUSH_SCHEDULED) && !TclInExit()) { SetFlag(statePtr, BG_FLUSH_SCHEDULED); UpdateInterest(chanPtr); } errorCode = 0; ReleaseChannelBuffer(bufPtr); break; } /* * Decide whether to report the error upwards or defer it. */ if (calledFromAsyncFlush) { /* * TIP #219, Tcl Channel Reflection API. * When defering the error copy a message from the bypass into * the unreported area. Or discard it if the new error is to * be ignored in favor of an earlier defered error. */ Tcl_Obj *msg = statePtr->chanMsg; if (statePtr->unreportedError == 0) { statePtr->unreportedError = errorCode; statePtr->unreportedMsg = msg; if (msg != NULL) { Tcl_IncrRefCount(msg); } } else { /* * An old unreported error is kept, and this error thrown * away. */ statePtr->chanMsg = NULL; if (msg != NULL) { TclDecrRefCount(msg); } } } else { /* * TIP #219, Tcl Channel Reflection API. * Move error messages put by the driver into the chan bypass * area into the regular interpreter result. Fall back to the * regular message if nothing was found in the bypasses. */ Tcl_SetErrno(errorCode); if (interp != NULL && !TclChanCaughtErrorBypass(interp, (Tcl_Channel) chanPtr)) { Tcl_SetObjResult(interp, Tcl_NewStringObj(Tcl_PosixError(interp), -1)); } /* * An unreportable bypassed message is kept, for the caller of * Tcl_Seek, Tcl_Write, etc. */ } /* * When we get an error we throw away all the output currently * queued. */ DiscardOutputQueued(statePtr); ReleaseChannelBuffer(bufPtr); break; } else { /* * TODO: Consider detecting and reacting to short writes on * blocking channels. Ought not happen. See iocmd-24.2. */ wroteSome = 1; } bufPtr->nextRemoved += written; /* * If this buffer is now empty, recycle it. */ if (IsBufferEmpty(bufPtr)) { statePtr->outQueueHead = bufPtr->nextPtr; if (statePtr->outQueueHead == NULL) { statePtr->outQueueTail = NULL; } RecycleBuffer(statePtr, bufPtr, 0); } ReleaseChannelBuffer(bufPtr); } /* Closes "while". */ /* * If we wrote some data while flushing in the background, we are done. * We can't finish the background flush until we run out of data and the * channel becomes writable again. This ensures that all of the pending * data has been flushed at the system level. */ if (GotFlag(statePtr, BG_FLUSH_SCHEDULED)) { if (wroteSome) { goto done; } else if (statePtr->outQueueHead == NULL) { ResetFlag(statePtr, BG_FLUSH_SCHEDULED); ChanWatch(chanPtr, statePtr->interestMask); } else { /* * When we are calledFromAsyncFlush, that means a writable * state on the channel triggered the call, so we should be * able to write something. Either we did write something * and wroteSome should be set, or there was nothing left to * write in this call, and we've completed the BG flush. * These are the two cases above. If we get here, that means * there is some kind failure in the writable event machinery. * * The tls extension indeed suffers from flaws in its channel * event mgmt. See http://core.tcl.tk/tcl/info/c31ca233ca. * Until that patch is broadly distributed, disable the * assertion checking here, so that programs using Tcl and * tls can be debugged. assert(!calledFromAsyncFlush); */ } } /* * If the channel is flagged as closed, delete it when the refCount drops * to zero, the output queue is empty and there is no output in the * current output buffer. */ if (GotFlag(statePtr, CHANNEL_CLOSED) && (statePtr->refCount <= 0) && (statePtr->outQueueHead == NULL) && ((statePtr->curOutPtr == NULL) || IsBufferEmpty(statePtr->curOutPtr))) { errorCode = CloseChannel(interp, chanPtr, errorCode); goto done; } /* * If the write-side of the channel is flagged as closed, delete it when * the output queue is empty and there is no output in the current output * buffer. */ if (GotFlag(statePtr, CHANNEL_CLOSEDWRITE) && (statePtr->outQueueHead == NULL) && ((statePtr->curOutPtr == NULL) || IsBufferEmpty(statePtr->curOutPtr))) { errorCode = CloseChannelPart(interp, chanPtr, errorCode, TCL_CLOSE_WRITE); goto done; } done: TclChannelRelease((Tcl_Channel)chanPtr); return errorCode; } /* *---------------------------------------------------------------------- * * CloseChannel -- * * Utility procedure to close a channel and free associated resources. * * If the channel was stacked, then the it will copy the necessary * elements of the NEXT channel into the TOP channel, in essence * unstacking the channel. The NEXT channel will then be freed. * * If the channel was not stacked, then we will free all the bits for the * TOP channel, including the data structure itself. * * Results: * Error code from an unreported error or the driver close operation. * * Side effects: * May close the actual channel, may free memory, may change the value of * errno. * *---------------------------------------------------------------------- */ static int CloseChannel( Tcl_Interp *interp, /* For error reporting. */ Channel *chanPtr, /* The channel to close. */ int errorCode) /* Status of operation so far. */ { int result = 0; /* Of calling driver close operation. */ ChannelState *statePtr; /* State of the channel stack. */ ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); if (chanPtr == NULL) { return result; } statePtr = chanPtr->state; /* * No more input can be consumed so discard any leftover input. */ DiscardInputQueued(statePtr, 1); /* * Discard a leftover buffer in the current output buffer field. */ if (statePtr->curOutPtr != NULL) { ReleaseChannelBuffer(statePtr->curOutPtr); statePtr->curOutPtr = NULL; } /* * The caller guarantees that there are no more buffers queued for output. */ if (statePtr->outQueueHead != NULL) { Tcl_Panic("TclFlush, closed channel: queued output left"); } /* * If the EOF character is set in the channel, append that to the output * device. */ if ((statePtr->outEofChar != 0) && GotFlag(statePtr, TCL_WRITABLE)) { int dummy; char c = (char) statePtr->outEofChar; (void) ChanWrite(chanPtr, &c, 1, &dummy); } /* * TIP #219, Tcl Channel Reflection API. * Move a leftover error message in the channel bypass into the * interpreter bypass. Just clear it if there is no interpreter. */ if (statePtr->chanMsg != NULL) { if (interp != NULL) { Tcl_SetChannelErrorInterp(interp, statePtr->chanMsg); } TclDecrRefCount(statePtr->chanMsg); statePtr->chanMsg = NULL; } /* * Remove this channel from of the list of all channels. */ CutChannel((Tcl_Channel) chanPtr); /* * Close and free the channel driver state. * This may leave a TIP #219 error message in the interp. */ result = ChanClose(chanPtr, interp); /* * Some resources can be cleared only if the bottom channel in a stack is * closed. All the other channels in the stack are not allowed to remove. */ if (chanPtr == statePtr->bottomChanPtr) { if (statePtr->channelName != NULL) { ckfree(statePtr->channelName); statePtr->channelName = NULL; } Tcl_FreeEncoding(statePtr->encoding); } /* * If we are being called synchronously, report either any latent error on * the channel or the current error. */ if (statePtr->unreportedError != 0) { errorCode = statePtr->unreportedError; /* * TIP #219, Tcl Channel Reflection API. * Move an error message found in the unreported area into the regular * bypass (interp). This kills any message in the channel bypass area. */ if (statePtr->chanMsg != NULL) { TclDecrRefCount(statePtr->chanMsg); statePtr->chanMsg = NULL; } if (interp) { Tcl_SetChannelErrorInterp(interp, statePtr->unreportedMsg); } } if (errorCode == 0) { errorCode = result; if (errorCode != 0) { Tcl_SetErrno(errorCode); } } /* * Cancel any outstanding timer. */ Tcl_DeleteTimerHandler(statePtr->timer); /* * Mark the channel as deleted by clearing the type structure. */ if (chanPtr->downChanPtr != NULL) { Channel *downChanPtr = chanPtr->downChanPtr; statePtr->nextCSPtr = tsdPtr->firstCSPtr; tsdPtr->firstCSPtr = statePtr; statePtr->topChanPtr = downChanPtr; downChanPtr->upChanPtr = NULL; ChannelFree(chanPtr); return Tcl_Close(interp, (Tcl_Channel) downChanPtr); } /* * There is only the TOP Channel, so we free the remaining pointers we * have and then ourselves. Since this is the last of the channels in the * stack, make sure to free the ChannelState structure associated with it. */ ChannelFree(chanPtr); Tcl_EventuallyFree(statePtr, TCL_DYNAMIC); return errorCode; } /* *---------------------------------------------------------------------- * * Tcl_CutChannel -- * CutChannel -- * * Removes a channel from the (thread-)global list of all channels (in * that thread). This is actually the statePtr for the stack of channel. * * Results: * Nothing. * * Side effects: * Resets the field 'nextCSPtr' of the specified channel state to NULL. * * NOTE: * The channel to cut out of the list must not be referenced in any * interpreter. This is something this procedure cannot check (despite * the refcount) because the caller usually wants fiddle with the channel * (like transfering it to a different thread) and thus keeps the * refcount artifically high to prevent its destruction. * *---------------------------------------------------------------------- */ static void CutChannel( Tcl_Channel chan) /* The channel being removed. Must not be * referenced in any interpreter. */ { ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); ChannelState *prevCSPtr; /* Preceding channel state in list of all * states - used to splice a channel out of * the list on close. */ ChannelState *statePtr = ((Channel *) chan)->state; /* State of the channel stack. */ /* * Remove this channel from of the list of all channels (in the current * thread). */ if (tsdPtr->firstCSPtr && (statePtr == tsdPtr->firstCSPtr)) { tsdPtr->firstCSPtr = statePtr->nextCSPtr; } else { for (prevCSPtr = tsdPtr->firstCSPtr; prevCSPtr && (prevCSPtr->nextCSPtr != statePtr); prevCSPtr = prevCSPtr->nextCSPtr) { /* Empty loop body. */ } if (prevCSPtr == NULL) { Tcl_Panic("FlushChannel: damaged channel list"); } prevCSPtr->nextCSPtr = statePtr->nextCSPtr; } statePtr->nextCSPtr = NULL; /* * TIP #218, Channel Thread Actions */ ChanThreadAction((Channel *) chan, TCL_CHANNEL_THREAD_REMOVE); } void Tcl_CutChannel( Tcl_Channel chan) /* The channel being added. Must not be * referenced in any interpreter. */ { Channel *chanPtr = ((Channel *) chan)->state->bottomChanPtr; ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); ChannelState *prevCSPtr; /* Preceding channel state in list of all * states - used to splice a channel out of * the list on close. */ ChannelState *statePtr = chanPtr->state; /* State of the channel stack. */ /* * Remove this channel from of the list of all channels (in the current * thread). */ if (tsdPtr->firstCSPtr && (statePtr == tsdPtr->firstCSPtr)) { tsdPtr->firstCSPtr = statePtr->nextCSPtr; } else { for (prevCSPtr = tsdPtr->firstCSPtr; prevCSPtr && (prevCSPtr->nextCSPtr != statePtr); prevCSPtr = prevCSPtr->nextCSPtr) { /* Empty loop body. */ } if (prevCSPtr == NULL) { Tcl_Panic("FlushChannel: damaged channel list"); } prevCSPtr->nextCSPtr = statePtr->nextCSPtr; } statePtr->nextCSPtr = NULL; /* * TIP #218, Channel Thread Actions * For all transformations and the base channel. */ for (; chanPtr != NULL ; chanPtr = chanPtr->upChanPtr) { ChanThreadAction(chanPtr, TCL_CHANNEL_THREAD_REMOVE); } } /* *---------------------------------------------------------------------- * * Tcl_SpliceChannel -- * SpliceChannel -- * * Adds a channel to the (thread-)global list of all channels (in that * thread). Expects that the field 'nextChanPtr' in the channel is set to * NULL. * * Results: * Nothing. * * Side effects: * Nothing. * * NOTE: * The channel to splice into the list must not be referenced in any * interpreter. This is something this procedure cannot check (despite * the refcount) because the caller usually wants figgle with the channel * (like transfering it to a different thread) and thus keeps the * refcount artifically high to prevent its destruction. * *---------------------------------------------------------------------- */ static void SpliceChannel( Tcl_Channel chan) /* The channel being added. Must not be * referenced in any interpreter. */ { ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); ChannelState *statePtr = ((Channel *) chan)->state; if (statePtr->nextCSPtr != NULL) { Tcl_Panic("SpliceChannel: trying to add channel used in different list"); } statePtr->nextCSPtr = tsdPtr->firstCSPtr; tsdPtr->firstCSPtr = statePtr; /* * TIP #10. Mark the current thread as the new one managing this channel. * Note: 'Tcl_GetCurrentThread' returns sensible values even for * a non-threaded core. */ statePtr->managingThread = Tcl_GetCurrentThread(); /* * TIP #218, Channel Thread Actions */ ChanThreadAction((Channel *) chan, TCL_CHANNEL_THREAD_INSERT); } void Tcl_SpliceChannel( Tcl_Channel chan) /* The channel being added. Must not be * referenced in any interpreter. */ { Channel *chanPtr = ((Channel *) chan)->state->bottomChanPtr; ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); ChannelState *statePtr = chanPtr->state; if (statePtr->nextCSPtr != NULL) { Tcl_Panic("SpliceChannel: trying to add channel used in different list"); } statePtr->nextCSPtr = tsdPtr->firstCSPtr; tsdPtr->firstCSPtr = statePtr; /* * TIP #10. Mark the current thread as the new one managing this channel. * Note: 'Tcl_GetCurrentThread' returns sensible values even for * a non-threaded core. */ statePtr->managingThread = Tcl_GetCurrentThread(); /* * TIP #218, Channel Thread Actions * For all transformations and the base channel. */ for (; chanPtr != NULL ; chanPtr = chanPtr->upChanPtr) { ChanThreadAction(chanPtr, TCL_CHANNEL_THREAD_INSERT); } } /* *---------------------------------------------------------------------- * * Tcl_Close -- * * Closes a channel. * * Results: * A standard Tcl result. * * Side effects: * Closes the channel if this is the last reference. * * NOTE: * Tcl_Close removes the channel as far as the user is concerned. * However, it may continue to exist for a while longer if it has a * background flush scheduled. The device itself is eventually closed and * the channel record removed, in CloseChannel, above. * *---------------------------------------------------------------------- */ /* ARGSUSED */ int Tcl_Close( Tcl_Interp *interp, /* Interpreter for errors. */ Tcl_Channel chan) /* The channel being closed. Must not be * referenced in any interpreter. */ { CloseCallback *cbPtr; /* Iterate over close callbacks for this * channel. */ Channel *chanPtr; /* The real IO channel. */ ChannelState *statePtr; /* State of real IO channel. */ int result; /* Of calling FlushChannel. */ int flushcode; int stickyError; if (chan == NULL) { return TCL_OK; } /* * Perform special handling for standard channels being closed. If the * refCount is now 1 it means that the last reference to the standard * channel is being explicitly closed, so bump the refCount down * artificially to 0. This will ensure that the channel is actually * closed, below. Also set the static pointer to NULL for the channel. */ CheckForStdChannelsBeingClosed(chan); /* * This operation should occur at the top of a channel stack. */ chanPtr = (Channel *) chan; statePtr = chanPtr->state; chanPtr = statePtr->topChanPtr; if (statePtr->refCount > 0) { Tcl_Panic("called Tcl_Close on channel with refCount > 0"); } if (GotFlag(statePtr, CHANNEL_INCLOSE)) { if (interp) { Tcl_SetObjResult(interp, Tcl_NewStringObj( "illegal recursive call to close through close-handler" " of channel", -1)); } return TCL_ERROR; } SetFlag(statePtr, CHANNEL_INCLOSE); /* * When the channel has an escape sequence driven encoding such as * iso2022, the terminated escape sequence must write to the buffer. */ stickyError = 0; if (GotFlag(statePtr, TCL_WRITABLE) && (statePtr->encoding != NULL) && !(statePtr->outputEncodingFlags & TCL_ENCODING_START)) { int code = CheckChannelErrors(statePtr, TCL_WRITABLE); if (code == 0) { statePtr->outputEncodingFlags |= TCL_ENCODING_END; code = WriteChars(chanPtr, "", 0); statePtr->outputEncodingFlags &= ~TCL_ENCODING_END; statePtr->outputEncodingFlags |= TCL_ENCODING_START; } if (code < 0) { stickyError = Tcl_GetErrno(); } /* * TIP #219, Tcl Channel Reflection API. * Move an error message found in the channel bypass into the * interpreter bypass. Just clear it if there is no interpreter. */ if (statePtr->chanMsg != NULL) { if (interp != NULL) { Tcl_SetChannelErrorInterp(interp, statePtr->chanMsg); } TclDecrRefCount(statePtr->chanMsg); statePtr->chanMsg = NULL; } } Tcl_ClearChannelHandlers(chan); /* * Invoke the registered close callbacks and delete their records. */ while (statePtr->closeCbPtr != NULL) { cbPtr = statePtr->closeCbPtr; statePtr->closeCbPtr = cbPtr->nextPtr; cbPtr->proc(cbPtr->clientData); ckfree(cbPtr); } ResetFlag(statePtr, CHANNEL_INCLOSE); /* * If this channel supports it, close the read side, since we don't need * it anymore and this will help avoid deadlocks on some channel types. */ if (chanPtr->typePtr->closeProc == TCL_CLOSE2PROC) { result = chanPtr->typePtr->close2Proc(chanPtr->instanceData, interp, TCL_CLOSE_READ); } else { result = 0; } /* * The call to FlushChannel will flush any queued output and invoke the * close function of the channel driver, or it will set up the channel to * be flushed and closed asynchronously. */ SetFlag(statePtr, CHANNEL_CLOSED); flushcode = FlushChannel(interp, chanPtr, 0); /* * TIP #219. * Capture error messages put by the driver into the bypass area and put * them into the regular interpreter result. * * Notes: Due to the assertion of CHANNEL_CLOSED in the flags * FlushChannel() has called CloseChannel() and thus freed all the channel * structures. We must not try to access "chan" anymore, hence the NULL * argument in the call below. The only place which may still contain a * message is the interpreter itself, and "CloseChannel" made sure to lift * any channel message it generated into it. */ if (TclChanCaughtErrorBypass(interp, NULL)) { result = EINVAL; } if (stickyError != 0) { Tcl_SetErrno(stickyError); if (interp != NULL) { Tcl_SetObjResult(interp, Tcl_NewStringObj(Tcl_PosixError(interp), -1)); } return TCL_ERROR; } /* * Bug 97069ea11a: set error message if a flush code is set and no error * message set up to now. */ if (flushcode != 0 && interp != NULL && 0 == Tcl_GetCharLength(Tcl_GetObjResult(interp))) { Tcl_SetErrno(flushcode); Tcl_SetObjResult(interp, Tcl_NewStringObj(Tcl_PosixError(interp), -1)); } if ((flushcode != 0) || (result != 0)) { return TCL_ERROR; } return TCL_OK; } /* *---------------------------------------------------------------------- * * Tcl_CloseEx -- * * Closes one side of a channel, read or write. * * Results: * A standard Tcl result. * * Side effects: * Closes one direction of the channel. * * NOTE: * Tcl_CloseEx closes the specified direction of the channel as far as * the user is concerned. The channel keeps existing however. You cannot * calls this function to close the last possible direction of the * channel. Use Tcl_Close for that. * *---------------------------------------------------------------------- */ /* ARGSUSED */ int Tcl_CloseEx( Tcl_Interp *interp, /* Interpreter for errors. */ Tcl_Channel chan, /* The channel being closed. May still be used * by some interpreter. */ int flags) /* Flags telling us which side to close. */ { Channel *chanPtr; /* The real IO channel. */ ChannelState *statePtr; /* State of real IO channel. */ if (chan == NULL) { return TCL_OK; } /* TODO: assert flags validity ? */ chanPtr = (Channel *) chan; statePtr = chanPtr->state; /* * Does the channel support half-close anyway? Error if not. */ if (!chanPtr->typePtr->close2Proc) { Tcl_SetObjResult(interp, Tcl_ObjPrintf( "half-close of channels not supported by %ss", chanPtr->typePtr->typeName)); return TCL_ERROR; } /* * Is the channel unstacked ? If not we fail. */ if (chanPtr != statePtr->topChanPtr) { Tcl_SetObjResult(interp, Tcl_NewStringObj( "half-close not applicable to stack of transformations", -1)); return TCL_ERROR; } /* * Check direction against channel mode. It is an error if we try to close * a direction not supported by the channel (already closed, or never * opened for that direction). */ if (!(statePtr->flags & (TCL_READABLE | TCL_WRITABLE) & flags)) { const char *msg; if (flags & TCL_CLOSE_READ) { msg = "read"; } else { msg = "write"; } Tcl_SetObjResult(interp, Tcl_ObjPrintf( "Half-close of %s-side not possible, side not opened or" " already closed", msg)); return TCL_ERROR; } /* * A user may try to call half-close from within a channel close handler. * That won't do. */ if (statePtr->flags & CHANNEL_INCLOSE) { if (interp) { Tcl_SetObjResult(interp, Tcl_NewStringObj( "illegal recursive call to close through close-handler" " of channel", -1)); } return TCL_ERROR; } if (flags & TCL_CLOSE_READ) { /* * Call the finalization code directly. There are no events to handle, * there cannot be for the read-side. */ return CloseChannelPart(interp, chanPtr, 0, flags); } else if (flags & TCL_CLOSE_WRITE) { Tcl_Preserve(statePtr); if (!GotFlag(statePtr, BG_FLUSH_SCHEDULED)) { /* * We don't want to re-enter CloseWrite(). */ if (!GotFlag(statePtr, CHANNEL_CLOSEDWRITE)) { if (CloseWrite(interp, chanPtr) != TCL_OK) { SetFlag(statePtr, CHANNEL_CLOSEDWRITE); Tcl_Release(statePtr); return TCL_ERROR; } } } SetFlag(statePtr, CHANNEL_CLOSEDWRITE); Tcl_Release(statePtr); } return TCL_OK; } /* *---------------------------------------------------------------------- * * CloseWrite -- * * Closes the write side a channel. * * Results: * A standard Tcl result. * * Side effects: * Closes the write side of the channel. * * NOTE: * CloseWrite removes the channel as far as the user is concerned. * However, the ooutput data structures may continue to exist for a while * longer if it has a background flush scheduled. The device itself is * eventually closed and the channel structures modified, in * CloseChannelPart, below. * *---------------------------------------------------------------------- */ static int CloseWrite( Tcl_Interp *interp, /* Interpreter for errors. */ Channel *chanPtr) /* The channel whose write side is being * closed. May still be used by some * interpreter */ { /* * Notes: clear-channel-handlers - write side only ? or keep around, just * not called. * * No close callbacks are run - channel is still open (read side) */ ChannelState *statePtr = chanPtr->state; /* State of real IO channel. */ int flushcode; int result = 0; /* * The call to FlushChannel will flush any queued output and invoke the * close function of the channel driver, or it will set up the channel to * be flushed and closed asynchronously. */ SetFlag(statePtr, CHANNEL_CLOSEDWRITE); flushcode = FlushChannel(interp, chanPtr, 0); /* * TIP #219. * Capture error messages put by the driver into the bypass area and put * them into the regular interpreter result. * * Notes: Due to the assertion of CHANNEL_CLOSEDWRITE in the flags * FlushChannel() has called CloseChannelPart(). While we can still access * "chan" (no structures were freed), the only place which may still * contain a message is the interpreter itself, and "CloseChannelPart" * made sure to lift any channel message it generated into it. Hence the * NULL argument in the call below. */ if (TclChanCaughtErrorBypass(interp, NULL)) { result = EINVAL; } if ((flushcode != 0) || (result != 0)) { return TCL_ERROR; } return TCL_OK; } /* *---------------------------------------------------------------------- * * CloseChannelPart -- * * Utility procedure to close a channel partially and free associated * resources. If the channel was stacked it will never be run (The higher * level forbid this). If the channel was not stacked, then we will free * all the bits of the chosen side (read, or write) for the TOP channel. * * Results: * Error code from an unreported error or the driver close2 operation. * * Side effects: * May free memory, may change the value of errno. * *---------------------------------------------------------------------- */ static int CloseChannelPart( Tcl_Interp *interp, /* Interpreter for errors. */ Channel *chanPtr, /* The channel being closed. May still be used * by some interpreter. */ int errorCode, /* Status of operation so far. */ int flags) /* Flags telling us which side to close. */ { ChannelState *statePtr; /* State of real IO channel. */ int result; /* Of calling the close2proc. */ statePtr = chanPtr->state; if (flags & TCL_CLOSE_READ) { /* * No more input can be consumed so discard any leftover input. */ DiscardInputQueued(statePtr, 1); } else if (flags & TCL_CLOSE_WRITE) { /* * The caller guarantees that there are no more buffers queued for * output. */ if (statePtr->outQueueHead != NULL) { Tcl_Panic("ClosechanHalf, closed write-side of channel: " "queued output left"); } /* * If the EOF character is set in the channel, append that to the * output device. */ if ((statePtr->outEofChar != 0) && GotFlag(statePtr, TCL_WRITABLE)) { int dummy; char c = (char) statePtr->outEofChar; (void) ChanWrite(chanPtr, &c, 1, &dummy); } /* * TIP #219, Tcl Channel Reflection API. * Move a leftover error message in the channel bypass into the * interpreter bypass. Just clear it if there is no interpreter. */ if (statePtr->chanMsg != NULL) { if (interp != NULL) { Tcl_SetChannelErrorInterp(interp, statePtr->chanMsg); } TclDecrRefCount(statePtr->chanMsg); statePtr->chanMsg = NULL; } } /* * Finally do what is asked of us. Close and free the channel driver state * for the chosen side of the channel. This may leave a TIP #219 error * message in the interp. */ result = ChanCloseHalf(chanPtr, interp, flags); /* * If we are being called synchronously, report either any latent error on * the channel or the current error. */ if (statePtr->unreportedError != 0) { errorCode = statePtr->unreportedError; /* * TIP #219, Tcl Channel Reflection API. * Move an error message found in the unreported area into the regular * bypass (interp). This kills any message in the channel bypass area. */ if (statePtr->chanMsg != NULL) { TclDecrRefCount(statePtr->chanMsg); statePtr->chanMsg = NULL; } if (interp) { Tcl_SetChannelErrorInterp(interp, statePtr->unreportedMsg); } } if (errorCode == 0) { errorCode = result; if (errorCode != 0) { Tcl_SetErrno(errorCode); } } /* * TIP #219. * Capture error messages put by the driver into the bypass area and put * them into the regular interpreter result. See also the bottom of * CloseWrite(). */ if (TclChanCaughtErrorBypass(interp, (Tcl_Channel) chanPtr)) { result = EINVAL; } if (result != 0) { return TCL_ERROR; } /* * Remove the closed side from the channel mode/flags. */ ResetFlag(statePtr, flags & (TCL_READABLE | TCL_WRITABLE)); return TCL_OK; } /* *---------------------------------------------------------------------- * * Tcl_ClearChannelHandlers -- * * Removes all channel handlers and event scripts from the channel, * cancels all background copies involving the channel and any interest * in events. * * Results: * None. * * Side effects: * See above. Deallocates memory. * *---------------------------------------------------------------------- */ void Tcl_ClearChannelHandlers( Tcl_Channel channel) { ChannelHandler *chPtr, *chNext; /* Iterate over channel handlers. */ EventScriptRecord *ePtr, *eNextPtr; /* Iterate over eventscript records. */ Channel *chanPtr; /* The real IO channel. */ ChannelState *statePtr; /* State of real IO channel. */ ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); NextChannelHandler *nhPtr; /* * This operation should occur at the top of a channel stack. */ chanPtr = (Channel *) channel; statePtr = chanPtr->state; chanPtr = statePtr->topChanPtr; /* * Cancel any outstanding timer. */ Tcl_DeleteTimerHandler(statePtr->timer); /* * Remove any references to channel handlers for this channel that may be * about to be invoked. */ for (nhPtr = tsdPtr->nestedHandlerPtr; nhPtr != NULL; nhPtr = nhPtr->nestedHandlerPtr) { if (nhPtr->nextHandlerPtr && (nhPtr->nextHandlerPtr->chanPtr == chanPtr)) { nhPtr->nextHandlerPtr = NULL; } } /* * Remove all the channel handler records attached to the channel itself. */ for (chPtr = statePtr->chPtr; chPtr != NULL; chPtr = chNext) { chNext = chPtr->nextPtr; ckfree(chPtr); } statePtr->chPtr = NULL; /* * Cancel any pending copy operation. */ StopCopy(statePtr->csPtrR); StopCopy(statePtr->csPtrW); /* * Must set the interest mask now to 0, otherwise infinite loops will * occur if Tcl_DoOneEvent is called before the channel is finally deleted * in FlushChannel. This can happen if the channel has a background flush * active. */ statePtr->interestMask = 0; /* * Remove any EventScript records for this channel. */ for (ePtr = statePtr->scriptRecordPtr; ePtr != NULL; ePtr = eNextPtr) { eNextPtr = ePtr->nextPtr; TclDecrRefCount(ePtr->scriptPtr); ckfree(ePtr); } statePtr->scriptRecordPtr = NULL; } /* *---------------------------------------------------------------------- * * Tcl_Write -- * * Puts a sequence of bytes into an output buffer, may queue the buffer * for output if it gets full, and also remembers whether the current * buffer is ready e.g. if it contains a newline and we are in line * buffering mode. Compensates stacking, i.e. will redirect the data from * the specified channel to the topmost channel in a stack. * * No encoding conversions are applied to the bytes being read. * * Results: * The number of bytes written or -1 in case of error. If -1, * Tcl_GetErrno will return the error code. * * Side effects: * May buffer up output and may cause output to be produced on the * channel. * *---------------------------------------------------------------------- */ int Tcl_Write( Tcl_Channel chan, /* The channel to buffer output for. */ const char *src, /* Data to queue in output buffer. */ int srcLen) /* Length of data in bytes, or < 0 for * strlen(). */ { /* * Always use the topmost channel of the stack */ Channel *chanPtr; ChannelState *statePtr; /* State info for channel */ statePtr = ((Channel *) chan)->state; chanPtr = statePtr->topChanPtr; if (CheckChannelErrors(statePtr, TCL_WRITABLE) != 0) { return -1; } if (srcLen < 0) { srcLen = strlen(src); } if (WriteBytes(chanPtr, src, srcLen) < 0) { return -1; } return srcLen; } /* *---------------------------------------------------------------------- * * Tcl_WriteRaw -- * * Puts a sequence of bytes into an output buffer, may queue the buffer * for output if it gets full, and also remembers whether the current * buffer is ready e.g. if it contains a newline and we are in line * buffering mode. Writes directly to the driver of the channel, does not * compensate for stacking. * * No encoding conversions are applied to the bytes being read. * * Results: * The number of bytes written or -1 in case of error. If -1, * Tcl_GetErrno will return the error code. * * Side effects: * May buffer up output and may cause output to be produced on the * channel. * *---------------------------------------------------------------------- */ int Tcl_WriteRaw( Tcl_Channel chan, /* The channel to buffer output for. */ const char *src, /* Data to queue in output buffer. */ int srcLen) /* Length of data in bytes, or < 0 for * strlen(). */ { Channel *chanPtr = ((Channel *) chan); ChannelState *statePtr = chanPtr->state; /* State info for channel */ int errorCode, written; if (CheckChannelErrors(statePtr, TCL_WRITABLE | CHANNEL_RAW_MODE) != 0) { return -1; } if (srcLen < 0) { srcLen = strlen(src); } /* * Go immediately to the driver, do all the error handling by ourselves. * The code was stolen from 'FlushChannel'. */ written = ChanWrite(chanPtr, src, srcLen, &errorCode); if (written < 0) { Tcl_SetErrno(errorCode); } return written; } /* *--------------------------------------------------------------------------- * * Tcl_WriteChars -- * * Takes a sequence of UTF-8 characters and converts them for output * using the channel's current encoding, may queue the buffer for output * if it gets full, and also remembers whether the current buffer is * ready e.g. if it contains a newline and we are in line buffering * mode. Compensates stacking, i.e. will redirect the data from the * specified channel to the topmost channel in a stack. * * Results: * The number of bytes written or -1 in case of error. If -1, * Tcl_GetErrno will return the error code. * * Side effects: * May buffer up output and may cause output to be produced on the * channel. * *---------------------------------------------------------------------- */ int Tcl_WriteChars( Tcl_Channel chan, /* The channel to buffer output for. */ const char *src, /* UTF-8 characters to queue in output * buffer. */ int len) /* Length of string in bytes, or < 0 for * strlen(). */ { Channel *chanPtr = (Channel *) chan; ChannelState *statePtr = chanPtr->state; /* State info for channel */ int result; Tcl_Obj *objPtr; if (CheckChannelErrors(statePtr, TCL_WRITABLE) != 0) { return -1; } chanPtr = statePtr->topChanPtr; if (len < 0) { len = strlen(src); } if (statePtr->encoding) { return WriteChars(chanPtr, src, len); } /* * Inefficient way to convert UTF-8 to byte-array, but the code * parallels the way it is done for objects. Special case for 1-byte * (used by eg [puts] for the \n) could be extended to more efficient * translation of the src string. */ if ((len == 1) && (UCHAR(*src) < 0xC0)) { return WriteBytes(chanPtr, src, len); } objPtr = Tcl_NewStringObj(src, len); src = (char *) Tcl_GetByteArrayFromObj(objPtr, &len); result = WriteBytes(chanPtr, src, len); TclDecrRefCount(objPtr); return result; } /* *--------------------------------------------------------------------------- * * Tcl_WriteObj -- * * Takes the Tcl object and queues its contents for output. If the * encoding of the channel is NULL, takes the byte-array representation * of the object and queues those bytes for output. Otherwise, takes the * characters in the UTF-8 (string) representation of the object and * converts them for output using the channel's current encoding. May * flush internal buffers to output if one becomes full or is ready for * some other reason, e.g. if it contains a newline and the channel is in * line buffering mode. * * Results: * The number of bytes written or -1 in case of error. If -1, * Tcl_GetErrno() will return the error code. * * Side effects: * May buffer up output and may cause output to be produced on the * channel. * *---------------------------------------------------------------------- */ int Tcl_WriteObj( Tcl_Channel chan, /* The channel to buffer output for. */ Tcl_Obj *objPtr) /* The object to write. */ { /* * Always use the topmost channel of the stack */ Channel *chanPtr; ChannelState *statePtr; /* State info for channel */ const char *src; int srcLen; statePtr = ((Channel *) chan)->state; chanPtr = statePtr->topChanPtr; if (CheckChannelErrors(statePtr, TCL_WRITABLE) != 0) { return -1; } if (statePtr->encoding == NULL) { src = (char *) Tcl_GetByteArrayFromObj(objPtr, &srcLen); return WriteBytes(chanPtr, src, srcLen); } else { src = TclGetStringFromObj(objPtr, &srcLen); return WriteChars(chanPtr, src, srcLen); } } static void WillWrite( Channel *chanPtr) { int inputBuffered; if ((chanPtr->typePtr->seekProc != NULL) && ((inputBuffered = Tcl_InputBuffered((Tcl_Channel) chanPtr)) > 0)){ int ignore; DiscardInputQueued(chanPtr->state, 0); ChanSeek(chanPtr, -inputBuffered, SEEK_CUR, &ignore); } } static int WillRead( Channel *chanPtr) { if (chanPtr->typePtr == NULL) { /* * Prevent read attempts on a closed channel. */ DiscardInputQueued(chanPtr->state, 0); Tcl_SetErrno(EINVAL); return -1; } if ((chanPtr->typePtr->seekProc != NULL) && (Tcl_OutputBuffered((Tcl_Channel) chanPtr) > 0)) { /* * CAVEAT - The assumption here is that FlushChannel() will push out * the bytes of any writes that are in progress. Since this is a * seekable channel, we assume it is not one that can block and force * bg flushing. Channels we know that can do that - sockets, pipes - * are not seekable. If the assumption is wrong, more drastic measures * may be required here like temporarily setting the channel into * blocking mode. */ if (FlushChannel(NULL, chanPtr, 0) != 0) { return -1; } } return 0; } /* *---------------------------------------------------------------------- * * Write -- * * Convert srcLen bytes starting at src according to encoding and write * produced bytes into an output buffer, may queue the buffer for output * if it gets full, and also remembers whether the current buffer is * ready e.g. if it contains a newline and we are in line buffering mode. * * Results: * The number of bytes written or -1 in case of error. If -1, * Tcl_GetErrno will return the error code. * * Side effects: * May buffer up output and may cause output to be produced on the * channel. * *---------------------------------------------------------------------- */ static int Write( Channel *chanPtr, /* The channel to buffer output for. */ const char *src, /* UTF-8 string to write. */ int srcLen, /* Length of UTF-8 string in bytes. */ Tcl_Encoding encoding) { ChannelState *statePtr = chanPtr->state; /* State info for channel */ char *nextNewLine = NULL; int endEncoding, saved = 0, total = 0, flushed = 0, needNlFlush = 0; if (srcLen) { WillWrite(chanPtr); } /* * Write the terminated escape sequence even if srcLen is 0. */ endEncoding = ((statePtr->outputEncodingFlags & TCL_ENCODING_END) != 0); if (GotFlag(statePtr, CHANNEL_LINEBUFFERED) || (statePtr->outputTranslation != TCL_TRANSLATE_LF)) { nextNewLine = memchr(src, '\n', srcLen); } while (srcLen + saved + endEncoding > 0) { ChannelBuffer *bufPtr; char *dst, safe[BUFFER_PADDING]; int result, srcRead, dstLen, dstWrote, srcLimit = srcLen; if (nextNewLine) { srcLimit = nextNewLine - src; } /* Get space to write into */ bufPtr = statePtr->curOutPtr; if (bufPtr == NULL) { bufPtr = AllocChannelBuffer(statePtr->bufSize); statePtr->curOutPtr = bufPtr; } if (saved) { /* * Here's some translated bytes left over from the last buffer * that we need to stick at the beginning of this buffer. */ memcpy(InsertPoint(bufPtr), safe, (size_t) saved); bufPtr->nextAdded += saved; saved = 0; } PreserveChannelBuffer(bufPtr); dst = InsertPoint(bufPtr); dstLen = SpaceLeft(bufPtr); result = Tcl_UtfToExternal(NULL, encoding, src, srcLimit, statePtr->outputEncodingFlags, &statePtr->outputEncodingState, dst, dstLen + BUFFER_PADDING, &srcRead, &dstWrote, NULL); /* * See chan-io-1.[89]. Tcl Bug 506297. */ statePtr->outputEncodingFlags &= ~TCL_ENCODING_START; if ((result != TCL_OK) && (srcRead + dstWrote == 0)) { /* * We're reading from invalid/incomplete UTF-8. */ ReleaseChannelBuffer(bufPtr); if (total == 0) { Tcl_SetErrno(EINVAL); return -1; } break; } bufPtr->nextAdded += dstWrote; src += srcRead; srcLen -= srcRead; total += dstWrote; dst += dstWrote; dstLen -= dstWrote; if (src == nextNewLine && dstLen > 0) { static char crln[3] = "\r\n"; char *nl = NULL; int nlLen = 0; switch (statePtr->outputTranslation) { case TCL_TRANSLATE_LF: nl = crln + 1; nlLen = 1; break; case TCL_TRANSLATE_CR: nl = crln; nlLen = 1; break; case TCL_TRANSLATE_CRLF: nl = crln; nlLen = 2; break; default: Tcl_Panic("unknown output translation requested"); break; } result |= Tcl_UtfToExternal(NULL, encoding, nl, nlLen, statePtr->outputEncodingFlags, &statePtr->outputEncodingState, dst, dstLen + BUFFER_PADDING, &srcRead, &dstWrote, NULL); assert(srcRead == nlLen); bufPtr->nextAdded += dstWrote; src++; srcLen--; total += dstWrote; dst += dstWrote; dstLen -= dstWrote; nextNewLine = memchr(src, '\n', srcLen); needNlFlush = 1; } if (IsBufferOverflowing(bufPtr)) { /* * When translating from UTF-8 to external encoding, we allowed * the translation to produce a character that crossed the end of * the output buffer, so that we would get a completely full * buffer before flushing it. The extra bytes will be moved to the * beginning of the next buffer. */ saved = -SpaceLeft(bufPtr); memcpy(safe, dst + dstLen, (size_t) saved); bufPtr->nextAdded = bufPtr->bufLength; } if ((srcLen + saved == 0) && (result == TCL_OK)) { endEncoding = 0; } if (IsBufferFull(bufPtr)) { if (FlushChannel(NULL, chanPtr, 0) != 0) { ReleaseChannelBuffer(bufPtr); return -1; } flushed += statePtr->bufSize; /* * We just flushed. So if we have needNlFlush set to record that * we need to flush because theres a (translated) newline in the * buffer, that's likely not true any more. But there is a tricky * exception. If we have saved bytes that did not really get * flushed and those bytes came from a translation of a newline as * the last thing taken from the src array, then needNlFlush needs * to remain set to flag that the next buffer still needs a * newline flush. */ if (needNlFlush && (saved == 0 || src[-1] != '\n')) { needNlFlush = 0; } } ReleaseChannelBuffer(bufPtr); } if ((flushed < total) && (GotFlag(statePtr, CHANNEL_UNBUFFERED) || (needNlFlush && GotFlag(statePtr, CHANNEL_LINEBUFFERED)))) { if (FlushChannel(NULL, chanPtr, 0) != 0) { return -1; } } return total; } /* *--------------------------------------------------------------------------- * * Tcl_Gets -- * * Reads a complete line of input from the channel into a Tcl_DString. * * Results: * Length of line read (in characters) or -1 if error, EOF, or blocked. * If -1, use Tcl_GetErrno() to retrieve the POSIX error code for the * error or condition that occurred. * * Side effects: * May flush output on the channel. May cause input to be consumed from * the channel. * *--------------------------------------------------------------------------- */ int Tcl_Gets( Tcl_Channel chan, /* Channel from which to read. */ Tcl_DString *lineRead) /* The line read will be appended to this * DString as UTF-8 characters. The caller * must have initialized it and is responsible * for managing the storage. */ { Tcl_Obj *objPtr; int charsStored; TclNewObj(objPtr); charsStored = Tcl_GetsObj(chan, objPtr); if (charsStored > 0) { TclDStringAppendObj(lineRead, objPtr); } TclDecrRefCount(objPtr); return charsStored; } /* *--------------------------------------------------------------------------- * * Tcl_GetsObj -- * * Accumulate input from the input channel until end-of-line or * end-of-file has been seen. Bytes read from the input channel are * converted to UTF-8 using the encoding specified by the channel. * * Results: * Number of characters accumulated in the object or -1 if error, * blocked, or EOF. If -1, use Tcl_GetErrno() to retrieve the POSIX error * code for the error or condition that occurred. * * Side effects: * Consumes input from the channel. * * On reading EOF, leave channel pointing at EOF char. On reading EOL, * leave channel pointing after EOL, but don't return EOL in dst buffer. * *--------------------------------------------------------------------------- */ int Tcl_GetsObj( Tcl_Channel chan, /* Channel from which to read. */ Tcl_Obj *objPtr) /* The line read will be appended to this * object as UTF-8 characters. */ { GetsState gs; Channel *chanPtr = (Channel *) chan; ChannelState *statePtr = chanPtr->state; /* State info for channel */ ChannelBuffer *bufPtr; int inEofChar, skip, copiedTotal, oldLength, oldFlags, oldRemoved; Tcl_Encoding encoding; char *dst, *dstEnd, *eol, *eof; Tcl_EncodingState oldState; if (CheckChannelErrors(statePtr, TCL_READABLE) != 0) { return -1; } /* * If we're sitting ready to read the eofchar, there's no need to * do it. */ if (GotFlag(statePtr, CHANNEL_STICKY_EOF)) { SetFlag(statePtr, CHANNEL_EOF); assert(statePtr->inputEncodingFlags & TCL_ENCODING_END); assert(!GotFlag(statePtr, CHANNEL_BLOCKED|INPUT_SAW_CR)); /* TODO: Do we need this? */ UpdateInterest(chanPtr); return -1; } /* * A binary version of Tcl_GetsObj. This could also handle encodings that * are ascii-7 pure (iso8859, utf-8, ...) with a final encoding conversion * done on objPtr. */ if ((statePtr->encoding == NULL) && ((statePtr->inputTranslation == TCL_TRANSLATE_LF) || (statePtr->inputTranslation == TCL_TRANSLATE_CR))) { return TclGetsObjBinary(chan, objPtr); } /* * This operation should occur at the top of a channel stack. */ chanPtr = statePtr->topChanPtr; TclChannelPreserve((Tcl_Channel)chanPtr); bufPtr = statePtr->inQueueHead; encoding = statePtr->encoding; /* * Preserved so we can restore the channel's state in case we don't find a * newline in the available input. */ TclGetStringFromObj(objPtr, &oldLength); oldFlags = statePtr->inputEncodingFlags; oldState = statePtr->inputEncodingState; oldRemoved = BUFFER_PADDING; if (bufPtr != NULL) { oldRemoved = bufPtr->nextRemoved; } /* * If there is no encoding, use "iso8859-1" -- Tcl_GetsObj() doesn't * produce ByteArray objects. */ if (encoding == NULL) { encoding = GetBinaryEncoding(); } /* * Object used by FilterInputBytes to keep track of how much data has been * consumed from the channel buffers. */ gs.objPtr = objPtr; gs.dstPtr = &dst; gs.encoding = encoding; gs.bufPtr = bufPtr; gs.state = oldState; gs.rawRead = 0; gs.bytesWrote = 0; gs.charsWrote = 0; gs.totalChars = 0; dst = objPtr->bytes + oldLength; dstEnd = dst; skip = 0; eof = NULL; inEofChar = statePtr->inEofChar; ResetFlag(statePtr, CHANNEL_BLOCKED); while (1) { if (dst >= dstEnd) { if (FilterInputBytes(chanPtr, &gs) != 0) { goto restore; } dstEnd = dst + gs.bytesWrote; } /* * Remember if EOF char is seen, then look for EOL anyhow, because the * EOL might be before the EOF char. */ if (inEofChar != '\0') { for (eol = dst; eol < dstEnd; eol++) { if (*eol == inEofChar) { dstEnd = eol; eof = eol; break; } } } /* * On EOL, leave current file position pointing after the EOL, but * don't store the EOL in the output string. */ switch (statePtr->inputTranslation) { case TCL_TRANSLATE_LF: for (eol = dst; eol < dstEnd; eol++) { if (*eol == '\n') { skip = 1; goto gotEOL; } } break; case TCL_TRANSLATE_CR: for (eol = dst; eol < dstEnd; eol++) { if (*eol == '\r') { skip = 1; goto gotEOL; } } break; case TCL_TRANSLATE_CRLF: for (eol = dst; eol < dstEnd; eol++) { if (*eol == '\r') { eol++; /* * If a CR is at the end of the buffer, then check for a * LF at the begining of the next buffer, unless EOF char * was found already. */ if (eol >= dstEnd) { int offset; if (eol != eof) { offset = eol - objPtr->bytes; dst = dstEnd; if (FilterInputBytes(chanPtr, &gs) != 0) { goto restore; } dstEnd = dst + gs.bytesWrote; eol = objPtr->bytes + offset; } if (eol >= dstEnd) { skip = 0; goto gotEOL; } } if (*eol == '\n') { eol--; skip = 2; goto gotEOL; } } } break; case TCL_TRANSLATE_AUTO: eol = dst; skip = 1; if (GotFlag(statePtr, INPUT_SAW_CR)) { ResetFlag(statePtr, INPUT_SAW_CR); if ((eol < dstEnd) && (*eol == '\n')) { /* * Skip the raw bytes that make up the '\n'. */ char tmp[TCL_UTF_MAX]; int rawRead; bufPtr = gs.bufPtr; Tcl_ExternalToUtf(NULL, gs.encoding, RemovePoint(bufPtr), gs.rawRead, statePtr->inputEncodingFlags | TCL_ENCODING_NO_TERMINATE, &gs.state, tmp, TCL_UTF_MAX, &rawRead, NULL, NULL); bufPtr->nextRemoved += rawRead; gs.rawRead -= rawRead; gs.bytesWrote--; gs.charsWrote--; memmove(dst, dst + 1, (size_t) (dstEnd - dst)); dstEnd--; } } for (eol = dst; eol < dstEnd; eol++) { if (*eol == '\r') { eol++; if (eol == dstEnd) { /* * If buffer ended on \r, peek ahead to see if a \n is * available, unless EOF char was found already. */ if (eol != eof) { int offset; offset = eol - objPtr->bytes; dst = dstEnd; PeekAhead(chanPtr, &dstEnd, &gs); eol = objPtr->bytes + offset; } if (eol >= dstEnd) { eol--; SetFlag(statePtr, INPUT_SAW_CR); goto gotEOL; } } if (*eol == '\n') { skip++; } eol--; goto gotEOL; } else if (*eol == '\n') { goto gotEOL; } } } if (eof != NULL) { /* * EOF character was seen. On EOF, leave current file position * pointing at the EOF character, but don't store the EOF * character in the output string. */ dstEnd = eof; SetFlag(statePtr, CHANNEL_EOF | CHANNEL_STICKY_EOF); statePtr->inputEncodingFlags |= TCL_ENCODING_END; ResetFlag(statePtr, CHANNEL_BLOCKED|INPUT_SAW_CR); } if (GotFlag(statePtr, CHANNEL_EOF)) { skip = 0; eol = dstEnd; if (eol == objPtr->bytes + oldLength) { /* * If we didn't append any bytes before encountering EOF, * caller needs to see -1. */ Tcl_SetObjLength(objPtr, oldLength); CommonGetsCleanup(chanPtr); copiedTotal = -1; ResetFlag(statePtr, CHANNEL_BLOCKED); goto done; } goto gotEOL; } dst = dstEnd; } /* * Found EOL or EOF, but the output buffer may now contain too many UTF-8 * characters. We need to know how many raw bytes correspond to the number * of UTF-8 characters we want, plus how many raw bytes correspond to the * character(s) making up EOL (if any), so we can remove the correct * number of bytes from the channel buffer. */ gotEOL: /* * Regenerate the top channel, in case it was changed due to * self-modifying reflected transforms. */ if (chanPtr != statePtr->topChanPtr) { TclChannelRelease((Tcl_Channel)chanPtr); chanPtr = statePtr->topChanPtr; TclChannelPreserve((Tcl_Channel)chanPtr); } bufPtr = gs.bufPtr; if (bufPtr == NULL) { Tcl_Panic("Tcl_GetsObj: gotEOL reached with bufPtr==NULL"); } statePtr->inputEncodingState = gs.state; Tcl_ExternalToUtf(NULL, gs.encoding, RemovePoint(bufPtr), gs.rawRead, statePtr->inputEncodingFlags | TCL_ENCODING_NO_TERMINATE, &statePtr->inputEncodingState, dst, eol - dst + skip + TCL_UTF_MAX - 1, &gs.rawRead, NULL, &gs.charsWrote); bufPtr->nextRemoved += gs.rawRead; /* * Recycle all the emptied buffers. */ Tcl_SetObjLength(objPtr, eol - objPtr->bytes); CommonGetsCleanup(chanPtr); ResetFlag(statePtr, CHANNEL_BLOCKED); copiedTotal = gs.totalChars + gs.charsWrote - skip; goto done; /* * Couldn't get a complete line. This only happens if we get a error * reading from the channel or we are non-blocking and there wasn't an EOL * or EOF in the data available. */ restore: /* * Regenerate the top channel, in case it was changed due to * self-modifying reflected transforms. */ if (chanPtr != statePtr->topChanPtr) { TclChannelRelease((Tcl_Channel)chanPtr); chanPtr = statePtr->topChanPtr; TclChannelPreserve((Tcl_Channel)chanPtr); } bufPtr = statePtr->inQueueHead; if (bufPtr != NULL) { bufPtr->nextRemoved = oldRemoved; bufPtr = bufPtr->nextPtr; } for ( ; bufPtr != NULL; bufPtr = bufPtr->nextPtr) { bufPtr->nextRemoved = BUFFER_PADDING; } CommonGetsCleanup(chanPtr); statePtr->inputEncodingState = oldState; statePtr->inputEncodingFlags = oldFlags; Tcl_SetObjLength(objPtr, oldLength); /* * We didn't get a complete line so we need to indicate to UpdateInterest * that the gets blocked. It will wait for more data instead of firing a * timer, avoiding a busy wait. This is where we are assuming that the * next operation is a gets. No more file events will be delivered on this * channel until new data arrives or some operation is performed on the * channel (e.g. gets, read, fconfigure) that changes the blocking state. * Note that this means a file event will not be delivered even though a * read would be able to consume the buffered data. */ SetFlag(statePtr, CHANNEL_NEED_MORE_DATA); copiedTotal = -1; /* * Update the notifier state so we don't block while there is still data * in the buffers. */ done: assert(!GotFlag(statePtr, CHANNEL_EOF) || GotFlag(statePtr, CHANNEL_STICKY_EOF) || Tcl_InputBuffered((Tcl_Channel)chanPtr) == 0); assert(!