/* * BRLTTY - A background process providing access to the console screen (when in * text mode) for a blind person using a refreshable braille display. * * Copyright (C) 1995-2019 by The BRLTTY Developers. * * BRLTTY comes with ABSOLUTELY NO WARRANTY. * * This is free software, placed under the terms of the * GNU Lesser General Public License, as published by the Free Software * Foundation; either version 2.1 of the License, or (at your option) any * later version. Please see the file LICENSE-LGPL for details. * * Web Page: http://brltty.app/ * * This software is maintained by Dave Mielke . */ #include "prologue.h" #include #include #include "get_select.h" #ifdef __MINGW32__ #if _WIN32_WINNT < _WIN32_WINNT_VISTA #define CancelIoEx(handle, ol) CancelIo((handle)) #endif /* _WIN32_WINNT < _WIN32_WINNT_VISTA */ #endif /* __MINGW32__ */ #ifdef __MSDOS__ #include "system_msdos.h" #endif /* __MSDOS__ */ #undef ASYNC_CAN_MONITOR_IO #if defined(__MINGW32__) #define ASYNC_CAN_MONITOR_IO typedef HANDLE MonitorEntry; #elif defined(HAVE_SYS_POLL_H) #define ASYNC_CAN_MONITOR_IO #include typedef struct pollfd MonitorEntry; #elif defined(GOT_SELECT) #define ASYNC_CAN_MONITOR_IO typedef struct { int size; fd_set set; } SelectDescriptor; static SelectDescriptor selectDescriptor_read; static SelectDescriptor selectDescriptor_write; static SelectDescriptor selectDescriptor_exception; typedef struct { fd_set *selectSet; FileDescriptor fileDescriptor; } MonitorEntry; #endif /* monitor definitions */ #include "log.h" #include "async_io.h" #include "async_internal.h" #include "timing.h" typedef struct FunctionEntryStruct FunctionEntry; typedef struct { AsyncMonitorCallback *callback; } MonitorExtension; typedef union { struct { AsyncInputCallback *callback; unsigned end:1; } input; struct { AsyncOutputCallback *callback; } output; } TransferDirectionUnion; typedef struct { TransferDirectionUnion direction; size_t size; size_t length; unsigned char buffer[]; } TransferExtension; typedef struct { FunctionEntry *function; void *extension; void *data; MonitorEntry *monitor; int error; unsigned active:1; unsigned cancel:1; unsigned finished:1; } OperationEntry; typedef struct { const char *functionName; void (*beginFunction) (FunctionEntry *function); void (*endFunction) (FunctionEntry *function); void (*startOperation) (OperationEntry *operation); void (*finishOperation) (OperationEntry *operation); void (*cancelOperation) (OperationEntry *operation); int (*invokeCallback) (OperationEntry *operation); } FunctionMethods; struct FunctionEntryStruct { FileDescriptor fileDescriptor; const FunctionMethods *methods; Queue *operations; #if defined(__MINGW32__) struct { OVERLAPPED overlapped; } windows; #elif defined(HAVE_SYS_POLL_H) struct { short int events; } poll; #elif defined(HAVE_SELECT) struct { SelectDescriptor *descriptor; } select; #endif /* monitor paradigms */ }; typedef struct { FileDescriptor fileDescriptor; const FunctionMethods *methods; } FunctionKey; typedef struct { MonitorEntry *const array; unsigned int count; } MonitorGroup; struct AsyncIoDataStruct { Queue *functionQueue; }; void asyncDeallocateIoData (AsyncIoData *iod) { if (iod) { if (iod->functionQueue) deallocateQueue(iod->functionQueue); free(iod); } } static AsyncIoData * getIoData (void) { AsyncThreadSpecificData *tsd = asyncGetThreadSpecificData(); if (!tsd) return NULL; if (!tsd->ioData) { AsyncIoData *iod; if (!(iod = malloc(sizeof(*iod)))) { logMallocError(); return NULL; } memset(iod, 0, sizeof(*iod)); iod->functionQueue = NULL; tsd->ioData = iod; } return tsd->ioData; } static void logOperation (const OperationEntry *operation, void *callback) { logSymbol(LOG_CATEGORY(ASYNC_EVENTS), callback, "%s", operation->function->methods->functionName); } #ifdef __MINGW32__ static void prepareMonitors (void) { } static int awaitMonitors (const MonitorGroup *monitors, int timeout) { if (monitors->count) { DWORD result = WaitForMultipleObjects(monitors->count, monitors->array, FALSE, timeout); if ((result >= WAIT_OBJECT_0) && (result < (WAIT_OBJECT_0 + monitors->count))) return 1; if (result == WAIT_FAILED) { logWindowsSystemError("WaitForMultipleObjects"); } } else { approximateDelay(timeout); } return 0; } static void initializeMonitor (MonitorEntry *monitor, const FunctionEntry *function, const OperationEntry *operation) { *monitor = function->windows.overlapped.hEvent; if (*monitor == INVALID_HANDLE_VALUE) *monitor = function->fileDescriptor; } static int testMonitor (const MonitorEntry *monitor, int *error) { DWORD result = WaitForSingleObject(*monitor, 0); if (result == WAIT_OBJECT_0) return 1; if (result == WAIT_FAILED) { logWindowsSystemError("WaitForSingleObject"); } return 0; } static int allocateWindowsEvent (HANDLE *event) { if (*event == INVALID_HANDLE_VALUE) { HANDLE handle = CreateEvent(NULL, TRUE, FALSE, NULL); if (!handle) return 0; *event = handle; } return ResetEvent(*event); } static void deallocateWindowsEvent (HANDLE *event) { if (*event != INVALID_HANDLE_VALUE) { CloseHandle(*event); *event = INVALID_HANDLE_VALUE; } } static int allocateWindowsResources (OperationEntry *operation) { FunctionEntry *function = operation->function; if (allocateWindowsEvent(&function->windows.overlapped.hEvent)) { return 1; } operation->finished = 1; operation->error = GetLastError(); return 0; } static void setWindowsTransferResult (OperationEntry *operation, DWORD success, DWORD count) { TransferExtension *extension = operation->extension; if (success) { extension->length += count; } else { DWORD error = GetLastError(); if ((error == ERROR_HANDLE_EOF) || (error == ERROR_BROKEN_PIPE)) { extension->direction.input.end = 1; } else { setErrno(error); operation->error = errno; if (error == ERROR_IO_PENDING) return; if (error == ERROR_IO_INCOMPLETE) return; } } operation->finished = 1; } static void beginWindowsFunction (FunctionEntry *function) { ZeroMemory(&function->windows.overlapped, sizeof(function->windows.overlapped)); function->windows.overlapped.hEvent = INVALID_HANDLE_VALUE; } static void endWindowsFunction (FunctionEntry *function) { deallocateWindowsEvent(&function->windows.overlapped.hEvent); } static void startWindowsRead (OperationEntry *operation) { FunctionEntry *function = operation->function; TransferExtension *extension = operation->extension; if (allocateWindowsResources(operation)) { DWORD count; BOOL success = ReadFile(function->fileDescriptor, &extension->buffer[extension->length], extension->size - extension->length, &count, &function->windows.overlapped); setWindowsTransferResult(operation, success, count); } } static void startWindowsWrite (OperationEntry *operation) { FunctionEntry *function = operation->function; TransferExtension *extension = operation->extension; if (allocateWindowsResources(operation)) { DWORD count; BOOL success = WriteFile(function->fileDescriptor, &extension->buffer[extension->length], extension->size - extension->length, &count, &function->windows.overlapped); setWindowsTransferResult(operation, success, count); } } static void finishWindowsTransferOperation (OperationEntry *operation) { FunctionEntry *function = operation->function; DWORD count; BOOL success = GetOverlappedResult(function->fileDescriptor, &function->windows.overlapped, &count, FALSE); setWindowsTransferResult(operation, success, count); } static void cancelWindowsTransferOperation (OperationEntry *operation) { FunctionEntry *function = operation->function; DWORD count; if (CancelIoEx(function->fileDescriptor, &function->windows.overlapped)) { GetOverlappedResult(function->fileDescriptor, &function->windows.overlapped, &count, TRUE); } } #else /* __MINGW32__ */ #ifdef HAVE_SYS_POLL_H static void prepareMonitors (void) { } static int awaitMonitors (const MonitorGroup *monitors, int timeout) { int result = poll(monitors->array, monitors->count, timeout); if (result > 0) return 1; if (result == -1) { if (errno != EINTR) logSystemError("poll"); } return 0; } static void initializeMonitor (MonitorEntry *monitor, const FunctionEntry *function, const OperationEntry *operation) { monitor->fd = function->fileDescriptor; monitor->events = function->poll.events; monitor->revents = 0; } static int testMonitor (const MonitorEntry *monitor, int *error) { if (!monitor->revents) return 0; if (!