LineageOS/android_external_rsync
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8ee6adefe38a00af526ce15c51a24580bea0212c
android_external_rsync/io.c
Wayne Davison 626bec8e84 - Added maybe_flush_socket() for use by the generator. 
- Always maintain the last_io value for the generator.
2005-04-05 20:07:42 +00:00

1386 lines
32 KiB
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/* -*- c-file-style: "linux" -*-
*
* Copyright (C) 1996-2001 by Andrew Tridgell
* Copyright (C) Paul Mackerras 1996
* Copyright (C) 2001, 2002 by Martin Pool <mbp@samba.org>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
/**
* @file io.c
*
* Socket and pipe I/O utilities used in rsync.
*
* rsync provides its own multiplexing system, which is used to send
* stderr and stdout over a single socket. We need this because
* stdout normally carries the binary data stream, and stderr all our
* error messages.
*
* For historical reasons this is off during the start of the
* connection, but it's switched on quite early using
* io_start_multiplex_out() and io_start_multiplex_in().
**/
#include "rsync.h"
/** If no timeout is specified then use a 60 second select timeout */
#define SELECT_TIMEOUT 60
extern int bwlimit;
extern size_t bwlimit_writemax;
extern int verbose;
extern int io_timeout;
extern int allowed_lull;
extern int am_server;
extern int am_daemon;
extern int am_sender;
extern int am_generator;
extern int eol_nulls;
extern int csum_length;
extern int checksum_seed;
extern int protocol_version;
extern int remove_sent_files;
extern int preserve_hard_links;
extern char *filesfrom_host;
extern struct stats stats;
extern struct file_list *the_file_list;
const char phase_unknown[] = "unknown";
int select_timeout = SELECT_TIMEOUT;
int ignore_timeout = 0;
int batch_fd = -1;
int batch_gen_fd = -1;
/**
* The connection might be dropped at some point; perhaps because the
* remote instance crashed. Just giving the offset on the stream is
* not very helpful. So instead we try to make io_phase_name point to
* something useful.
*
* For buffered/multiplexed I/O these names will be somewhat
* approximate; perhaps for ease of support we would rather make the
* buffer always flush when a single application-level I/O finishes.
*
* @todo Perhaps we want some simple stack functionality, but there's
* no need to overdo it.
**/
const char *io_write_phase = phase_unknown;
const char *io_read_phase = phase_unknown;
/* Ignore an EOF error if non-zero. See whine_about_eof(). */
int kluge_around_eof = 0;
int msg_fd_in = -1;
int msg_fd_out = -1;
int sock_f_in = -1;
int sock_f_out = -1;
static int io_multiplexing_out;
static int io_multiplexing_in;
static time_t last_io;
static int no_flush;
static int write_batch_monitor_in = -1;
static int write_batch_monitor_out = -1;
static int io_filesfrom_f_in = -1;
static int io_filesfrom_f_out = -1;
static char io_filesfrom_buf[2048];
static char *io_filesfrom_bp;
static char io_filesfrom_lastchar;
static int io_filesfrom_buflen;
static size_t contiguous_write_len = 0;
static void read_loop(int fd, char *buf, size_t len);
struct flist_ndx_item {
struct flist_ndx_item *next;
int ndx;
};
struct flist_ndx_list {
struct flist_ndx_item *head, *tail;
};
static struct flist_ndx_list redo_list, hlink_list;
struct msg_list {
struct msg_list *next;
char *buf;
int len;
};
static struct msg_list *msg_list_head;
static struct msg_list *msg_list_tail;
static void flist_ndx_push(struct flist_ndx_list *lp, int ndx)
{
struct flist_ndx_item *item;
if (!(item = new(struct flist_ndx_item)))
out_of_memory("flist_ndx_push");
item->next = NULL;
item->ndx = ndx;
if (lp->tail)
lp->tail->next = item;
else
lp->head = item;
lp->tail = item;
}
static int flist_ndx_pop(struct flist_ndx_list *lp)
{
struct flist_ndx_item *next;