(GotFlag(statePtr, CHANNEL_EOF|CHANNEL_BLOCKED) == (CHANNEL_EOF|CHANNEL_BLOCKED))); /* * Regenerate the top channel, in case it was changed due to * self-modifying reflected transforms. */ if (chanPtr != statePtr->topChanPtr) { TclChannelRelease((Tcl_Channel)chanPtr); chanPtr = statePtr->topChanPtr; TclChannelPreserve((Tcl_Channel)chanPtr); } UpdateInterest(chanPtr); TclChannelRelease((Tcl_Channel)chanPtr); return copiedTotal; } /* *--------------------------------------------------------------------------- * * TclGetsObjBinary -- * * A variation of Tcl_GetsObj that works directly on the buffers until * end-of-line or end-of-file has been seen. Bytes read from the input * channel return as a ByteArray obj. * * WARNING! The notion of "binary" used here is different from notions * of "binary" used in other places. In particular, this "binary" routine * may be called when an -eofchar is set on the channel. * * Results: * Number of characters accumulated in the object or -1 if error, * blocked, or EOF. If -1, use Tcl_GetErrno() to retrieve the POSIX error * code for the error or condition that occurred. * * Side effects: * Consumes input from the channel. * * On reading EOF, leave channel pointing at EOF char. On reading EOL, * leave channel pointing after EOL, but don't return EOL in dst buffer. * *--------------------------------------------------------------------------- */ static int TclGetsObjBinary( Tcl_Channel chan, /* Channel from which to read. */ Tcl_Obj *objPtr) /* The line read will be appended to this * object as UTF-8 characters. */ { Channel *chanPtr = (Channel *) chan; ChannelState *statePtr = chanPtr->state; /* State info for channel */ ChannelBuffer *bufPtr; int inEofChar, skip, copiedTotal, oldLength, oldFlags, oldRemoved; int rawLen, byteLen, eolChar; unsigned char *dst, *dstEnd, *eol, *eof, *byteArray; /* * This operation should occur at the top of a channel stack. */ chanPtr = statePtr->topChanPtr; TclChannelPreserve((Tcl_Channel)chanPtr); bufPtr = statePtr->inQueueHead; /* * Preserved so we can restore the channel's state in case we don't find a * newline in the available input. */ byteArray = Tcl_GetByteArrayFromObj(objPtr, &byteLen); oldFlags = statePtr->inputEncodingFlags; oldRemoved = BUFFER_PADDING; oldLength = byteLen; if (bufPtr != NULL) { oldRemoved = bufPtr->nextRemoved; } rawLen = 0; skip = 0; eof = NULL; inEofChar = statePtr->inEofChar; /* * Only handle TCL_TRANSLATE_LF and TCL_TRANSLATE_CR. */ eolChar = (statePtr->inputTranslation == TCL_TRANSLATE_LF) ? '\n' : '\r'; ResetFlag(statePtr, CHANNEL_BLOCKED); while (1) { /* * Subtract the number of bytes that were removed from channel buffer * during last call. */ if (bufPtr != NULL) { bufPtr->nextRemoved += rawLen; if (!IsBufferReady(bufPtr)) { bufPtr = bufPtr->nextPtr; } } if ((bufPtr == NULL) || (bufPtr->nextAdded == BUFFER_PADDING)) { /* * All channel buffers were exhausted and the caller still hasn't * seen EOL. Need to read more bytes from the channel device. Side * effect is to allocate another channel buffer. */ if (GetInput(chanPtr) != 0) { goto restore; } bufPtr = statePtr->inQueueTail; if (bufPtr == NULL) { goto restore; } } else { /* * Incoming CHANNEL_STICKY_EOF is filtered out on entry. A new * CHANNEL_STICKY_EOF set in this routine leads to return before * coming back here. When we are not dealing with * CHANNEL_STICKY_EOF, a CHANNEL_EOF implies an empty buffer. * Here the buffer is non-empty so we know we're a non-EOF. */ assert(!GotFlag(statePtr, CHANNEL_STICKY_EOF)); assert(!GotFlag(statePtr, CHANNEL_EOF)); } dst = (unsigned char *) RemovePoint(bufPtr); dstEnd = dst + BytesLeft(bufPtr); /* * Remember if EOF char is seen, then look for EOL anyhow, because the * EOL might be before the EOF char. * XXX - in the binary case, consider coincident search for eol/eof. */ if (inEofChar != '\0') { for (eol = dst; eol < dstEnd; eol++) { if (*eol == inEofChar) { dstEnd = eol; eof = eol; break; } } } /* * On EOL, leave current file position pointing after the EOL, but * don't store the EOL in the output string. */ for (eol = dst; eol < dstEnd; eol++) { if (*eol == eolChar) { skip = 1; goto gotEOL; } } if (eof != NULL) { /* * EOF character was seen. On EOF, leave current file position * pointing at the EOF character, but don't store the EOF * character in the output string. */ SetFlag(statePtr, CHANNEL_EOF | CHANNEL_STICKY_EOF); statePtr->inputEncodingFlags |= TCL_ENCODING_END; ResetFlag(statePtr, CHANNEL_BLOCKED|INPUT_SAW_CR); } if (GotFlag(statePtr, CHANNEL_EOF)) { skip = 0; eol = dstEnd; if ((dst == dstEnd) && (byteLen == oldLength)) { /* * If we didn't append any bytes before encountering EOF, * caller needs to see -1. */ byteArray = Tcl_SetByteArrayLength(objPtr, oldLength); CommonGetsCleanup(chanPtr); copiedTotal = -1; ResetFlag(statePtr, CHANNEL_BLOCKED); goto done; } goto gotEOL; } if (GotFlag(statePtr, CHANNEL_BLOCKED|CHANNEL_NONBLOCKING) == (CHANNEL_BLOCKED|CHANNEL_NONBLOCKING)) { goto restore; } /* * Copy bytes from the channel buffer to the ByteArray. This may * realloc space, so keep track of result. */ rawLen = dstEnd - dst; byteArray = Tcl_SetByteArrayLength(objPtr, byteLen + rawLen); memcpy(byteArray + byteLen, dst, (size_t) rawLen); byteLen += rawLen; } /* * Found EOL or EOF, but the output buffer may now contain too many bytes. * We need to know how many bytes correspond to the number we want, so we * can remove the correct number of bytes from the channel buffer. */ gotEOL: if (bufPtr == NULL) { Tcl_Panic("TclGetsObjBinary: gotEOL reached with bufPtr==NULL"); } rawLen = eol - dst; byteArray = Tcl_SetByteArrayLength(objPtr, byteLen + rawLen); memcpy(byteArray + byteLen, dst, (size_t) rawLen); byteLen += rawLen; bufPtr->nextRemoved += rawLen + skip; /* * Convert the buffer if there was an encoding. * XXX - unimplemented. */ if (statePtr->encoding != NULL) { } /* * Recycle all the emptied buffers. */ CommonGetsCleanup(chanPtr); ResetFlag(statePtr, CHANNEL_BLOCKED); copiedTotal = byteLen; goto done; /* * Couldn't get a complete line. This only happens if we get a error * reading from the channel or we are non-blocking and there wasn't an EOL * or EOF in the data available. */ restore: bufPtr = statePtr->inQueueHead; if (bufPtr) { bufPtr->nextRemoved = oldRemoved; bufPtr = bufPtr->nextPtr; } for ( ; bufPtr != NULL; bufPtr = bufPtr->nextPtr) { bufPtr->nextRemoved = BUFFER_PADDING; } CommonGetsCleanup(chanPtr); statePtr->inputEncodingFlags = oldFlags; byteArray = Tcl_SetByteArrayLength(objPtr, oldLength); /* * We didn't get a complete line so we need to indicate to UpdateInterest * that the gets blocked. It will wait for more data instead of firing a * timer, avoiding a busy wait. This is where we are assuming that the * next operation is a gets. No more file events will be delivered on this * channel until new data arrives or some operation is performed on the * channel (e.g. gets, read, fconfigure) that changes the blocking state. * Note that this means a file event will not be delivered even though a * read would be able to consume the buffered data. */ SetFlag(statePtr, CHANNEL_NEED_MORE_DATA); copiedTotal = -1; /* * Update the notifier state so we don't block while there is still data * in the buffers. */ done: assert(!GotFlag(statePtr, CHANNEL_EOF) || GotFlag(statePtr, CHANNEL_STICKY_EOF) || Tcl_InputBuffered((Tcl_Channel)chanPtr) == 0); assert(!(GotFlag(statePtr, CHANNEL_EOF|CHANNEL_BLOCKED) == (CHANNEL_EOF|CHANNEL_BLOCKED))); UpdateInterest(chanPtr); TclChannelRelease((Tcl_Channel)chanPtr); return copiedTotal; } /* *--------------------------------------------------------------------------- * * FreeBinaryEncoding -- * * Frees any "iso8859-1" Tcl_Encoding created by [gets] on a binary * channel in a thread as part of that thread's finalization. * * Results: * None. * *--------------------------------------------------------------------------- */ static void FreeBinaryEncoding( ClientData dummy) /* Not used */ { ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); if (tsdPtr->binaryEncoding != NULL) { Tcl_FreeEncoding(tsdPtr->binaryEncoding); tsdPtr->binaryEncoding = NULL; } } static Tcl_Encoding GetBinaryEncoding() { ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); if (tsdPtr->binaryEncoding == NULL) { tsdPtr->binaryEncoding = Tcl_GetEncoding(NULL, "iso8859-1"); Tcl_CreateThreadExitHandler(FreeBinaryEncoding, NULL); } if (tsdPtr->binaryEncoding == NULL) { Tcl_Panic("binary encoding is not available"); } return tsdPtr->binaryEncoding; } /* *--------------------------------------------------------------------------- * * FilterInputBytes -- * * Helper function for Tcl_GetsObj. Produces UTF-8 characters from raw * bytes read from the channel. * * Consumes available bytes from channel buffers. When channel buffers * are exhausted, reads more bytes from channel device into a new channel * buffer. It is the caller's responsibility to free the channel buffers * that have been exhausted. * * Results: * The return value is -1 if there was an error reading from the channel, * 0 otherwise. * * Side effects: * Status object keeps track of how much data from channel buffers has * been consumed and where UTF-8 bytes should be stored. * *--------------------------------------------------------------------------- */ static int FilterInputBytes( Channel *chanPtr, /* Channel to read. */ GetsState *gsPtr) /* Current state of gets operation. */ { ChannelState *statePtr = chanPtr->state; /* State info for channel */ ChannelBuffer *bufPtr; char *raw, *dst; int offset, toRead, dstNeeded, spaceLeft, result, rawLen; Tcl_Obj *objPtr; #define ENCODING_LINESIZE 20 /* Lower bound on how many bytes to convert at * a time. Since we don't know a priori how * many bytes of storage this many source * bytes will use, we actually need at least * ENCODING_LINESIZE * TCL_MAX_UTF bytes of * room. */ objPtr = gsPtr->objPtr; /* * Subtract the number of bytes that were removed from channel buffer * during last call. */ bufPtr = gsPtr->bufPtr; if (bufPtr != NULL) { bufPtr->nextRemoved += gsPtr->rawRead; if (!IsBufferReady(bufPtr)) { bufPtr = bufPtr->nextPtr; } } gsPtr->totalChars += gsPtr->charsWrote; if ((bufPtr == NULL) || (bufPtr->nextAdded == BUFFER_PADDING)) { /* * All channel buffers were exhausted and the caller still hasn't seen * EOL. Need to read more bytes from the channel device. Side effect * is to allocate another channel buffer. */ read: if (GotFlag(statePtr, CHANNEL_NONBLOCKING|CHANNEL_BLOCKED) == (CHANNEL_NONBLOCKING|CHANNEL_BLOCKED)) { gsPtr->charsWrote = 0; gsPtr->rawRead = 0; return -1; } if (GetInput(chanPtr) != 0) { gsPtr->charsWrote = 0; gsPtr->rawRead = 0; return -1; } bufPtr = statePtr->inQueueTail; gsPtr->bufPtr = bufPtr; if (bufPtr == NULL) { gsPtr->charsWrote = 0; gsPtr->rawRead = 0; return -1; } } else { /* * Incoming CHANNEL_STICKY_EOF is filtered out on entry. A new * CHANNEL_STICKY_EOF set in this routine leads to return before * coming back here. When we are not dealing with CHANNEL_STICKY_EOF, * a CHANNEL_EOF implies an empty buffer. Here the buffer is * non-empty so we know we're a non-EOF. */ assert(!GotFlag(statePtr, CHANNEL_STICKY_EOF)); assert(!GotFlag(statePtr, CHANNEL_EOF)); } /* * Convert some of the bytes from the channel buffer to UTF-8. Space in * objPtr's string rep is used to hold the UTF-8 characters. Grow the * string rep if we need more space. */ raw = RemovePoint(bufPtr); rawLen = BytesLeft(bufPtr); dst = *gsPtr->dstPtr; offset = dst - objPtr->bytes; toRead = ENCODING_LINESIZE; if (toRead > rawLen) { toRead = rawLen; } dstNeeded = toRead * TCL_UTF_MAX; spaceLeft = objPtr->length - offset; if (dstNeeded > spaceLeft) { int length = offset + ((offset < dstNeeded) ? dstNeeded : offset); if (Tcl_AttemptSetObjLength(objPtr, length) == 0) { length = offset + dstNeeded; if (Tcl_AttemptSetObjLength(objPtr, length) == 0) { dstNeeded = TCL_UTF_MAX - 1 + toRead; length = offset + dstNeeded; Tcl_SetObjLength(objPtr, length); } } spaceLeft = length - offset; dst = objPtr->bytes + offset; *gsPtr->dstPtr = dst; } gsPtr->state = statePtr->inputEncodingState; result = Tcl_ExternalToUtf(NULL, gsPtr->encoding, raw, rawLen, statePtr->inputEncodingFlags | TCL_ENCODING_NO_TERMINATE, &statePtr->inputEncodingState, dst, spaceLeft, &gsPtr->rawRead, &gsPtr->bytesWrote, &gsPtr->charsWrote); /* * Make sure that if we go through 'gets', that we reset the * TCL_ENCODING_START flag still. [Bug #523988] */ statePtr->inputEncodingFlags &= ~TCL_ENCODING_START; if (result == TCL_CONVERT_MULTIBYTE) { /* * The last few bytes in this channel buffer were the start of a * multibyte sequence. If this buffer was full, then move them to the * next buffer so the bytes will be contiguous. */ ChannelBuffer *nextPtr; int extra; nextPtr = bufPtr->nextPtr; if (!IsBufferFull(bufPtr)) { if (gsPtr->rawRead > 0) { /* * Some raw bytes were converted to UTF-8. Fall through, * returning those UTF-8 characters because a EOL might be * present in them. */ } else if (GotFlag(statePtr, CHANNEL_EOF)) { /* * There was a partial character followed by EOF on the * device. Fall through, returning that nothing was found. */ bufPtr->nextRemoved = bufPtr->nextAdded; } else { /* * There are no more cached raw bytes left. See if we can get * some more, but avoid blocking on a non-blocking channel. */ goto read; } } else { if (nextPtr == NULL) { nextPtr = AllocChannelBuffer(statePtr->bufSize); bufPtr->nextPtr = nextPtr; statePtr->inQueueTail = nextPtr; } extra = rawLen - gsPtr->rawRead; memcpy(nextPtr->buf + (BUFFER_PADDING - extra), raw + gsPtr->rawRead, (size_t) extra); nextPtr->nextRemoved -= extra; bufPtr->nextAdded -= extra; } } gsPtr->bufPtr = bufPtr; return 0; } /* *--------------------------------------------------------------------------- * * PeekAhead -- * * Helper function used by Tcl_GetsObj(). Called when we've seen a \r at * the end of the UTF-8 string and want to look ahead one character to * see if it is a \n. * * Results: * *gsPtr->dstPtr is filled with a pointer to the start of the range of * UTF-8 characters that were found by peeking and *dstEndPtr is filled * with a pointer to the bytes just after the end of the range. * * Side effects: * If no more raw bytes were available in one of the channel buffers, * tries to perform a non-blocking read to get more bytes from the * channel device. * *--------------------------------------------------------------------------- */ static void PeekAhead( Channel *chanPtr, /* The channel to read. */ char **dstEndPtr, /* Filled with pointer to end of new range of * UTF-8 characters. */ GetsState *gsPtr) /* Current state of gets operation. */ { ChannelState *statePtr = chanPtr->state; /* State info for channel */ ChannelBuffer *bufPtr; Tcl_DriverBlockModeProc *blockModeProc; int bytesLeft; bufPtr = gsPtr->bufPtr; /* * If there's any more raw input that's still buffered, we'll peek into * that. Otherwise, only get more data from the channel driver if it looks * like there might actually be more data. The assumption is that if the * channel buffer is filled right up to the end, then there might be more * data to read. */ blockModeProc = NULL; if (bufPtr->nextPtr == NULL) { bytesLeft = BytesLeft(bufPtr) - gsPtr->rawRead; if (bytesLeft == 0) { if (!IsBufferFull(bufPtr)) { /* * Don't peek ahead if last read was short read. */ goto cleanup; } if (!GotFlag(statePtr, CHANNEL_NONBLOCKING)) { blockModeProc = Tcl_ChannelBlockModeProc(chanPtr->typePtr); if (blockModeProc == NULL) { /* * Don't peek ahead if cannot set non-blocking mode. */ goto cleanup; } StackSetBlockMode(chanPtr, TCL_MODE_NONBLOCKING); } } } if (FilterInputBytes(chanPtr, gsPtr) == 0) { *dstEndPtr = *gsPtr->dstPtr + gsPtr->bytesWrote; } if (blockModeProc != NULL) { StackSetBlockMode(chanPtr, TCL_MODE_BLOCKING); } return; cleanup: bufPtr->nextRemoved += gsPtr->rawRead; gsPtr->rawRead = 0; gsPtr->totalChars += gsPtr->charsWrote; gsPtr->bytesWrote = 0; gsPtr->charsWrote = 0; } /* *--------------------------------------------------------------------------- * * CommonGetsCleanup -- * * Helper function for Tcl_GetsObj() to restore the channel after a * "gets" operation. * * Results: * None. * * Side effects: * Encoding may be freed. * *--------------------------------------------------------------------------- */ static void CommonGetsCleanup( Channel *chanPtr) { ChannelState *statePtr = chanPtr->state; /* State info for channel */ ChannelBuffer *bufPtr, *nextPtr; bufPtr = statePtr->inQueueHead; for ( ; bufPtr != NULL; bufPtr = nextPtr) { nextPtr = bufPtr->nextPtr; if (IsBufferReady(bufPtr)) { break; } RecycleBuffer(statePtr, bufPtr, 0); } statePtr->inQueueHead = bufPtr; if (bufPtr == NULL) { statePtr->inQueueTail = NULL; } else { /* * If any multi-byte characters were split across channel buffer * boundaries, the split-up bytes were moved to the next channel * buffer by FilterInputBytes(). Move the bytes back to their original * buffer because the caller could change the channel's encoding which * could change the interpretation of whether those bytes really made * up multi-byte characters after all. */ nextPtr = bufPtr->nextPtr; for ( ; nextPtr != NULL; nextPtr = bufPtr->nextPtr) { int extra; extra = SpaceLeft(bufPtr); if (extra > 0) { memcpy(InsertPoint(bufPtr), nextPtr->buf + (BUFFER_PADDING - extra), (size_t) extra); bufPtr->nextAdded += extra; nextPtr->nextRemoved = BUFFER_PADDING; } bufPtr = nextPtr; } } } /* *---------------------------------------------------------------------- * * Tcl_Read -- * * Reads a given number of bytes from a channel. EOL and EOF translation * is done on the bytes being read, so the number of bytes consumed from * the channel may not be equal to the number of bytes stored in the * destination buffer. * * No encoding conversions are applied to the bytes being read. * * Results: * The number of bytes read, or -1 on error. Use Tcl_GetErrno() to * retrieve the error code for the error that occurred. * * Side effects: * May cause input to be buffered. * *---------------------------------------------------------------------- */ int Tcl_Read( Tcl_Channel chan, /* The channel from which to read. */ char *dst, /* Where to store input read. */ int bytesToRead) /* Maximum number of bytes to read. */ { Channel *chanPtr = (Channel *) chan; ChannelState *statePtr = chanPtr->state; /* State info for channel */ /* * This operation should occur at the top of a channel stack. */ chanPtr = statePtr->topChanPtr; if (CheckChannelErrors(statePtr, TCL_READABLE) != 0) { return -1; } return DoRead(chanPtr, dst, bytesToRead, 0); } /* *---------------------------------------------------------------------- * * Tcl_ReadRaw -- * * Reads a given number of bytes from a channel. EOL and EOF translation * is done on the bytes being read, so the number of bytes consumed from * the channel may not be equal to the number of bytes stored in the * destination buffer. * * No encoding conversions are applied to the bytes being read. * * Results: * The number of bytes read, or -1 on error. Use Tcl_GetErrno() to * retrieve the error code for the error that occurred. * * Side effects: * May cause input to be buffered. * *---------------------------------------------------------------------- */ int Tcl_ReadRaw( Tcl_Channel chan, /* The channel from which to read. */ char *readBuf, /* Where to store input read. */ int bytesToRead) /* Maximum number of bytes to read. */ { Channel *chanPtr = (Channel *) chan; ChannelState *statePtr = chanPtr->state; /* State info for channel */ int copied = 0; assert(bytesToRead > 0); if (CheckChannelErrors(statePtr, TCL_READABLE | CHANNEL_RAW_MODE) != 0) { return -1; } /* * First read bytes from the push-back buffers. */ while (chanPtr->inQueueHead && bytesToRead > 0) { ChannelBuffer *bufPtr = chanPtr->inQueueHead; int bytesInBuffer = BytesLeft(bufPtr); int toCopy = (bytesInBuffer < bytesToRead) ? bytesInBuffer : bytesToRead; /* * Copy the current chunk into the read buffer. */ memcpy(readBuf, RemovePoint(bufPtr), (size_t) toCopy); bufPtr->nextRemoved += toCopy; copied += toCopy; readBuf += toCopy; bytesToRead -= toCopy; /* * If the current buffer is empty recycle it. */ if (IsBufferEmpty(bufPtr)) { chanPtr->inQueueHead = bufPtr->nextPtr; if (chanPtr->inQueueHead == NULL) { chanPtr->inQueueTail = NULL; } RecycleBuffer(chanPtr->state, bufPtr, 0); } } /* * Go to the driver only if we got nothing from pushback. Have to do it * this way to avoid EOF mis-timings when we consider the ability that EOF * may not be a permanent condition in the driver, and in that case we * have to synchronize. */ if (copied) { return copied; } /* * This test not needed. */ if (bytesToRead > 0) { int nread = ChanRead(chanPtr, readBuf, bytesToRead); if (nread > 0) { /* * Successful read (short is OK) - add to bytes copied. */ copied += nread; } else if (nread < 0) { /* * An error signaled. If CHANNEL_BLOCKED, then the error is not * real, but an indication of blocked state. In that case, retain * the flag and let caller receive the short read of copied bytes * from the pushback. HOWEVER, if copied==0 bytes from pushback * then repeat signalling the blocked state as an error to caller * so there is no false report of an EOF. When !CHANNEL_BLOCKED, * the error is real and passes on to caller. */ if (!GotFlag(statePtr, CHANNEL_BLOCKED) || copied == 0) { copied = -1; } } else { /* * nread == 0. Driver is at EOF. Let that state filter up. */ } } return copied; } /* *--------------------------------------------------------------------------- * * Tcl_ReadChars -- * * Reads from the channel until the requested number of characters have * been seen, EOF is seen, or the channel would block. EOL and EOF * translation is done. If reading binary data, the raw bytes are wrapped * in a Tcl byte array object. Otherwise, the raw bytes are converted to * UTF-8 using the channel's current encoding and stored in a Tcl string * object. * * Results: * The number of characters read, or -1 on error. Use Tcl_GetErrno() to * retrieve the error code for the error that occurred. * * Side effects: * May cause input to be buffered. * *--------------------------------------------------------------------------- */ int Tcl_ReadChars( Tcl_Channel chan, /* The channel to read. */ Tcl_Obj *objPtr, /* Input data is stored in this object. */ int toRead, /* Maximum number of characters to store, or * -1 to read all available data (up to EOF or * when channel blocks). */ int appendFlag) /* If non-zero, data read from the channel * will be appended to the object. Otherwise, * the data will replace the existing contents * of the object. */ { Channel *chanPtr = (Channel *) chan; ChannelState *statePtr = chanPtr->state; /* State info for channel */ /* * This operation should occur at the top of a channel stack. */ chanPtr = statePtr->topChanPtr; if (CheckChannelErrors(statePtr, TCL_READABLE) != 0) { /* * Update the notifier state so we don't block while there is still * data in the buffers. */ UpdateInterest(chanPtr); return -1; } return DoReadChars(chanPtr, objPtr, toRead, appendFlag); } /* *--------------------------------------------------------------------------- * * DoReadChars -- * * Reads from the channel until the requested number of characters have * been seen, EOF is seen, or the channel would block. EOL and EOF * translation is done. If reading binary data, the raw bytes are wrapped * in a Tcl byte array object. Otherwise, the raw bytes are converted to * UTF-8 using the channel's current encoding and stored in a Tcl string * object. * * Results: * The number of characters read, or -1 on error. Use Tcl_GetErrno() to * retrieve the error code for the error that occurred. * * Side effects: * May cause input to be buffered. * *--------------------------------------------------------------------------- */ static int DoReadChars( Channel *chanPtr, /* The channel to read. */ Tcl_Obj *objPtr, /* Input data is stored in this object. */ int toRead, /* Maximum number of characters to store, or * -1 to read all available data (up to EOF or * when channel blocks). */ int appendFlag) /* If non-zero, data read from the channel * will be appended to the object. Otherwise, * the data will replace the existing contents * of the object. */ { ChannelState *statePtr = chanPtr->state; /* State info for channel */ ChannelBuffer *bufPtr; int copied, copiedNow, result; Tcl_Encoding encoding = statePtr->encoding; int binaryMode; #define UTF_EXPANSION_FACTOR 1024 int factor = UTF_EXPANSION_FACTOR; binaryMode = (encoding == NULL) && (statePtr->inputTranslation == TCL_TRANSLATE_LF) && (statePtr->inEofChar == '\0'); if (appendFlag == 0) { if (binaryMode) { Tcl_SetByteArrayLength(objPtr, 0); } else { Tcl_SetObjLength(objPtr, 0); /* * We're going to access objPtr->bytes directly, so we must ensure * that this is actually a string object (otherwise it might have * been pure Unicode). * * Probably not needed anymore. */ TclGetString(objPtr); } } /* * Early out when next read will see eofchar. * * NOTE: See DoRead for argument that it's a bug (one we're keeping) to * have this escape before the one for zero-char read request. */ if (GotFlag(statePtr, CHANNEL_STICKY_EOF)) { SetFlag(statePtr, CHANNEL_EOF); assert(statePtr->inputEncodingFlags & TCL_ENCODING_END); assert(!GotFlag(statePtr, CHANNEL_BLOCKED|INPUT_SAW_CR)); /* TODO: We don't need this call? */ UpdateInterest(chanPtr); return 0; } /* * Special handling for zero-char read request. */ if (toRead == 0) { if (GotFlag(statePtr, CHANNEL_EOF)) { statePtr->inputEncodingFlags |= TCL_ENCODING_START; } ResetFlag(statePtr, CHANNEL_BLOCKED|CHANNEL_EOF); statePtr->inputEncodingFlags &= ~TCL_ENCODING_END; /* TODO: We don't need this call? */ UpdateInterest(chanPtr); return 0; } /* * This operation should occur at the top of a channel stack. */ chanPtr = statePtr->topChanPtr; TclChannelPreserve((Tcl_Channel)chanPtr); /* * Must clear the BLOCKED|EOF flags here since we check before reading. */ if (GotFlag(statePtr, CHANNEL_EOF)) { statePtr->inputEncodingFlags |= TCL_ENCODING_START; } ResetFlag(statePtr, CHANNEL_BLOCKED|CHANNEL_EOF); statePtr->inputEncodingFlags &= ~TCL_ENCODING_END; for (copied = 0; (unsigned) toRead > 0; ) { copiedNow = -1; if (statePtr->inQueueHead != NULL) { if (binaryMode) { copiedNow = ReadBytes(statePtr, objPtr, toRead); } else { copiedNow = ReadChars(statePtr, objPtr, toRead, &factor); } /* * If the current buffer is empty recycle it. */ bufPtr = statePtr->inQueueHead; if (IsBufferEmpty(bufPtr)) { ChannelBuffer *nextPtr = bufPtr->nextPtr; RecycleBuffer(statePtr, bufPtr, 0); statePtr->inQueueHead = nextPtr; if (nextPtr == NULL) { statePtr->inQueueTail = NULL; } } } if (copiedNow < 0) { if (GotFlag(statePtr, CHANNEL_EOF)) { break; } if (GotFlag(statePtr, CHANNEL_NONBLOCKING|CHANNEL_BLOCKED) == (CHANNEL_NONBLOCKING|CHANNEL_BLOCKED)) { break; } result = GetInput(chanPtr); if (chanPtr != statePtr->topChanPtr) { TclChannelRelease((Tcl_Channel)chanPtr); chanPtr = statePtr->topChanPtr; TclChannelPreserve((Tcl_Channel)chanPtr); } if (result != 0) { if (!GotFlag(statePtr, CHANNEL_BLOCKED)) { copied = -1; } break; } } else { copied += copiedNow; toRead -= copiedNow; } } /* * Failure to fill a channel buffer may have left channel reporting a * "blocked" state, but so long as we fulfilled the request here, the * caller does not consider us blocked. */ if (toRead == 0) { ResetFlag(statePtr, CHANNEL_BLOCKED); } /* * Regenerate the top channel, in case it was changed due to * self-modifying reflected transforms. */ if (chanPtr != statePtr->topChanPtr) { TclChannelRelease((Tcl_Channel)chanPtr); chanPtr = statePtr->topChanPtr; TclChannelPreserve((Tcl_Channel)chanPtr); } /* * Update the notifier state so we don't block while there is still data * in the buffers. */ assert(!GotFlag(statePtr, CHANNEL_EOF) || GotFlag(statePtr, CHANNEL_STICKY_EOF) || Tcl_InputBuffered((Tcl_Channel)chanPtr) == 0); assert(!