Mercurial > dropbear
view common-channel.c @ 1270:6d00eca524fe
rename loop variable
2 nested loops with the same variable 'i',
line 219 and line 309
author | Francois Perrad <francois.perrad@gadz.org> |
---|---|
date | Thu, 31 Dec 2015 18:47:51 +0100 |
parents | af940cefdba1 |
children | 750ec4ec4cbe |
line wrap: on
line source
/* * Dropbear SSH * * Copyright (c) 2002-2004 Matt Johnston * All rights reserved. * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. */ /* Handle the multiplexed channels, such as sessions, x11, agent connections */ #include "includes.h" #include "session.h" #include "packet.h" #include "ssh.h" #include "buffer.h" #include "circbuffer.h" #include "dbutil.h" #include "channel.h" #include "ssh.h" #include "listener.h" #include "runopts.h" #include "netio.h" static void send_msg_channel_open_failure(unsigned int remotechan, int reason, const char *text, const char *lang); static void send_msg_channel_open_confirmation(struct Channel* channel, unsigned int recvwindow, unsigned int recvmaxpacket); static int writechannel(struct Channel* channel, int fd, circbuffer *cbuf, const unsigned char *moredata, unsigned int *morelen); static void send_msg_channel_window_adjust(struct Channel *channel, unsigned int incr); static void send_msg_channel_data(struct Channel *channel, int isextended); static void send_msg_channel_eof(struct Channel *channel); static void send_msg_channel_close(struct Channel *channel); static void remove_channel(struct Channel *channel); static unsigned int write_pending(struct Channel * channel); static void check_close(struct Channel *channel); static void close_chan_fd(struct Channel *channel, int fd, int how); #define FD_UNINIT (-2) #define FD_CLOSED (-1) #define ERRFD_IS_READ(channel) ((channel)->extrabuf == NULL) #define ERRFD_IS_WRITE(channel) (!ERRFD_IS_READ(channel)) /* allow space for: * 1 byte byte SSH_MSG_CHANNEL_DATA * 4 bytes uint32 recipient channel * 4 bytes string data */ #define RECV_MAX_CHANNEL_DATA_LEN (RECV_MAX_PAYLOAD_LEN-(1+4+4)) /* Initialise all the channels */ void chaninitialise(const struct ChanType *chantypes[]) { /* may as well create space for a single channel */ ses.channels = (struct Channel**)m_malloc(sizeof(struct Channel*)); ses.chansize = 1; ses.channels[0] = NULL; ses.chancount = 0; ses.chantypes = chantypes; #ifdef USING_LISTENERS listeners_initialise(); #endif } /* Clean up channels, freeing allocated memory */ void chancleanup() { unsigned int i; TRACE(("enter chancleanup")) for (i = 0; i < ses.chansize; i++) { if (ses.channels[i] != NULL) { TRACE(("channel %d closing", i)) remove_channel(ses.channels[i]); } } m_free(ses.channels); TRACE(("leave chancleanup")) } /* Create a new channel entry, send a reply confirm or failure */ /* If remotechan, transwindow and transmaxpacket are not know (for a new * outgoing connection, with them to be filled on confirmation), they should * all be set to 0 */ static struct Channel* newchannel(unsigned int remotechan, const struct ChanType *type, unsigned int transwindow, unsigned int transmaxpacket) { struct Channel * newchan; unsigned int i, j; TRACE(("enter newchannel")) /* first see if we can use existing channels */ for (i = 0; i < ses.chansize; i++) { if (ses.channels[i] == NULL) { break; } } /* otherwise extend the list */ if (i == ses.chansize) { if (ses.chansize >= MAX_CHANNELS) { TRACE(("leave newchannel: max chans reached")) return NULL; } /* extend the channels */ ses.channels = (struct Channel**)m_realloc(ses.channels, (ses.chansize+CHAN_EXTEND_SIZE)*sizeof(struct Channel*)); ses.chansize += CHAN_EXTEND_SIZE; /* set the new channels to null */ for (j = i; j < ses.chansize; j++) { ses.channels[j] = NULL; } } newchan = (struct Channel*)m_malloc(sizeof(struct Channel)); newchan->type = type; newchan->index = i; newchan->sent_close = newchan->recv_close = 0; newchan->sent_eof = newchan->recv_eof = 0; newchan->close_handler_done = 0; newchan->remotechan = remotechan; newchan->transwindow = transwindow; newchan->transmaxpacket = transmaxpacket; newchan->typedata = NULL; newchan->writefd = FD_UNINIT; newchan->readfd = FD_UNINIT; newchan->errfd = FD_CLOSED; /* this isn't always set to start with */ newchan->await_open = 0; newchan->flushing = 0; newchan->writebuf = cbuf_new(opts.recv_window); newchan->recvwindow = opts.recv_window; newchan->extrabuf = NULL; /* The user code can set it up */ newchan->recvdonelen = 0; newchan->recvmaxpacket = RECV_MAX_CHANNEL_DATA_LEN; newchan->prio = DROPBEAR_CHANNEL_PRIO_EARLY; /* inithandler sets it */ ses.channels[i] = newchan; ses.chancount++; TRACE(("leave newchannel")) return newchan; } /* Returns the channel structure corresponding to the channel in the current * data packet (ses.payload must be positioned appropriately). * A valid channel is always returns, it will fail fatally with an unknown * channel */ static struct Channel* getchannel_msg(const char* kind) { unsigned int chan; chan = buf_getint(ses.payload); if (chan >= ses.chansize || ses.channels[chan] == NULL) { if (kind) { dropbear_exit("%s for unknown channel %d", kind, chan); } else { dropbear_exit("Unknown channel %d", chan); } } return ses.channels[chan]; } struct Channel* getchannel() { return getchannel_msg(NULL); } /* Iterate through the channels, performing IO if available */ void channelio(fd_set *readfds, fd_set *writefds) { /* Listeners such as TCP, X11, agent-auth */ struct Channel *channel; unsigned int i; /* foreach channel */ for (i = 0; i < ses.chansize; i++) { /* Close checking only needs to occur for channels that had IO events */ int do_check_close = 0; channel = ses.channels[i]; if (channel == NULL) { /* only process in-use channels */ continue; } /* read data and send it over the wire */ if (channel->readfd >= 0 && FD_ISSET(channel->readfd, readfds)) { TRACE(("send normal readfd")) send_msg_channel_data(channel, 0); do_check_close = 1; } /* read stderr data and send it over the wire */ if (ERRFD_IS_READ(channel) && channel->errfd >= 0 && FD_ISSET(channel->errfd, readfds)) { TRACE(("send normal errfd")) send_msg_channel_data(channel, 1); do_check_close = 1; } /* write to program/pipe stdin */ if (channel->writefd >= 0 && FD_ISSET(channel->writefd, writefds)) { writechannel(channel, channel->writefd, channel->writebuf, NULL, NULL); do_check_close = 1; } /* stderr for client mode */ if (ERRFD_IS_WRITE(channel) && channel->errfd >= 0 && FD_ISSET(channel->errfd, writefds)) { writechannel(channel, channel->errfd, channel->extrabuf, NULL, NULL); do_check_close = 1; } if (ses.channel_signal_pending) { /* SIGCHLD can change channel state for server sessions */ do_check_close = 1; } /* handle any channel closing etc */ if (do_check_close) { check_close(channel); } } #ifdef USING_LISTENERS handle_listeners(readfds); #endif } /* Returns true if there is data remaining to be written to stdin or * stderr of a channel's endpoint. */ static unsigned int write_pending(struct Channel * channel) { if (channel->writefd >= 0 && cbuf_getused(channel->writebuf) > 0) { return 1; } else if (channel->errfd >= 0 && channel->extrabuf && cbuf_getused(channel->extrabuf) > 0) { return 1; } return 0; } /* EOF/close handling */ static void check_close(struct Channel *channel) { int close_allowed = 0; TRACE2(("check_close: writefd %d, readfd %d, errfd %d, sent_close %d, recv_close %d", channel->writefd, channel->readfd, channel->errfd, channel->sent_close, channel->recv_close)) TRACE2(("writebuf size %d extrabuf size %d", channel->writebuf ? cbuf_getused(channel->writebuf) : 0, channel->extrabuf ? cbuf_getused(channel->extrabuf) : 0)) if (!channel->flushing && !channel->close_handler_done && channel->type->check_close && channel->type->check_close(channel)) { channel->flushing = 1; } /* if a type-specific check_close is defined we will only exit once that has been triggered. this is only used for a server "session" channel, to ensure that the shell has exited (and the exit status retrieved) before we close things up. */ if (!channel->type->check_close || channel->close_handler_done || channel->type->check_close(channel)) { close_allowed = 1; } if (channel->recv_close && !write_pending(channel) && close_allowed) { if (!channel->sent_close) { TRACE(("Sending MSG_CHANNEL_CLOSE in response to same.")) send_msg_channel_close(channel); } remove_channel(channel); return; } if ((channel->recv_eof && !write_pending(channel)) /* have a server "session" and child has exited */ || (channel->type->check_close && close_allowed)) { close_chan_fd(channel, channel->writefd, SHUT_WR); } /* Special handling for flushing read data after an exit. We read regardless of whether the select FD was set, and if there isn't data available, the channel will get closed. */ if (channel->flushing) { TRACE(("might send data, flushing")) if (channel->readfd >= 0 && channel->transwindow > 0) { TRACE(("send data readfd")) send_msg_channel_data(channel, 0); } if (ERRFD_IS_READ(channel) && channel->errfd >= 0 && channel->transwindow > 0) { TRACE(("send data errfd")) send_msg_channel_data(channel, 1); } } /* If we're not going to send any more data, send EOF */ if (!channel->sent_eof && channel->readfd == FD_CLOSED && (ERRFD_IS_WRITE(channel) || channel->errfd == FD_CLOSED)) { send_msg_channel_eof(channel); } /* And if we can't receive any more data from them either, close up */ if (channel->readfd == FD_CLOSED && channel->writefd == FD_CLOSED && (ERRFD_IS_WRITE(channel) || channel->errfd == FD_CLOSED) && !channel->sent_close && close_allowed && !write_pending(channel)) { TRACE(("sending close, readfd is closed")) send_msg_channel_close(channel); } } /* Check whether a deferred (EINPROGRESS) connect() was successful, and * if so, set up the channel properly. Otherwise, the channel is cleaned up, so * it is important that the channel reference isn't used after a call to this * function */ void channel_connect_done(int result, int sock, void* user_data, const char* UNUSED(errstring)) { struct Channel *channel = user_data; TRACE(("enter channel_connect_done")) if (result == DROPBEAR_SUCCESS) { channel->readfd = channel->writefd = sock; channel->conn_pending = NULL; send_msg_channel_open_confirmation(channel, channel->recvwindow, channel->recvmaxpacket); TRACE(("leave channel_connect_done: success")) } else { send_msg_channel_open_failure(channel->remotechan, SSH_OPEN_CONNECT_FAILED, "", ""); remove_channel(channel); TRACE(("leave check_in_progress: fail")) } } /* Send the close message and set the channel as closed */ static void send_msg_channel_close(struct Channel *channel) { TRACE(("enter send_msg_channel_close %p", (void*)channel)) if (channel->type->closehandler && !channel->close_handler_done) { channel->type->closehandler(channel); channel->close_handler_done = 1; } CHECKCLEARTOWRITE(); buf_putbyte(ses.writepayload, SSH_MSG_CHANNEL_CLOSE); buf_putint(ses.writepayload, channel->remotechan); encrypt_packet(); channel->sent_eof = 1; channel->sent_close = 1; close_chan_fd(channel, channel->readfd, SHUT_RD); close_chan_fd(channel, channel->errfd, SHUT_RDWR); close_chan_fd(channel, channel->writefd, SHUT_WR); TRACE(("leave send_msg_channel_close")) } /* call this when trans/eof channels are closed */ static void send_msg_channel_eof(struct Channel *channel) { TRACE(("enter send_msg_channel_eof")) CHECKCLEARTOWRITE(); buf_putbyte(ses.writepayload, SSH_MSG_CHANNEL_EOF); buf_putint(ses.writepayload, channel->remotechan); encrypt_packet(); channel->sent_eof = 1; TRACE(("leave send_msg_channel_eof")) } #ifndef HAVE_WRITEV static int writechannel_fallback(struct Channel* channel, int fd, circbuffer *cbuf, const unsigned char *UNUSED(moredata), unsigned int *morelen) { unsigned char *circ_p1, *circ_p2; unsigned int circ_len1, circ_len2; ssize_t written; if (morelen) { /* fallback doesn't consume moredata */ *morelen = 0; } /* Write the first portion of the circular buffer */ cbuf_readptrs(cbuf, &circ_p1, &circ_len1, &circ_p2, &circ_len2); written = write(fd, circ_p1, circ_len1); if (written < 0) { if (errno != EINTR && errno != EAGAIN) { TRACE(("channel IO write error fd %d %s", fd, strerror(errno))) close_chan_fd(channel, fd, SHUT_WR); return DROPBEAR_FAILURE; } } else { cbuf_incrread(cbuf, written); channel->recvdonelen += written; } return