int ndx;
if (!lp->head)
return -1;
ndx = lp->head->ndx;
next = lp->head->next;
free(lp->head);
lp->head = next;
if (!next)
lp->tail = NULL;
return ndx;
}
static void check_timeout(void)
{
time_t t;
if (!io_timeout || ignore_timeout)
return;
if (!last_io) {
last_io = time(NULL);
return;
}
t = time(NULL);
if (t - last_io >= io_timeout) {
if (!am_server && !am_daemon) {
rprintf(FERROR, "io timeout after %d seconds -- exiting\n",
(int)(t-last_io));
}
exit_cleanup(RERR_TIMEOUT);
}
}
/* Note the fds used for the main socket (which might really be a pipe
* for a local transfer, but we can ignore that). */
void io_set_sock_fds(int f_in, int f_out)
{
sock_f_in = f_in;
sock_f_out = f_out;
}
/* Setup the fd used to receive MSG_* messages. Only needed during the
* early stages of being a local sender (up through the sending of the
* file list) or when we're the generator (to fetch the messages from
* the receiver). */
void set_msg_fd_in(int fd)
{
msg_fd_in = fd;
}
/* Setup the fd used to send our MSG_* messages. Only needed when
* we're the receiver (to send our messages to the generator). */
void set_msg_fd_out(int fd)
{
msg_fd_out = fd;
set_nonblocking(msg_fd_out);
}
/* Add a message to the pending MSG_* list. */
static void msg_list_add(int code, char *buf, int len)
{
struct msg_list *ml;
if (!(ml = new(struct msg_list)))
out_of_memory("msg_list_add");
ml->next = NULL;
if (!(ml->buf = new_array(char, len+4)))
out_of_memory("msg_list_add");
SIVAL(ml->buf, 0, ((code+MPLEX_BASE)<<24) | len);
memcpy(ml->buf+4, buf, len);
ml->len = len+4;
if (msg_list_tail)
msg_list_tail->next = ml;
else
msg_list_head = ml;
msg_list_tail = ml;
}
void send_msg(enum msgcode code, char *buf, int len)
{
if (msg_fd_out < 0) {
io_multiplex_write(code, buf, len);
return;
}
msg_list_add(code, buf, len);
msg_list_push(NORMAL_FLUSH);
}
/* Read a message from the MSG_* fd and handle it. This is called either
* during the early stages of being a local sender (up through the sending
* of the file list) or when we're the generator (to fetch the messages
* from the receiver). */
static void read_msg_fd(void)
{
char buf[2048];
size_t n;
int fd = msg_fd_in;
int tag, len;
/* Temporarily disable msg_fd_in. This is needed to avoid looping back
* to this routine from writefd_unbuffered(). */
msg_fd_in = -1;
read_loop(fd, buf, 4);
tag = IVAL(buf, 0);
len = tag & 0xFFFFFF;
tag = (tag >> 24) - MPLEX_BASE;
switch (tag) {
case MSG_DONE:
if (len != 0 || !am_generator) {
rprintf(FERROR, "invalid message %d:%d\n", tag, len);
exit_cleanup(RERR_STREAMIO);
}
flist_ndx_push(&redo_list, -1);
break;
case MSG_REDO:
if (len != 4 || !am_generator) {
rprintf(FERROR, "invalid message %d:%d\n", tag, len);
exit_cleanup(RERR_STREAMIO);
}
read_loop(fd, buf, 4);
flist_ndx_push(&redo_list, IVAL(buf,0));
break;
case MSG_DELETED:
if (len >= (int)sizeof buf || !am_generator) {
rprintf(FERROR, "invalid message %d:%d\n", tag, len);
exit_cleanup(RERR_STREAMIO);
}
read_loop(fd, buf, len);
io_multiplex_write(MSG_DELETED, buf, len);
break;
case MSG_SUCCESS:
if (len != 4 || !am_generator) {
rprintf(FERROR, "invalid message %d:%d\n", tag, len);
exit_cleanup(RERR_STREAMIO);
}
read_loop(fd, buf, len);
if (remove_sent_files)
io_multiplex_write(MSG_SUCCESS, buf, len);
if (preserve_hard_links)
flist_ndx_push(&hlink_list, IVAL(buf,0));
break;
case MSG_INFO:
case MSG_ERROR:
case MSG_LOG:
while (len) {
n = len;
if (n >= sizeof buf)
n = sizeof buf - 1;
read_loop(fd, buf, n);
rwrite((enum logcode)tag, buf, n);
len -= n;
}
break;
default:
rprintf(FERROR, "unknown message %d:%d\n", tag, len);
exit_cleanup(RERR_STREAMIO);
}
msg_fd_in = fd;
}
/* Try to push messages off the list onto the wire. If we leave with more
* to do, return 0. On error, return -1. If everything flushed, return 1.