(GotFlag(statePtr, CHANNEL_EOF|CHANNEL_BLOCKED) == (CHANNEL_EOF|CHANNEL_BLOCKED))); UpdateInterest(chanPtr); TclChannelRelease((Tcl_Channel)chanPtr); return copied; } /* *--------------------------------------------------------------------------- * * ReadBytes -- * * Reads from the channel until the requested number of bytes have been * seen, EOF is seen, or the channel would block. Bytes from the channel * are stored in objPtr as a ByteArray object. EOL and EOF translation * are done. * * 'bytesToRead' can safely be a very large number because space is only * allocated to hold data read from the channel as needed. * * Results: * The return value is the number of bytes appended to the object, or * -1 to indicate that zero bytes were read due to an EOF. * * Side effects: * The storage of bytes in objPtr can cause (re-)allocation of memory. * *--------------------------------------------------------------------------- */ static int ReadBytes( ChannelState *statePtr, /* State of the channel to read. */ Tcl_Obj *objPtr, /* Input data is appended to this ByteArray * object. Its length is how much space has * been allocated to hold data, not how many * bytes of data have been stored in the * object. */ int bytesToRead) /* Maximum number of bytes to store, or < 0 to * get all available bytes. Bytes are obtained * from the first buffer in the queue - even * if this number is larger than the number of * bytes available in the first buffer, only * the bytes from the first buffer are * returned. */ { ChannelBuffer *bufPtr = statePtr->inQueueHead; int srcLen = BytesLeft(bufPtr); int toRead = bytesToRead>srcLen || bytesToRead<0 ? srcLen : bytesToRead; TclAppendBytesToByteArray(objPtr, (unsigned char *) RemovePoint(bufPtr), toRead); bufPtr->nextRemoved += toRead; return toRead; } /* *--------------------------------------------------------------------------- * * ReadChars -- * * Reads from the channel until the requested number of UTF-8 characters * have been seen, EOF is seen, or the channel would block. Raw bytes * from the channel are converted to UTF-8 and stored in objPtr. EOL and * EOF translation is done. * * 'charsToRead' can safely be a very large number because space is only * allocated to hold data read from the channel as needed. * * 'charsToRead' may *not* be 0. * * Results: * The return value is the number of characters appended to the object, * *offsetPtr is filled with the number of bytes that were appended, and * *factorPtr is filled with the expansion factor used to guess how many * bytes of UTF-8 to allocate to hold N source bytes. * * Side effects: * None. * *--------------------------------------------------------------------------- */ static int ReadChars( ChannelState *statePtr, /* State of channel to read. */ Tcl_Obj *objPtr, /* Input data is appended to this object. * objPtr->length is how much space has been * allocated to hold data, not how many bytes * of data have been stored in the object. */ int charsToRead, /* Maximum number of characters to store, or * -1 to get all available characters. * Characters are obtained from the first * buffer in the queue -- even if this number * is larger than the number of characters * available in the first buffer, only the * characters from the first buffer are * returned. The execption is when there is * not any complete character in the first * buffer. In that case, a recursive call * effectively obtains chars from the * second buffer. */ int *factorPtr) /* On input, contains a guess of how many * bytes need to be allocated to hold the * result of converting N source bytes to * UTF-8. On output, contains another guess * based on the data seen so far. */ { Tcl_Encoding encoding = statePtr->encoding? statePtr->encoding : GetBinaryEncoding(); Tcl_EncodingState savedState = statePtr->inputEncodingState; ChannelBuffer *bufPtr = statePtr->inQueueHead; int savedIEFlags = statePtr->inputEncodingFlags; int savedFlags = statePtr->flags; char *dst, *src = RemovePoint(bufPtr); int numBytes, srcLen = BytesLeft(bufPtr); /* * One src byte can yield at most one character. So when the number of * src bytes we plan to read is less than the limit on character count to * be read, clearly we will remain within that limit, and we can use the * value of "srcLen" as a tighter limit for sizing receiving buffers. */ int toRead = ((charsToRead<0)||(charsToRead > srcLen)) ? srcLen : charsToRead; /* * 'factor' is how much we guess that the bytes in the source buffer will * expand when converted to UTF-8 chars. This guess comes from analyzing * how many characters were produced by the previous pass. */ int factor = *factorPtr; int dstLimit = TCL_UTF_MAX - 1 + toRead * factor / UTF_EXPANSION_FACTOR; (void) TclGetStringFromObj(objPtr, &numBytes); Tcl_AppendToObj(objPtr, NULL, dstLimit); if (toRead == srcLen) { unsigned int size; dst = TclGetStringStorage(objPtr, &size) + numBytes; dstLimit = size - numBytes; } else { dst = TclGetString(objPtr) + numBytes; } /* * This routine is burdened with satisfying several constraints. It cannot * append more than 'charsToRead` chars onto objPtr. This is measured * after encoding and translation transformations are completed. There is * no precise number of src bytes that can be associated with the limit. * Yet, when we are done, we must know precisely the number of src bytes * that were consumed to produce the appended chars, so that all * subsequent bytes are left in the buffers for future read operations. * * The consequence is that we have no choice but to implement a "trial and * error" approach, where in general we may need to perform * transformations and copies multiple times to achieve a consistent set * of results. This takes the shape of a loop. */ while (1) { int dstDecoded, dstRead, dstWrote, srcRead, numChars, code; int flags = statePtr->inputEncodingFlags | TCL_ENCODING_NO_TERMINATE; if (charsToRead > 0) { flags |= TCL_ENCODING_CHAR_LIMIT; numChars = charsToRead; } /* * Perform the encoding transformation. Read no more than srcLen * bytes, write no more than dstLimit bytes. * * Some trickiness with encoding flags here. We do not want the end * of a buffer to be treated as the end of all input when the presence * of bytes in a next buffer are already known to exist. This is * checked with an assert() because so far no test case causing the * assertion to be false has been created. The normal operations of * channel reading appear to cause EOF and TCL_ENCODING_END setting to * appear only in situations where there are no further bytes in any * buffers. */ assert(bufPtr->nextPtr == NULL || BytesLeft(bufPtr->nextPtr) == 0 || (statePtr->inputEncodingFlags & TCL_ENCODING_END) == 0); code = Tcl_ExternalToUtf(NULL, encoding, src, srcLen, flags, &statePtr->inputEncodingState, dst, dstLimit, &srcRead, &dstDecoded, &numChars); /* * Perform the translation transformation in place. Read no more than * the dstDecoded bytes the encoding transformation actually produced. * Capture the number of bytes written in dstWrote. Capture the number * of bytes actually consumed in dstRead. */ dstWrote = dstLimit; dstRead = dstDecoded; TranslateInputEOL(statePtr, dst, dst, &dstWrote, &dstRead); if (dstRead < dstDecoded) { /* * The encoding transformation produced bytes that the translation * transformation did not consume. Why did this happen? */ if (statePtr->inEofChar && dst[dstRead] == statePtr->inEofChar) { /* * 1) There's an eof char set on the channel, and * we saw it and stopped translating at that point. * * NOTE the bizarre spec of TranslateInputEOL in this case. * Clearly the eof char had to be read in order to account for * the stopping, but the value of dstRead does not include it. * * Also rather bizarre, our caller can only notice an EOF * condition if we return the value -1 as the number of chars * read. This forces us to perform a 2-call dance where the * first call can read all the chars up to the eof char, and * the second call is solely for consuming the encoded eof * char then pointed at by src so that we can return that * magic -1 value. This seems really wasteful, especially * since the first decoding pass of each call is likely to * decode many bytes beyond that eof char that's all we care * about. */ if (dstRead == 0) { /* * Curious choice in the eof char handling. We leave the * eof char in the buffer. So, no need to compute a proper * srcRead value. At this point, there are no chars before * the eof char in the buffer. */ Tcl_SetObjLength(objPtr, numBytes); return -1; } { /* * There are chars leading the buffer before the eof char. * Adjust the dstLimit so we go back and read only those * and do not encounter the eof char this time. */ dstLimit = dstRead - 1 + TCL_UTF_MAX; statePtr->flags = savedFlags; statePtr->inputEncodingFlags = savedIEFlags; statePtr->inputEncodingState = savedState; continue; } } /* * 2) The other way to read fewer bytes than are decoded is when * the final byte is \r and we're in a CRLF translation mode so * we cannot decide whether to record \r or \n yet. */ assert(dst[dstRead] == '\r'); assert(statePtr->inputTranslation == TCL_TRANSLATE_CRLF); if (dstWrote > 0) { /* * There are chars we can read before we hit the bare CR. Go * back with a smaller dstLimit so we get them in the next * pass, compute a matching srcRead, and don't end up back * here in this call. */ dstLimit = dstRead - 1 + TCL_UTF_MAX; statePtr->flags = savedFlags; statePtr->inputEncodingFlags = savedIEFlags; statePtr->inputEncodingState = savedState; continue; } assert(dstWrote == 0); assert(dstRead == 0); /* * We decoded only the bare CR, and we cannot read a translated * char from that alone. We have to know what's next. So why do * we only have the one decoded char? */ if (code != TCL_OK) { char buffer[TCL_UTF_MAX + 1]; int read, decoded, count; /* * Didn't get everything the buffer could offer */ statePtr->flags = savedFlags; statePtr->inputEncodingFlags = savedIEFlags; statePtr->inputEncodingState = savedState; assert(bufPtr->nextPtr == NULL || BytesLeft(bufPtr->nextPtr) == 0 || 0 == (statePtr->inputEncodingFlags & TCL_ENCODING_END)); Tcl_ExternalToUtf(NULL, encoding, src, srcLen, (statePtr->inputEncodingFlags | TCL_ENCODING_NO_TERMINATE), &statePtr->inputEncodingState, buffer, TCL_UTF_MAX + 1, &read, &decoded, &count); if (count == 2) { if (buffer[1] == '\n') { /* \r\n translate to \n */ dst[0] = '\n'; bufPtr->nextRemoved += read; } else { dst[0] = '\r'; bufPtr->nextRemoved += srcRead; } statePtr->inputEncodingFlags &= ~TCL_ENCODING_START; Tcl_SetObjLength(objPtr, numBytes + 1); return 1; } } else if (statePtr->flags & CHANNEL_EOF) { /* * The bare \r is the only char and we will never read a * subsequent char to make the determination. */ dst[0] = '\r'; bufPtr->nextRemoved = bufPtr->nextAdded; Tcl_SetObjLength(objPtr, numBytes + 1); return 1; } /* * Revise the dstRead value so that the numChars calc below * correctly computes zero characters read. */ dstRead = numChars; /* FALL THROUGH - get more data (dstWrote == 0) */ } /* * The translation transformation can only reduce the number of chars * when it converts \r\n into \n. The reduction in the number of chars * is the difference in bytes read and written. */ numChars -= (dstRead - dstWrote); if (charsToRead > 0 && numChars > charsToRead) { /* * TODO: This cannot happen anymore. * * We read more chars than allowed. Reset limits to prevent that * and try again. Don't forget the extra padding of TCL_UTF_MAX * bytes demanded by the Tcl_ExternalToUtf() call! */ dstLimit = Tcl_UtfAtIndex(dst, charsToRead) - 1 + TCL_UTF_MAX - dst; statePtr->flags = savedFlags; statePtr->inputEncodingFlags = savedIEFlags; statePtr->inputEncodingState = savedState; continue; } if (dstWrote == 0) { ChannelBuffer *nextPtr; /* * We were not able to read any chars. */ assert(numChars == 0); /* * There is one situation where this is the correct final result. * If the src buffer contains only a single \n byte, and we are in * TCL_TRANSLATE_AUTO mode, and when the translation pass was made * the INPUT_SAW_CR flag was set on the channel. In that case, the * correct behavior is to consume that \n and produce the empty * string. */ if (dstRead == 1 && dst[0] == '\n') { assert(statePtr->inputTranslation == TCL_TRANSLATE_AUTO); goto consume; } /* * Otherwise, reading zero characters indicates there's something * incomplete at the end of the src buffer. Maybe there were not * enough src bytes to decode into a char. Maybe a lone \r could * not be translated (crlf mode). Need to combine any unused src * bytes we have in the first buffer with subsequent bytes to try * again. */ nextPtr = bufPtr->nextPtr; if (nextPtr == NULL) { if (srcLen > 0) { SetFlag(statePtr, CHANNEL_NEED_MORE_DATA); } Tcl_SetObjLength(objPtr, numBytes); return -1; } /* * Space is made at the beginning of the buffer to copy the * previous unused bytes there. Check first if the buffer we are * using actually has enough space at its beginning for the data * we are copying. Because if not we will write over the buffer * management information, especially the 'nextPtr'. * * Note that the BUFFER_PADDING (See AllocChannelBuffer) is used * to prevent exactly this situation. I.e. it should never happen. * Therefore it is ok to panic should it happen despite the * precautions. */ if (nextPtr->nextRemoved - srcLen < 0) { Tcl_Panic("Buffer Underflow, BUFFER_PADDING not enough"); } nextPtr->nextRemoved -= srcLen; memcpy(RemovePoint(nextPtr), src, (size_t) srcLen); RecycleBuffer(statePtr, bufPtr, 0); statePtr->inQueueHead = nextPtr; Tcl_SetObjLength(objPtr, numBytes); return ReadChars(statePtr, objPtr, charsToRead, factorPtr); } statePtr->inputEncodingFlags &= ~TCL_ENCODING_START; consume: bufPtr->nextRemoved += srcRead; /* * If this read contained multibyte characters, revise factorPtr so * the next read will allocate bigger buffers. */ if (numChars && numChars < srcRead) { *factorPtr = srcRead * UTF_EXPANSION_FACTOR / numChars; } Tcl_SetObjLength(objPtr, numBytes + dstWrote); return numChars; } } /* *--------------------------------------------------------------------------- * * TranslateInputEOL -- * * Perform input EOL and EOF translation on the source buffer, leaving * the translated result in the destination buffer. * * Results: * The return value is 1 if the EOF character was found when copying * bytes to the destination buffer, 0 otherwise. * * Side effects: * None. * *--------------------------------------------------------------------------- */ static void TranslateInputEOL( ChannelState *statePtr, /* Channel being read, for EOL translation and * EOF character. */ char *dstStart, /* Output buffer filled with chars by applying * appropriate EOL translation to source * characters. */ const char *srcStart, /* Source characters. */ int *dstLenPtr, /* On entry, the maximum length of output * buffer in bytes. On exit, the number of * bytes actually used in output buffer. */ int *srcLenPtr) /* On entry, the length of source buffer. On * exit, the number of bytes read from the * source buffer. */ { const char *eof = NULL; int dstLen = *dstLenPtr; int srcLen = *srcLenPtr; int inEofChar = statePtr->inEofChar; /* * Depending on the translation mode in use, there's no need to scan more * srcLen bytes at srcStart than can possibly transform to dstLen bytes. * This keeps the scan for eof char below from being pointlessly long. */ switch (statePtr->inputTranslation) { case TCL_TRANSLATE_LF: case TCL_TRANSLATE_CR: if (srcLen > dstLen) { /* * In these modes, each src byte become a dst byte. */ srcLen = dstLen; } break; default: /* * In other modes, at most 2 src bytes become a dst byte. */ if (srcLen/2 > dstLen) { srcLen = 2 * dstLen; } break; } if (inEofChar != '\0') { /* * Make sure we do not read past any logical end of channel input * created by the presence of the input eof char. */ if ((eof = memchr(srcStart, inEofChar, srcLen))) { srcLen = eof - srcStart; } } switch (statePtr->inputTranslation) { case TCL_TRANSLATE_LF: case TCL_TRANSLATE_CR: if (dstStart != srcStart) { memcpy(dstStart, srcStart, (size_t) srcLen); } if (statePtr->inputTranslation == TCL_TRANSLATE_CR) { char *dst = dstStart; char *dstEnd = dstStart + srcLen; while ((dst = memchr(dst, '\r', dstEnd - dst))) { *dst++ = '\n'; } } dstLen = srcLen; break; case TCL_TRANSLATE_CRLF: { const char *crFound, *src = srcStart; char *dst = dstStart; int lesser = (dstLen < srcLen) ? dstLen : srcLen; while ((crFound = memchr(src, '\r', lesser))) { int numBytes = crFound - src; memmove(dst, src, numBytes); dst += numBytes; dstLen -= numBytes; src += numBytes; srcLen -= numBytes; if (srcLen == 1) { /* valid src bytes end in \r */ if (eof) { *dst++ = '\r'; src++; srcLen--; } else { lesser = 0; break; } } else if (src[1] == '\n') { *dst++ = '\n'; src += 2; srcLen -= 2; } else { *dst++ = '\r'; src++; srcLen--; } dstLen--; lesser = (dstLen < srcLen) ? dstLen : srcLen; } memmove(dst, src, lesser); srcLen = src + lesser - srcStart; dstLen = dst + lesser - dstStart; break; } case TCL_TRANSLATE_AUTO: { const char *crFound, *src = srcStart; char *dst = dstStart; int lesser; if ((statePtr->flags & INPUT_SAW_CR) && srcLen) { if (*src == '\n') { src++; srcLen--; } ResetFlag(statePtr, INPUT_SAW_CR); } lesser = (dstLen < srcLen) ? dstLen : srcLen; while ((crFound = memchr(src, '\r', lesser))) { int numBytes = crFound - src; memmove(dst, src, numBytes); dst[numBytes] = '\n'; dst += numBytes + 1; dstLen -= numBytes + 1; src += numBytes + 1; srcLen -= numBytes + 1; if (srcLen == 0) { SetFlag(statePtr, INPUT_SAW_CR); } else if (*src == '\n') { src++; srcLen--; } lesser = (dstLen < srcLen) ? dstLen : srcLen; } memmove(dst, src, lesser); srcLen = src + lesser - srcStart; dstLen = dst + lesser - dstStart; break; } default: Tcl_Panic("unknown input translation %d", statePtr->inputTranslation); } *dstLenPtr = dstLen; *srcLenPtr = srcLen; if (srcStart + srcLen == eof) { /* * EOF character was seen in EOL translated range. Leave current file * position pointing at the EOF character, but don't store the EOF * character in the output string. */ SetFlag(statePtr, CHANNEL_EOF | CHANNEL_STICKY_EOF); statePtr->inputEncodingFlags |= TCL_ENCODING_END; ResetFlag(statePtr, CHANNEL_BLOCKED|INPUT_SAW_CR); } } /* *---------------------------------------------------------------------- * * Tcl_Ungets -- * * Causes the supplied string to be added to the input queue of the * channel, at either the head or tail of the queue. * * Results: * The number of bytes stored in the channel, or -1 on error. * * Side effects: * Adds input to the input queue of a channel. * *---------------------------------------------------------------------- */ int Tcl_Ungets( Tcl_Channel chan, /* The channel for which to add the input. */ const char *str, /* The input itself. */ int len, /* The length of the input. */ int atEnd) /* If non-zero, add at end of queue; otherwise * add at head of queue. */ { Channel *chanPtr; /* The real IO channel. */ ChannelState *statePtr; /* State of actual channel. */ ChannelBuffer *bufPtr; /* Buffer to contain the data. */ int flags; chanPtr = (Channel *) chan; statePtr = chanPtr->state; /* * This operation should occur at the top of a channel stack. */ chanPtr = statePtr->topChanPtr; /* * CheckChannelErrors clears too many flag bits in this one case. */ flags = statePtr->flags; if (CheckChannelErrors(statePtr, TCL_READABLE) != 0) { len = -1; goto done; } statePtr->flags = flags; /* * Clear the EOF flags, and clear the BLOCKED bit. */ if (GotFlag(statePtr, CHANNEL_EOF)) { statePtr->inputEncodingFlags |= TCL_ENCODING_START; } ResetFlag(statePtr, CHANNEL_BLOCKED | CHANNEL_STICKY_EOF | CHANNEL_EOF | INPUT_SAW_CR); statePtr->inputEncodingFlags &= ~TCL_ENCODING_END; bufPtr = AllocChannelBuffer(len); memcpy(InsertPoint(bufPtr), str, (size_t) len); bufPtr->nextAdded += len; if (statePtr->inQueueHead == NULL) { bufPtr->nextPtr = NULL; statePtr->inQueueHead = bufPtr; statePtr->inQueueTail = bufPtr; } else if (atEnd) { bufPtr->nextPtr = NULL; statePtr->inQueueTail->nextPtr = bufPtr; statePtr->inQueueTail = bufPtr; } else { bufPtr->nextPtr = statePtr->inQueueHead; statePtr->inQueueHead = bufPtr; } /* * Update the notifier state so we don't block while there is still data * in the buffers. */ done: UpdateInterest(chanPtr); return len; } /* *---------------------------------------------------------------------- * * Tcl_Flush -- * * Flushes output data on a channel. * * Results: * A standard Tcl result. * * Side effects: * May flush output queued on this channel. * *---------------------------------------------------------------------- */ int Tcl_Flush( Tcl_Channel chan) /* The Channel to flush. */ { int result; /* Of calling FlushChannel. */ Channel *chanPtr = (Channel *) chan; /* The actual channel. */ ChannelState *statePtr = chanPtr->state; /* State of actual channel. */ /* * This operation should occur at the top of a channel stack. */ chanPtr = statePtr->topChanPtr; if (CheckChannelErrors(statePtr, TCL_WRITABLE) != 0) { return -1; } result = FlushChannel(NULL, chanPtr, 0); if (result != 0) { return TCL_ERROR; } return TCL_OK; } /* *---------------------------------------------------------------------- * * DiscardInputQueued -- * * Discards any input read from the channel but not yet consumed by Tcl * reading commands. * * Results: * None. * * Side effects: * May discard input from the channel. If discardLastBuffer is zero, * leaves one buffer in place for back-filling. * *---------------------------------------------------------------------- */ static void DiscardInputQueued( ChannelState *statePtr, /* Channel on which to discard the queued * input. */ int discardSavedBuffers) /* If non-zero, discard all buffers including * last one. */ { ChannelBuffer *bufPtr, *nxtPtr; /* Loop variables. */ bufPtr = statePtr->inQueueHead; statePtr->inQueueHead = NULL; statePtr->inQueueTail = NULL; for (; bufPtr != NULL; bufPtr = nxtPtr) { nxtPtr = bufPtr->nextPtr; RecycleBuffer(statePtr, bufPtr, discardSavedBuffers); } /* * If discardSavedBuffers is nonzero, must also discard any previously * saved buffer in the saveInBufPtr field. */ if (discardSavedBuffers && statePtr->saveInBufPtr != NULL) { ReleaseChannelBuffer(statePtr->saveInBufPtr); statePtr->saveInBufPtr = NULL; } } /* *--------------------------------------------------------------------------- * * GetInput -- * * Reads input data from a device into a channel buffer. * * IMPORTANT! This routine is only called on a chanPtr argument * that is the top channel of a stack! * * Results: * The return value is the Posix error code if an error occurred while * reading from the file, or 0 otherwise. * * Side effects: * Reads from the underlying device. * *--------------------------------------------------------------------------- */ static int GetInput( Channel *chanPtr) /* Channel to read input from. */ { int toRead; /* How much to read? */ int result; /* Of calling driver. */ int nread; /* How much was read from channel? */ ChannelBuffer *bufPtr; /* New buffer to add to input queue. */ ChannelState *statePtr = chanPtr->state; /* State info for channel */ /* * Verify that all callers know better than to call us when * it's recorded that the next char waiting to be read is the * eofchar. */ assert(!GotFlag(statePtr, CHANNEL_STICKY_EOF)); /* * Prevent reading from a dead channel -- a channel that has been closed * but not yet deallocated, which can happen if the exit handler for * channel cleanup has run but the channel is still registered in some * interpreter. */ if (CheckForDeadChannel(NULL, statePtr)) { return EINVAL; } /* * WARNING: There was once a comment here claiming that it was a bad idea * to make another call to the inputproc of a channel driver when EOF has * already been detected on the channel. Through much of Tcl's history, * this warning was then completely negated by having all (most?) read * paths clear the EOF setting before reaching here. So we had a guard * that was never triggered. * * Don't be tempted to restore the guard. Even if EOF is set on the * channel, continue through and call the inputproc again. This is the * way to enable the ability to [read] again beyond the EOF, which seems a * strange thing to do, but for which use cases exist [Tcl Bug 5adc350683] * and