(monitor->revents & monitor->events)) { if (monitor->revents & POLLHUP) { *error = ENODEV; } else { *error = EIO; } } return 1; } static void beginUnixInputFunction (FunctionEntry *function) { function->poll.events = POLLIN; } static void beginUnixOutputFunction (FunctionEntry *function) { function->poll.events = POLLOUT; } static void beginUnixAlertFunction (FunctionEntry *function) { function->poll.events = POLLPRI; } #elif defined(HAVE_SELECT) static void prepareSelectDescriptor (SelectDescriptor *descriptor) { FD_ZERO(&descriptor->set); descriptor->size = 0; } static void prepareMonitors (void) { prepareSelectDescriptor(&selectDescriptor_read); prepareSelectDescriptor(&selectDescriptor_write); prepareSelectDescriptor(&selectDescriptor_exception); } static fd_set * getSelectSet (SelectDescriptor *descriptor) { return descriptor->size? &descriptor->set: NULL; } static int doSelect (int setSize, fd_set *readSet, fd_set *writeSet, fd_set *exceptionSet, int timeout) { struct timeval time = { .tv_sec = timeout / MSECS_PER_SEC, .tv_usec = (timeout % MSECS_PER_SEC) * USECS_PER_MSEC }; { int result = select(setSize, readSet, writeSet, exceptionSet, &time); if (result > 0) return 1; if (result == -1) { if (errno != EINTR) logSystemError("select"); } return 0; } } static int awaitMonitors (const MonitorGroup *monitors, int timeout) { fd_set *readSet = getSelectSet(&selectDescriptor_read); fd_set *writeSet = getSelectSet(&selectDescriptor_write); fd_set *exceptionSet = getSelectSet(&selectDescriptor_exception); int setSize = selectDescriptor_read.size; setSize = MAX(setSize, selectDescriptor_write.size); setSize = MAX(setSize, selectDescriptor_exception.size); #ifdef __MSDOS__ int elapsed = 0; do { fd_set readSet1, writeSet1, exceptionSet1; if (readSet) readSet1 = *readSet; if (writeSet) writeSet1 = *writeSet; if (exceptionSet) exceptionSet1 = *exceptionSet; if (doSelect(setSize, (readSet? &readSet1: NULL), (writeSet? &writeSet1: NULL), (exceptionSet? &exceptionSet1: NULL), 0)) { if (readSet) *readSet = readSet1; if (writeSet) *writeSet = writeSet1; if (exceptionSet) *exceptionSet = exceptionSet1; return 1; } } while ((elapsed += msdosUSleep(USECS_PER_MSEC)) < timeout); #else /* __MSDOS__ */ if (doSelect(setSize, readSet, writeSet, exceptionSet, timeout)) return 1; #endif /* __MSDOS__ */ return 0; } static void initializeMonitor (MonitorEntry *monitor, const FunctionEntry *function, const OperationEntry *operation) { monitor->selectSet = &function->select.descriptor->set; monitor->fileDescriptor = function->fileDescriptor; FD_SET(function->fileDescriptor, &function->select.descriptor->set); if (function->fileDescriptor >= function->select.descriptor->size) { function->select.descriptor->size = function->fileDescriptor + 1; } } static int testMonitor (const MonitorEntry *monitor, int *error) { return FD_ISSET(monitor->fileDescriptor, monitor->selectSet); } static void beginUnixInputFunction (FunctionEntry *function) { function->select.descriptor = &selectDescriptor_read; } static void beginUnixOutputFunction (FunctionEntry *function) { function->select.descriptor = &selectDescriptor_write; } static void beginUnixAlertFunction (FunctionEntry *function) { function->select.descriptor = &selectDescriptor_exception; } #endif /* Unix I/O monitoring capabilities */ #ifdef ASYNC_CAN_MONITOR_IO static void setUnixTransferResult (OperationEntry *operation, ssize_t result) { TransferExtension *extension = operation->extension; if (result == -1) { operation->error = errno; } else if (result == 0) { extension->direction.input.end = 1; } else { extension->length += result; } operation->finished = 1; } static void finishUnixRead (OperationEntry *operation) { FunctionEntry *function = operation->function; TransferExtension *extension = operation->extension; ssize_t result = read(function->fileDescriptor, &extension->buffer[extension->length], extension->size - extension->length); setUnixTransferResult(operation, result); } static void finishUnixWrite (OperationEntry *operation) { FunctionEntry *function = operation->function; TransferExtension *extension = operation->extension; ssize_t result = write(function->fileDescriptor, &extension->buffer[extension->length], extension->size - extension->length); setUnixTransferResult(operation, result); } #endif /* ASYNC_CAN_MONITOR_IO */ #endif /* __MINGW32__ */ #ifdef ASYNC_CAN_MONITOR_IO static void deallocateFunctionEntry (void *item, void *data) { FunctionEntry *function = item; if (function->operations) deallocateQueue(function->operations); if (function->methods->endFunction) function->methods->endFunction(function); free(function); } static Queue * getFunctionQueue (int create) { AsyncIoData *iod = getIoData(); if (!iod) return NULL; if (!iod->functionQueue && create) { iod->functionQueue = newQueue(deallocateFunctionEntry, NULL); } return iod->functionQueue; } static int invokeMonitorCallback (OperationEntry *operation) { MonitorExtension *extension = operation->extension; AsyncMonitorCallback *callback = extension->callback; logOperation(operation, callback); if (callback) { const AsyncMonitorCallbackParameters parameters = { .error = operation->error, .data = operation->data }; if (callback(¶meters)) return 1; } return 0; } static int invokeInputCallback (OperationEntry *operation) { TransferExtension *extension = operation->extension; AsyncInputCallback *callback = extension->direction.input.callback; size_t count; logOperation(operation, callback); if (!callback) return 0; { const AsyncInputCallbackParameters parameters = { .data = operation->data, .buffer = extension->buffer, .size = extension->size, .length = extension->length, .error = operation->error, .end = extension->direction.input.end }; count = callback(¶meters); } if (operation->error) return 0; if (extension->direction.input.end) return 0; operation->finished = 0; if (count) { memmove(extension->buffer, &extension->buffer[count], extension->length -= count); if (extension->length > 0) operation->finished = 1; } return 1; } static int invokeOutputCallback (OperationEntry *operation) { TransferExtension *extension = operation->extension; AsyncOutputCallback *callback = extension->direction.output.callback; logOperation(operation, callback); if (!operation->error && (extension->length < extension->size)) { operation->finished = 0; return 1; } if (callback) { const AsyncOutputCallbackParameters parameters = { .data = operation->data, .buffer = extension->buffer, .size = extension->size, .error = operation->error }; callback(¶meters); } return 0; } static Element * getActiveOperationElement (const FunctionEntry *function) { Queue *queue = function->operations; if (function->methods->invokeCallback == invokeMonitorCallback) return getStackHead(queue); return getQueueHead(queue); } static OperationEntry * getActiveOperation (const FunctionEntry *function) { Element *element = getActiveOperationElement(function); if (element) return getElementItem(element); return NULL; } static void startOperation (OperationEntry *operation) { if (operation->function->methods->startOperation) { operation->function->methods->startOperation(operation); } } static void finishOperation (OperationEntry *operation) { if (operation->function->methods->finishOperation) { operation->function->methods->finishOperation(operation); } } static int addFunctionMonitor (void *item, void *data) { const FunctionEntry *function = item; MonitorGroup *monitors = data; OperationEntry *operation = getActiveOperation(function); if (operation) { operation->monitor = NULL; if (!operation->active) { if (operation->finished) return 1; operation->monitor = &monitors->array[monitors->count++]; initializeMonitor(operation->monitor, function, operation); } } return 0; } static int testFunctionMonitor (void *item, void *data) { FunctionEntry *function = item; OperationEntry *operation = getActiveOperation(function); if (operation && operation->monitor) { int *error = &operation->error; *error = 0; if (testMonitor(operation->monitor, error)) return 1; } return 0; } int asyncExecuteIoCallback (AsyncIoData *iod, long int timeout) { if (iod) { Queue *functions = iod->functionQueue; unsigned int functionCount = functions? getQueueSize(functions): 0; prepareMonitors(); if (functionCount) { MonitorEntry monitorArray[functionCount]; MonitorGroup monitors = { .array = monitorArray, .count = 0 }; int executed = 0; Element *functionElement = processQueue(functions, addFunctionMonitor, &monitors); if (!functionElement) { if (!monitors.count) { approximateDelay(timeout); } else if (awaitMonitors(&monitors, timeout)) { functionElement = processQueue(functions, testFunctionMonitor, NULL); } } if (functionElement) { FunctionEntry *function = getElementItem(functionElement); Element *operationElement = getActiveOperationElement(function); OperationEntry *operation = getElementItem(operationElement); if (!operation->finished) finishOperation(operation); operation->active = 1; if (!function->methods->invokeCallback(operation)) operation->cancel = 1; operation->active = 0; executed = 1; if (operation->cancel) { deleteElement(operationElement); } else { operation->error = 0; } if ((operationElement = getActiveOperationElement(function))) { operation = getElementItem(operationElement); if (!operation->finished) startOperation(operation); requeueElement(functionElement); } else { deleteElement(functionElement); } } return executed; } } approximateDelay(timeout); return 0; } static void deallocateOperationEntry (void *item, void *data) { OperationEntry *operation = item; if (operation->extension) free(operation->extension); free(operation); } static void cancelOperation (Element *operationElement) { OperationEntry *operation = getElementItem(operationElement); if (operation->active) { operation->cancel = 1; } else { FunctionEntry *function = operation->function; int isFirstOperation = operationElement == getActiveOperationElement(function); if (isFirstOperation) { if (!operation->finished) { if (operation->function->methods->cancelOperation) { operation->function->methods->cancelOperation(operation); } } } if (getQueueSize(function->operations) == 1) { deleteElement(findElementWithItem(getFunctionQueue(0), function)); } else { deleteElement(operationElement); if (isFirstOperation) { operationElement = getActiveOperationElement(function); operation = getElementItem(operationElement); if (!operation->finished) startOperation(operation); } } } } static int testFunctionEntry (const void *item, void *data) { const FunctionEntry *function = item; const FunctionKey *key = data; return (function->fileDescriptor == key->fileDescriptor) && (function->methods == key->methods); } static Element * getFunctionElement (FileDescriptor fileDescriptor, const FunctionMethods *methods, int create) { Queue *functions = getFunctionQueue(create); if (functions) { { FunctionKey key = { .fileDescriptor = fileDescriptor, .methods = methods }; { Element *element = findElement(functions, testFunctionEntry, &key); if (element) return element; } } if (create) { FunctionEntry *function; if ((function = malloc(sizeof(*function)))) { function->fileDescriptor = fileDescriptor; function->methods = methods; if ((function->operations = newQueue(deallocateOperationEntry, NULL))) { { static AsyncQueueMethods methods = { .cancelRequest = cancelOperation }; setQueueData(function->operations, &methods); } if (methods->beginFunction) methods->beginFunction(function); { Element *element = enqueueItem(functions, function); if (element) return element; } deallocateQueue(function->operations); } free(function); } else { logMallocError(); } } } return NULL; } static Element * newOperation ( FileDescriptor fileDescriptor, const FunctionMethods *methods, void *extension, void *data ) { OperationEntry *operation; if ((operation = malloc(sizeof(*operation)))) { Element *functionElement; if ((functionElement = getFunctionElement(fileDescriptor, methods, 1))) { FunctionEntry *function = getElementItem(functionElement); int isFirstOperation = !getQueueSize(function->operations); Element *operationElement = enqueueItem(function->operations, operation); if (operationElement) { operation->function = function; operation->extension = extension; operation->data = data; operation->monitor = NULL; operation->error = 0; operation->active = 0; operation->cancel = 0; operation->finished = 0; if (isFirstOperation) startOperation(operation); return operationElement; } if (isFirstOperation) deleteElement(functionElement); } free(operation); } else { logMallocError(); } return NULL; } typedef struct { FileDescriptor fileDescriptor; const FunctionMethods *methods; AsyncMonitorCallback *callback; void *data; } MonitorFileOperationParameters; static Element * newFileMonitorOperation (const void *parameters) { const MonitorFileOperationParameters *mop = parameters; MonitorExtension *extension; if ((extension = malloc(sizeof(*extension)))) { extension->callback = mop->callback; { Element *element = newOperation(mop->fileDescriptor, mop->methods, extension, mop->data); if (element) return element; } free(extension); } else { logMallocError(); } return NULL; } static Element * newTransferOperation ( FileDescriptor fileDescriptor, const FunctionMethods *methods, const TransferDirectionUnion *direction, size_t size, const void *buffer, void *data ) { TransferExtension *extension; if ((extension = malloc(sizeof(*extension) + size))) { extension->direction = *direction; extension->size = size; extension->length = 0; if (buffer) memcpy(extension->buffer, buffer, size); { Element *element = newOperation(fileDescriptor, methods, extension, data); if (element) return element; } free(extension); } else { logMallocError(); } return NULL; } typedef struct { FileDescriptor fileDescriptor; size_t size; AsyncInputCallback *callback; void *data; } InputOperationParameters; static Element * newInputOperation (const void *parameters) { const InputOperationParameters *iop = parameters; TransferDirectionUnion direction = { .input = { .callback = iop->callback, .end = 0 } }; static const FunctionMethods methods = { .functionName = "input transferred", #ifdef __MINGW32__ .beginFunction = beginWindowsFunction, .endFunction = endWindowsFunction, .startOperation = startWindowsRead, .finishOperation = finishWindowsTransferOperation, .cancelOperation = cancelWindowsTransferOperation, #else /* __MINGW32__ */ .beginFunction = beginUnixInputFunction, .finishOperation = finishUnixRead, #endif /* __MINGW32__ */ .invokeCallback = invokeInputCallback }; return newTransferOperation(iop->fileDescriptor, &methods, &direction, iop->size, NULL, iop->data); } typedef struct { FileDescriptor fileDescriptor; size_t size; const void *buffer; AsyncOutputCallback *callback; void *data; } OutputOperationParameters; static Element * newOutputOperation (const void *parameters) { const OutputOperationParameters *oop = parameters; TransferDirectionUnion direction = { .output = { .callback = oop->callback } }; static const FunctionMethods methods = { .functionName = "output transferred", #ifdef __MINGW32__ .beginFunction = beginWindowsFunction, .endFunction = endWindowsFunction, .startOperation = startWindowsWrite, .finishOperation = finishWindowsTransferOperation, .cancelOperation = cancelWindowsTransferOperation, #else /* __MINGW32__ */ .beginFunction = beginUnixOutputFunction, .finishOperation = finishUnixWrite, #endif /* __MINGW32__ */ .invokeCallback = invokeOutputCallback }; return newTransferOperation(oop->fileDescriptor, &methods, &direction, oop->size, oop->buffer, oop->data); } #else /* ASYNC_CAN_MONITOR_IO */ int asyncHandleOperation (AsyncThreadSpecificData *tsd, long int timeout) { approximateDelay(timeout); return 0; } #endif /* ASYNC_CAN_MONITOR_IO */ int asyncMonitorFileInput ( AsyncHandle *handle, FileDescriptor fileDescriptor, AsyncMonitorCallback *callback, void *data ) { #ifdef ASYNC_CAN_MONITOR_IO static const FunctionMethods methods = { .functionName = "file input monitor", #ifdef __MINGW32__ .beginFunction = beginWindowsFunction, .endFunction = endWindowsFunction, #else /* __MINGW32__ */ .beginFunction = beginUnixInputFunction, #endif /* __MINGW32__ */ .invokeCallback = invokeMonitorCallback }; const MonitorFileOperationParameters mop = { .fileDescriptor = fileDescriptor, .methods = &methods, .callback = callback, .data = data }; return asyncMakeHandle(handle, newFileMonitorOperation, &mop); #else /* ASYNC_CAN_MONITOR_IO */ logUnsupportedFunction(); return 0; #endif /* ASYNC_CAN_MONITOR_IO */ } int asyncMonitorFileOutput ( AsyncHandle *handle, FileDescriptor fileDescriptor, AsyncMonitorCallback *callback, void *data ) { #ifdef ASYNC_CAN_MONITOR_IO static const FunctionMethods methods = { .functionName = "file output monitor", #ifdef __MINGW32__ .beginFunction = beginWindowsFunction, .endFunction = endWindowsFunction, #else /* __MINGW32__ */ .beginFunction = beginUnixOutputFunction, #endif /* __MINGW32__ */ .invokeCallback = invokeMonitorCallback }; const MonitorFileOperationParameters mop = { .fileDescriptor = fileDescriptor, .methods = &methods, .callback = callback, .data = data }; return asyncMakeHandle(handle, newFileMonitorOperation, &mop); #else /* ASYNC_CAN_MONITOR_IO */ logUnsupportedFunction(); return 0; #endif /* ASYNC_CAN_MONITOR_IO */ } int asyncMonitorFileAlert ( AsyncHandle *handle, FileDescriptor fileDescriptor, AsyncMonitorCallback *callback, void *data ) { #ifdef ASYNC_CAN_MONITOR_IO static const FunctionMethods methods = { .functionName = "file alert monitor", #ifdef __MINGW32__ .beginFunction = beginWindowsFunction, .endFunction = endWindowsFunction, #else /* __MINGW32__ */ .beginFunction = beginUnixAlertFunction, #endif /* __MINGW32__ */ .invokeCallback = invokeMonitorCallback }; const MonitorFileOperationParameters mop = { .fileDescriptor = fileDescriptor, .methods = &methods, .callback = callback, .data = data }; return asyncMakeHandle(handle, newFileMonitorOperation, &mop); #else /* ASYNC_CAN_MONITOR_IO */ logUnsupportedFunction(); return 0; #endif /* ASYNC_CAN_MONITOR_IO */ } int asyncReadFile ( AsyncHandle *handle, FileDescriptor fileDescriptor, size_t size, AsyncInputCallback *callback, void *data ) { #ifdef ASYNC_CAN_MONITOR_IO const InputOperationParameters iop = { .fileDescriptor = fileDescriptor, .size = size, .callback = callback, .data = data }; return asyncMakeHandle(handle, newInputOperation, &iop); #else /* ASYNC_CAN_MONITOR_IO */ logUnsupportedFunction(); return 0; #endif /* ASYNC_CAN_MONITOR_IO */ } int asyncWriteFile ( AsyncHandle *handle, FileDescriptor fileDescriptor, const void *buffer, size_t size, AsyncOutputCallback *callback, void *data ) { #ifdef ASYNC_CAN_MONITOR_IO const OutputOperationParameters oop = { .fileDescriptor = fileDescriptor, .size = size, .buffer = buffer, .callback = callback, .data = data }; return asyncMakeHandle(handle, newOutputOperation, &oop); #else /* ASYNC_CAN_MONITOR_IO */ logUnsupportedFunction(); return 0; #endif /* ASYNC_CAN_MONITOR_IO */ } #ifdef __MINGW32__ int asyncMonitorSocketInput ( AsyncHandle *handle, SocketDescriptor socketDescriptor, AsyncMonitorCallback *callback, void *data ) { logUnsupportedFunction(); return 0; } int asyncMonitorSocketOutput ( AsyncHandle *handle, SocketDescriptor socketDescriptor, AsyncMonitorCallback *callback, void *data ) { logUnsupportedFunction(); return 0; } int asyncMonitorSocketAlert ( AsyncHandle *handle, SocketDescriptor socketDescriptor, AsyncMonitorCallback *callback, void *data ) { logUnsupportedFunction(); return 0; } int asyncReadSocket ( AsyncHandle *handle, SocketDescriptor socketDescriptor, size_t size, AsyncInputCallback *callback, void *data ) { logUnsupportedFunction(); return 0; } int asyncWriteSocket ( AsyncHandle *handle, SocketDescriptor socketDescriptor, const void *buffer, size_t size, AsyncOutputCallback *callback, void *data ) { logUnsupportedFunction(); return 0; } #else /* __MINGW32__ */ int asyncMonitorSocketInput ( AsyncHandle *handle, SocketDescriptor socketDescriptor, AsyncMonitorCallback *callback, void *data ) { return asyncMonitorFileInput(handle, socketDescriptor, callback, data); } int asyncMonitorSocketOutput ( AsyncHandle *handle, SocketDescriptor socketDescriptor, AsyncMonitorCallback *callback, void *data ) { return asyncMonitorFileOutput(handle, socketDescriptor, callback, data); } int asyncMonitorSocketAlert ( AsyncHandle *handle, SocketDescriptor socketDescriptor, AsyncMonitorCallback *callback, void *data ) { return asyncMonitorFileAlert(handle, socketDescriptor, callback, data); } int asyncReadSocket ( AsyncHandle *handle, SocketDescriptor socketDescriptor, size_t size, AsyncInputCallback *callback, void *data ) { return asyncReadFile(handle, socketDescriptor, size, callback, data); } int asyncWriteSocket ( AsyncHandle *handle, SocketDescriptor socketDescriptor, const void *buffer, size_t size, AsyncOutputCallback *callback, void *data ) { return asyncWriteFile(handle, socketDescriptor, buffer, size, callback, data); } #endif /* __MINGW32__ */