* This is only active in the receiver. */
int msg_list_push(int flush_it_all)
{
static int written = 0;
struct timeval tv;
fd_set fds;
if (msg_fd_out < 0)
return -1;
while (msg_list_head) {
struct msg_list *ml = msg_list_head;
int n = write(msg_fd_out, ml->buf + written, ml->len - written);
if (n < 0) {
if (errno == EINTR)
continue;
if (errno != EWOULDBLOCK && errno != EAGAIN)
return -1;
if (!flush_it_all)
return 0;
FD_ZERO(&fds);
FD_SET(msg_fd_out, &fds);
tv.tv_sec = select_timeout;
tv.tv_usec = 0;
if (!select(msg_fd_out+1, NULL, &fds, NULL, &tv))
check_timeout();
} else if ((written += n) == ml->len) {
free(ml->buf);
msg_list_head = ml->next;
if (!msg_list_head)
msg_list_tail = NULL;
free(ml);
written = 0;
}
}
return 1;
}
int get_redo_num(int itemizing, enum logcode code)
{
while (1) {
if (hlink_list.head)
check_for_finished_hlinks(itemizing, code);
if (redo_list.head)
break;
read_msg_fd();
}
return flist_ndx_pop(&redo_list);
}
int get_hlink_num(void)
{
return flist_ndx_pop(&hlink_list);
}
/**
* When we're the receiver and we have a local --files-from list of names
* that needs to be sent over the socket to the sender, we have to do two
* things at the same time: send the sender a list of what files we're
* processing and read the incoming file+info list from the sender. We do
* this by augmenting the read_timeout() function to copy this data. It
* uses the io_filesfrom_buf to read a block of data from f_in (when it is
* ready, since it might be a pipe) and then blast it out f_out (when it
* is ready to receive more data).
*/
void io_set_filesfrom_fds(int f_in, int f_out)
{
io_filesfrom_f_in = f_in;
io_filesfrom_f_out = f_out;
io_filesfrom_bp = io_filesfrom_buf;
io_filesfrom_lastchar = '\0';
io_filesfrom_buflen = 0;
}
/* It's almost always an error to get an EOF when we're trying to read from the
* network, because the protocol is (for the most part) self-terminating.
*
* There is one case for the receiver when it is at the end of the transfer
* (hanging around reading any keep-alive packets that might come its way): if
* the sender dies before the generator's kill-signal comes through, we can end
* up here needing to loop until the kill-signal arrives. In this situation,
* kluge_around_eof will be < 0.
*
* There is another case for older protocol versions (< 24) where the module
* listing was not terminated, so we must ignore an EOF error in that case and
* exit. In this situation, kluge_around_eof will be > 0. */
static void whine_about_eof(int fd)
{
if (kluge_around_eof && fd == sock_f_in) {
int i;
if (kluge_around_eof > 0)
exit_cleanup(0);
/* If we're still here after 10 seconds, exit with an error. */
for (i = 10*1000/20; i--; )
msleep(20);
}
rprintf(FERROR, RSYNC_NAME ": connection unexpectedly closed "
"(%.0f bytes received so far) [%s]\n",
(double)stats.total_read, who_am_i());
exit_cleanup(RERR_STREAMIO);
}
/**
* Read from a socket with I/O timeout. return the number of bytes
* read. If no bytes can be read then exit, never return a number <= 0.
*
* TODO: If the remote shell connection fails, then current versions
* actually report an "unexpected EOF" error here. Since it's a
* fairly common mistake to try to use rsh when ssh is required, we
* should trap that: if we fail to read any data at all, we should
* give a better explanation. We can tell whether the connection has
* started by looking e.g. at whether the remote version is known yet.
*/
static int read_timeout(int fd, char *buf, size_t len)
{
int n, ret = 0;
io_flush(NORMAL_FLUSH);
while (ret == 0) {
/* until we manage to read *something* */
fd_set r_fds, w_fds;
struct timeval tv;
int maxfd = fd;
int count;
FD_ZERO(&r_fds);
FD_ZERO(&w_fds);
FD_SET(fd, &r_fds);
if (msg_list_head) {
FD_SET(msg_fd_out, &w_fds);
if (msg_fd_out > maxfd)
maxfd = msg_fd_out;
}
if (io_filesfrom_f_out >= 0) {
int new_fd;
if (io_filesfrom_buflen == 0) {
if (io_filesfrom_f_in >= 0) {
FD_SET(io_filesfrom_f_in, &r_fds);
new_fd = io_filesfrom_f_in;
} else {
io_filesfrom_f_out = -1;
new_fd = -1;
}
} else {
FD_SET(io_filesfrom_f_out, &w_fds);
new_fd = io_filesfrom_f_out;
}