which may even be essential for channels representing things like * ttys or other devices where the stream might take the logical form of a * series of 'files' separated by an EOF condition. * * First check for more buffers in the pushback area of the topmost * channel in the stack and use them. They can be the result of a * transformation which went away without reading all the information * placed in the area when it was stacked. */ if (chanPtr->inQueueHead != NULL) { /* TODO: Tests to cover this. */ assert(statePtr->inQueueHead == NULL); statePtr->inQueueHead = chanPtr->inQueueHead; statePtr->inQueueTail = chanPtr->inQueueTail; chanPtr->inQueueHead = NULL; chanPtr->inQueueTail = NULL; return 0; } /* * Nothing in the pushback area, fall back to the usual handling (driver, * etc.) */ /* * See if we can fill an existing buffer. If we can, read only as much as * will fit in it. Otherwise allocate a new buffer, add it to the input * queue and attempt to fill it to the max. */ bufPtr = statePtr->inQueueTail; if ((bufPtr == NULL) || IsBufferFull(bufPtr)) { bufPtr = statePtr->saveInBufPtr; statePtr->saveInBufPtr = NULL; /* * Check the actual buffersize against the requested buffersize. * Saved buffers of the wrong size are squashed. This is done to honor * dynamic changes of the buffersize made by the user. * * TODO: Tests to cover this. */ if ((bufPtr != NULL) && (bufPtr->bufLength - BUFFER_PADDING != statePtr->bufSize)) { ReleaseChannelBuffer(bufPtr); bufPtr = NULL; } if (bufPtr == NULL) { bufPtr = AllocChannelBuffer(statePtr->bufSize); } bufPtr->nextPtr = NULL; toRead = SpaceLeft(bufPtr); assert(toRead == statePtr->bufSize); if (statePtr->inQueueTail == NULL) { statePtr->inQueueHead = bufPtr; } else { statePtr->inQueueTail->nextPtr = bufPtr; } statePtr->inQueueTail = bufPtr; } else { toRead = SpaceLeft(bufPtr); } PreserveChannelBuffer(bufPtr); nread = ChanRead(chanPtr, InsertPoint(bufPtr), toRead); if (nread < 0) { result = Tcl_GetErrno(); } else { result = 0; bufPtr->nextAdded += nread; } ReleaseChannelBuffer(bufPtr); return result; } /* *---------------------------------------------------------------------- * * Tcl_Seek -- * * Implements seeking on Tcl Channels. This is a public function so that * other C facilities may be implemented on top of it. * * Results: * The new access point or -1 on error. If error, use Tcl_GetErrno() to * retrieve the POSIX error code for the error that occurred. * * Side effects: * May flush output on the channel. May discard queued input. * *---------------------------------------------------------------------- */ Tcl_WideInt Tcl_Seek( Tcl_Channel chan, /* The channel on which to seek. */ Tcl_WideInt offset, /* Offset to seek to. */ int mode) /* Relative to which location to seek? */ { Channel *chanPtr = (Channel *) chan; /* The real IO channel. */ ChannelState *statePtr = chanPtr->state; /* State info for channel */ int inputBuffered, outputBuffered; /* # bytes held in buffers. */ int result; /* Of device driver operations. */ Tcl_WideInt curPos; /* Position on the device. */ int wasAsync; /* Was the channel nonblocking before the seek * operation? If so, must restore to * non-blocking mode after the seek. */ if (CheckChannelErrors(statePtr, TCL_WRITABLE | TCL_READABLE) != 0) { return Tcl_LongAsWide(-1); } /* * Disallow seek on dead channels - channels that have been closed but not * yet been deallocated. Such channels can be found if the exit handler * for channel cleanup has run but the channel is still registered in an * interpreter. */ if (CheckForDeadChannel(NULL, statePtr)) { return Tcl_LongAsWide(-1); } /* * This operation should occur at the top of a channel stack. */ chanPtr = statePtr->topChanPtr; /* * Disallow seek on channels whose type does not have a seek procedure * defined. This means that the channel does not support seeking. */ if (chanPtr->typePtr->seekProc == NULL) { Tcl_SetErrno(EINVAL); return Tcl_LongAsWide(-1); } /* * Compute how much input and output is buffered. If both input and output * is buffered, cannot compute the current position. */ inputBuffered = Tcl_InputBuffered(chan); outputBuffered = Tcl_OutputBuffered(chan); if ((inputBuffered != 0) && (outputBuffered != 0)) { Tcl_SetErrno(EFAULT); return Tcl_LongAsWide(-1); } /* * If we are seeking relative to the current position, compute the * corrected offset taking into account the amount of unread input. */ if (mode == SEEK_CUR) { offset -= inputBuffered; } /* * Discard any queued input - this input should not be read after the * seek. */ DiscardInputQueued(statePtr, 0); /* * Reset EOF and BLOCKED flags. We invalidate them by moving the access * point. Also clear CR related flags. */ if (GotFlag(statePtr, CHANNEL_EOF)) { statePtr->inputEncodingFlags |= TCL_ENCODING_START; } ResetFlag(statePtr, CHANNEL_EOF | CHANNEL_STICKY_EOF | CHANNEL_BLOCKED | INPUT_SAW_CR); statePtr->inputEncodingFlags &= ~TCL_ENCODING_END; /* * If the channel is in asynchronous output mode, switch it back to * synchronous mode and cancel any async flush that may be scheduled. * After the flush, the channel will be put back into asynchronous output * mode. */ wasAsync = 0; if (GotFlag(statePtr, CHANNEL_NONBLOCKING)) { wasAsync = 1; result = StackSetBlockMode(chanPtr, TCL_MODE_BLOCKING); if (result != 0) { return Tcl_LongAsWide(-1); } ResetFlag(statePtr, CHANNEL_NONBLOCKING); if (GotFlag(statePtr, BG_FLUSH_SCHEDULED)) { ResetFlag(statePtr, BG_FLUSH_SCHEDULED); } } /* * If the flush fails we cannot recover the original position. In that * case the seek is not attempted because we do not know where the access * position is - instead we return the error. FlushChannel has already * called Tcl_SetErrno() to report the error upwards. If the flush * succeeds we do the seek also. */ if (FlushChannel(NULL, chanPtr, 0) != 0) { curPos = -1; } else { /* * Now seek to the new position in the channel as requested by the * caller. */ curPos = ChanSeek(chanPtr, offset, mode, &result); if (curPos == Tcl_LongAsWide(-1)) { Tcl_SetErrno(result); } } /* * Restore to nonblocking mode if that was the previous behavior. * * NOTE: Even if there was an async flush active we do not restore it now * because we already flushed all the queued output, above. */ if (wasAsync) { SetFlag(statePtr, CHANNEL_NONBLOCKING); result = StackSetBlockMode(chanPtr, TCL_MODE_NONBLOCKING); if (result != 0) { return Tcl_LongAsWide(-1); } } return curPos; } /* *---------------------------------------------------------------------- * * Tcl_Tell -- * * Returns the position of the next character to be read/written on this * channel. * * Results: * A nonnegative integer on success, -1 on failure. If failed, use * Tcl_GetErrno() to retrieve the POSIX error code for the error that * occurred. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_WideInt Tcl_Tell( Tcl_Channel chan) /* The channel to return pos for. */ { Channel *chanPtr = (Channel *) chan; /* The real IO channel. */ ChannelState *statePtr = chanPtr->state; /* State info for channel */ int inputBuffered, outputBuffered; /* # bytes held in buffers. */ int result; /* Of calling device driver. */ Tcl_WideInt curPos; /* Position on device. */ if (CheckChannelErrors(statePtr, TCL_WRITABLE | TCL_READABLE) != 0) { return Tcl_LongAsWide(-1); } /* * Disallow tell on dead channels -- channels that have been closed but * not yet been deallocated. Such channels can be found if the exit * handler for channel cleanup has run but the channel is still registered * in an interpreter. */ if (CheckForDeadChannel(NULL, statePtr)) { return Tcl_LongAsWide(-1); } /* * This operation should occur at the top of a channel stack. */ chanPtr = statePtr->topChanPtr; /* * Disallow tell on channels whose type does not have a seek procedure * defined. This means that the channel does not support seeking. */ if (chanPtr->typePtr->seekProc == NULL) { Tcl_SetErrno(EINVAL); return Tcl_LongAsWide(-1); } /* * Compute how much input and output is buffered. If both input and output * is buffered, cannot compute the current position. */ inputBuffered = Tcl_InputBuffered(chan); outputBuffered = Tcl_OutputBuffered(chan); /* * Get the current position in the device and compute the position where * the next character will be read or written. Note that we prefer the * wideSeekProc if that is available and non-NULL... */ curPos = ChanSeek(chanPtr, Tcl_LongAsWide(0), SEEK_CUR, &result); if (curPos == Tcl_LongAsWide(-1)) { Tcl_SetErrno(result); return Tcl_LongAsWide(-1); } if (inputBuffered != 0) { return curPos - inputBuffered; } return curPos + outputBuffered; } /* *--------------------------------------------------------------------------- * * Tcl_TruncateChannel -- * * Truncate a channel to the given length. * * Results: * TCL_OK on success, TCL_ERROR if the operation failed (e.g., is not * supported by the type of channel, or the underlying OS operation * failed in some way). * * Side effects: * Seeks the channel to the current location. Sets errno on OS error. * *--------------------------------------------------------------------------- */ int Tcl_TruncateChannel( Tcl_Channel chan, /* Channel to truncate. */ Tcl_WideInt length) /* Length to truncate it to. */ { Channel *chanPtr = (Channel *) chan; Tcl_DriverTruncateProc *truncateProc = Tcl_ChannelTruncateProc(chanPtr->typePtr); int result; if (truncateProc == NULL) { /* * Feature not supported and it's not emulatable. Pretend it's * returned an EINVAL, a very generic error! */ Tcl_SetErrno(EINVAL); return TCL_ERROR; } if (!GotFlag(chanPtr->state, TCL_WRITABLE)) { /* * We require that the file was opened of writing. Do that check now * so that we only flush if we think we're going to succeed. */ Tcl_SetErrno(EINVAL); return TCL_ERROR; } /* * Seek first to force a total flush of all pending buffers and ditch any * pre-read input data. */ WillWrite(chanPtr); if (WillRead(chanPtr) < 0) { return TCL_ERROR; } /* * We're all flushed to disk now and we also don't have any unfortunate * input baggage around either; can truncate with impunity. */ result = truncateProc(chanPtr->instanceData, length); if (result != 0) { Tcl_SetErrno(result); return TCL_ERROR; } return TCL_OK; } /* *--------------------------------------------------------------------------- * * CheckChannelErrors -- * * See if the channel is in an ready state and can perform the desired * operation. * * Results: * The return value is 0 if the channel is OK, otherwise the return value * is -1 and errno is set to indicate the error. * * Side effects: * May clear the EOF and/or BLOCKED bits if reading from channel. * *--------------------------------------------------------------------------- */ static int CheckChannelErrors( ChannelState *statePtr, /* Channel to check. */ int flags) /* Test if channel supports desired operation: * TCL_READABLE, TCL_WRITABLE. Also indicates * Raw read or write for special close * processing */ { int direction = flags & (TCL_READABLE|TCL_WRITABLE); /* * Check for unreported error. */ if (statePtr->unreportedError != 0) { Tcl_SetErrno(statePtr->unreportedError); statePtr->unreportedError = 0; /* * TIP #219, Tcl Channel Reflection API. * Move a defered error message back into the channel bypass. */ if (statePtr->chanMsg != NULL) { TclDecrRefCount(statePtr->chanMsg); } statePtr->chanMsg = statePtr->unreportedMsg; statePtr->unreportedMsg = NULL; return -1; } /* * Only the raw read and write operations are allowed during close in * order to drain data from stacked channels. */ if (GotFlag(statePtr, CHANNEL_CLOSED) && !(flags & CHANNEL_RAW_MODE)) { Tcl_SetErrno(EACCES); return -1; } /* * Fail if the channel is not opened for desired operation. */ if ((statePtr->flags & direction) == 0) { Tcl_SetErrno(EACCES); return -1; } /* * Fail if the channel is in the middle of a background copy. * * Don't do this tests for raw channels here or else the chaining in the * transformation drivers will fail with 'file busy' error instead of * retrieving and transforming the data to copy. */ if (BUSY_STATE(statePtr, flags) && ((flags & CHANNEL_RAW_MODE) == 0)) { Tcl_SetErrno(EBUSY); return -1; } if (direction == TCL_READABLE) { ResetFlag(statePtr, CHANNEL_NEED_MORE_DATA); } return 0; } /* *---------------------------------------------------------------------- * * Tcl_Eof -- * * Returns 1 if the channel is at EOF, 0 otherwise. * * Results: * 1 or 0, always. * * Side effects: * None. * *---------------------------------------------------------------------- */ int Tcl_Eof( Tcl_Channel chan) /* Does this channel have EOF? */ { ChannelState *statePtr = ((Channel *) chan)->state; /* State of real channel structure. */ return GotFlag(statePtr, CHANNEL_EOF) ? 1 : 0; } /* *---------------------------------------------------------------------- * * Tcl_InputBlocked -- * * Returns 1 if input is blocked on this channel, 0 otherwise. * * Results: * 0 or 1, always. * * Side effects: * None. * *---------------------------------------------------------------------- */ int Tcl_InputBlocked( Tcl_Channel chan) /* Is this channel blocked? */ { ChannelState *statePtr = ((Channel *) chan)->state; /* State of real channel structure. */ return GotFlag(statePtr, CHANNEL_BLOCKED) ? 1 : 0; } /* *---------------------------------------------------------------------- * * Tcl_InputBuffered -- * * Returns the number of bytes of input currently buffered in the common * internal buffer of a channel. * * Results: * The number of input bytes buffered, or zero if the channel is not open * for reading. * * Side effects: * None. * *---------------------------------------------------------------------- */ int Tcl_InputBuffered( Tcl_Channel chan) /* The channel to query. */ { ChannelState *statePtr = ((Channel *) chan)->state; /* State of real channel structure. */ ChannelBuffer *bufPtr; int bytesBuffered; for (bytesBuffered = 0, bufPtr = statePtr->inQueueHead; bufPtr != NULL; bufPtr = bufPtr->nextPtr) { bytesBuffered += BytesLeft(bufPtr); } /* * Don't forget the bytes in the topmost pushback area. */ for (bufPtr = statePtr->topChanPtr->inQueueHead; bufPtr != NULL; bufPtr = bufPtr->nextPtr) { bytesBuffered += BytesLeft(bufPtr); } return bytesBuffered; } /* *---------------------------------------------------------------------- * * Tcl_OutputBuffered -- * * Returns the number of bytes of output currently buffered in the common * internal buffer of a channel. * * Results: * The number of output bytes buffered, or zero if the channel is not open * for writing. * * Side effects: * None. * *---------------------------------------------------------------------- */ int Tcl_OutputBuffered( Tcl_Channel chan) /* The channel to query. */ { ChannelState *statePtr = ((Channel *) chan)->state; /* State of real channel structure. */ ChannelBuffer *bufPtr; int bytesBuffered; for (bytesBuffered = 0, bufPtr = statePtr->outQueueHead; bufPtr != NULL; bufPtr = bufPtr->nextPtr) { bytesBuffered += BytesLeft(bufPtr); } if (statePtr->curOutPtr != NULL) { register ChannelBuffer *curOutPtr = statePtr->curOutPtr; if (IsBufferReady(curOutPtr)) { bytesBuffered += BytesLeft(curOutPtr); } } return bytesBuffered; } /* *---------------------------------------------------------------------- * * Tcl_ChannelBuffered -- * * Returns the number of bytes of input currently buffered in the * internal buffer (push back area) of a channel. * * Results: * The number of input bytes buffered, or zero if the channel is not open * for reading. * * Side effects: * None. * *---------------------------------------------------------------------- */ int Tcl_ChannelBuffered( Tcl_Channel chan) /* The channel to query. */ { Channel *chanPtr = (Channel *) chan; /* Real channel structure. */ ChannelBuffer *bufPtr; int bytesBuffered = 0; for (bufPtr = chanPtr->inQueueHead; bufPtr != NULL; bufPtr = bufPtr->nextPtr) { bytesBuffered += BytesLeft(bufPtr); } return bytesBuffered; } /* *---------------------------------------------------------------------- * * Tcl_SetChannelBufferSize -- * * Sets the size of buffers to allocate to store input or output in the * channel. The size must be between 1 byte and 1 MByte. * * Results: * None. * * Side effects: * Sets the size of buffers subsequently allocated for this channel. * *---------------------------------------------------------------------- */ void Tcl_SetChannelBufferSize( Tcl_Channel chan, /* The channel whose buffer size to set. */ int sz) /* The size to set. */ { ChannelState *statePtr; /* State of real channel structure. */ /* * Clip the buffer size to force it into the [1,1M] range */ if (sz < 1) { sz = 1; } else if (sz > MAX_CHANNEL_BUFFER_SIZE) { sz = MAX_CHANNEL_BUFFER_SIZE; } statePtr = ((Channel *) chan)->state; if (statePtr->bufSize == sz) { return; } statePtr->bufSize = sz; /* * If bufsize changes, need to get rid of old utility buffer. */ if (statePtr->saveInBufPtr != NULL) { RecycleBuffer(statePtr, statePtr->saveInBufPtr, 1); statePtr->saveInBufPtr = NULL; } if ((statePtr->inQueueHead != NULL) && (statePtr->inQueueHead->nextPtr == NULL) && IsBufferEmpty(statePtr->inQueueHead)) { RecycleBuffer(statePtr, statePtr->inQueueHead, 1); statePtr->inQueueHead = NULL; statePtr->inQueueTail = NULL; } } /* *---------------------------------------------------------------------- * * Tcl_GetChannelBufferSize -- * * Retrieves the size of buffers to allocate for this channel. * * Results: * The size. * * Side effects: * None. * *---------------------------------------------------------------------- */ int Tcl_GetChannelBufferSize( Tcl_Channel chan) /* The channel for which to find the buffer * size. */ { ChannelState *statePtr = ((Channel *) chan)->state; /* State of real channel structure. */ return statePtr->bufSize; } /* *---------------------------------------------------------------------- * * Tcl_BadChannelOption -- * * This procedure generates a "bad option" error message in an (optional) * interpreter. It is used by channel drivers when a invalid Set/Get * option is requested. Its purpose is to concatenate the generic options * list to the specific ones and factorize the generic options error * message string. * * Results: * TCL_ERROR. * * Side effects: * An error message is generated in interp's result object to indicate * that a command was invoked with the a bad option. The message has the * form: * bad option "blah": should be one of * <...generic options...>+<...specific options...> * "blah" is the optionName argument and "" is a space * separated list of specific option words. The function takes good care * of inserting minus signs before each option, commas after, and an "or" * before the last option. * *---------------------------------------------------------------------- */ int Tcl_BadChannelOption( Tcl_Interp *interp, /* Current interpreter (can be NULL).*/ const char *optionName, /* 'bad option' name */ const char *optionList) /* Specific options list to append to the * standard generic options. Can be NULL for * generic options only. */ { if (interp != NULL) { const char *genericopt = "blocking buffering buffersize encoding eofchar translation"; const char **argv; int argc, i; Tcl_DString ds; Tcl_Obj *errObj; Tcl_DStringInit(&ds); Tcl_DStringAppend(&ds, genericopt, -1); if (optionList && (*optionList)) { TclDStringAppendLiteral(&ds, " "); Tcl_DStringAppend(&ds, optionList, -1); } if (Tcl_SplitList(interp, Tcl_DStringValue(&ds), &argc, &argv) != TCL_OK) { Tcl_Panic("malformed option list in channel driver"); } Tcl_ResetResult(interp); errObj = Tcl_ObjPrintf("bad option \"%s\": should be one of ", optionName); argc--; for (i = 0; i < argc; i++) { Tcl_AppendPrintfToObj(errObj, "-%s, ", argv[i]); } Tcl_AppendPrintfToObj(errObj, "or -%s", argv[i]); Tcl_SetObjResult(interp, errObj); Tcl_DStringFree(&ds); ckfree(argv); } Tcl_SetErrno(EINVAL); return TCL_ERROR; } /* *---------------------------------------------------------------------- * * Tcl_GetChannelOption -- * * Gets a mode associated with an IO channel. If the optionName arg is * non NULL, retrieves the value of that option. If the optionName arg is * NULL, retrieves a list of alternating option names and values for the * given channel. * * Results: * A standard Tcl result. Also sets the supplied DString to the string * value of the option(s) returned. * * Side effects: * None. * *---------------------------------------------------------------------- */ int Tcl_GetChannelOption( Tcl_Interp *interp, /* For error reporting - can be NULL. */ Tcl_Channel chan, /* Channel on which to get option. */ const char *optionName, /* Option to get. */ Tcl_DString *dsPtr) /* Where to store value(s). */ { size_t len; /* Length of optionName string. */ char optionVal[128]; /* Buffer for sprintf. */ Channel *chanPtr = (Channel *) chan; ChannelState *statePtr = chanPtr->state; /* State info for channel */ int flags; /* * Disallow options on dead channels -- channels that have been closed but * not yet been deallocated. Such channels can be found if the exit * handler for channel cleanup has run but the channel is still registered * in an interpreter. */ if (CheckForDeadChannel(interp, statePtr)) { return TCL_ERROR; } /* * This operation should occur at the top of a channel stack. */ chanPtr = statePtr->topChanPtr; /* * If we are in the middle of a background copy, use the saved flags. */ if (statePtr->csPtrR) { flags = statePtr->csPtrR->readFlags; } else if (statePtr->csPtrW) { flags = statePtr->csPtrW->writeFlags; } else { flags = statePtr->flags; } /* * If the optionName is NULL it means that we want a list of all options * and values. */ if (optionName == NULL) { len = 0; } else { len = strlen(optionName); } if (len == 0 || HaveOpt(2, "-blocking")) { if (len == 0) { Tcl_DStringAppendElement(dsPtr, "-blocking"); } Tcl_DStringAppendElement(dsPtr, (flags & CHANNEL_NONBLOCKING) ? "0" : "1"); if (len > 0) { return TCL_OK; } } if (len == 0 || HaveOpt(7, "-buffering")) { if (len == 0) { Tcl_DStringAppendElement(dsPtr, "-buffering"); } if (flags & CHANNEL_LINEBUFFERED) { Tcl_DStringAppendElement(dsPtr, "line"); } else if (flags & CHANNEL_UNBUFFERED) { Tcl_DStringAppendElement(dsPtr, "none"); } else { Tcl_DStringAppendElement(dsPtr, "full"); } if (len > 0) { return TCL_OK; } } if (len == 0 || HaveOpt(7, "-buffersize")) { if (len == 0) { Tcl_DStringAppendElement(dsPtr, "-buffersize"); } TclFormatInt(optionVal, statePtr->bufSize); Tcl_DStringAppendElement(dsPtr, optionVal); if (len > 0) { return TCL_OK; } } if (len == 0 || HaveOpt(2, "-encoding")) { if (len == 0) { Tcl_DStringAppendElement(dsPtr, "-encoding"); } if (statePtr->encoding == NULL) { Tcl_DStringAppendElement(dsPtr, "binary"); } else { Tcl_DStringAppendElement(dsPtr, Tcl_GetEncodingName(statePtr->encoding)); } if (len > 0) { return TCL_OK; } } if (len == 0 || HaveOpt(2, "-eofchar")) { if (len == 0) { Tcl_DStringAppendElement(dsPtr, "-eofchar"); } if (((flags & (TCL_READABLE|TCL_WRITABLE)) == (TCL_READABLE|TCL_WRITABLE)) && (len == 0)) { Tcl_DStringStartSublist(dsPtr); } if (flags & TCL_READABLE) { if (statePtr->inEofChar == 0) { Tcl_DStringAppendElement(dsPtr, ""); } else { char buf[4]; sprintf(buf, "%c", statePtr->inEofChar); Tcl_DStringAppendElement(dsPtr, buf); } } if (flags & TCL_WRITABLE) { if (statePtr->outEofChar == 0) { Tcl_DStringAppendElement(dsPtr, ""); } else { char buf[4]; sprintf(buf, "%c", statePtr->outEofChar); Tcl_DStringAppendElement(dsPtr, buf); } } if (!(flags & (TCL_READABLE|TCL_WRITABLE))) { /* * Not readable or writable (e.g. server socket) */ Tcl_DStringAppendElement(dsPtr, ""); } if (((flags & (TCL_READABLE|TCL_WRITABLE)) == (TCL_READABLE|TCL_WRITABLE)) && (len == 0)) { Tcl_DStringEndSublist(dsPtr); } if (len > 0) { return TCL_OK; } } if (len == 0 || HaveOpt(1, "-translation")) { if (len == 0) { Tcl_DStringAppendElement(dsPtr, "-translation"); } if (((flags & (TCL_READABLE|TCL_WRITABLE)) == (TCL_READABLE|TCL_WRITABLE)) && (len == 0)) { Tcl_DStringStartSublist(dsPtr); } if (flags & TCL_READABLE) { if (statePtr->inputTranslation == TCL_TRANSLATE_AUTO) { Tcl_DStringAppendElement(dsPtr, "auto"); } else if (statePtr->inputTranslation == TCL_TRANSLATE_CR) { Tcl_DStringAppendElement(dsPtr, "cr"); } else if (statePtr->inputTranslation == TCL_TRANSLATE_CRLF) { Tcl_DStringAppendElement(dsPtr, "crlf"); } else { Tcl_DStringAppendElement(dsPtr, "lf"); } } if (flags & TCL_WRITABLE) { if (statePtr->outputTranslation == TCL_TRANSLATE_AUTO) { Tcl_DStringAppendElement(dsPtr, "auto"); } else if (statePtr->outputTranslation == TCL_TRANSLATE_CR) { Tcl_DStringAppendElement(dsPtr, "cr"); } else if (statePtr->outputTranslation == TCL_TRANSLATE_CRLF) { Tcl_DStringAppendElement(dsPtr, "crlf"); } else { Tcl_DStringAppendElement(dsPtr, "lf"); } } if (!