DROPBEAR_SUCCESS; } #endif /* !HAVE_WRITEV */ #ifdef HAVE_WRITEV static int writechannel_writev(struct Channel* channel, int fd, circbuffer *cbuf, const unsigned char *moredata, unsigned int *morelen) { struct iovec iov[3]; unsigned char *circ_p1, *circ_p2; unsigned int circ_len1, circ_len2; int io_count = 0; ssize_t written; cbuf_readptrs(cbuf, &circ_p1, &circ_len1, &circ_p2, &circ_len2); if (circ_len1 > 0) { TRACE(("circ1 %d", circ_len1)) iov[io_count].iov_base = circ_p1; iov[io_count].iov_len = circ_len1; io_count++; } if (circ_len2 > 0) { TRACE(("circ2 %d", circ_len2)) iov[io_count].iov_base = circ_p2; iov[io_count].iov_len = circ_len2; io_count++; } if (morelen) { assert(moredata); TRACE(("more %d", *morelen)) iov[io_count].iov_base = (void*)moredata; iov[io_count].iov_len = *morelen; io_count++; } if (io_count == 0) { /* writechannel may sometimes be called twice in a main loop iteration. From common_recv_msg_channel_data() then channelio(). The second call may not have any data to write, so we just return. */ TRACE(("leave writechannel, no data")) return DROPBEAR_SUCCESS; } if (morelen) { /* Default return value, none consumed */ *morelen = 0; } written = writev(fd, iov, io_count); if (written < 0) { if (errno != EINTR && errno != EAGAIN) { TRACE(("channel IO write error fd %d %s", fd, strerror(errno))) close_chan_fd(channel, fd, SHUT_WR); return DROPBEAR_FAILURE; } } else { int cbuf_written = MIN(circ_len1+circ_len2, (unsigned int)written); cbuf_incrread(cbuf, cbuf_written); if (morelen) { *morelen = written - cbuf_written; } channel->recvdonelen += written; } return DROPBEAR_SUCCESS; } #endif /* HAVE_WRITEV */ /* Called to write data out to the local side of the channel. Writes the circular buffer contents and also the "moredata" buffer if not null. Will ignore EAGAIN. Returns DROPBEAR_FAILURE if writing to fd had an error and the channel is being closed, DROPBEAR_SUCCESS otherwise */ static int writechannel(struct Channel* channel, int fd, circbuffer *cbuf, const unsigned char *moredata, unsigned int *morelen) { int ret = DROPBEAR_SUCCESS; TRACE(("enter writechannel fd %d", fd)) #ifdef HAVE_WRITEV ret = writechannel_writev(channel, fd, cbuf, moredata, morelen); #else ret = writechannel_fallback(channel, fd, cbuf, moredata, morelen); #endif /* Window adjust handling */ if (channel->recvdonelen >= RECV_WINDOWEXTEND) { send_msg_channel_window_adjust(channel, channel->recvdonelen); channel->recvwindow += channel->recvdonelen; channel->recvdonelen = 0; } dropbear_assert(channel->recvwindow <= opts.recv_window); dropbear_assert(channel->recvwindow <= cbuf_getavail(channel->writebuf)); dropbear_assert(channel->extrabuf == NULL || channel->recvwindow <= cbuf_getavail(channel->extrabuf)); TRACE(("leave writechannel")) return ret; } /* Set the file descriptors for the main select in session.c * This avoid channels which don't have any window available, are closed, etc*/ void setchannelfds(fd_set *readfds, fd_set *writefds, int allow_reads) { unsigned int i; struct Channel * channel; for (i = 0; i < ses.chansize; i++) { channel = ses.channels[i]; if (channel == NULL) { continue; } /* Stuff to put over the wire. Avoid queueing data to send if we're in the middle of a key re-exchange (!dataallowed), but still read from the FD if there's the possibility of "~."" to kill an interactive session (the read_mangler) */ if (channel->transwindow > 0 && ((ses.dataallowed && allow_reads) || channel->read_mangler)) { if (channel->readfd >= 0) { FD_SET(channel->readfd, readfds); } if (ERRFD_IS_READ(channel) && channel->errfd >= 0) { FD_SET(channel->errfd, readfds); } } /* Stuff from the wire */ if (channel->writefd >= 0 && cbuf_getused(channel->writebuf) > 0) { FD_SET(channel->writefd, writefds); } if (ERRFD_IS_WRITE(channel) && channel->errfd >= 0 && cbuf_getused(channel->extrabuf) > 0) { FD_SET(channel->errfd, writefds); } } /* foreach channel */ #ifdef USING_LISTENERS set_listener_fds(readfds); #endif } /* handle the channel EOF event, by closing the channel filedescriptor. The * channel isn't closed