if (new_fd > maxfd)
maxfd = new_fd;
}
tv.tv_sec = select_timeout;
tv.tv_usec = 0;
errno = 0;
count = select(maxfd + 1, &r_fds, &w_fds, NULL, &tv);
if (count <= 0) {
if (errno == EBADF)
exit_cleanup(RERR_SOCKETIO);
check_timeout();
continue;
}
if (msg_list_head && FD_ISSET(msg_fd_out, &w_fds))
msg_list_push(NORMAL_FLUSH);
if (io_filesfrom_f_out >= 0) {
if (io_filesfrom_buflen) {
if (FD_ISSET(io_filesfrom_f_out, &w_fds)) {
int l = write(io_filesfrom_f_out,
io_filesfrom_bp,
io_filesfrom_buflen);
if (l > 0) {
if (!(io_filesfrom_buflen -= l))
io_filesfrom_bp = io_filesfrom_buf;
else
io_filesfrom_bp += l;
} else {
/* XXX should we complain? */
io_filesfrom_f_out = -1;
}
}
} else if (io_filesfrom_f_in >= 0) {
if (FD_ISSET(io_filesfrom_f_in, &r_fds)) {
int l = read(io_filesfrom_f_in,
io_filesfrom_buf,
sizeof io_filesfrom_buf);
if (l <= 0) {
/* Send end-of-file marker */
io_filesfrom_buf[0] = '\0';
io_filesfrom_buf[1] = '\0';
io_filesfrom_buflen = io_filesfrom_lastchar? 2 : 1;
io_filesfrom_f_in = -1;
} else {
if (!eol_nulls) {
char *s = io_filesfrom_buf + l;
/* Transform CR and/or LF into '\0' */
while (s-- > io_filesfrom_buf) {
if (*s == '\n' || *s == '\r')
*s = '\0';
}
}
if (!io_filesfrom_lastchar) {
/* Last buf ended with a '\0', so don't
* let this buf start with one. */
while (l && !*io_filesfrom_bp)
io_filesfrom_bp++, l--;
}
if (!l)
io_filesfrom_bp = io_filesfrom_buf;
else {
char *f = io_filesfrom_bp;
char *t = f;
char *eob = f + l;
/* Eliminate any multi-'\0' runs. */
while (f != eob) {
if (!(*t++ = *f++)) {
while (f != eob && !*f)
f++, l--;
}
}
io_filesfrom_lastchar = f[-1];
}
io_filesfrom_buflen = l;
}
}
}
}
if (!FD_ISSET(fd, &r_fds))
continue;
n = read(fd, buf, len);
if (n <= 0) {
if (n == 0)
whine_about_eof(fd); /* Doesn't return. */
if (errno == EINTR || errno == EWOULDBLOCK
|| errno == EAGAIN)
continue;
/* Don't write errors on a dead socket. */
if (fd == sock_f_in)
close_multiplexing_out();
rsyserr(FERROR, errno, "read error");
exit_cleanup(RERR_STREAMIO);
}
buf += n;
len -= n;
ret += n;
if (fd == sock_f_in && (io_timeout || am_generator))
last_io = time(NULL);
}
return ret;
}
/**
* Read a line into the "fname" buffer (which must be at least MAXPATHLEN
* characters long).
*/
int read_filesfrom_line(int fd, char *fname)
{
char ch, *s, *eob = fname + MAXPATHLEN - 1;
int cnt;
int reading_remotely = filesfrom_host != NULL;
int nulls = eol_nulls || reading_remotely;
start:
s = fname;
while (1) {
cnt = read(fd, &ch, 1);
if (cnt < 0 && (errno == EWOULDBLOCK
|| errno == EINTR || errno == EAGAIN)) {
struct timeval tv;
fd_set fds;
FD_ZERO(&fds);
FD_SET(fd, &fds);
tv.tv_sec = select_timeout;
tv.tv_usec = 0;
if (!select(fd+1, &fds, NULL, NULL, &tv))
check_timeout();
continue;
}
if (cnt != 1)
break;
if (nulls? !ch : (ch == '\r' || ch == '\n')) {
/* Skip empty lines if reading locally. */
if (!reading_remotely && s == fname)
continue;
break;
}
if (s < eob)
*s++ = ch;
}
*s = '\0';
/* Dump comments. */
if (*fname == '#' || *fname == ';')
goto start;
return s - fname;
}
static char *iobuf_out;
static int iobuf_out_cnt;
void io_start_buffering_out(void)
{
if (iobuf_out)
return;
if (!(iobuf_out = new_array(char, IO_BUFFER_SIZE)))
out_of_memory("io_start_buffering_out");
iobuf_out_cnt = 0;
}
static char *iobuf_in;
static size_t iobuf_in_siz;
void io_start_buffering_in(void)
{
if (iobuf_in)
return;
iobuf_in_siz = 2 * IO_BUFFER_SIZE;
if (!(iobuf_in = new_array(char, iobuf_in_siz)))
out_of_memory("io_start_buffering_in");
}
void io_end_buffering(void)
{
io_flush(NORMAL_FLUSH);
if (!io_multiplexing_out) {
free(iobuf_out);
iobuf_out = NULL;
}
}
void maybe_flush_socket(void)
{
if (iobuf_out && iobuf_out_cnt && time(NULL) - last_io >= 5)
io_flush(NORMAL_FLUSH);
}
void maybe_send_keepalive(void)
{
if (time(NULL) - last_io >= allowed_lull) {
if (!iobuf_out || !iobuf_out_cnt) {
if (protocol_version < 29)
return; /* there's nothing we can do */
write_int(sock_f_out, the_file_list->count);
write_shortint(sock_f_out, ITEM_IS_NEW);
}
if (iobuf_out)
io_flush(NORMAL_FLUSH);
}
}
/**
* Continue trying to read len bytes - don't return until len has been
* read.