(flags & (TCL_READABLE|TCL_WRITABLE))) { /* * Not readable or writable (e.g. server socket) */ Tcl_DStringAppendElement(dsPtr, "auto"); } if (((flags & (TCL_READABLE|TCL_WRITABLE)) == (TCL_READABLE|TCL_WRITABLE)) && (len == 0)) { Tcl_DStringEndSublist(dsPtr); } if (len > 0) { return TCL_OK; } } if (chanPtr->typePtr->getOptionProc != NULL) { /* * Let the driver specific handle additional options and result code * and message. */ return chanPtr->typePtr->getOptionProc(chanPtr->instanceData, interp, optionName, dsPtr); } else { /* * No driver specific options case. */ if (len == 0) { return TCL_OK; } return Tcl_BadChannelOption(interp, optionName, NULL); } } /* *--------------------------------------------------------------------------- * * Tcl_SetChannelOption -- * * Sets an option on a channel. * * Results: * A standard Tcl result. On error, sets interp's result object if * interp is not NULL. * * Side effects: * May modify an option on a device. * *--------------------------------------------------------------------------- */ int Tcl_SetChannelOption( Tcl_Interp *interp, /* For error reporting - can be NULL. */ Tcl_Channel chan, /* Channel on which to set mode. */ const char *optionName, /* Which option to set? */ const char *newValue) /* New value for option. */ { Channel *chanPtr = (Channel *) chan; /* The real IO channel. */ ChannelState *statePtr = chanPtr->state; /* State info for channel */ size_t len; /* Length of optionName string. */ int argc; const char **argv; /* * If the channel is in the middle of a background copy, fail. */ if (statePtr->csPtrR || statePtr->csPtrW) { if (interp) { Tcl_SetObjResult(interp, Tcl_NewStringObj( "unable to set channel options: background copy in" " progress", -1)); } return TCL_ERROR; } /* * Disallow options on dead channels -- channels that have been closed but * not yet been deallocated. Such channels can be found if the exit * handler for channel cleanup has run but the channel is still registered * in an interpreter. */ if (CheckForDeadChannel(NULL, statePtr)) { return TCL_ERROR; } /* * This operation should occur at the top of a channel stack. */ chanPtr = statePtr->topChanPtr; len = strlen(optionName); if (HaveOpt(2, "-blocking")) { int newMode; if (Tcl_GetBoolean(interp, newValue, &newMode) == TCL_ERROR) { return TCL_ERROR; } if (newMode) { newMode = TCL_MODE_BLOCKING; } else { newMode = TCL_MODE_NONBLOCKING; } return SetBlockMode(interp, chanPtr, newMode); } else if (HaveOpt(7, "-buffering")) { len = strlen(newValue); if ((newValue[0] == 'f') && (strncmp(newValue, "full", len) == 0)) { ResetFlag(statePtr, CHANNEL_UNBUFFERED | CHANNEL_LINEBUFFERED); } else if ((newValue[0] == 'l') && (strncmp(newValue, "line", len) == 0)) { ResetFlag(statePtr, CHANNEL_UNBUFFERED); SetFlag(statePtr, CHANNEL_LINEBUFFERED); } else if ((newValue[0] == 'n') && (strncmp(newValue, "none", len) == 0)) { ResetFlag(statePtr, CHANNEL_LINEBUFFERED); SetFlag(statePtr, CHANNEL_UNBUFFERED); } else if (interp) { Tcl_SetObjResult(interp, Tcl_NewStringObj( "bad value for -buffering: must be one of" " full, line, or none", -1)); return TCL_ERROR; } return TCL_OK; } else if (HaveOpt(7, "-buffersize")) { int newBufferSize; if (Tcl_GetInt(interp, newValue, &newBufferSize) == TCL_ERROR) { return TCL_ERROR; } Tcl_SetChannelBufferSize(chan, newBufferSize); return TCL_OK; } else if (HaveOpt(2, "-encoding")) { Tcl_Encoding encoding; if ((newValue[0] == '\0') || (strcmp(newValue, "binary") == 0)) { encoding = NULL; } else { encoding = Tcl_GetEncoding(interp, newValue); if (encoding == NULL) { return TCL_ERROR; } } /* * When the channel has an escape sequence driven encoding such as * iso2022, the terminated escape sequence must write to the buffer. */ if ((statePtr->encoding != NULL) && !(statePtr->outputEncodingFlags & TCL_ENCODING_START) && (CheckChannelErrors(statePtr, TCL_WRITABLE) == 0)) { statePtr->outputEncodingFlags |= TCL_ENCODING_END; WriteChars(chanPtr, "", 0); } Tcl_FreeEncoding(statePtr->encoding); statePtr->encoding = encoding; statePtr->inputEncodingState = NULL; statePtr->inputEncodingFlags = TCL_ENCODING_START; statePtr->outputEncodingState = NULL; statePtr->outputEncodingFlags = TCL_ENCODING_START; ResetFlag(statePtr, CHANNEL_NEED_MORE_DATA); UpdateInterest(chanPtr); return TCL_OK; } else if (HaveOpt(2, "-eofchar")) { if (Tcl_SplitList(interp, newValue, &argc, &argv) == TCL_ERROR) { return TCL_ERROR; } if (argc == 0) { statePtr->inEofChar = 0; statePtr->outEofChar = 0; } else if (argc == 1 || argc == 2) { int outIndex = (argc - 1); int inValue = (int) argv[0][0]; int outValue = (int) argv[outIndex][0]; if (inValue & 0x80 || outValue & 0x80) { if (interp) { Tcl_SetObjResult(interp, Tcl_NewStringObj( "bad value for -eofchar: must be non-NUL ASCII" " character", -1)); } ckfree(argv); return TCL_ERROR; } if (GotFlag(statePtr, TCL_READABLE)) { statePtr->inEofChar = inValue; } if (GotFlag(statePtr, TCL_WRITABLE)) { statePtr->outEofChar = outValue; } } else { if (interp) { Tcl_SetObjResult(interp, Tcl_NewStringObj( "bad value for -eofchar: should be a list of zero," " one, or two elements", -1)); } ckfree(argv); return TCL_ERROR; } if (argv != NULL) { ckfree(argv); } /* * [Bug 930851] Reset EOF and BLOCKED flags. Changing the character * which signals eof can transform a current eof condition into a 'go * ahead'. Ditto for blocked. */ if (GotFlag(statePtr, CHANNEL_EOF)) { statePtr->inputEncodingFlags |= TCL_ENCODING_START; } ResetFlag(statePtr, CHANNEL_EOF|CHANNEL_STICKY_EOF|CHANNEL_BLOCKED); statePtr->inputEncodingFlags &= ~TCL_ENCODING_END; return TCL_OK; } else if (HaveOpt(1, "-translation")) { const char *readMode, *writeMode; if (Tcl_SplitList(interp, newValue, &argc, &argv) == TCL_ERROR) { return TCL_ERROR; } if (argc == 1) { readMode = GotFlag(statePtr, TCL_READABLE) ? argv[0] : NULL; writeMode = GotFlag(statePtr, TCL_WRITABLE) ? argv[0] : NULL; } else if (argc == 2) { readMode = GotFlag(statePtr, TCL_READABLE) ? argv[0] : NULL; writeMode = GotFlag(statePtr, TCL_WRITABLE) ? argv[1] : NULL; } else { if (interp) { Tcl_SetObjResult(interp, Tcl_NewStringObj( "bad value for -translation: must be a one or two" " element list", -1)); } ckfree(argv); return TCL_ERROR; } if (readMode) { TclEolTranslation translation; if (*readMode == '\0') { translation = statePtr->inputTranslation; } else if (strcmp(readMode, "auto") == 0) { translation = TCL_TRANSLATE_AUTO; } else if (strcmp(readMode, "binary") == 0) { translation = TCL_TRANSLATE_LF; statePtr->inEofChar = 0; Tcl_FreeEncoding(statePtr->encoding); statePtr->encoding = NULL; } else if (strcmp(readMode, "lf") == 0) { translation = TCL_TRANSLATE_LF; } else if (strcmp(readMode, "cr") == 0) { translation = TCL_TRANSLATE_CR; } else if (strcmp(readMode, "crlf") == 0) { translation = TCL_TRANSLATE_CRLF; } else if (strcmp(readMode, "platform") == 0) { translation = TCL_PLATFORM_TRANSLATION; } else { if (interp) { Tcl_SetObjResult(interp, Tcl_NewStringObj( "bad value for -translation: must be one of " "auto, binary, cr, lf, crlf, or platform", -1)); } ckfree(argv); return TCL_ERROR; } /* * Reset the EOL flags since we need to look at any buffered data * to see if the new translation mode allows us to complete the * line. */ if (translation != statePtr->inputTranslation) { statePtr->inputTranslation = translation; ResetFlag(statePtr, INPUT_SAW_CR | CHANNEL_NEED_MORE_DATA); UpdateInterest(chanPtr); } } if (writeMode) { if (*writeMode == '\0') { /* Do nothing. */ } else if (strcmp(writeMode, "auto") == 0) { /* * This is a hack to get TCP sockets to produce output in CRLF * mode if they are being set into AUTO mode. A better * solution for achieving this effect will be coded later. */ if (strcmp(Tcl_ChannelName(chanPtr->typePtr), "tcp") == 0) { statePtr->outputTranslation = TCL_TRANSLATE_CRLF; } else { statePtr->outputTranslation = TCL_PLATFORM_TRANSLATION; } } else if (strcmp(writeMode, "binary") == 0) { statePtr->outEofChar = 0; statePtr->outputTranslation = TCL_TRANSLATE_LF; Tcl_FreeEncoding(statePtr->encoding); statePtr->encoding = NULL; } else if (strcmp(writeMode, "lf") == 0) { statePtr->outputTranslation = TCL_TRANSLATE_LF; } else if (strcmp(writeMode, "cr") == 0) { statePtr->outputTranslation = TCL_TRANSLATE_CR; } else if (strcmp(writeMode, "crlf") == 0) { statePtr->outputTranslation = TCL_TRANSLATE_CRLF; } else if (strcmp(writeMode, "platform") == 0) { statePtr->outputTranslation = TCL_PLATFORM_TRANSLATION; } else { if (interp) { Tcl_SetObjResult(interp, Tcl_NewStringObj( "bad value for -translation: must be one of " "auto, binary, cr, lf, crlf, or platform", -1)); } ckfree(argv); return TCL_ERROR; } } ckfree(argv); return TCL_OK; } else if (chanPtr->typePtr->setOptionProc != NULL) { return chanPtr->typePtr->setOptionProc(chanPtr->instanceData, interp, optionName, newValue); } else { return Tcl_BadChannelOption(interp, optionName, NULL); } return TCL_OK; } /* *---------------------------------------------------------------------- * * CleanupChannelHandlers -- * * Removes channel handlers that refer to the supplied interpreter, so * that if the actual channel is not closed now, these handlers will not * run on subsequent events on the channel. This would be erroneous, * because the interpreter no longer has a reference to this channel. * * Results: * None. * * Side effects: * Removes channel handlers. * *---------------------------------------------------------------------- */ static void CleanupChannelHandlers( Tcl_Interp *interp, Channel *chanPtr) { ChannelState *statePtr = chanPtr->state; /* State info for channel */ EventScriptRecord *sPtr, *prevPtr, *nextPtr; /* * Remove fileevent records on this channel that refer to the given * interpreter. */ for (sPtr = statePtr->scriptRecordPtr, prevPtr = NULL; sPtr != NULL; sPtr = nextPtr) { nextPtr = sPtr->nextPtr; if (sPtr->interp == interp) { if (prevPtr == NULL) { statePtr->scriptRecordPtr = nextPtr; } else { prevPtr->nextPtr = nextPtr; } Tcl_DeleteChannelHandler((Tcl_Channel) chanPtr, TclChannelEventScriptInvoker, sPtr); TclDecrRefCount(sPtr->scriptPtr); ckfree(sPtr); } else { prevPtr = sPtr; } } } /* *---------------------------------------------------------------------- * * Tcl_NotifyChannel -- * * This procedure is called by a channel driver when a driver detects an * event on a channel. This procedure is responsible for actually * handling the event by invoking any channel handler callbacks. * * Results: * None. * * Side effects: * Whatever the channel handler callback procedure does. * *---------------------------------------------------------------------- */ void Tcl_NotifyChannel( Tcl_Channel channel, /* Channel that detected an event. */ int mask) /* OR'ed combination of TCL_READABLE, * TCL_WRITABLE, or TCL_EXCEPTION: indicates * which events were detected. */ { Channel *chanPtr = (Channel *) channel; ChannelState *statePtr = chanPtr->state; /* State info for channel */ ChannelHandler *chPtr; ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); NextChannelHandler nh; Channel *upChanPtr; const Tcl_ChannelType *upTypePtr; /* * In contrast to the other API functions this procedure walks towards the * top of a stack and not down from it. * * The channel calling this procedure is the one who generated the event, * and thus does not take part in handling it. IOW, its HandlerProc is not * called, instead we begin with the channel above it. * * This behaviour also allows the transformation channels to generate * their own events and pass them upward. */ while (mask && (chanPtr->upChanPtr != NULL)) { Tcl_DriverHandlerProc *upHandlerProc; upChanPtr = chanPtr->upChanPtr; upTypePtr = upChanPtr->typePtr; upHandlerProc = Tcl_ChannelHandlerProc(upTypePtr); if (upHandlerProc != NULL) { mask = upHandlerProc(upChanPtr->instanceData, mask); } /* * ELSE: Ignore transformations which are unable to handle the event * coming from below. Assume that they don't change the mask and pass * it on. */ chanPtr = upChanPtr; } channel = (Tcl_Channel) chanPtr; /* * Here we have either reached the top of the stack or the mask is empty. * We break out of the procedure if it is the latter. */ if (!mask) { return; } /* * We are now above the topmost channel in a stack and have events left. * Now call the channel handlers as usual. * * Preserve the channel struct in case the script closes it. */ TclChannelPreserve((Tcl_Channel)channel); Tcl_Preserve(statePtr); /* * If we are flushing in the background, be sure to call FlushChannel for * writable events. Note that we have to discard the writable event so we * don't call any write handlers before the flush is complete. */ if (GotFlag(statePtr, BG_FLUSH_SCHEDULED) && (mask & TCL_WRITABLE)) { if (0 == FlushChannel(NULL, chanPtr, 1)) { mask &= ~TCL_WRITABLE; } } /* * Add this invocation to the list of recursive invocations of * Tcl_NotifyChannel. */ nh.nextHandlerPtr = NULL; nh.nestedHandlerPtr = tsdPtr->nestedHandlerPtr; tsdPtr->nestedHandlerPtr = &nh; for (chPtr = statePtr->chPtr; chPtr != NULL; ) { /* * If this channel handler is interested in any of the events that * have occurred on the channel, invoke its procedure. */ if ((chPtr->mask & mask) != 0) { nh.nextHandlerPtr = chPtr->nextPtr; chPtr->proc(chPtr->clientData, chPtr->mask & mask); chPtr = nh.nextHandlerPtr; } else { chPtr = chPtr->nextPtr; } } /* * Update the notifier interest, since it may have changed after invoking * event handlers. Skip that if the channel was deleted in the call to the * channel handler. */ if (chanPtr->typePtr != NULL) { /* * TODO: This call may not be needed. If a handler induced a * change in interest, that handler should have made its own * UpdateInterest() call, one would think. */ UpdateInterest(chanPtr); } Tcl_Release(statePtr); TclChannelRelease(channel); tsdPtr->nestedHandlerPtr = nh.nestedHandlerPtr; } /* *---------------------------------------------------------------------- * * UpdateInterest -- * * Arrange for the notifier to call us back at appropriate times based on * the current state of the channel. * * Results: * None. * * Side effects: * May schedule a timer or driver handler. * *---------------------------------------------------------------------- */ static void UpdateInterest( Channel *chanPtr) /* Channel to update. */ { ChannelState *statePtr = chanPtr->state; /* State info for channel */ int mask = statePtr->interestMask; if (chanPtr->typePtr == NULL) { /* Do not update interest on a closed channel */ return; } /* * If there are flushed buffers waiting to be written, then we need to * watch for the channel to become writable. */ if (GotFlag(statePtr, BG_FLUSH_SCHEDULED)) { mask |= TCL_WRITABLE; } /* * If there is data in the input queue, and we aren't waiting for more * data, then we need to schedule a timer so we don't block in the * notifier. Also, cancel the read interest so we don't get duplicate * events. */ if (mask & TCL_READABLE) { if (!GotFlag(statePtr, CHANNEL_NEED_MORE_DATA) && (statePtr->inQueueHead != NULL) && IsBufferReady(statePtr->inQueueHead)) { mask &= ~TCL_READABLE; /* * Andreas Kupries, April 11, 2003 * * Some operating systems (Solaris 2.6 and higher (but not Solaris * 2.5, go figure)) generate READABLE and EXCEPTION events when * select()'ing [*] on a plain file, even if EOF was not yet * reached. This is a problem in the following situation: * * - An extension asks to get both READABLE and EXCEPTION events. * - It reads data into a buffer smaller than the buffer used by * Tcl itself. * - It does not process all events in the event queue, but only * one, at least in some situations. * * In that case we can get into a situation where * * - Tcl drops READABLE here, because it has data in its own * buffers waiting to be read by the extension. * - A READABLE event is syntesized via timer. * - The OS still reports the EXCEPTION condition on the file. * - And the extension gets the EXCPTION event first, and handles * this as EOF. * * End result ==> Premature end of reading from a file. * * The concrete example is 'Expect', and its [expect] command * (and at the C-level, deep in the bowels of Expect, * 'exp_get_next_event'. See marker 'SunOS' for commentary in * that function too). * * [*] As the Tcl notifier does. See also for marker 'SunOS' in * file 'exp_event.c' of Expect. * * Our solution here is to drop the interest in the EXCEPTION * events too. This compiles on all platforms, and also passes the * testsuite on all of them. */ mask &= ~TCL_EXCEPTION; if (!statePtr->timer) { statePtr->timer = Tcl_CreateTimerHandler(SYNTHETIC_EVENT_TIME, ChannelTimerProc, chanPtr); } } } ChanWatch(chanPtr, mask); } /* *---------------------------------------------------------------------- * * ChannelTimerProc -- * * Timer handler scheduled by UpdateInterest to monitor the channel * buffers until they are empty. * * Results: * None. * * Side effects: * May invoke channel handlers. * *---------------------------------------------------------------------- */ static void ChannelTimerProc( ClientData clientData) { Channel *chanPtr = clientData; ChannelState *statePtr = chanPtr->state; /* State info for channel */ if (!GotFlag(statePtr, CHANNEL_NEED_MORE_DATA) && (statePtr->interestMask & TCL_READABLE) && (statePtr->inQueueHead != NULL) && IsBufferReady(statePtr->inQueueHead)) { /* * Restart the timer in case a channel handler reenters the event loop * before UpdateInterest gets called by Tcl_NotifyChannel. */ statePtr->timer = Tcl_CreateTimerHandler(SYNTHETIC_EVENT_TIME, ChannelTimerProc,chanPtr); Tcl_Preserve(statePtr); Tcl_NotifyChannel((Tcl_Channel) chanPtr, TCL_READABLE); Tcl_Release(statePtr); } else { statePtr->timer = NULL; UpdateInterest(chanPtr); } } /* *---------------------------------------------------------------------- * * Tcl_CreateChannelHandler -- * * Arrange for a given procedure to be invoked whenever the channel * indicated by the chanPtr arg becomes readable or writable. * * Results: * None. * * Side effects: * From now on, whenever the I/O channel given by chanPtr becomes ready * in the way indicated by mask, proc will be invoked. See the manual * entry for details on the calling sequence to proc. If there is already * an event handler for chan, proc and clientData, then the mask will be * updated. * *---------------------------------------------------------------------- */ void Tcl_CreateChannelHandler( Tcl_Channel chan, /* The channel to create the handler for. */ int mask, /* OR'ed combination of TCL_READABLE, * TCL_WRITABLE, and TCL_EXCEPTION: indicates * conditions under which proc should be * called. Use 0 to disable a registered * handler. */ Tcl_ChannelProc *proc, /* Procedure to call for each selected * event. */ ClientData clientData) /* Arbitrary data to pass to proc. */ { ChannelHandler *chPtr; Channel *chanPtr = (Channel *) chan; ChannelState *statePtr = chanPtr->state; /* State info for channel */ /* * Check whether this channel handler is not already registered. If it is * not, create a new record, else reuse existing record (smash current * values). */ for (chPtr = statePtr->chPtr; chPtr != NULL; chPtr = chPtr->nextPtr) { if ((chPtr->chanPtr == chanPtr) && (chPtr->proc == proc) && (chPtr->clientData == clientData)) { break; } } if (chPtr == NULL) { chPtr = ckalloc(sizeof(ChannelHandler)); chPtr->mask = 0; chPtr->proc = proc; chPtr->clientData = clientData; chPtr->chanPtr = chanPtr; chPtr->nextPtr = statePtr->chPtr; statePtr->chPtr = chPtr; } /* * The remainder of the initialization below is done regardless of whether * or not this is a new record or a modification of an old one. */ chPtr->mask = mask; /* * Recompute the interest mask for the channel - this call may actually be * disabling an existing handler. */ statePtr->interestMask = 0; for (chPtr = statePtr->chPtr; chPtr != NULL; chPtr = chPtr->nextPtr) { statePtr->interestMask |= chPtr->mask; } UpdateInterest(statePtr->topChanPtr); } /* *---------------------------------------------------------------------- * * Tcl_DeleteChannelHandler -- * * Cancel a previously arranged callback arrangement for an IO channel. * * Results: * None. * * Side effects: * If a callback was previously registered for this chan, proc and * clientData, it is removed and the callback will no longer be called * when the channel becomes ready for IO. * *---------------------------------------------------------------------- */ void Tcl_DeleteChannelHandler( Tcl_Channel chan, /* The channel for which to remove the * callback. */ Tcl_ChannelProc *proc, /* The procedure in the callback to delete. */ ClientData clientData) /* The client data in the callback to * delete. */ { ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); ChannelHandler *chPtr, *prevChPtr; Channel *chanPtr = (Channel *) chan; ChannelState *statePtr = chanPtr->state; /* State info for channel */ NextChannelHandler *nhPtr; /* * Find the entry and the previous one in the list. */ for (prevChPtr = NULL, chPtr = statePtr->chPtr; chPtr != NULL; chPtr = chPtr->nextPtr) { if ((chPtr->chanPtr == chanPtr) && (chPtr->clientData == clientData) && (chPtr->proc == proc)) { break; } prevChPtr = chPtr; } /* * If not found, return without doing anything. */ if (chPtr == NULL) { return; } /* * If Tcl_NotifyChannel is about to process this handler, tell it to * process the next one instead - we are going to delete *this* one. */ for (nhPtr = tsdPtr->nestedHandlerPtr; nhPtr != NULL; nhPtr = nhPtr->nestedHandlerPtr) { if (nhPtr->nextHandlerPtr == chPtr) { nhPtr->nextHandlerPtr = chPtr->nextPtr; } } /* * Splice it out of the list of channel handlers. */ if (prevChPtr == NULL) { statePtr->chPtr = chPtr->nextPtr; } else { prevChPtr->nextPtr = chPtr->nextPtr; } ckfree(chPtr); /* * Recompute the interest list for the channel, so that infinite loops * will not result if Tcl_DeleteChannelHandler is called inside an event. */ statePtr->interestMask = 0; for (chPtr = statePtr->chPtr; chPtr != NULL; chPtr = chPtr->nextPtr) { statePtr->interestMask |= chPtr->mask; } UpdateInterest(statePtr->topChanPtr); } /* *---------------------------------------------------------------------- * * DeleteScriptRecord -- * * Delete a script record for this combination of channel, interp and * mask. * * Results: * None. * * Side effects: * Deletes a script record and cancels a channel event handler. * *---------------------------------------------------------------------- */ static void DeleteScriptRecord( Tcl_Interp *interp, /* Interpreter in which script was to be * executed. */ Channel *chanPtr, /* The channel for which to delete the script * record (if any). */ int mask) /* Events in mask must exactly match mask of * script to delete. */ { ChannelState *statePtr = chanPtr->state; /* State info for channel */ EventScriptRecord *esPtr, *prevEsPtr; for (esPtr = statePtr->scriptRecordPtr, prevEsPtr = NULL; esPtr != NULL; prevEsPtr = esPtr, esPtr = esPtr->nextPtr) { if ((esPtr->interp == interp) && (esPtr->mask == mask)) { if (esPtr == statePtr->scriptRecordPtr) { statePtr->scriptRecordPtr = esPtr->nextPtr; } else { CLANG_ASSERT(prevEsPtr); prevEsPtr->nextPtr = esPtr->nextPtr; } Tcl_DeleteChannelHandler((Tcl_Channel) chanPtr, TclChannelEventScriptInvoker, esPtr); TclDecrRefCount(esPtr->scriptPtr); ckfree(esPtr); break; } } } /* *---------------------------------------------------------------------- * * CreateScriptRecord -- * * Creates a record to store a script to be executed when a specific * event fires on a specific channel. * * Results: * None. * * Side effects: * Causes the script to be stored for later execution. * *---------------------------------------------------------------------- */ static void CreateScriptRecord( Tcl_Interp *interp, /* Interpreter in which to execute the stored * script. */ Channel *chanPtr, /* Channel for which script is to be stored */ int mask, /* Set of events for which script will be * invoked. */ Tcl_Obj *scriptPtr) /* Pointer to script object. */ { ChannelState *statePtr = chanPtr->state; /* State info for channel */ EventScriptRecord *esPtr; int makeCH; for (esPtr=statePtr->scriptRecordPtr; esPtr!