yet, it is left until the incoming (from the program * etc) FD is also EOF */ void recv_msg_channel_eof() { struct Channel * channel; TRACE(("enter recv_msg_channel_eof")) channel = getchannel_msg("EOF"); channel->recv_eof = 1; check_close(channel); TRACE(("leave recv_msg_channel_eof")) } /* Handle channel closure(), respond in kind and close the channels */ void recv_msg_channel_close() { struct Channel * channel; TRACE(("enter recv_msg_channel_close")) channel = getchannel_msg("Close"); channel->recv_eof = 1; channel->recv_close = 1; check_close(channel); TRACE(("leave recv_msg_channel_close")) } /* Remove a channel entry, this is only executed after both sides have sent * channel close */ static void remove_channel(struct Channel * channel) { TRACE(("enter remove_channel")) TRACE(("channel index is %d", channel->index)) cbuf_free(channel->writebuf); channel->writebuf = NULL; if (channel->extrabuf) { cbuf_free(channel->extrabuf); channel->extrabuf = NULL; } if (IS_DROPBEAR_SERVER || (channel->writefd != STDOUT_FILENO)) { /* close the FDs in case they haven't been done * yet (they might have been shutdown etc) */ TRACE(("CLOSE writefd %d", channel->writefd)) m_close(channel->writefd); TRACE(("CLOSE readfd %d", channel->readfd)) m_close(channel->readfd); TRACE(("CLOSE errfd %d", channel->errfd)) m_close(channel->errfd); } if (!channel->close_handler_done && channel->type->closehandler) { channel->type->closehandler(channel); channel->close_handler_done = 1; } if (channel->conn_pending) { cancel_connect(channel->conn_pending); } ses.channels[channel->index] = NULL; m_free(channel); ses.chancount--; update_channel_prio(); TRACE(("leave remove_channel")) } /* Handle channel specific requests, passing off to corresponding handlers * such as chansession or x11fwd */ void recv_msg_channel_request() { struct Channel *channel; channel = getchannel(); TRACE(("enter recv_msg_channel_request %p", (void*)channel)) if (channel->sent_close) { TRACE(("leave recv_msg_channel_request: already closed channel")) return; } if (channel->type->reqhandler && !channel->close_handler_done) { channel->type->reqhandler(channel); } else { int wantreply; buf_eatstring(ses.payload); wantreply = buf_getbool(ses.payload); if (wantreply) { send_msg_channel_failure(channel); } } TRACE(("leave recv_msg_channel_request")) } /* Reads data from the server's program/shell/etc, and puts it in a * channel_data packet to send. * chan is the remote channel, isextended is 0 if it is normal data, 1 * if it is extended data. if it is extended, then the type is in * exttype */ static void send_msg_channel_data(struct Channel *channel, int isextended) { int len; size_t maxlen, size_pos; int fd; CHECKCLEARTOWRITE(); TRACE(("enter send_msg_channel_data")) dropbear_assert(!channel->sent_close); if (isextended) { fd = channel->errfd; } else { fd = channel->readfd; } TRACE(("enter send_msg_channel_data isextended %d fd %d", isextended, fd)) dropbear_assert(fd >= 0); maxlen = MIN(channel->transwindow, channel->transmaxpacket); /* -(1+4+4) is SSH_MSG_CHANNEL_DATA, channel number, string length, and * exttype if is extended */ maxlen = MIN(maxlen, ses.writepayload->size - 1 - 4 - 4 - (isextended ? 4 : 0)); TRACE(("maxlen %zd", maxlen)) if (maxlen == 0) { TRACE(("leave send_msg_channel_data: no window")) return; } buf_putbyte(ses.writepayload, isextended ? SSH_MSG_CHANNEL_EXTENDED_DATA : SSH_MSG_CHANNEL_DATA); buf_putint(ses.writepayload, channel->remotechan); if (isextended) { buf_putint(ses.writepayload, SSH_EXTENDED_DATA_STDERR); } /* a dummy size first ...