**/
static void read_loop(int fd, char *buf, size_t len)
{
while (len) {
int n = read_timeout(fd, buf, len);
buf += n;
len -= n;
}
}
/**
* Read from the file descriptor handling multiplexing - return number
* of bytes read.
*
* Never returns <= 0.
*/
static int readfd_unbuffered(int fd, char *buf, size_t len)
{
static size_t remaining;
static size_t iobuf_in_ndx;
int tag, ret = 0;
#if MAXPATHLEN < 4096
char line[4096+1024];
#else
char line[MAXPATHLEN+1024];
#endif
if (!iobuf_in || fd != sock_f_in)
return read_timeout(fd, buf, len);
if (!io_multiplexing_in && remaining == 0) {
remaining = read_timeout(fd, iobuf_in, iobuf_in_siz);
iobuf_in_ndx = 0;
}
while (ret == 0) {
if (remaining) {
len = MIN(len, remaining);
memcpy(buf, iobuf_in + iobuf_in_ndx, len);
iobuf_in_ndx += len;
remaining -= len;
ret = len;
break;
}
read_loop(fd, line, 4);
tag = IVAL(line, 0);
remaining = tag & 0xFFFFFF;
tag = (tag >> 24) - MPLEX_BASE;
switch (tag) {
case MSG_DATA:
if (remaining > iobuf_in_siz) {
if (!(iobuf_in = realloc_array(iobuf_in, char,
remaining)))
out_of_memory("readfd_unbuffered");
iobuf_in_siz = remaining;
}
read_loop(fd, iobuf_in, remaining);
iobuf_in_ndx = 0;
break;
case MSG_DELETED:
if (remaining >= sizeof line) {
rprintf(FERROR, "invalid multi-message %d:%ld\n",
tag, (long)remaining);
exit_cleanup(RERR_STREAMIO);
}
read_loop(fd, line, remaining);
line[remaining] = '\0';
/* A directory name was sent with the trailing null */
if (remaining > 0 && !line[remaining-1])
log_delete(line, S_IFDIR);
else
log_delete(line, S_IFREG);
remaining = 0;
break;
case MSG_SUCCESS:
if (remaining != 4) {
rprintf(FERROR, "invalid multi-message %d:%ld [%s]\n",
tag, (long)remaining, who_am_i());
exit_cleanup(RERR_STREAMIO);
}
read_loop(fd, line, remaining);
successful_send(IVAL(line, 0));
remaining = 0;
break;
case MSG_INFO:
case MSG_ERROR:
if (remaining >= sizeof line) {
rprintf(FERROR,
"multiplexing overflow %d:%ld [%s]\n",
tag, (long)remaining, who_am_i());
exit_cleanup(RERR_STREAMIO);
}
read_loop(fd, line, remaining);
rwrite((enum logcode)tag, line, remaining);
remaining = 0;
break;
default:
rprintf(FERROR, "unexpected tag %d [%s]\n",
tag, who_am_i());
exit_cleanup(RERR_STREAMIO);
}
}
if (remaining == 0)
io_flush(NORMAL_FLUSH);
return ret;
}
/**
* Do a buffered read from @p fd. Don't return until all @p n bytes
* have been read. If all @p n can't be read then exit with an
* error.