=NULL; esPtr=esPtr->nextPtr) { if ((esPtr->interp == interp) && (esPtr->mask == mask)) { TclDecrRefCount(esPtr->scriptPtr); esPtr->scriptPtr = NULL; break; } } makeCH = (esPtr == NULL); if (makeCH) { esPtr = ckalloc(sizeof(EventScriptRecord)); } /* * Initialize the structure before calling Tcl_CreateChannelHandler, * because a reflected channel calling 'chan postevent' aka * 'Tcl_NotifyChannel' in its 'watch'Proc will invoke * 'TclChannelEventScriptInvoker' immediately, and we do not wish it to * see uninitialized memory and crash. See [Bug 2918110]. */ esPtr->chanPtr = chanPtr; esPtr->interp = interp; esPtr->mask = mask; Tcl_IncrRefCount(scriptPtr); esPtr->scriptPtr = scriptPtr; if (makeCH) { esPtr->nextPtr = statePtr->scriptRecordPtr; statePtr->scriptRecordPtr = esPtr; Tcl_CreateChannelHandler((Tcl_Channel) chanPtr, mask, TclChannelEventScriptInvoker, esPtr); } } /* *---------------------------------------------------------------------- * * TclChannelEventScriptInvoker -- * * Invokes a script scheduled by "fileevent" for when the channel becomes * ready for IO. This function is invoked by the channel handler which * was created by the Tcl "fileevent" command. * * Results: * None. * * Side effects: * Whatever the script does. * *---------------------------------------------------------------------- */ void TclChannelEventScriptInvoker( ClientData clientData, /* The script+interp record. */ int mask) /* Not used. */ { Tcl_Interp *interp; /* Interpreter in which to eval the script. */ Channel *chanPtr; /* The channel for which this handler is * registered. */ EventScriptRecord *esPtr; /* The event script + interpreter to eval it * in. */ int result; /* Result of call to eval script. */ esPtr = clientData; chanPtr = esPtr->chanPtr; mask = esPtr->mask; interp = esPtr->interp; /* * We must preserve the interpreter so we can report errors on it later. * Note that we do not need to preserve the channel because that is done * by Tcl_NotifyChannel before calling channel handlers. */ Tcl_Preserve(interp); TclChannelPreserve((Tcl_Channel)chanPtr); result = Tcl_EvalObjEx(interp, esPtr->scriptPtr, TCL_EVAL_GLOBAL); /* * On error, cause a background error and remove the channel handler and * the script record. * * NOTE: Must delete channel handler before causing the background error * because the background error may want to reinstall the handler. */ if (result != TCL_OK) { if (chanPtr->typePtr != NULL) { DeleteScriptRecord(interp, chanPtr, mask); } Tcl_BackgroundException(interp, result); } TclChannelRelease((Tcl_Channel)chanPtr); Tcl_Release(interp); } /* *---------------------------------------------------------------------- * * Tcl_FileEventObjCmd -- * * This procedure implements the "fileevent" Tcl command. See the user * documentation for details on what it does. This command is based on * the Tk command "fileevent" which in turn is based on work contributed * by Mark Diekhans. * * Results: * A standard Tcl result. * * Side effects: * May create a channel handler for the specified channel. * *---------------------------------------------------------------------- */ /* ARGSUSED */ int Tcl_FileEventObjCmd( ClientData clientData, /* Not used. */ Tcl_Interp *interp, /* Interpreter in which the channel for which * to create the handler is found. */ int objc, /* Number of arguments. */ Tcl_Obj *const objv[]) /* Argument objects. */ { Channel *chanPtr; /* The channel to create the handler for. */ ChannelState *statePtr; /* State info for channel */ Tcl_Channel chan; /* The opaque type for the channel. */ const char *chanName; int modeIndex; /* Index of mode argument. */ int mask; static const char *const modeOptions[] = {"readable", "writable", NULL}; static const int maskArray[] = {TCL_READABLE, TCL_WRITABLE}; if ((objc != 3) && (objc != 4)) { Tcl_WrongNumArgs(interp, 1, objv, "channelId event ?script?"); return TCL_ERROR; } if (Tcl_GetIndexFromObj(interp, objv[2], modeOptions, "event name", 0, &modeIndex) != TCL_OK) { return TCL_ERROR; } mask = maskArray[modeIndex]; chanName = TclGetString(objv[1]); chan = Tcl_GetChannel(interp, chanName, NULL); if (chan == NULL) { return TCL_ERROR; } chanPtr = (Channel *) chan; statePtr = chanPtr->state; if ((statePtr->flags & mask) == 0) { Tcl_SetObjResult(interp, Tcl_ObjPrintf("channel is not %s", (mask == TCL_READABLE) ? "readable" : "writable")); return TCL_ERROR; } /* * If we are supposed to return the script, do so. */ if (objc == 3) { EventScriptRecord *esPtr; for (esPtr = statePtr->scriptRecordPtr; esPtr != NULL; esPtr = esPtr->nextPtr) { if ((esPtr->interp == interp) && (esPtr->mask == mask)) { Tcl_SetObjResult(interp, esPtr->scriptPtr); break; } } return TCL_OK; } /* * If we are supposed to delete a stored script, do so. */ if (*(TclGetString(objv[3])) == '\0') { DeleteScriptRecord(interp, chanPtr, mask); return TCL_OK; } /* * Make the script record that will link between the event and the script * to invoke. This also creates a channel event handler which will * evaluate the script in the supplied interpreter. */ CreateScriptRecord(interp, chanPtr, mask, objv[3]); return TCL_OK; } /* *---------------------------------------------------------------------- * * ZeroTransferTimerProc -- * * Timer handler scheduled by TclCopyChannel so that -command is * called asynchronously even when -size is 0. * * Results: * None. * * Side effects: * Calls CopyData for -command invocation. * *---------------------------------------------------------------------- */ static void ZeroTransferTimerProc( ClientData clientData) { /* calling CopyData with mask==0 still implies immediate invocation of the * -command callback, and completion of the fcopy. */ CopyData(clientData, 0); } /* *---------------------------------------------------------------------- * * TclCopyChannel -- * * This routine copies data from one channel to another, either * synchronously or asynchronously. If a command script is supplied, the * operation runs in the background. The script is invoked when the copy * completes. Otherwise the function waits until the copy is completed * before returning. * * Results: * A standard Tcl result. * * Side effects: * May schedule a background copy operation that causes both channels to * be marked busy. * *---------------------------------------------------------------------- */ int TclCopyChannelOld( Tcl_Interp *interp, /* Current interpreter. */ Tcl_Channel inChan, /* Channel to read from. */ Tcl_Channel outChan, /* Channel to write to. */ int toRead, /* Amount of data to copy, or -1 for all. */ Tcl_Obj *cmdPtr) /* Pointer to script to execute or NULL. */ { return TclCopyChannel(interp, inChan, outChan, (Tcl_WideInt) toRead, cmdPtr); } int TclCopyChannel( Tcl_Interp *interp, /* Current interpreter. */ Tcl_Channel inChan, /* Channel to read from. */ Tcl_Channel outChan, /* Channel to write to. */ Tcl_WideInt toRead, /* Amount of data to copy, or -1 for all. */ Tcl_Obj *cmdPtr) /* Pointer to script to execute or NULL. */ { Channel *inPtr = (Channel *) inChan; Channel *outPtr = (Channel *) outChan; ChannelState *inStatePtr, *outStatePtr; int readFlags, writeFlags; CopyState *csPtr; int nonBlocking = (cmdPtr) ? CHANNEL_NONBLOCKING : 0; int moveBytes; inStatePtr = inPtr->state; outStatePtr = outPtr->state; if (BUSY_STATE(inStatePtr, TCL_READABLE)) { if (interp) { Tcl_SetObjResult(interp, Tcl_ObjPrintf( "channel \"%s\" is busy", Tcl_GetChannelName(inChan))); } return TCL_ERROR; } if (BUSY_STATE(outStatePtr, TCL_WRITABLE)) { if (interp) { Tcl_SetObjResult(interp, Tcl_ObjPrintf( "channel \"%s\" is busy", Tcl_GetChannelName(outChan))); } return TCL_ERROR; } readFlags = inStatePtr->flags; writeFlags = outStatePtr->flags; /* * Set up the blocking mode appropriately. Background copies need * non-blocking channels. Foreground copies need blocking channels. If * there is an error, restore the old blocking mode. */ if (nonBlocking != (readFlags & CHANNEL_NONBLOCKING)) { if (SetBlockMode(interp, inPtr, nonBlocking ? TCL_MODE_NONBLOCKING : TCL_MODE_BLOCKING) != TCL_OK) { return TCL_ERROR; } } if ((inPtr!=outPtr) && (nonBlocking!=(writeFlags&CHANNEL_NONBLOCKING)) && (SetBlockMode(NULL, outPtr, nonBlocking ? TCL_MODE_NONBLOCKING : TCL_MODE_BLOCKING) != TCL_OK) && (nonBlocking != (readFlags & CHANNEL_NONBLOCKING))) { SetBlockMode(NULL, inPtr, (readFlags & CHANNEL_NONBLOCKING) ? TCL_MODE_NONBLOCKING : TCL_MODE_BLOCKING); return TCL_ERROR; } /* * Make sure the output side is unbuffered. */ outStatePtr->flags = (outStatePtr->flags & ~CHANNEL_LINEBUFFERED) | CHANNEL_UNBUFFERED; /* * Test for conditions where we know we can just move bytes from input * channel to output channel with no transformation or even examination * of the bytes themselves. */ moveBytes = inStatePtr->inEofChar == '\0' /* No eofChar to stop input */ && inStatePtr->inputTranslation == TCL_TRANSLATE_LF && outStatePtr->outputTranslation == TCL_TRANSLATE_LF && inStatePtr->encoding == outStatePtr->encoding; /* * Allocate a new CopyState to maintain info about the current copy in * progress. This structure will be deallocated when the copy is * completed. */ csPtr = ckalloc(sizeof(CopyState) + !moveBytes * inStatePtr->bufSize); csPtr->bufSize = !moveBytes * inStatePtr->bufSize; csPtr->readPtr = inPtr; csPtr->writePtr = outPtr; csPtr->readFlags = readFlags; csPtr->writeFlags = writeFlags; csPtr->toRead = toRead; csPtr->total = (Tcl_WideInt) 0; csPtr->interp = interp; if (cmdPtr) { Tcl_IncrRefCount(cmdPtr); } csPtr->cmdPtr = cmdPtr; inStatePtr->csPtrR = csPtr; outStatePtr->csPtrW = csPtr; if (moveBytes) { return MoveBytes(csPtr); } /* * Special handling of -size 0 async transfers, so that the -command is * still called asynchronously. */ if ((nonBlocking == CHANNEL_NONBLOCKING) && (toRead == 0)) { Tcl_CreateTimerHandler(0, ZeroTransferTimerProc, csPtr); return 0; } /* * Start copying data between the channels. */ return CopyData(csPtr, 0); } /* *---------------------------------------------------------------------- * * CopyData -- * * This function implements the lowest level of the copying mechanism for * TclCopyChannel. * * Results: * Returns TCL_OK on success, else TCL_ERROR. * * Side effects: * Moves data between channels, may create channel handlers. * *---------------------------------------------------------------------- */ static void MBCallback( CopyState *csPtr, Tcl_Obj *errObj) { Tcl_Obj *cmdPtr = Tcl_DuplicateObj(csPtr->cmdPtr); Tcl_WideInt total = csPtr->total; Tcl_Interp *interp = csPtr->interp; int code; Tcl_IncrRefCount(cmdPtr); StopCopy(csPtr); /* TODO: What if cmdPtr is not a list?! */ Tcl_ListObjAppendElement(NULL, cmdPtr, Tcl_NewWideIntObj(total)); if (errObj) { Tcl_ListObjAppendElement(NULL, cmdPtr, errObj); } Tcl_Preserve(interp); code = Tcl_EvalObjEx(interp, cmdPtr, TCL_EVAL_GLOBAL); if (code != TCL_OK) { Tcl_BackgroundException(interp, code); } Tcl_Release(interp); TclDecrRefCount(cmdPtr); } static void MBError( CopyState *csPtr, int mask, int errorCode) { Tcl_Channel inChan = (Tcl_Channel) csPtr->readPtr; Tcl_Channel outChan = (Tcl_Channel) csPtr->writePtr; Tcl_Obj *errObj; Tcl_SetErrno(errorCode); errObj = Tcl_ObjPrintf( "error %sing \"%s\": %s", (mask & TCL_READABLE) ? "read" : "writ", Tcl_GetChannelName((mask & TCL_READABLE) ? inChan : outChan), Tcl_PosixError(csPtr->interp)); if (csPtr->cmdPtr) { MBCallback(csPtr, errObj); } else { Tcl_SetObjResult(csPtr->interp, errObj); StopCopy(csPtr); } } static void MBEvent( ClientData clientData, int mask) { CopyState *csPtr = (CopyState *) clientData; Tcl_Channel inChan = (Tcl_Channel) csPtr->readPtr; Tcl_Channel outChan = (Tcl_Channel) csPtr->writePtr; ChannelState *inStatePtr = csPtr->readPtr->state; if (mask & TCL_WRITABLE) { Tcl_DeleteChannelHandler(inChan, MBEvent, csPtr); Tcl_DeleteChannelHandler(outChan, MBEvent, csPtr); switch (MBWrite(csPtr)) { case TCL_OK: MBCallback(csPtr, NULL); break; case TCL_CONTINUE: Tcl_CreateChannelHandler(inChan, TCL_READABLE, MBEvent, csPtr); break; } } else if (mask & TCL_READABLE) { if (TCL_OK == MBRead(csPtr)) { /* When at least one full buffer is present, stop reading. */ if (IsBufferFull(inStatePtr->inQueueHead) || !Tcl_InputBlocked(inChan)) { Tcl_DeleteChannelHandler(inChan, MBEvent, csPtr); } /* Successful read -- set up to write the bytes we read */ Tcl_CreateChannelHandler(outChan, TCL_WRITABLE, MBEvent, csPtr); } } } static int MBRead( CopyState *csPtr) { ChannelState *inStatePtr = csPtr->readPtr->state; ChannelBuffer *bufPtr = inStatePtr->inQueueHead; int code; if (bufPtr && BytesLeft(bufPtr) > 0) { return TCL_OK; } code = GetInput(inStatePtr->topChanPtr); if (code == 0 || GotFlag(inStatePtr, CHANNEL_BLOCKED)) { return TCL_OK; } else { MBError(csPtr, TCL_READABLE, code); return TCL_ERROR; } } static int MBWrite( CopyState *csPtr) { ChannelState *inStatePtr = csPtr->readPtr->state; ChannelState *outStatePtr = csPtr->writePtr->state; ChannelBuffer *bufPtr = inStatePtr->inQueueHead; ChannelBuffer *tail = NULL; int code; Tcl_WideInt inBytes = 0; /* Count up number of bytes waiting in the input queue */ while (bufPtr) { inBytes += BytesLeft(bufPtr); tail = bufPtr; if (csPtr->toRead != -1 && csPtr->toRead < inBytes) { /* Queue has enough bytes to complete the copy */ break; } bufPtr = bufPtr->nextPtr; } if (bufPtr) { /* Split the overflowing buffer in two */ int extra = (int) (inBytes - csPtr->toRead); /* Note that going with int for extra assumes that inBytes is not too * much over toRead to require a wide itself. If that gets violated * then the calculations involving extra must be made wide too. * * Noted with Win32/MSVC debug build treating the warning (possible of * data in __int64 to int conversion) as error. */ bufPtr = AllocChannelBuffer(extra); tail->nextAdded -= extra; memcpy(InsertPoint(bufPtr), InsertPoint(tail), extra); bufPtr->nextAdded += extra; bufPtr->nextPtr = tail->nextPtr; tail->nextPtr = NULL; inBytes = csPtr->toRead; } /* Update the byte counts */ if (csPtr->toRead != -1) { csPtr->toRead -= inBytes; } csPtr->total += inBytes; /* Move buffers from input to output channels */ if (outStatePtr->outQueueTail) { outStatePtr->outQueueTail->nextPtr = inStatePtr->inQueueHead; } else { outStatePtr->outQueueHead = inStatePtr->inQueueHead; } outStatePtr->outQueueTail = tail; inStatePtr->inQueueHead = bufPtr; if (inStatePtr->inQueueTail == tail) { inStatePtr->inQueueTail = bufPtr; } if (bufPtr == NULL) { inStatePtr->inQueueTail = NULL; } code = FlushChannel(csPtr->interp, outStatePtr->topChanPtr, 0); if (code) { MBError(csPtr, TCL_WRITABLE, code); return TCL_ERROR; } if (csPtr->toRead == 0 || GotFlag(inStatePtr, CHANNEL_EOF)) { return TCL_OK; } return TCL_CONTINUE; } static int MoveBytes( CopyState *csPtr) /* State of copy operation. */ { ChannelState *outStatePtr = csPtr->writePtr->state; ChannelBuffer *bufPtr = outStatePtr->curOutPtr; int errorCode; if (bufPtr && BytesLeft(bufPtr)) { /* If we start with unflushed bytes in the destination * channel, flush them out of the way first. */ errorCode = FlushChannel(csPtr->interp, outStatePtr->topChanPtr, 0); if (errorCode != 0) { MBError(csPtr, TCL_WRITABLE, errorCode); return TCL_ERROR; } } if (csPtr->cmdPtr) { Tcl_Channel inChan = (Tcl_Channel) csPtr->readPtr; Tcl_CreateChannelHandler(inChan, TCL_READABLE, MBEvent, csPtr); return TCL_OK; } while (1) { int code; if (TCL_ERROR == MBRead(csPtr)) { return TCL_ERROR; } code = MBWrite(csPtr); if (code == TCL_OK) { Tcl_SetObjResult(csPtr->interp, Tcl_NewWideIntObj(csPtr->total)); StopCopy(csPtr); return TCL_OK; } if (code == TCL_ERROR) { return TCL_ERROR; } /* code == TCL_CONTINUE --> continue the loop */ } return TCL_OK; /* Silence compiler warnings */ } static int CopyData( CopyState *csPtr, /* State of copy operation. */ int mask) /* Current channel event flags. */ { Tcl_Interp *interp; Tcl_Obj *cmdPtr, *errObj = NULL, *bufObj = NULL, *msg = NULL; Tcl_Channel inChan, outChan; ChannelState *inStatePtr, *outStatePtr; int result = TCL_OK, size, sizeb; Tcl_WideInt total; const char *buffer; int inBinary, outBinary, sameEncoding; /* Encoding control */ int underflow; /* Input underflow */ inChan = (Tcl_Channel) csPtr->readPtr; outChan = (Tcl_Channel) csPtr->writePtr; inStatePtr = csPtr->readPtr->state; outStatePtr = csPtr->writePtr->state; interp = csPtr->interp; cmdPtr = csPtr->cmdPtr; /* * Copy the data the slow way, using the translation mechanism. * * Note: We have make sure that we use the topmost channel in a stack for * the copying. The caller uses Tcl_GetChannel to access it, and thus gets * the bottom of the stack. */ inBinary = (inStatePtr->encoding == NULL); outBinary = (outStatePtr->encoding == NULL); sameEncoding = (inStatePtr->encoding == outStatePtr->encoding); if (!(inBinary || sameEncoding)) { TclNewObj(bufObj); Tcl_IncrRefCount(bufObj); } while (csPtr->toRead != (Tcl_WideInt) 0) { /* * Check for unreported background errors. */ Tcl_GetChannelError(inChan, &msg); if ((inStatePtr->unreportedError != 0) || (msg != NULL)) { Tcl_SetErrno(inStatePtr->unreportedError); inStatePtr->unreportedError = 0; goto readError; } Tcl_GetChannelError(outChan, &msg); if ((outStatePtr->unreportedError != 0) || (msg != NULL)) { Tcl_SetErrno(outStatePtr->unreportedError); outStatePtr->unreportedError = 0; goto writeError; } if (cmdPtr && (mask == 0)) { /* * In async mode, we skip reading synchronously and fake an * underflow instead to prime the readable fileevent. */ size = 0; underflow = 1; } else { /* * Read up to bufSize bytes. */ if ((csPtr->toRead == (Tcl_WideInt) -1) || (csPtr->toRead > (Tcl_WideInt) csPtr->bufSize)) { sizeb = csPtr->bufSize; } else { sizeb = (int) csPtr->toRead; } if (inBinary || sameEncoding) { size = DoRead(inStatePtr->topChanPtr, csPtr->buffer, sizeb, !GotFlag(inStatePtr, CHANNEL_NONBLOCKING)); } else { size = DoReadChars(inStatePtr->topChanPtr, bufObj, sizeb, 0 /* No append */); } underflow = (size >= 0) && (size < sizeb); /* Input underflow */ } if (size < 0) { readError: if (interp) { TclNewObj(errObj); Tcl_AppendStringsToObj(errObj, "error reading \"", Tcl_GetChannelName(inChan), "\": ", NULL); if (msg != NULL) { Tcl_AppendObjToObj(errObj, msg); } else { Tcl_AppendStringsToObj(errObj, Tcl_PosixError(interp), NULL); } } if (msg != NULL) { Tcl_DecrRefCount(msg); } break; } else if (underflow) { /* * We had an underflow on the read side. If we are at EOF, and not * in the synchronous part of an asynchronous fcopy, then the * copying is done, otherwise set up a channel handler to detect * when the channel becomes readable again. */ if ((size == 0) && Tcl_Eof(inChan) && !(cmdPtr && (mask == 0))) { break; } if (cmdPtr && (!Tcl_Eof(inChan) || (mask == 0)) && !(mask & TCL_READABLE)) { if (mask & TCL_WRITABLE) { Tcl_DeleteChannelHandler(outChan, CopyEventProc, csPtr); } Tcl_CreateChannelHandler(inChan, TCL_READABLE, CopyEventProc, csPtr); } if (size == 0) { if (!GotFlag(inStatePtr, CHANNEL_NONBLOCKING)) { /* * We allowed a short read. Keep trying. */ continue; } if (bufObj != NULL) { TclDecrRefCount(bufObj); bufObj = NULL; } return TCL_OK; } } /* * Now write the buffer out. */ if (inBinary || sameEncoding) { buffer = csPtr->buffer; sizeb = size; } else { buffer = TclGetStringFromObj(bufObj, &sizeb); } if (outBinary || sameEncoding) { sizeb = WriteBytes(outStatePtr->topChanPtr, buffer, sizeb); } else { sizeb = WriteChars(outStatePtr->topChanPtr, buffer, sizeb); } /* * [Bug 2895565]. At this point 'size' still contains the number of * bytes or characters which have been read. We keep this to later to * update the totals and toRead information, see marker (UP) below. We * must not overwrite it with 'sizeb', which is the number of written * bytes or characters, and both EOL translation and encoding * conversion may have changed this number unpredictably in relation * to 'size' (It can be smaller or larger, in the latter case able to * drive toRead below -1, causing infinite looping). Completely * unsuitable for updating totals and toRead. */ if (sizeb < 0) { writeError: if (interp) { TclNewObj(errObj); Tcl_AppendStringsToObj(errObj, "error writing \"", Tcl_GetChannelName(outChan), "\": ", NULL); if (msg != NULL) { Tcl_AppendObjToObj(errObj, msg); } else { Tcl_AppendStringsToObj(errObj, Tcl_PosixError(interp), NULL); } } if (msg != NULL) { Tcl_DecrRefCount(msg); } break; } /* * Update the current byte count. Do it now so the count is valid * before a return or break takes us out of the loop. The invariant at * the top of the loop should be that csPtr->toRead holds the number * of bytes left to copy. */ if (csPtr->toRead != -1) { csPtr->toRead -= size; } csPtr->total += size; /* * Break loop if EOF && (size>0) */ if (Tcl_Eof(inChan)) { break; } /* * Check to see if the write is happening in the background. If so, * stop copying and wait for the channel to become writable again. * After input underflow we already installed a readable handler * therefore we don't need a writable handler. */ if (!underflow && GotFlag(outStatePtr, BG_FLUSH_SCHEDULED)) { if (!(mask & TCL_WRITABLE)) { if (mask & TCL_READABLE) { Tcl_DeleteChannelHandler(inChan, CopyEventProc, csPtr); } Tcl_CreateChannelHandler(outChan, TCL_WRITABLE, CopyEventProc, csPtr); } if (bufObj != NULL) { TclDecrRefCount(bufObj); bufObj = NULL; } return TCL_OK; } /* * For background copies, we only do one buffer per invocation so we * don't starve the rest of the system. */ if (cmdPtr && (csPtr->toRead != 0)) { /* * The first time we enter this code, there won't be a channel * handler established yet, so do it here. */ if (mask == 0) { Tcl_CreateChannelHandler(outChan, TCL_WRITABLE, CopyEventProc, csPtr); } if (bufObj != NULL) { TclDecrRefCount(bufObj); bufObj = NULL; } return TCL_OK; } } /* while */ if (bufObj != NULL) { TclDecrRefCount(bufObj); bufObj = NULL; } /* * Make the callback or return the number of bytes transferred. The local * total is used because StopCopy frees csPtr. */ total = csPtr->total; if (cmdPtr && interp) { int code; /* * Get a private copy of the command so we can mutate it by adding * arguments. Note that StopCopy frees our saved reference to the * original command obj. */ cmdPtr = Tcl_DuplicateObj(cmdPtr); Tcl_IncrRefCount(cmdPtr); StopCopy(csPtr); Tcl_Preserve(interp); Tcl_ListObjAppendElement(interp, cmdPtr, Tcl_NewWideIntObj(total)); if (errObj) { Tcl_ListObjAppendElement(interp, cmdPtr, errObj); } code = Tcl_EvalObjEx(interp, cmdPtr, TCL_EVAL_GLOBAL); if (code != TCL_OK) { Tcl_BackgroundException(interp, code); result = TCL_ERROR; } TclDecrRefCount(cmdPtr); Tcl_Release(interp); } else { StopCopy(csPtr); if (interp) { if (errObj) { Tcl_SetObjResult(interp, errObj); result = TCL_ERROR; } else { Tcl_ResetResult(interp); Tcl_SetObjResult(interp, Tcl_NewWideIntObj(total)); } } } return result; } /* *---------------------------------------------------------------------- * * DoRead -- * * Stores up to "bytesToRead" bytes in memory pointed to by "dst". * These bytes come from reading the channel "chanPtr" and * performing the configured translations. No encoding conversions * are applied to the bytes being read. * * Results: * The number of bytes actually stored (<= bytesToRead), * or -1 if there is an error in reading the channel. Use * Tcl_GetErrno() to retrieve the error code for the error * that occurred. * * The number of bytes stored can be less than the number * requested when * - EOF is reached on the channel; or * - the channel is non-blocking, and we've read all we can * without blocking. * - a channel reading error occurs (and we return -1) * * Side effects: * May cause input to be buffered. * *---------------------------------------------------------------------- */ static int DoRead( Channel *chanPtr, /* The channel from which to read. */ char *dst, /* Where to store input read. */ int bytesToRead, /* Maximum number of bytes to read. */ int allowShortReads) /* Allow half-blocking (pipes,sockets) */ { ChannelState *statePtr = chanPtr->state; char *p = dst; assert(bytesToRead >= 0); /* * Early out when we know a read will get the eofchar. * * NOTE: This seems to be a bug. The special handling for * a zero-char read request ought to come first. As coded * the EOF due to eofchar has distinguishing behavior from * the EOF due to reported EOF on the underlying device, and * that seems undesirable. However recent history indicates * that new inconsistent behavior in a patchlevel has problems * too. Keep on keeping on for now. */ if (GotFlag(statePtr, CHANNEL_STICKY_EOF)) { SetFlag(statePtr, CHANNEL_EOF); assert(statePtr->inputEncodingFlags & TCL_ENCODING_END); assert(!GotFlag(statePtr, CHANNEL_BLOCKED|INPUT_SAW_CR)); /* TODO: Don't need this call */ UpdateInterest(chanPtr); return 0; } /* * Special handling for zero-char read request. */ if (bytesToRead == 0) { if (GotFlag(statePtr, CHANNEL_EOF)) { statePtr->inputEncodingFlags |= TCL_ENCODING_START; } ResetFlag(statePtr, CHANNEL_BLOCKED|CHANNEL_EOF); statePtr->inputEncodingFlags &= ~TCL_ENCODING_END; /* TODO: Don't need this call */ UpdateInterest(chanPtr); return 0; } TclChannelPreserve((Tcl_Channel)chanPtr); while (bytesToRead) { /* * Each pass through the loop is intended to process up to one channel * buffer. */ int bytesRead, bytesWritten; ChannelBuffer *bufPtr = statePtr->inQueueHead; /* * Don't read more data if we have what we need. */ while (!bufPtr || /* We got no buffer! OR */ (!IsBufferFull(bufPtr) && /* Our buffer has room AND */ (BytesLeft(bufPtr) < bytesToRead))) { /* Not enough bytes in it yet * to fill the dst */ int code; moreData: code = GetInput(chanPtr); bufPtr = statePtr->inQueueHead; assert(bufPtr != NULL); if (GotFlag(statePtr, CHANNEL_EOF|CHANNEL_BLOCKED)) { /* * Further reads cannot do any more. */ break; } if (code) { /* * Read error */ UpdateInterest(chanPtr); TclChannelRelease((Tcl_Channel)chanPtr); return -1; } assert(IsBufferFull(bufPtr)); } assert(bufPtr != NULL); bytesRead = BytesLeft(bufPtr); bytesWritten = bytesToRead; TranslateInputEOL(statePtr, p, RemovePoint(bufPtr), &bytesWritten, &bytesRead); bufPtr->nextRemoved += bytesRead; p += bytesWritten; bytesToRead -= bytesWritten; if (!IsBufferEmpty(bufPtr)) { /* * Buffer is not empty. How can that be? * * 0) We stopped early because we got all the bytes we were * seeking. That's fine. */ if (bytesToRead == 0) { break; } /* * 1) We're @EOF because we saw eof char. */ if (GotFlag(statePtr, CHANNEL_STICKY_EOF)) { break; } /* * 2) The buffer holds a \r while in CRLF translation, followed by * the end of the buffer. */ assert(statePtr->inputTranslation == TCL_TRANSLATE_CRLF); assert(RemovePoint(bufPtr)[0] == '\r'); assert(BytesLeft(bufPtr) == 1); if (bufPtr->nextPtr == NULL) { /* * There's no more buffered data... */ if (statePtr->flags & CHANNEL_EOF) { /* * ...and there never will be. */ *p++ = '\r'; bytesToRead--; bufPtr->nextRemoved++; } else if (statePtr->flags & CHANNEL_BLOCKED) { /* * ...and we cannot get more now. */ SetFlag(statePtr, CHANNEL_NEED_MORE_DATA); break; } else { /* * ...so we need to get some. */ goto moreData; } } if (bufPtr->nextPtr) { /* * There's a next buffer. Shift orphan \r to it. */ ChannelBuffer *nextPtr = bufPtr->nextPtr; nextPtr->nextRemoved -= 1; RemovePoint(nextPtr)[0] = '\r'; bufPtr->nextRemoved++; } } if (IsBufferEmpty(bufPtr)) { statePtr->inQueueHead = bufPtr->nextPtr; if (statePtr->inQueueHead == NULL) { statePtr->inQueueTail = NULL; } RecycleBuffer(statePtr, bufPtr, 0); bufPtr = statePtr->inQueueHead; } if ((GotFlag(statePtr, CHANNEL_NONBLOCKING) || allowShortReads) && GotFlag(statePtr, CHANNEL_BLOCKED)) { break; } /* * When there's no buffered data to read, and we're at EOF, escape to * the caller. */ if (GotFlag(statePtr, CHANNEL_EOF) && (bufPtr == NULL || IsBufferEmpty(bufPtr))) { break; } } if (bytesToRead == 0) { ResetFlag(statePtr, CHANNEL_BLOCKED); } assert(!GotFlag(statePtr, CHANNEL_EOF) || GotFlag(statePtr, CHANNEL_STICKY_EOF) || Tcl_InputBuffered((Tcl_Channel)chanPtr) == 0); assert(!