/* Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed with * this work for additional information regarding copyright ownership. * The ASF licenses this file to You under the Apache License, Version 2.0 * (the "License"); you may not use this file except in compliance with * the License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "apr_arch_file_io.h" #include "apr_file_io.h" #include "apr_general.h" #include "apr_strings.h" #include "apr_lib.h" #include "apr_errno.h" #include <malloc.h> #include "apr_arch_atime.h" #include "apr_arch_misc.h" /* * read_with_timeout() * Uses async i/o to emulate unix non-blocking i/o with timeouts. */ static apr_status_t read_with_timeout(apr_file_t *file, void *buf, apr_size_t len_in, apr_size_t *nbytes) { apr_status_t rv; DWORD res; DWORD len = (DWORD)len_in; DWORD bytesread = 0; /* Handle the zero timeout non-blocking case */ if (file->timeout == 0) { /* Peek at the pipe. If there is no data available, return APR_EAGAIN. * If data is available, go ahead and read it. */ if (file->pipe) { DWORD bytes; if (!PeekNamedPipe(file->filehand, NULL, 0, NULL, &bytes, NULL)) { rv = apr_get_os_error(); if (rv == APR_FROM_OS_ERROR(ERROR_BROKEN_PIPE)) { rv = APR_EOF; } *nbytes = 0; return rv; } else { if (bytes == 0) { *nbytes = 0; return APR_EAGAIN; } if (len > bytes) { len = bytes; } } } else { /* ToDo: Handle zero timeout non-blocking file i/o * This is not needed until an APR application needs to * timeout file i/o (which means setting file i/o non-blocking) */ } } if (file->pOverlapped && !file->pipe) { file->pOverlapped->Offset = (DWORD)file->filePtr; file->pOverlapped->OffsetHigh = (DWORD)(file->filePtr >> 32); } if (ReadFile(file->filehand, buf, len, &bytesread, file->pOverlapped)) { rv = APR_SUCCESS; } else { rv = apr_get_os_error(); if (rv == APR_FROM_OS_ERROR(ERROR_IO_PENDING)) { /* Wait for the pending i/o, timeout converted from us to ms * Note that we loop if someone gives up the event, since * folks suggest that WAIT_ABANDONED isn't actually a result * but an alert that ownership of the event has passed from * one owner to a new proc/thread. */ do { res = WaitForSingleObject(file->pOverlapped->hEvent, (file->timeout > 0) ? (DWORD)(file->timeout/1000) : ((file->timeout == -1) ? INFINITE : 0)); } while (res == WAIT_ABANDONED); /* There is one case that represents entirely * successful operations, otherwise we will cancel * the operation in progress. */ if (res != WAIT_OBJECT_0) { CancelIo(file->filehand); } /* Ignore any failures above. Attempt to complete * the overlapped operation and use only _its_ result. * For example, CancelIo or WaitForSingleObject can * fail if the handle is closed, yet the read may have * completed before we attempted to CancelIo... */ if (GetOverlappedResult(file->filehand, file->pOverlapped, &bytesread, TRUE)) { rv = APR_SUCCESS; } else { rv = apr_get_os_error(); if (((rv == APR_FROM_OS_ERROR(ERROR_IO_INCOMPLETE)) || (rv == APR_FROM_OS_ERROR(ERROR_OPERATION_ABORTED))) && (res == WAIT_TIMEOUT)) rv = APR_TIMEUP; } } if (rv == APR_FROM_OS_ERROR(ERROR_BROKEN_PIPE)) { /* Assume ERROR_BROKEN_PIPE signals an EOF reading from a pipe */ rv = APR_EOF; } else