**/
static void readfd(int fd, char *buffer, size_t N)
{
int ret;
size_t total = 0;
while (total < N) {
ret = readfd_unbuffered(fd, buffer + total, N-total);
total += ret;
}
if (fd == write_batch_monitor_in) {
if ((size_t)write(batch_fd, buffer, total) != total)
exit_cleanup(RERR_FILEIO);
}
if (fd == sock_f_in)
stats.total_read += total;
}
int read_shortint(int f)
{
uchar b[2];
readfd(f, (char *)b, 2);
return (b[1] << 8) + b[0];
}
int32 read_int(int f)
{
char b[4];
int32 ret;
readfd(f,b,4);
ret = IVAL(b,0);
if (ret == (int32)0xffffffff)
return -1;
return ret;
}
int64 read_longint(int f)
{
int64 ret;
char b[8];
ret = read_int(f);
if ((int32)ret != (int32)0xffffffff)
return ret;
#if SIZEOF_INT64 < 8
rprintf(FERROR, "Integer overflow: attempted 64-bit offset\n");
exit_cleanup(RERR_UNSUPPORTED);
#else
readfd(f,b,8);
ret = IVAL(b,0) | (((int64)IVAL(b,4))<<32);
#endif
return ret;
}
void read_buf(int f,char *buf,size_t len)
{
readfd(f,buf,len);
}
void read_sbuf(int f,char *buf,size_t len)
{
readfd(f, buf, len);
buf[len] = '\0';
}
uchar read_byte(int f)
{
uchar c;
readfd(f, (char *)&c, 1);
return c;
}
int read_vstring(int f, char *buf, int bufsize)
{
int len = read_byte(f);
if (len & 0x80)
len = (len & ~0x80) * 0x100 + read_byte(f);
if (len >= bufsize) {
rprintf(FERROR, "over-long vstring received (%d > %d)\n",
len, bufsize - 1);
return -1;
}
if (len)
readfd(f, buf, len);
buf[len] = '\0';
return len;
}
/* Populate a sum_struct with values from the socket. This is
* called by both the sender and the receiver. */
void read_sum_head(int f, struct sum_struct *sum)
{
sum->count = read_int(f);
sum->blength = read_int(f);
if (sum->blength < 0 || sum->blength > MAX_BLOCK_SIZE) {
rprintf(FERROR, "Invalid block length %ld [%s]\n",
(long)sum->blength, who_am_i());
exit_cleanup(RERR_PROTOCOL);
}
sum->s2length = protocol_version < 27 ? csum_length : (int)read_int(f);
if (sum->s2length < 0 || sum->s2length > MD4_SUM_LENGTH) {
rprintf(FERROR, "Invalid checksum length %d [%s]\n",
sum->s2length, who_am_i());
exit_cleanup(RERR_PROTOCOL);
}
sum->remainder = read_int(f);
if (sum->remainder < 0 || sum->remainder > sum->blength) {
rprintf(FERROR, "Invalid remainder length %ld [%s]\n",
(long)sum->remainder, who_am_i());
exit_cleanup(RERR_PROTOCOL);
}
}
/* Send the values from a sum_struct over the socket. Set sum to
* NULL if there are no checksums to send. This is called by both
* the generator and the sender. */
void write_sum_head(int f, struct sum_struct *sum)
{
static struct sum_struct null_sum;
if (sum == NULL)
sum = &null_sum;
write_int(f, sum->count);
write_int(f, sum->blength);
if (protocol_version >= 27)
write_int(f, sum->s2length);
write_int(f, sum->remainder);
}
/**
* Sleep after writing to limit I/O bandwidth usage.
*
* @todo Rather than sleeping after each write, it might be better to
* use some kind of averaging. The current algorithm seems to always
* use a bit less bandwidth than specified, because it doesn't make up
* for slow periods. But arguably this is a feature. In addition, we
* ought to take the time used to write the data into account.
*
* During some phases of big transfers (file FOO is uptodate) this is
* called with a small bytes_written every time. As the kernel has to
* round small waits up to guarantee that we actually wait at least the
* requested number of microseconds, this can become grossly inaccurate.
* We therefore keep track of the bytes we've written over time and only
* sleep when the accumulated delay is at least 1 tenth of a second.
**/
static void sleep_for_bwlimit(int bytes_written)
{
static struct timeval prior_tv;
static long total_written = 0;
struct timeval tv, start_tv;
long elapsed_usec, sleep_usec;
#define ONE_SEC 1000000L /* # of microseconds in a second */
if (!bwlimit)
return;
total_written += bytes_written;
gettimeofday(&start_tv, NULL);
if (prior_tv.tv_sec) {
elapsed_usec = (start_tv.tv_sec - prior_tv.tv_sec) * ONE_SEC
+ (start_tv.tv_usec - prior_tv.tv_usec);
total_written -= elapsed_usec * bwlimit / (ONE_SEC/1024);
if (total_written < 0)
total_written = 0;
}
sleep_usec = total_written * (ONE_SEC/1024) / bwlimit;
if (sleep_usec < ONE_SEC / 10) {
prior_tv = start_tv;
return;
}
tv.tv_sec = sleep_usec / ONE_SEC;
tv.tv_usec = sleep_usec % ONE_SEC;
select(0, NULL, NULL, NULL, &tv);
gettimeofday(&prior_tv, NULL);
elapsed_usec = (prior_tv.tv_sec - start_tv.tv_sec) * ONE_SEC
+ (prior_tv.tv_usec - start_tv.tv_usec);
total_written = (sleep_usec - elapsed_usec) * bwlimit / (ONE_SEC/1024);
}
/* Write len bytes to the file descriptor fd, looping as necessary to get
* the job done and also (in certain circumstnces) reading any data on
* msg_fd_in to avoid deadlock.