(GotFlag(statePtr, CHANNEL_EOF|CHANNEL_BLOCKED) == (CHANNEL_EOF|CHANNEL_BLOCKED))); UpdateInterest(chanPtr); TclChannelRelease((Tcl_Channel)chanPtr); return (int)(p - dst); } /* *---------------------------------------------------------------------- * * CopyEventProc -- * * This routine is invoked as a channel event handler for the background * copy operation. It is just a trivial wrapper around the CopyData * routine. * * Results: * None. * * Side effects: * None. * *---------------------------------------------------------------------- */ static void CopyEventProc( ClientData clientData, int mask) { (void) CopyData(clientData, mask); } /* *---------------------------------------------------------------------- * * StopCopy -- * * This routine halts a copy that is in progress. * * Results: * None. * * Side effects: * Removes any pending channel handlers and restores the blocking and * buffering modes of the channels. The CopyState is freed. * *---------------------------------------------------------------------- */ static void StopCopy( CopyState *csPtr) /* State for bg copy to stop . */ { ChannelState *inStatePtr, *outStatePtr; Tcl_Channel inChan, outChan; int nonBlocking; if (!csPtr) { return; } inChan = (Tcl_Channel) csPtr->readPtr; outChan = (Tcl_Channel) csPtr->writePtr; inStatePtr = csPtr->readPtr->state; outStatePtr = csPtr->writePtr->state; /* * Restore the old blocking mode and output buffering mode. */ nonBlocking = csPtr->readFlags & CHANNEL_NONBLOCKING; if (nonBlocking != (inStatePtr->flags & CHANNEL_NONBLOCKING)) { SetBlockMode(NULL, csPtr->readPtr, nonBlocking ? TCL_MODE_NONBLOCKING : TCL_MODE_BLOCKING); } if (csPtr->readPtr != csPtr->writePtr) { nonBlocking = csPtr->writeFlags & CHANNEL_NONBLOCKING; if (nonBlocking != (outStatePtr->flags & CHANNEL_NONBLOCKING)) { SetBlockMode(NULL, csPtr->writePtr, nonBlocking ? TCL_MODE_NONBLOCKING : TCL_MODE_BLOCKING); } } ResetFlag(outStatePtr, CHANNEL_LINEBUFFERED | CHANNEL_UNBUFFERED); outStatePtr->flags |= csPtr->writeFlags & (CHANNEL_LINEBUFFERED | CHANNEL_UNBUFFERED); if (csPtr->cmdPtr) { Tcl_DeleteChannelHandler(inChan, CopyEventProc, csPtr); if (inChan != outChan) { Tcl_DeleteChannelHandler(outChan, CopyEventProc, csPtr); } Tcl_DeleteChannelHandler(inChan, MBEvent, csPtr); Tcl_DeleteChannelHandler(outChan, MBEvent, csPtr); TclDecrRefCount(csPtr->cmdPtr); } inStatePtr->csPtrR = NULL; outStatePtr->csPtrW = NULL; ckfree(csPtr); } /* *---------------------------------------------------------------------- * * StackSetBlockMode -- * * This function sets the blocking mode for a channel, iterating through * each channel in a stack and updates the state flags. * * Results: * 0 if OK, result code from failed blockModeProc otherwise. * * Side effects: * Modifies the blocking mode of the channel and possibly generates an * error. * *---------------------------------------------------------------------- */ static int StackSetBlockMode( Channel *chanPtr, /* Channel to modify. */ int mode) /* One of TCL_MODE_BLOCKING or * TCL_MODE_NONBLOCKING. */ { int result = 0; Tcl_DriverBlockModeProc *blockModeProc; ChannelState *statePtr = chanPtr->state; /* * Start at the top of the channel stack * TODO: Examine what can go wrong when blockModeProc calls * disturb the stacking state of the channel. */ chanPtr = statePtr->topChanPtr; while (chanPtr != NULL) { blockModeProc = Tcl_ChannelBlockModeProc(chanPtr->typePtr); if (blockModeProc != NULL) { result = blockModeProc(chanPtr->instanceData, mode); if (result != 0) { Tcl_SetErrno(result); return result; } } chanPtr = chanPtr->downChanPtr; } return 0; } /* *---------------------------------------------------------------------- * * SetBlockMode -- * * This function sets the blocking mode for a channel and updates the * state flags. * * Results: * A standard Tcl result. * * Side effects: * Modifies the blocking mode of the channel and possibly generates an * error. * *---------------------------------------------------------------------- */ static int SetBlockMode( Tcl_Interp *interp, /* Interp for error reporting. */ Channel *chanPtr, /* Channel to modify. */ int mode) /* One of TCL_MODE_BLOCKING or * TCL_MODE_NONBLOCKING. */ { int result = 0; ChannelState *statePtr = chanPtr->state; /* State info for channel */ result = StackSetBlockMode(chanPtr, mode); if (result != 0) { if (interp != NULL) { /* * TIP #219. * Move error messages put by the driver into the bypass area and * put them into the regular interpreter result. Fall back to the * regular message if nothing was found in the bypass. * * Note that we cannot have a message in the interpreter bypass * area, StackSetBlockMode is restricted to the channel bypass. * We still need the interp as the destination of the move. */ if (!TclChanCaughtErrorBypass(interp, (Tcl_Channel) chanPtr)) { Tcl_SetObjResult(interp, Tcl_ObjPrintf( "error setting blocking mode: %s", Tcl_PosixError(interp))); } } else { /* * TIP #219. * If we have no interpreter to put a bypass message into we have * to clear it, to prevent its propagation and use in other places * unrelated to the actual occurence of the problem. */ Tcl_SetChannelError((Tcl_Channel) chanPtr, NULL); } return TCL_ERROR; } if (mode == TCL_MODE_BLOCKING) { ResetFlag(statePtr, CHANNEL_NONBLOCKING | BG_FLUSH_SCHEDULED); } else { SetFlag(statePtr, CHANNEL_NONBLOCKING); } return TCL_OK; } /* *---------------------------------------------------------------------- * * Tcl_GetChannelNames -- * * Return the names of all open channels in the interp. * * Results: * TCL_OK or TCL_ERROR. * * Side effects: * Interp result modified with list of channel names. * *---------------------------------------------------------------------- */ int Tcl_GetChannelNames( Tcl_Interp *interp) /* Interp for error reporting. */ { return Tcl_GetChannelNamesEx(interp, NULL); } /* *---------------------------------------------------------------------- * * Tcl_GetChannelNamesEx -- * * Return the names of open channels in the interp filtered filtered * through a pattern. If pattern is NULL, it returns all the open * channels. * * Results: * TCL_OK or TCL_ERROR. * * Side effects: * Interp result modified with list of channel names. * *---------------------------------------------------------------------- */ int Tcl_GetChannelNamesEx( Tcl_Interp *interp, /* Interp for error reporting. */ const char *pattern) /* Pattern to filter on. */ { ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); ChannelState *statePtr; const char *name; /* Name for channel */ Tcl_Obj *resultPtr; /* Pointer to result object */ Tcl_HashTable *hTblPtr; /* Hash table of channels. */ Tcl_HashEntry *hPtr; /* Search variable. */ Tcl_HashSearch hSearch; /* Search variable. */ if (interp == NULL) { return TCL_OK; } /* * Get the channel table that stores the channels registered for this * interpreter. */ hTblPtr = GetChannelTable(interp); TclNewObj(resultPtr); if ((pattern != NULL) && TclMatchIsTrivial(pattern) && !((pattern[0] == 's') && (pattern[1] == 't') && (pattern[2] == 'd'))) { if ((Tcl_FindHashEntry(hTblPtr, pattern) != NULL) && (Tcl_ListObjAppendElement(interp, resultPtr, Tcl_NewStringObj(pattern, -1)) != TCL_OK)) { goto error; } goto done; } for (hPtr = Tcl_FirstHashEntry(hTblPtr, &hSearch); hPtr != NULL; hPtr = Tcl_NextHashEntry(&hSearch)) { statePtr = ((Channel *) Tcl_GetHashValue(hPtr))->state; if (statePtr->topChanPtr == (Channel *) tsdPtr->stdinChannel) { name = "stdin"; } else if (statePtr->topChanPtr == (Channel *) tsdPtr->stdoutChannel) { name = "stdout"; } else if (statePtr->topChanPtr == (Channel *) tsdPtr->stderrChannel) { name = "stderr"; } else { /* * This is also stored in Tcl_GetHashKey(hTblPtr, hPtr), but it's * simpler to just grab the name from the statePtr. */ name = statePtr->channelName; } if (((pattern == NULL) || Tcl_StringMatch(name, pattern)) && (Tcl_ListObjAppendElement(interp, resultPtr, Tcl_NewStringObj(name, -1)) != TCL_OK)) { error: TclDecrRefCount(resultPtr); return TCL_ERROR; } } done: Tcl_SetObjResult(interp, resultPtr); return TCL_OK; } /* *---------------------------------------------------------------------- * * Tcl_IsChannelRegistered -- * * Checks whether the channel is associated with the interp. See also * Tcl_RegisterChannel and Tcl_UnregisterChannel. * * Results: * 0 if the channel is not registered in the interpreter, 1 else. * * Side effects: * None. * *---------------------------------------------------------------------- */ int Tcl_IsChannelRegistered( Tcl_Interp *interp, /* The interp to query of the channel */ Tcl_Channel chan) /* The channel to check */ { Tcl_HashTable *hTblPtr; /* Hash table of channels. */ Tcl_HashEntry *hPtr; /* Search variable. */ Channel *chanPtr; /* The real IO channel. */ ChannelState *statePtr; /* State of the real channel. */ /* * Always check bottom-most channel in the stack. This is the one that * gets registered. */ chanPtr = ((Channel *) chan)->state->bottomChanPtr; statePtr = chanPtr->state; hTblPtr = Tcl_GetAssocData(interp, "tclIO", NULL); if (hTblPtr == NULL) { return 0; } hPtr = Tcl_FindHashEntry(hTblPtr, statePtr->channelName); if (hPtr == NULL) { return 0; } if ((Channel *) Tcl_GetHashValue(hPtr) != chanPtr) { return 0; } return 1; } /* *---------------------------------------------------------------------- * * Tcl_IsChannelShared -- * * Checks whether the channel is shared by multiple interpreters. * * Results: * A boolean value (0 = Not shared, 1 = Shared). * * Side effects: * None. * *---------------------------------------------------------------------- */ int Tcl_IsChannelShared( Tcl_Channel chan) /* The channel to query */ { ChannelState *statePtr = ((Channel *) chan)->state; /* State of real channel structure. */ return ((statePtr->refCount > 1) ? 1 : 0); } /* *---------------------------------------------------------------------- * * Tcl_IsChannelExisting -- * * Checks whether a channel of the given name exists in the * (thread)-global list of all channels. See Tcl_GetChannelNamesEx for * function exposed at the Tcl level. * * Results: * A boolean value (0 = Does not exist, 1 = Does exist). * * Side effects: * None. * *---------------------------------------------------------------------- */ int Tcl_IsChannelExisting( const char *chanName) /* The name of the channel to look for. */ { ChannelState *statePtr; ThreadSpecificData *tsdPtr = TCL_TSD_INIT(&dataKey); const char *name; int chanNameLen; chanNameLen = strlen(chanName); for (statePtr = tsdPtr->firstCSPtr; statePtr != NULL; statePtr = statePtr->nextCSPtr) { if (statePtr->topChanPtr == (Channel *) tsdPtr->stdinChannel) { name = "stdin"; } else if (statePtr->topChanPtr == (Channel *) tsdPtr->stdoutChannel) { name = "stdout"; } else if (statePtr->topChanPtr == (Channel *) tsdPtr->stderrChannel) { name = "stderr"; } else { name = statePtr->channelName; } if ((*chanName == *name) && (memcmp(name, chanName, (size_t) chanNameLen + 1) == 0)) { return 1; } } return 0; } /* *---------------------------------------------------------------------- * * Tcl_ChannelName -- * * Return the name of the channel type. * * Results: * A pointer the name of the channel type. * * Side effects: * None. * *---------------------------------------------------------------------- */ const char * Tcl_ChannelName( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { return chanTypePtr->typeName; } /* *---------------------------------------------------------------------- * * Tcl_ChannelVersion -- * * Return the of version of the channel type. * * Results: * One of the TCL_CHANNEL_VERSION_* constants from tcl.h * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_ChannelTypeVersion Tcl_ChannelVersion( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { if (chanTypePtr->version == TCL_CHANNEL_VERSION_2) { return TCL_CHANNEL_VERSION_2; } else if (chanTypePtr->version == TCL_CHANNEL_VERSION_3) { return TCL_CHANNEL_VERSION_3; } else if (chanTypePtr->version == TCL_CHANNEL_VERSION_4) { return TCL_CHANNEL_VERSION_4; } else if (chanTypePtr->version == TCL_CHANNEL_VERSION_5) { return TCL_CHANNEL_VERSION_5; } else { /* * In = (PTR2INT(minimumVersion)); } /* *---------------------------------------------------------------------- * * Tcl_ChannelBlockModeProc -- * * Return the Tcl_DriverBlockModeProc of the channel type. * * Results: * A pointer to the proc. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_DriverBlockModeProc * Tcl_ChannelBlockModeProc( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { if (HaveVersion(chanTypePtr, TCL_CHANNEL_VERSION_2)) { return chanTypePtr->blockModeProc; } /* * The v1 structure had the blockModeProc in a different place. */ return (Tcl_DriverBlockModeProc *) chanTypePtr->version; } /* *---------------------------------------------------------------------- * * Tcl_ChannelCloseProc -- * * Return the Tcl_DriverCloseProc of the channel type. * * Results: * A pointer to the proc. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_DriverCloseProc * Tcl_ChannelCloseProc( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { return chanTypePtr->closeProc; } /* *---------------------------------------------------------------------- * * Tcl_ChannelClose2Proc -- * * Return the Tcl_DriverClose2Proc of the channel type. * * Results: * A pointer to the proc. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_DriverClose2Proc * Tcl_ChannelClose2Proc( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { return chanTypePtr->close2Proc; } /* *---------------------------------------------------------------------- * * Tcl_ChannelInputProc -- * * Return the Tcl_DriverInputProc of the channel type. * * Results: * A pointer to the proc. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_DriverInputProc * Tcl_ChannelInputProc( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { return chanTypePtr->inputProc; } /* *---------------------------------------------------------------------- * * Tcl_ChannelOutputProc -- * * Return the Tcl_DriverOutputProc of the channel type. * * Results: * A pointer to the proc. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_DriverOutputProc * Tcl_ChannelOutputProc( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { return chanTypePtr->outputProc; } /* *---------------------------------------------------------------------- * * Tcl_ChannelSeekProc -- * * Return the Tcl_DriverSeekProc of the channel type. * * Results: * A pointer to the proc. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_DriverSeekProc * Tcl_ChannelSeekProc( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { return chanTypePtr->seekProc; } /* *---------------------------------------------------------------------- * * Tcl_ChannelSetOptionProc -- * * Return the Tcl_DriverSetOptionProc of the channel type. * * Results: * A pointer to the proc. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_DriverSetOptionProc * Tcl_ChannelSetOptionProc( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { return chanTypePtr->setOptionProc; } /* *---------------------------------------------------------------------- * * Tcl_ChannelGetOptionProc -- * * Return the Tcl_DriverGetOptionProc of the channel type. * * Results: * A pointer to the proc. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_DriverGetOptionProc * Tcl_ChannelGetOptionProc( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { return chanTypePtr->getOptionProc; } /* *---------------------------------------------------------------------- * * Tcl_ChannelWatchProc -- * * Return the Tcl_DriverWatchProc of the channel type. * * Results: * A pointer to the proc. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_DriverWatchProc * Tcl_ChannelWatchProc( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { return chanTypePtr->watchProc; } /* *---------------------------------------------------------------------- * * Tcl_ChannelGetHandleProc -- * * Return the Tcl_DriverGetHandleProc of the channel type. * * Results: * A pointer to the proc. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_DriverGetHandleProc * Tcl_ChannelGetHandleProc( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { return chanTypePtr->getHandleProc; } /* *---------------------------------------------------------------------- * * Tcl_ChannelFlushProc -- * * Return the Tcl_DriverFlushProc of the channel type. * * Results: * A pointer to the proc. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_DriverFlushProc * Tcl_ChannelFlushProc( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { if (HaveVersion(chanTypePtr, TCL_CHANNEL_VERSION_2)) { return chanTypePtr->flushProc; } return NULL; } /* *---------------------------------------------------------------------- * * Tcl_ChannelHandlerProc -- * * Return the Tcl_DriverHandlerProc of the channel type. * * Results: * A pointer to the proc. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_DriverHandlerProc * Tcl_ChannelHandlerProc( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { if (HaveVersion(chanTypePtr, TCL_CHANNEL_VERSION_2)) { return chanTypePtr->handlerProc; } return NULL; } /* *---------------------------------------------------------------------- * * Tcl_ChannelWideSeekProc -- * * Return the Tcl_DriverWideSeekProc of the channel type. * * Results: * A pointer to the proc. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_DriverWideSeekProc * Tcl_ChannelWideSeekProc( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { if (HaveVersion(chanTypePtr, TCL_CHANNEL_VERSION_3)) { return chanTypePtr->wideSeekProc; } return NULL; } /* *---------------------------------------------------------------------- * * Tcl_ChannelThreadActionProc -- * * TIP #218, Channel Thread Actions. Return the * Tcl_DriverThreadActionProc of the channel type. * * Results: * A pointer to the proc. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_DriverThreadActionProc * Tcl_ChannelThreadActionProc( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { if (HaveVersion(chanTypePtr, TCL_CHANNEL_VERSION_4)) { return chanTypePtr->threadActionProc; } return NULL; } /* *---------------------------------------------------------------------- * * Tcl_SetChannelErrorInterp -- * * TIP #219, Tcl Channel Reflection API. * Store an error message for the I/O system. * * Results: * None. * * Side effects: * Discards a previously stored message. * *---------------------------------------------------------------------- */ void Tcl_SetChannelErrorInterp( Tcl_Interp *interp, /* Interp to store the data into. */ Tcl_Obj *msg) /* Error message to store. */ { Interp *iPtr = (Interp *) interp; if (iPtr->chanMsg != NULL) { TclDecrRefCount(iPtr->chanMsg); iPtr->chanMsg = NULL; } if (msg != NULL) { iPtr->chanMsg = FixLevelCode(msg); Tcl_IncrRefCount(iPtr->chanMsg); } return; } /* *---------------------------------------------------------------------- * * Tcl_SetChannelError -- * * TIP #219, Tcl Channel Reflection API. * Store an error message for the I/O system. * * Results: * None. * * Side effects: * Discards a previously stored message. * *---------------------------------------------------------------------- */ void Tcl_SetChannelError( Tcl_Channel chan, /* Channel to store the data into. */ Tcl_Obj *msg) /* Error message to store. */ { ChannelState *statePtr = ((Channel *) chan)->state; if (statePtr->chanMsg != NULL) { TclDecrRefCount(statePtr->chanMsg); statePtr->chanMsg = NULL; } if (msg != NULL) { statePtr->chanMsg = FixLevelCode(msg); Tcl_IncrRefCount(statePtr->chanMsg); } return; } /* *---------------------------------------------------------------------- * * FixLevelCode -- * * TIP #219, Tcl Channel Reflection API. * Scans an error message for bad -code / -level directives. Returns a * modified copy with such directives corrected, and the input if it had * no problems. * * Results: * A Tcl_Obj* * * Side effects: * None. * *---------------------------------------------------------------------- */ static Tcl_Obj * FixLevelCode( Tcl_Obj *msg) { int explicitResult, numOptions, lc, lcn; Tcl_Obj **lv, **lvn; int res, i, j, val, lignore, cignore; int newlevel = -1, newcode = -1; /* ASSERT msg != NULL */ /* * Process the caught message. * * Syntax = (option value)... ?message? * * Bad message syntax causes a panic, because the other side uses * Tcl_GetReturnOptions and list construction functions to marshall the * information. Hence an error means that we've got serious breakage. */ res = Tcl_ListObjGetElements(NULL, msg, &lc, &lv); if (res != TCL_OK) { Tcl_Panic("Tcl_SetChannelError: bad syntax of message"); } explicitResult = (1 == (lc % 2)); numOptions = lc - explicitResult; /* * No options, nothing to do. */ if (numOptions == 0) { return msg; } /* * Check for -code x, x != 1|error, and -level x, x != 0 */ for (i = 0; i < numOptions; i += 2) { if (0 == strcmp(TclGetString(lv[i]), "-code")) { /* * !"error", !integer, integer != 1 (numeric code for error) */ res = TclGetIntFromObj(NULL, lv[i+1], &val); if (((res == TCL_OK) && (val != 1)) || ((res != TCL_OK) && (0 != strcmp(TclGetString(lv[i+1]), "error")))) { newcode = 1; } } else if (0 == strcmp(TclGetString(lv[i]), "-level")) { /* * !integer, integer != 0 */ res = TclGetIntFromObj(NULL, lv [i+1], &val); if ((res != TCL_OK) || (val != 0)) { newlevel = 0; } } } /* * -code, -level are either not present or ok. Nothing to do. */ if ((newlevel < 0) && (newcode < 0)) { return msg; } lcn = numOptions; if (explicitResult) { lcn ++; } if (newlevel >= 0) { lcn += 2; } if (newcode >= 0) { lcn += 2; } lvn = ckalloc(lcn * sizeof(Tcl_Obj *)); /* * New level/code information is spliced into the first occurence of * -level, -code, further occurences are ignored. The options cannot be * not present, we would not come here. Options which are ok are simply * copied over. */ lignore = cignore = 0; for (i=0, j=0; i= 0) { lvn[j++] = lv[i]; lvn[j++] = Tcl_NewIntObj(newlevel); newlevel = -1; lignore = 1; continue; } else if (lignore) { continue; } } else if (0 == strcmp(TclGetString(lv[i]), "-code")) { if (newcode >= 0) { lvn[j++] = lv[i]; lvn[j++] = Tcl_NewIntObj(newcode); newcode = -1; cignore = 1; continue; } else if (cignore) { continue; } } /* * Keep everything else, possibly copied down. */ lvn[j++] = lv[i]; lvn[j++] = lv[i+1]; } if (newlevel >= 0) { Tcl_Panic("Defined newlevel not used in rewrite"); } if (newcode >= 0) { Tcl_Panic("Defined newcode not used in rewrite"); } if (explicitResult) { lvn[j++] = lv[i]; } msg = Tcl_NewListObj(j, lvn); ckfree(lvn); return msg; } /* *---------------------------------------------------------------------- * * Tcl_GetChannelErrorInterp -- * * TIP #219, Tcl Channel Reflection API. * Return the message stored by the channel driver. * * Results: * Tcl error message object. * * Side effects: * Resets the stored data to NULL. * *---------------------------------------------------------------------- */ void Tcl_GetChannelErrorInterp( Tcl_Interp *interp, /* Interp to query. */ Tcl_Obj **msg) /* Place for error message. */ { Interp *iPtr = (Interp *) interp; *msg = iPtr->chanMsg; iPtr->chanMsg = NULL; } /* *---------------------------------------------------------------------- * * Tcl_GetChannelError -- * * TIP #219, Tcl Channel Reflection API. * Return the message stored by the channel driver. * * Results: * Tcl error message object. * * Side effects: * Resets the stored data to NULL. * *---------------------------------------------------------------------- */ void Tcl_GetChannelError( Tcl_Channel chan, /* Channel to query. */ Tcl_Obj **msg) /* Place for error message. */ { ChannelState *statePtr = ((Channel *) chan)->state; *msg = statePtr->chanMsg; statePtr->chanMsg = NULL; } /* *---------------------------------------------------------------------- * * Tcl_ChannelTruncateProc -- * * TIP #208 (subsection relating to truncation, based on TIP #206). * Return the Tcl_DriverTruncateProc of the channel type. * * Results: * A pointer to the proc. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tcl_DriverTruncateProc * Tcl_ChannelTruncateProc( const Tcl_ChannelType *chanTypePtr) /* Pointer to channel type. */ { if (HaveVersion(chanTypePtr, TCL_CHANNEL_VERSION_5)) { return chanTypePtr->truncateProc; } return NULL; } /* *---------------------------------------------------------------------- * * DupChannelIntRep -- * * Initialize the internal representation of a new Tcl_Obj to a copy of * the internal representation of an existing string object. * * Results: * None. * * Side effects: * copyPtr's internal rep is set to a copy of srcPtr's internal * representation. * *---------------------------------------------------------------------- */ static void DupChannelIntRep( register Tcl_Obj *srcPtr, /* Object with internal rep to copy. Must have * an internal rep of type "Channel". */ register Tcl_Obj *copyPtr) /* Object with internal rep to set. Must not * currently have an internal rep.*/ { ResolvedChanName *resPtr = srcPtr->internalRep.twoPtrValue.ptr1; resPtr->refCount++; copyPtr->internalRep.twoPtrValue.ptr1 = resPtr; copyPtr->typePtr = srcPtr->typePtr; } /* *---------------------------------------------------------------------- * * FreeChannelIntRep -- * * Release statePtr storage. * * Results: * None. * * Side effects: * May cause state to be freed. * *---------------------------------------------------------------------- */ static void FreeChannelIntRep( Tcl_Obj *objPtr) /* Object with internal rep to free. */ { ResolvedChanName *resPtr = objPtr->internalRep.twoPtrValue.ptr1; objPtr->typePtr = NULL; if (resPtr->refCount-- > 1) { return; } Tcl_Release(resPtr->statePtr); ckfree(resPtr); } #if 0 /* * For future debugging work, a simple function to print the flags of a * channel in semi-readable form. */ static int DumpFlags( char *str, int flags) { char buf[20]; int i = 0; #define ChanFlag(chr, bit) (buf[i++] = ((flags & (bit)) ? (chr) : '_')) ChanFlag('r', TCL_READABLE); ChanFlag('w', TCL_WRITABLE); ChanFlag('n', CHANNEL_NONBLOCKING); ChanFlag('l', CHANNEL_LINEBUFFERED); ChanFlag('u', CHANNEL_UNBUFFERED); ChanFlag('F', BG_FLUSH_SCHEDULED); ChanFlag('c', CHANNEL_CLOSED); ChanFlag('E', CHANNEL_EOF); ChanFlag('S', CHANNEL_STICKY_EOF); ChanFlag('B', CHANNEL_BLOCKED); ChanFlag('/', INPUT_SAW_CR); ChanFlag('D', CHANNEL_DEAD); ChanFlag('R', CHANNEL_RAW_MODE); ChanFlag('x', CHANNEL_INCLOSE); buf[i] ='\0'; fprintf(stderr, "%s: %s\n", str, buf); return 0; } #endif /* * Local Variables: * mode: c * c-basic-offset: 4 * fill-column: 78 * tab-width: 8 * indent-tabs-mode: nil * End: */