if (rv == APR_FROM_OS_ERROR(ERROR_HANDLE_EOF)) { /* Did we hit EOF reading from the handle? */ rv = APR_EOF; } } /* OK and 0 bytes read ==> end of file */ if (rv == APR_SUCCESS && bytesread == 0) rv = APR_EOF; if (rv == APR_SUCCESS && file->pOverlapped && !file->pipe) { file->filePtr += bytesread; } *nbytes = bytesread; return rv; } APR_DECLARE(apr_status_t) apr_file_read(apr_file_t *thefile, void *buf, apr_size_t *len) { apr_status_t rv; DWORD bytes_read = 0; if (*len <= 0) { *len = 0; return APR_SUCCESS; } /* If the file is open for xthread support, allocate and * initialize the overlapped and io completion event (hEvent). * Threads should NOT share an apr_file_t or its hEvent. */ if ((thefile->flags & APR_XTHREAD) && !thefile->pOverlapped ) { thefile->pOverlapped = (OVERLAPPED*) apr_pcalloc(thefile->pool, sizeof(OVERLAPPED)); thefile->pOverlapped->hEvent = CreateEvent(NULL, FALSE, FALSE, NULL); if (!thefile->pOverlapped->hEvent) { rv = apr_get_os_error(); return rv; } } /* Handle the ungetchar if there is one */ if (thefile->ungetchar != -1) { bytes_read = 1; *(char *)buf = (char)thefile->ungetchar; buf = (char *)buf + 1; (*len)--; thefile->ungetchar = -1; if (*len == 0) { *len = bytes_read; return APR_SUCCESS; } } if (thefile->buffered) { char *pos = (char *)buf; apr_size_t blocksize; apr_size_t size = *len; apr_thread_mutex_lock(thefile->mutex); if (thefile->direction == 1) { rv = apr_file_flush(thefile); if (rv != APR_SUCCESS) { apr_thread_mutex_unlock(thefile->mutex); return rv; } thefile->bufpos = 0; thefile->direction = 0; thefile->dataRead = 0; } rv = 0; while (rv == 0 && size > 0) { if (thefile->bufpos >= thefile->dataRead) { apr_size_t read; rv = read_with_timeout(thefile, thefile->buffer, thefile->bufsize, &read); if (read == 0) { if (rv == APR_EOF) thefile->eof_hit = TRUE; break; } else { thefile->dataRead = read; thefile->filePtr += thefile->dataRead; thefile->bufpos = 0; } } blocksize = size > thefile->dataRead - thefile->bufpos ? thefile->dataRead - thefile->bufpos : size; memcpy(pos, thefile->buffer + thefile->bufpos, blocksize); thefile->bufpos += blocksize; pos += blocksize; size -= blocksize; } *len = pos - (char *)buf; if (*len) { rv = APR_SUCCESS; } apr_thread_mutex_unlock(thefile->mutex); } else { /* Unbuffered i/o */ apr_size_t nbytes; rv = read_with_timeout(thefile, buf, *len, &nbytes); if (rv == APR_EOF) thefile->eof_hit = TRUE; *len = nbytes; } return rv; } APR_DECLARE(apr_status_t) apr_file_write(apr_file_t *thefile, const void *buf, apr_size_t *nbytes) { apr_status_t rv; DWORD bwrote; /* If the file is open for xthread support, allocate and * initialize the overlapped and io completion event (hEvent). * Threads should NOT share an apr_file_t or its hEvent. */ if ((thefile->flags & APR_XTHREAD) && !thefile->pOverlapped ) { thefile->pOverlapped = (OVERLAPPED*) apr_pcalloc(thefile->pool, sizeof(OVERLAPPED)); thefile->pOverlapped->hEvent = CreateEvent(NULL, FALSE, FALSE, NULL); if (!thefile->pOverlapped->hEvent) { rv = apr_get_os_error(); return rv; } } if (thefile->buffered) { char *pos = (char *)buf; apr_size_t blocksize; apr_size_t size = *nbytes; apr_thread_mutex_lock(thefile->mutex); if (thefile->direction == 0) { // Position file pointer for writing at the offset we are logically reading from apr_off_t offset = thefile->filePtr - thefile->dataRead + thefile->bufpos; DWORD offlo = (DWORD)offset; DWORD offhi = (DWORD)(offset >> 32); if (offset != thefile->filePtr) SetFilePointer(thefile->filehand, offlo, &offhi, FILE_BEGIN); thefile->bufpos = thefile->dataRead = 0; thefile->direction = 1; } rv = 0; while (rv == 0 && size > 0) { if (thefile->bufpos == thefile->bufsize) // write buffer is full rv = apr_file_flush(thefile); blocksize = size > thefile->bufsize - thefile->bufpos ? thefile->bufsize - thefile->bufpos : size; memcpy(thefile->buffer + thefile->bufpos, pos, blocksize); thefile->bufpos += blocksize; pos += blocksize; size -= blocksize; } apr_thread_mutex_unlock(thefile->mutex); return rv; } else { if (!thefile->pipe) { apr_off_t offset = 0; apr_status_t rc; if (thefile->append) { /* apr_file_lock will mutex the file across processes. * The call to apr_thread_mutex_lock is added to avoid * a race condition between LockFile and WriteFile * that occasionally leads to deadlocked threads. */ apr_thread_mutex_lock(thefile->mutex); rc = apr_file_lock(thefile, APR_FLOCK_EXCLUSIVE); if (rc != APR_SUCCESS) { apr_thread_mutex_unlock(thefile->mutex); return rc; } rc = apr_file_seek(thefile, APR_END, &offset); if (rc != APR_SUCCESS) { apr_thread_mutex_unlock(thefile->mutex); return rc; } } if (thefile->pOverlapped) { thefile->pOverlapped->Offset = (DWORD)thefile->filePtr; thefile->pOverlapped->OffsetHigh = (DWORD)(thefile->filePtr >> 32); } rv = WriteFile(thefile->filehand, buf, (DWORD)*nbytes, &bwrote, thefile->pOverlapped); if (thefile->append) { apr_file_unlock(thefile); apr_thread_mutex_unlock(thefile->mutex); } } else { rv = WriteFile(thefile->filehand, buf, (DWORD)*nbytes, &bwrote, thefile->pOverlapped); } if (rv) { *nbytes = bwrote; rv = APR_SUCCESS; } else { (*nbytes) = 0; rv = apr_get_os_error(); /* XXX: This must be corrected, per the apr_file_read logic!!! */ if (rv == APR_FROM_OS_ERROR(ERROR_IO_PENDING)) { DWORD timeout_ms; if (thefile->timeout == 0) { timeout_ms = 0; } else if (thefile->timeout < 0) { timeout_ms = INFINITE; } else { timeout_ms = (DWORD)(thefile->timeout / 1000); } rv = WaitForSingleObject(thefile->pOverlapped->hEvent, timeout_ms); switch (rv) { case WAIT_OBJECT_0: GetOverlappedResult(thefile->filehand, thefile->pOverlapped, &bwrote, TRUE); *nbytes = bwrote; rv = APR_SUCCESS; break; case WAIT_TIMEOUT: rv = (timeout_ms == 0) ? APR_EAGAIN : APR_TIMEUP; break; case WAIT_FAILED: rv = apr_get_os_error(); break; default: break; } if (rv != APR_SUCCESS) { if (apr_os_level >= APR_WIN_98) CancelIo(thefile->filehand); } } } if (rv == APR_SUCCESS && thefile->pOverlapped && !thefile->pipe) { thefile->filePtr += *nbytes; } } return rv; } /* ToDo: Write for it anyway and test the oslevel! * Too bad WriteFileGather() is not supported on 95&98 (or NT prior to SP2) */ APR_DECLARE(apr_status_t) apr_file_writev(apr_file_t *thefile, const struct iovec *vec, apr_size_t nvec, apr_size_t *nbytes) { apr_status_t rv = APR_SUCCESS; apr_size_t i; apr_size_t bwrote = 0; char *buf; *nbytes = 0; for (i = 0; i < nvec; i++) { buf = vec[i].iov_base; bwrote = vec[i].iov_len; rv = apr_file_write(thefile, buf, &bwrote); *nbytes += bwrote; if (rv != APR_SUCCESS) { break; } } return rv; } APR_DECLARE(apr_status_t) apr_file_putc(char ch, apr_file_t *thefile) { apr_size_t len = 1; return apr_file_write(thefile, &ch, &len); } APR_DECLARE(apr_status_t) apr_file_ungetc(char ch, apr_file_t *thefile) { thefile->ungetchar = (unsigned char) ch; return APR_SUCCESS; } APR_DECLARE(apr_status_t) apr_file_getc(char *ch, apr_file_t *thefile) { apr_status_t rc; apr_size_t bread; bread = 1; rc = apr_file_read(thefile, ch, &bread); if (rc) { return rc; } if (bread == 0) { thefile->eof_hit = TRUE; return APR_EOF; } return APR_SUCCESS; } APR_DECLARE(apr_status_t) apr_file_puts(const char *str, apr_file_t *thefile) { apr_size_t len = strlen(str); return apr_file_write(thefile, str, &len); } APR_DECLARE(apr_status_t) apr_file_gets(char *str, int len, apr_file_t *thefile) { apr_size_t readlen; apr_status_t rv = APR_SUCCESS; int i; for (i = 0; i < len-1; i++) { readlen = 1; rv = apr_file_read(thefile, str+i, &readlen); if (rv != APR_SUCCESS && rv != APR_EOF) return rv; if (readlen == 0) { /* If we have bytes, defer APR_EOF to the next call */ if (i > 0) rv = APR_SUCCESS; break; } if (str[i] == '\n') { i++; /* don't clobber this char below */ break; } } str[i] = 0; return rv; } APR_DECLARE(apr_status_t) apr_file_flush(apr_file_t *thefile) { if (thefile->buffered) { DWORD numbytes, written = 0; apr_status_t rc = 0; char *buffer; apr_size_t bytesleft; if (thefile->direction == 1 && thefile->bufpos) { buffer = thefile->buffer; bytesleft = thefile->bufpos; do { if (bytesleft > APR_DWORD_MAX) { numbytes = APR_DWORD_MAX; } else { numbytes = (DWORD)bytesleft; } if (!WriteFile(thefile->filehand, buffer, numbytes, &written, NULL)) { rc = apr_get_os_error(); thefile->filePtr += written; break; } thefile->filePtr += written; bytesleft -= written; buffer += written; } while (bytesleft > 0); if (rc == 0) thefile->bufpos = 0; } return rc; } /* There isn't anything to do if we aren't buffering the output * so just return success. */ return APR_SUCCESS; } struct apr_file_printf_data { apr_vformatter_buff_t vbuff; apr_file_t *fptr; char *buf; }; static int file_printf_flush(apr_vformatter_buff_t *buff) { struct apr_file_printf_data *data = (struct apr_file_printf_data *)buff; if (apr_file_write_full(data->fptr, data->buf, data->vbuff.curpos - data->buf, NULL)) { return -1; } data->vbuff.curpos = data->buf; return 0; } APR_DECLARE_NONSTD(int) apr_file_printf(apr_file_t *fptr, const char *format, ...) { struct apr_file_printf_data data; va_list ap; int count; data.buf = malloc(HUGE_STRING_LEN); if (data.buf == NULL) { return 0; } data.vbuff.curpos = data.buf; data.vbuff.endpos = data.buf + HUGE_STRING_LEN; data.fptr = fptr; va_start(ap, format); count = apr_vformatter(file_printf_flush, (apr_vformatter_buff_t *)&data, format, ap); /* apr_vformatter does not call flush for the last bits */ if (count >= 0) file_printf_flush((apr_vformatter_buff_t *)&data); va_end(ap); free(data.buf); return count; }
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