*
* This function underlies the multiplexing system. The body of the
* application never calls this function directly. */
static void writefd_unbuffered(int fd,char *buf,size_t len)
{
size_t n, total = 0;
fd_set w_fds, r_fds;
int maxfd, count, ret, using_r_fds;
struct timeval tv;
no_flush++;
while (total < len) {
FD_ZERO(&w_fds);
FD_SET(fd,&w_fds);
maxfd = fd;
if (msg_fd_in >= 0 && len-total >= contiguous_write_len) {
FD_ZERO(&r_fds);
FD_SET(msg_fd_in,&r_fds);
if (msg_fd_in > maxfd)
maxfd = msg_fd_in;
using_r_fds = 1;
} else
using_r_fds = 0;
if (fd != sock_f_out && iobuf_out_cnt && no_flush == 1) {
FD_SET(sock_f_out, &w_fds);
if (sock_f_out > maxfd)
maxfd = sock_f_out;
}
tv.tv_sec = select_timeout;
tv.tv_usec = 0;
errno = 0;
count = select(maxfd + 1, using_r_fds ? &r_fds : NULL,
&w_fds, NULL, &tv);
if (count <= 0) {
if (count < 0 && errno == EBADF)
exit_cleanup(RERR_SOCKETIO);
check_timeout();
continue;
}
if (using_r_fds && FD_ISSET(msg_fd_in, &r_fds))
read_msg_fd();
if (!FD_ISSET(fd, &w_fds))
continue;
n = len - total;
if (bwlimit && n > bwlimit_writemax)
n = bwlimit_writemax;
ret = write(fd, buf + total, n);
if (ret <= 0) {
if (ret < 0) {
if (errno == EINTR)
continue;
if (errno == EWOULDBLOCK || errno == EAGAIN) {
msleep(1);
continue;
}
}
/* Don't try to write errors back across the stream. */
if (fd == sock_f_out)
close_multiplexing_out();
rsyserr(FERROR, errno,
"writefd_unbuffered failed to write %ld bytes: phase \"%s\" [%s]",
(long)len, io_write_phase, who_am_i());
/* If the other side is sending us error messages, try
* to grab any messages they sent before they died. */
while (fd == sock_f_out && io_multiplexing_in) {
io_timeout = select_timeout = 30;
ignore_timeout = 0;
readfd_unbuffered(sock_f_in, io_filesfrom_buf,
sizeof io_filesfrom_buf);
}
exit_cleanup(RERR_STREAMIO);
}
total += ret;
if (fd == sock_f_out) {
if (io_timeout || am_generator)
last_io = time(NULL);
sleep_for_bwlimit(ret);
}
}
no_flush--;
}
/**
* Write an message to a multiplexed stream. If this fails then rsync
* exits.
**/
static void mplex_write(enum msgcode code, char *buf, size_t len)
{
char buffer[4096];
size_t n = len;
SIVAL(buffer, 0, ((MPLEX_BASE + (int)code)<<24) + len);
/* When the generator reads messages from the msg_fd_in pipe, it can
* cause output to occur down the socket. Setting contiguous_write_len
* prevents the reading of msg_fd_in once we actually start to write
* this sequence of data (though we might read it before the start). */
if (am_generator && msg_fd_in >= 0)
contiguous_write_len = len + 4;
if (n > sizeof buffer - 4)
n = sizeof buffer - 4;
memcpy(&buffer[4], buf, n);
writefd_unbuffered(sock_f_out, buffer, n+4);
len -= n;
buf += n;
if (len)
writefd_unbuffered(sock_f_out, buf, len);
if (am_generator && msg_fd_in >= 0)
contiguous_write_len = 0;
}
void io_flush(int flush_it_all)
{
msg_list_push(flush_it_all);
if (!iobuf_out_cnt || no_flush)
return;
if (io_multiplexing_out)
mplex_write(MSG_DATA, iobuf_out, iobuf_out_cnt);
else
writefd_unbuffered(sock_f_out, iobuf_out, iobuf_out_cnt);
iobuf_out_cnt = 0;
}
static void writefd(int fd,char *buf,size_t len)
{
if (fd == msg_fd_out) {
rprintf(FERROR, "Internal error: wrong write used in receiver.\n");
exit_cleanup(RERR_PROTOCOL);
}
if (fd == sock_f_out)
stats.total_written += len;
if (fd == write_batch_monitor_out) {
if ((size_t)write(batch_fd, buf, len) != len)
exit_cleanup(RERR_FILEIO);
}
if (!iobuf_out || fd != sock_f_out) {
writefd_unbuffered(fd, buf, len);
return;
}
while (len) {
int n = MIN((int)len, IO_BUFFER_SIZE - iobuf_out_cnt);
if (n > 0) {
memcpy(iobuf_out+iobuf_out_cnt, buf, n);
buf += n;
len -= n;
iobuf_out_cnt += n;
}
if (iobuf_out_cnt == IO_BUFFER_SIZE)
io_flush(NORMAL_FLUSH);
}
}
void write_shortint(int f, int x)
{
uchar b[2];
b[0] = x;
b[1] = x >> 8;
writefd(f, (char *)b, 2);
}
void write_int(int f,int32 x)
{
char b[4];
SIVAL(b,0,x);
writefd(f,b,4);
}
void write_int_named(int f, int32 x, const char *phase)
{
io_write_phase = phase;
write_int(f, x);
io_write_phase = phase_unknown;
}
/*
* Note: int64 may actually be a 32-bit type if ./configure couldn't find any
* 64-bit types on this platform.
