/* 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_strings.h" #include "apr_thread_mutex.h" #include "apr_support.h" /* The only case where we don't use wait_for_io_or_timeout is on * pre-BONE BeOS, so this check should be sufficient and simpler */ #if !BEOS_R5 #define USE_WAIT_FOR_IO #endif static apr_status_t file_read_buffered(apr_file_t *thefile, void *buf, apr_size_t *nbytes) { apr_ssize_t rv; char *pos = (char *)buf; apr_uint64_t blocksize; apr_uint64_t size = *nbytes; if (thefile->direction == 1) { rv = apr_file_flush_locked(thefile); if (rv) { return rv; } thefile->bufpos = 0; thefile->direction = 0; thefile->dataRead = 0; } rv = 0; if (thefile->ungetchar != -1) { *pos = (char)thefile->ungetchar; ++pos; --size; thefile->ungetchar = -1; } while (rv == 0 && size > 0) { if (thefile->bufpos >= thefile->dataRead) { int bytesread = read(thefile->filedes, thefile->buffer, thefile->bufsize); if (bytesread == 0) { thefile->eof_hit = TRUE; rv = APR_EOF; break; } else if (bytesread == -1) { rv = errno; break; } thefile->dataRead = bytesread; 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; } *nbytes = pos - (char *)buf; if (*nbytes) { rv = 0; } return rv; } APR_DECLARE(apr_status_t) apr_file_read(apr_file_t *thefile, void *buf, apr_size_t *nbytes) { apr_ssize_t rv; apr_size_t bytes_read; if (*nbytes <= 0) { *nbytes = 0; return APR_SUCCESS; } if (thefile->buffered) { file_lock(thefile); rv = file_read_buffered(thefile, buf, nbytes); file_unlock(thefile); return rv; } else { bytes_read = 0; if (thefile->ungetchar != -1) { bytes_read = 1; *(char *)buf = (char)thefile->ungetchar; buf = (char *)buf + 1; (*nbytes)--; thefile->ungetchar = -1; if (*nbytes == 0) { *nbytes = bytes_read; return APR_SUCCESS; } } do { rv = read(thefile->filedes, buf, *nbytes); } while (rv == -1 && errno == EINTR); #ifdef USE_WAIT_FOR_IO if (rv == -1 && (errno == EAGAIN || errno == EWOULDBLOCK) && thefile->timeout != 0) { apr_status_t arv = apr_wait_for_io_or_timeout(thefile, NULL, 1); if (arv != APR_SUCCESS) { *nbytes = bytes_read; return arv; } else { do { rv = read(thefile->filedes, buf, *nbytes); } while (rv == -1 && errno == EINTR); } } #endif *nbytes = bytes_read; if (rv == 0) { thefile->eof_hit = TRUE; return APR_EOF; } if (rv > 0) { *nbytes += rv; return APR_SUCCESS; } return errno; } } APR_DECLARE(apr_status_t) apr_file_write(apr_file_t *thefile, const void *buf, apr_size_t *nbytes) { apr_size_t rv; if (thefile->buffered) { char *pos = (char *)buf; int blocksize; int size = *nbytes; file_lock(thefile); if ( thefile->direction == 0 ) { /* Position file pointer for writing at the offset we are * logically reading from */ apr_int64_t offset = thefile->filePtr - thefile->dataRead + thefile->bufpos; if (offset != thefile->filePtr) lseek(thefile->filedes, offset, SEEK_SET); 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_locked(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; } file_unlock(thefile); return rv; } else { do { rv = write(thefile->filedes, buf, *nbytes); } while (rv == (apr_size_t)-1 && errno == EINTR); #ifdef USE_WAIT_FOR_IO if (rv == (apr_size_t)-1 && (errno == EAGAIN || errno == EWOULDBLOCK) && thefile->timeout != 0) { apr_status_t arv = apr_wait_for_io_or_timeout(thefile, NULL, 0); if (arv != APR_SUCCESS) { *nbytes = 0; return arv; } else { do { do { rv = write(thefile->filedes, buf, *nbytes); } while (rv == (apr_size_t)-1 && errno == EINTR); if (rv == (apr_size_t)-1 && (errno == EAGAIN || errno == EWOULDBLOCK)) { *nbytes /= 2; /* yes, we'll loop if kernel lied * and we can't even write 1 byte */ } else { break; } } while (1); } } #endif if (rv == (apr_size_t)-1) { (*nbytes) = 0; return errno; } *nbytes = rv; return APR_SUCCESS; } } APR_DECLARE(apr_status_t) apr_file_writev(apr_file_t *thefile, const struct iovec *vec, apr_size_t nvec, apr_size_t *nbytes) { #ifdef HAVE_WRITEV apr_status_t rv; apr_ssize_t bytes; if (thefile->buffered) { file_lock(thefile); rv = apr_file_flush_locked(thefile); if (rv != APR_SUCCESS) { file_unlock(thefile); return rv; } if (thefile->direction == 0) { /* Position file pointer for writing at the offset we are * logically reading from */ apr_int64_t offset = thefile->filePtr - thefile->dataRead + thefile->bufpos; if (offset != thefile->filePtr) lseek(thefile->filedes, offset, SEEK_SET); thefile->bufpos = thefile->dataRead = 0; } file_unlock(thefile); } if ((bytes = writev(thefile->filedes, vec, nvec)) < 0) { *nbytes = 0; rv = errno; } else { *nbytes = bytes; rv = APR_SUCCESS; } return rv; #else /** * The problem with trying to output the entire iovec is that we cannot * maintain the behaviour that a real writev would have. If we iterate * over the iovec one at a time, we lose the atomic properties of * writev(). The other option is to combine the entire iovec into one * buffer that we could then send in one call to write(). This is not * reasonable since we do not know how much data an iovec could contain. * * The only reasonable option, that maintains the semantics of a real * writev(), is to only write the first iovec. Callers of file_writev() * must deal with partial writes as they normally would. If you want to * ensure an entire iovec is written, use apr_file_writev_full(). */ *nbytes = vec[0].iov_len; return apr_file_write(thefile, vec[0].iov_base, nbytes); #endif } APR_DECLARE(apr_status_t) apr_file_putc(char ch, apr_file_t *thefile) { apr_size_t nbytes = 1; return apr_file_write(thefile, &ch, &nbytes); } 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_size_t nbytes = 1; return apr_file_read(thefile, ch, &nbytes); } APR_DECLARE(apr_status_t) apr_file_puts(const char *str, apr_file_t *thefile) { return apr_file_write_full(thefile, str, strlen(str), NULL); } apr_status_t apr_file_flush_locked(apr_file_t *thefile) { apr_status_t rv = APR_SUCCESS; if (thefile->direction == 1 && thefile->bufpos) { apr_ssize_t written = 0, ret; do { ret = write(thefile->filedes, thefile->buffer + written, thefile->bufpos - written); if (ret > 0) written += ret; } while (written < thefile->bufpos && (ret > 0 || (ret == -1 && errno == EINTR))); if (ret == -1) { rv = errno; } else { thefile->filePtr += written; thefile->bufpos = 0; } } return rv; } APR_DECLARE(apr_status_t) apr_file_flush(apr_file_t *thefile) { apr_status_t rv = APR_SUCCESS; if (thefile->buffered) { file_lock(thefile); rv = apr_file_flush_locked(thefile); file_unlock(thefile); } /* There isn't anything to do if we aren't buffering the output * so just return success. */ return rv; } APR_DECLARE(apr_status_t) apr_file_sync(apr_file_t *thefile) { apr_status_t rv = APR_SUCCESS; file_lock(thefile); if (thefile->buffered) { rv = apr_file_flush_locked(thefile); if (rv != APR_SUCCESS) { file_unlock(thefile); return rv; } } if (fsync(thefile->filedes)) { rv = apr_get_os_error(); } file_unlock(thefile); return rv; } APR_DECLARE(apr_status_t) apr_file_datasync(apr_file_t *thefile) { apr_status_t rv = APR_SUCCESS; file_lock(thefile); if (thefile->buffered) { rv = apr_file_flush_locked(thefile); if (rv != APR_SUCCESS) { file_unlock(thefile); return rv; } } #ifdef HAVE_FDATASYNC if (fdatasync(thefile->filedes)) { #else if (fsync(thefile->filedes)) { #endif rv = apr_get_os_error(); } file_unlock(thefile); return rv; } APR_DECLARE(apr_status_t) apr_file_gets(char *str, int len, apr_file_t *thefile) { apr_status_t rv = APR_SUCCESS; /* get rid of gcc warning */ apr_size_t nbytes; const char *str_start = str; char *final = str + len - 1; if (len <= 1) { /* sort of like fgets(), which returns NULL and stores no bytes */ return APR_SUCCESS; } /* If we have an underlying buffer, we can be *much* more efficient * and skip over the apr_file_read calls. */ if (thefile->buffered) { file_lock(thefile); if (thefile->direction == 1) { rv = apr_file_flush_locked(thefile); if (rv) { file_unlock(thefile); return rv; } thefile->direction = 0; thefile->bufpos = 0; thefile->dataRead = 0; } while (str < final) { /* leave room for trailing '\0' */ /* Force ungetc leftover to call apr_file_read. */ if (thefile->bufpos < thefile->dataRead && thefile->ungetchar == -1) { *str = thefile->buffer[thefile->bufpos++]; } else { nbytes = 1; rv = file_read_buffered(thefile, str, &nbytes); if (rv != APR_SUCCESS) { break; } } if (*str == '\n') { ++str; break; } ++str; } file_unlock(thefile); } else { while (str < final) { /* leave room for trailing '\0' */ nbytes = 1; rv = apr_file_read(thefile, str, &nbytes); if (rv != APR_SUCCESS) { break; } if (*str == '\n') { ++str; break; } ++str; } } /* We must store a terminating '\0' if we've stored any chars. We can * get away with storing it if we hit an error first. */ *str = '\0'; if (str > str_start) { /* we stored chars; don't report EOF or any other errors; * the app will find out about that on the next call */ return APR_SUCCESS; } return rv; } 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; /* don't really need a HUGE_STRING_LEN anymore */ data.buf = malloc(HUGE_STRING_LEN); if (data.buf == NULL) { return -1; } 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; }