*/ size_pos = ses.writepayload->pos; buf_putint(ses.writepayload, 0); /* read the data */ len = read(fd, buf_getwriteptr(ses.writepayload, maxlen), maxlen); if (len <= 0) { if (len == 0 || errno != EINTR) { /* This will also get hit in the case of EAGAIN. The only time we expect to receive EAGAIN is when we're flushing a FD, in which case it can be treated the same as EOF */ close_chan_fd(channel, fd, SHUT_RD); } buf_setpos(ses.writepayload, 0); buf_setlen(ses.writepayload, 0); TRACE(("leave send_msg_channel_data: len %d read err %d or EOF for fd %d", len, errno, fd)) return; } if (channel->read_mangler) { channel->read_mangler(channel, buf_getwriteptr(ses.writepayload, len), &len); if (len == 0) { buf_setpos(ses.writepayload, 0); buf_setlen(ses.writepayload, 0); return; } } TRACE(("send_msg_channel_data: len %d fd %d", len, fd)) buf_incrwritepos(ses.writepayload, len); /* ... real size here */ buf_setpos(ses.writepayload, size_pos); buf_putint(ses.writepayload, len); channel->transwindow -= len; encrypt_packet(); /* If we receive less data than we requested when flushing, we've reached the equivalent of EOF */ if (channel->flushing && len < (ssize_t)maxlen) { TRACE(("closing from channel, flushing out.")) close_chan_fd(channel, fd, SHUT_RD); } TRACE(("leave send_msg_channel_data")) } /* We receive channel data */ void recv_msg_channel_data() { struct Channel *channel; channel = getchannel(); common_recv_msg_channel_data(channel, channel->writefd, channel->writebuf); } /* Shared for data and stderr data - when we receive data, put it in a buffer * for writing to the local file descriptor */ void common_recv_msg_channel_data(struct Channel *channel, int fd, circbuffer * cbuf) { unsigned int datalen; unsigned int maxdata; unsigned int buflen; unsigned int len; unsigned int consumed; int res; TRACE(("enter recv_msg_channel_data")) if (channel->recv_eof) { dropbear_exit("Received data after eof"); } if (fd < 0 || !cbuf) { /* If we have encountered failed write, the far side might still * be sending data without having yet received our close notification. * We just drop the data. */ return; } datalen = buf_getint(ses.payload); TRACE(("length %d", datalen)) maxdata = cbuf_getavail(cbuf); /* Whilst the spec says we "MAY ignore data past the end" this could * lead to corrupted file transfers etc (chunks missed etc). It's better to * just die horribly */ if (datalen > maxdata) { dropbear_exit("Oversized packet"); } dropbear_assert(channel->recvwindow >= datalen); channel->recvwindow -= datalen; dropbear_assert(channel->recvwindow <= opts.recv_window); /* Attempt to write the data immediately without having to put it in the circular buffer */ consumed = datalen; res = writechannel(channel, fd, cbuf, buf_getptr(ses.payload, datalen), &consumed); datalen -= consumed; buf_incrpos(ses.payload, consumed); /* We may have to run throught twice, if the buffer wraps around. Can't * just "leave it for next time" like with writechannel, since this * is payload data. * If the writechannel() failed then remaining data is discarded */ if (res == DROPBEAR_SUCCESS) { len = datalen; while (len > 0) { buflen = cbuf_writelen(cbuf); buflen = MIN(buflen, len); memcpy(cbuf_writeptr(cbuf, buflen), buf_getptr(ses.payload, buflen), buflen); cbuf_incrwrite(cbuf, buflen); buf_incrpos(ses.payload, buflen); len -= buflen; } } TRACE(("leave recv_msg_channel_data")) } /* Increment the outgoing data window for a channel - the remote end limits * the amount of data which may be transmitted, this window is decremented * as data is sent, and incremented upon receiving window-adjust messages */ void recv_msg_channel_window_adjust() { struct Channel * channel; unsigned int incr; channel = getchannel(); incr = buf_getint(ses.payload); TRACE(("received window increment %d", incr)) incr = MIN(incr, TRANS_MAX_WIN_INCR); channel->transwindow += incr; channel->transwindow = MIN(channel->transwindow, TRANS_MAX_WINDOW); } /* Increment the incoming data window for a channel, and let the remote * end know */ static void send_msg_channel_window_adjust(struct Channel* channel, unsigned int incr) { TRACE(("sending window adjust %d", incr)) CHECKCLEARTOWRITE(); buf_putbyte(ses.writepayload, SSH_MSG_CHANNEL_WINDOW_ADJUST); buf_putint(ses.writepayload, channel->remotechan); buf_putint(ses.writepayload, incr); encrypt_packet(); } /* Handle a new channel request, performing any channel-type-specific setup */ void recv_msg_channel_open() { char *type; unsigned int typelen; unsigned int remotechan, transwindow, transmaxpacket; struct Channel *channel; const struct