*/
void write_longint(int f, int64 x)
{
char b[8];
if (x <= 0x7FFFFFFF) {
write_int(f, (int)x);
return;
}
#if SIZEOF_INT64 < 8
rprintf(FERROR, "Integer overflow: attempted 64-bit offset\n");
exit_cleanup(RERR_UNSUPPORTED);
#else
write_int(f, (int32)0xFFFFFFFF);
SIVAL(b,0,(x&0xFFFFFFFF));
SIVAL(b,4,((x>>32)&0xFFFFFFFF));
writefd(f,b,8);
#endif
}
void write_buf(int f,char *buf,size_t len)
{
writefd(f,buf,len);
}
/** Write a string to the connection */
void write_sbuf(int f, char *buf)
{
writefd(f, buf, strlen(buf));
}
void write_byte(int f, uchar c)
{
writefd(f, (char *)&c, 1);
}
void write_vstring(int f, char *str, int len)
{
uchar lenbuf[3], *lb = lenbuf;
if (len > 0x7F) {
if (len > 0x7FFF) {
rprintf(FERROR,
"attempting to send over-long vstring (%d > %d)\n",
len, 0x7FFF);
exit_cleanup(RERR_PROTOCOL);
}
*lb++ = len / 0x100 + 0x80;
}
*lb = len;
writefd(f, (char*)lenbuf, lb - lenbuf + 1);
if (len)
writefd(f, str, len);
}
/**
* Read a line of up to @p maxlen characters into @p buf (not counting
* the trailing null). Strips the (required) trailing newline and all
* carriage returns.
*
* @return 1 for success; 0 for I/O error or truncation.
**/
int read_line(int f, char *buf, size_t maxlen)
{
while (maxlen) {
buf[0] = 0;
read_buf(f, buf, 1);
if (buf[0] == 0)
return 0;
if (buf[0] == '\n')
break;
if (buf[0] != '\r') {
buf++;
maxlen--;
}
}
*buf = '\0';
return maxlen > 0;
}
void io_printf(int fd, const char *format, ...)
{
va_list ap;
char buf[1024];
int len;
va_start(ap, format);
len = vsnprintf(buf, sizeof buf, format, ap);
va_end(ap);
if (len < 0)
exit_cleanup(RERR_STREAMIO);
write_sbuf(fd, buf);
}
/** Setup for multiplexing a MSG_* stream with the data stream. */
void io_start_multiplex_out(void)
{
io_flush(NORMAL_FLUSH);
io_start_buffering_out();
io_multiplexing_out = 1;
}
/** Setup for multiplexing a MSG_* stream with the data stream. */
void io_start_multiplex_in(void)
{
io_flush(NORMAL_FLUSH);
io_start_buffering_in();
io_multiplexing_in = 1;
}
/** Write an message to the multiplexed data stream. */
int io_multiplex_write(enum msgcode code, char *buf, size_t len)
{
if (!io_multiplexing_out)
return 0;
io_flush(NORMAL_FLUSH);
stats.total_written += (len+4);
mplex_write(code, buf, len);
return 1;
}
void close_multiplexing_in(void)
{
io_multiplexing_in = 0;
}
/** Stop output multiplexing. */
void close_multiplexing_out(void)
{
io_multiplexing_out = 0;
}
void start_write_batch(int fd)
{
write_stream_flags(batch_fd);
/* Some communication has already taken place, but we don't
* enable batch writing until here so that we can write a
* canonical record of the communication even though the
* actual communication so far depends on whether a daemon
* is involved. */
write_int(batch_fd, protocol_version);
write_int(batch_fd, checksum_seed);
if (am_sender)
write_batch_monitor_out = fd;
else
write_batch_monitor_in = fd;
}
void stop_write_batch(void)
{
write_batch_monitor_out = -1;
write_batch_monitor_in = -1;
}
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