ChanType **cp; const struct ChanType *chantype; unsigned int errtype = SSH_OPEN_UNKNOWN_CHANNEL_TYPE; int ret; TRACE(("enter recv_msg_channel_open")) /* get the packet contents */ type = buf_getstring(ses.payload, &typelen); remotechan = buf_getint(ses.payload); transwindow = buf_getint(ses.payload); transwindow = MIN(transwindow, TRANS_MAX_WINDOW); transmaxpacket = buf_getint(ses.payload); transmaxpacket = MIN(transmaxpacket, TRANS_MAX_PAYLOAD_LEN); /* figure what type of packet it is */ if (typelen > MAX_NAME_LEN) { goto failure; } /* Get the channel type. Client and server style invokation will set up a * different list for ses.chantypes at startup. We just iterate through * this list and find the matching name */ for (cp = &ses.chantypes[0], chantype = (*cp); chantype != NULL; cp++, chantype = (*cp)) { if (strcmp(type, chantype->name) == 0) { break; } } if (chantype == NULL) { TRACE(("No matching type for '%s'", type)) goto failure; } TRACE(("matched type '%s'", type)) /* create the channel */ channel = newchannel(remotechan, chantype, transwindow, transmaxpacket); if (channel == NULL) { TRACE(("newchannel returned NULL")) errtype = SSH_OPEN_RESOURCE_SHORTAGE; goto failure; } if (channel->type->inithandler) { ret = channel->type->inithandler(channel); if (ret == SSH_OPEN_IN_PROGRESS) { /* We'll send the confirmation later */ goto cleanup; } if (ret > 0) { errtype = ret; remove_channel(channel); TRACE(("inithandler returned failure %d", ret)) goto failure; } } if (channel->prio == DROPBEAR_CHANNEL_PRIO_EARLY) { channel->prio = DROPBEAR_CHANNEL_PRIO_BULK; } /* success */ send_msg_channel_open_confirmation(channel, channel->recvwindow, channel->recvmaxpacket); goto cleanup; failure: TRACE(("recv_msg_channel_open failure")) send_msg_channel_open_failure(remotechan, errtype, "", ""); cleanup: m_free(type); update_channel_prio(); TRACE(("leave recv_msg_channel_open")) } /* Send a failure message */ void send_msg_channel_failure(struct Channel *channel) { TRACE(("enter send_msg_channel_failure")) CHECKCLEARTOWRITE(); buf_putbyte(ses.writepayload, SSH_MSG_CHANNEL_FAILURE); buf_putint(ses.writepayload, channel->remotechan); encrypt_packet(); TRACE(("leave send_msg_channel_failure")) } /* Send a success message */ void send_msg_channel_success(struct Channel *channel) { TRACE(("enter send_msg_channel_success")) CHECKCLEARTOWRITE(); buf_putbyte(ses.writepayload, SSH_MSG_CHANNEL_SUCCESS); buf_putint(ses.writepayload, channel->remotechan); encrypt_packet(); TRACE(("leave send_msg_channel_success")) } /* Send a channel open failure message, with a corresponding reason * code (usually resource shortage or unknown chan type) */ static void send_msg_channel_open_failure(unsigned int remotechan, int reason, const char *text, const char *lang) { TRACE(("enter send_msg_channel_open_failure")) CHECKCLEARTOWRITE(); buf_putbyte(ses.writepayload, SSH_MSG_CHANNEL_OPEN_FAILURE); buf_putint(ses.writepayload, remotechan); buf_putint(ses.writepayload, reason); buf_putstring(ses.writepayload, text, strlen(text)); buf_putstring(ses.writepayload, lang, strlen(lang)); encrypt_packet(); TRACE(("leave send_msg_channel_open_failure")) } /* Confirm a channel open, and let the remote end know what number we've * allocated and the receive parameters */ static void send_msg_channel_open_confirmation(struct Channel* channel, unsigned int recvwindow, unsigned int recvmaxpacket) { TRACE(("enter send_msg_channel_open_confirmation")) CHECKCLEARTOWRITE(); buf_putbyte(ses.writepayload, SSH_MSG_CHANNEL_OPEN_CONFIRMATION); buf_putint(ses.writepayload, channel->remotechan); buf_putint(ses.writepayload, channel->index); buf_putint(ses.writepayload, recvwindow); buf_putint(ses.writepayload, recvmaxpacket); encrypt_packet(); TRACE(("leave send_msg_channel_open_confirmation")) } /* close a fd, how is SHUT_RD or SHUT_WR */ static void close_chan_fd(struct Channel *channel, int fd, int how) { int closein = 0, closeout = 0; if (channel->type->sepfds) { TRACE(("SHUTDOWN(%d, %d)", fd, how)) shutdown(fd, how); if (how == 0) { closeout = 1; } else { closein = 1; } } else { TRACE(("CLOSE some fd %d", fd)) m_close(fd); closein = closeout = 1; } if (closeout && (fd == channel->readfd)) { channel->readfd = FD_CLOSED; } if (closeout && ERRFD_IS_READ(channel) && (fd == channel->errfd)) { channel->errfd = FD_CLOSED; } if (closein && fd == channel->writefd) { channel->writefd = FD_CLOSED; } if (closein && ERRFD_IS_WRITE(channel) && (fd == channel->errfd)) { channel->errfd = FD_CLOSED; } /* if we called shutdown on it and all references are gone, then we * need to close() it to stop it lingering */ if (channel->type->sepfds && channel->readfd == FD_CLOSED && channel->writefd == FD_CLOSED && channel->errfd == FD_CLOSED) { TRACE(("CLOSE (finally) of %d", fd)) m_close(fd); } } #if defined(USING_LISTENERS) || defined(DROPBEAR_CLIENT) /* Create a new channel, and start the open request. This is intended * for X11, agent, tcp forwarding, and should be filled with channel-specific * options, with the calling function calling encrypt_packet() after * completion. It is mandatory for the caller to encrypt_packet() if * a channel is returned. NULL is returned on failure. */ int send_msg_channel_open_init(int fd, const struct ChanType *type) { struct Channel* chan; TRACE(("enter send_msg_channel_open_init()")) chan = newchannel(0, type, 0, 0); if (!chan) { TRACE(("leave send_msg_channel_open_init() - FAILED in newchannel()")) return DROPBEAR_FAILURE; } /* Outbound opened channels don't make use of in-progress connections, * we can set it up straight away */ /* set fd non-blocking */ setnonblocking(fd); chan->writefd = chan->readfd = fd; ses.maxfd = MAX(ses.maxfd, fd); chan->await_open = 1; /* now open the channel connection */ CHECKCLEARTOWRITE(); buf_putbyte(ses.writepayload, SSH_MSG_CHANNEL_OPEN); buf_putstring(ses.writepayload, type->name, strlen(type->name)); buf_putint(ses.writepayload, chan->index); buf_putint(ses.writepayload, opts.recv_window); buf_putint(ses.writepayload, RECV_MAX_CHANNEL_DATA_LEN); TRACE(("leave send_msg_channel_open_init()")) return DROPBEAR_SUCCESS; } /* Confirmation that our channel open request (for forwardings) was * successful*/ void recv_msg_channel_open_confirmation() { struct Channel * channel; int ret; TRACE(("enter recv_msg_channel_open_confirmation")) channel = getchannel(); if (!channel->await_open) { dropbear_exit("Unexpected channel reply"); } channel->await_open = 0; channel->remotechan = buf_getint(ses.payload); channel->transwindow = buf_getint(ses.payload); channel->transmaxpacket = buf_getint(ses.payload); TRACE(("new chan remote %d local %d", channel->remotechan, channel->index)) /* Run the inithandler callback */ if (channel->type->inithandler) { ret = channel->type->inithandler(channel); if (ret > 0) { remove_channel(channel); TRACE(("inithandler returned failure %d", ret)) return; } } if (channel->prio == DROPBEAR_CHANNEL_PRIO_EARLY) { channel->prio = DROPBEAR_CHANNEL_PRIO_BULK; } update_channel_prio(); TRACE(("leave recv_msg_channel_open_confirmation")) } /* Notification that our channel open request failed */ void recv_msg_channel_open_failure() { struct Channel * channel; channel = getchannel(); if (!channel->await_open) { dropbear_exit("Unexpected channel reply"); } channel->await_open = 0; remove_channel(channel); } #endif /* USING_LISTENERS */ void send_msg_request_success() { CHECKCLEARTOWRITE(); buf_putbyte(ses.writepayload, SSH_MSG_REQUEST_SUCCESS); encrypt_packet(); } void send_msg_request_failure() { CHECKCLEARTOWRITE(); buf_putbyte(ses.writepayload, SSH_MSG_REQUEST_FAILURE); encrypt_packet(); } struct Channel* get_any_ready_channel() { size_t i; if (ses.chancount == 0) { return NULL; } for (i = 0; i < ses.chansize; i++) { struct Channel *chan = ses.channels[i]; if (chan && !(chan->sent_eof || chan->recv_eof) && !(chan->await_open)) { return chan; } } return NULL; } void start_send_channel_request(struct Channel *channel, char *type) { CHECKCLEARTOWRITE(); buf_putbyte(ses.writepayload, SSH_MSG_CHANNEL_REQUEST); buf_putint(ses.writepayload, channel->remotechan); buf_putstring(ses.writepayload, type, strlen(type)); }