/* -*- indent-tabs-mode: nil; -*- */ #define LOG_GROUP LOG_GROUP_NAT_SERVICE #define _USE_WINSTD_ERRNO /* XXX: replace POSIX file operations with IPRT, to avoid hacks with errno renamings */ #include "winutils.h" #include "proxy.h" #include "tftp.h" #ifndef RT_OS_WINDOWS #include #include #include #include #include #include #include #include #else #include #include #include #include #include #include #include #include # define O_RDONLY _O_RDONLY # define S_ISREG(x) ((x) & _S_IFREG) #endif #include "lwip/timers.h" #include "lwip/udp.h" #include struct xfer { struct udp_pcb *pcb; int fd; unsigned int ack; struct pbuf *pbuf; struct pbuf *oack; int rexmit; ipX_addr_t peer_ip; u16_t peer_port; char *filename; int octet; /* options */ unsigned int blksize; int blksize_from_opt; unsigned int timeout; int timeout_from_opt; off_t tsize; int tsize_from_opt; }; struct tftpd { struct udp_pcb *pcb; char *root; #define TFTP_MAX_XFERS 3 struct xfer xfers[TFTP_MAX_XFERS]; }; struct tftp_option { const char *name; int (*getopt)(struct xfer *, const char *); int (*ackopt)(struct xfer *, char **, size_t *); }; static void tftpd_recv(void *, struct udp_pcb *, struct pbuf *, ip_addr_t *, u16_t); static void tftpd_rrq(struct pbuf *, ip_addr_t *, u16_t); static void tftp_xfer_recv(void *, struct udp_pcb *, struct pbuf *, ip_addr_t *, u16_t); static void tftp_recv_ack(struct xfer *, u16_t); static void tftp_fillbuf(struct xfer *); static void tftp_send(struct xfer *); static void tftp_timeout(void *); static struct xfer *tftp_xfer_alloc(ip_addr_t *, u16_t); static int tftp_xfer_create_pcb(struct xfer *); static void tftp_xfer_free(struct xfer *); static int tftp_parse_filename(struct xfer *, char **, size_t *); static int tftp_parse_mode(struct xfer *, char **, size_t *); static int tftp_parse_option(struct xfer *, char **, size_t *); static int tftp_opt_blksize(struct xfer *, const char *); static int tftp_opt_timeout(struct xfer *, const char *); static int tftp_opt_tsize(struct xfer *, const char *); static char *tftp_getstr(struct xfer *, const char *, char **, size_t *); static int tftp_ack_blksize(struct xfer *, char **, size_t *); static int tftp_ack_timeout(struct xfer *, char **, size_t *); static int tftp_ack_tsize(struct xfer *, char **, size_t *); static int tftp_add_oack(char **, size_t *, const char *, const char *, ...) __attribute__((format(printf, 4, 5))); static ssize_t tftp_strnlen(char *, size_t); static int tftp_internal_error(struct xfer *); static int tftp_error(struct xfer *, u16_t, const char *, ...) __attribute__((format(printf, 3, 4))); static void tftpd_error(ip_addr_t *, u16_t, u16_t, const char *, ...) __attribute__((format(printf, 4, 5))); static struct pbuf *tftp_verror(u16_t, const char *, va_list); /* const */ int report_transient_errors = 1; static struct tftpd tftpd; static struct tftp_option tftp_options[] = { { "blksize", tftp_opt_blksize, tftp_ack_blksize }, /* RFC 2348 */ { "timeout", tftp_opt_timeout, tftp_ack_timeout }, /* RFC 2349 */ { "tsize", tftp_opt_tsize, tftp_ack_tsize }, /* RFC 2349 */ { NULL, NULL, NULL } }; err_t tftpd_init(struct netif *proxy_netif, const char *tftproot) { size_t len; err_t error; tftpd.root = strdup(tftproot); if (tftpd.root == NULL) { DPRINTF0(("%s: failed to allocate tftpd.root\n", __func__)); return ERR_MEM; } len = strlen(tftproot); if (tftpd.root[len - 1] == '/') { tftpd.root[len - 1] = '\0'; } tftpd.pcb = udp_new(); if (tftpd.pcb == NULL) { DPRINTF0(("%s: failed to allocate PCB\n", __func__)); return ERR_MEM; } udp_recv(tftpd.pcb, tftpd_recv, NULL); error = udp_bind(tftpd.pcb, &proxy_netif->ip_addr, TFTP_SERVER_PORT); if (error != ERR_OK) { DPRINTF0(("%s: failed to bind PCB\n", __func__)); return error; } return ERR_OK; } static void tftpd_recv(void *arg, struct udp_pcb *pcb, struct pbuf *p, ip_addr_t *addr, u16_t port) { u16_t op; LWIP_ASSERT1(pcb == tftpd.pcb); LWIP_UNUSED_ARG(pcb); /* only in assert */ LWIP_UNUSED_ARG(arg); if (pbuf_clen(p) > 1) { /* this code assumes contiguous aligned payload */ pbuf_free(p); return; } op = ntohs(*(u16_t *)p->payload); switch (op) { case TFTP_RRQ: tftpd_rrq(p, addr, port); break; case TFTP_WRQ: tftpd_error(addr, port, TFTP_EACCESS, "Permission denied"); break; default: tftpd_error(addr, port, TFTP_ENOSYS, "Bad opcode %d", op); break; } pbuf_free(p); } /** * Parse Read Request packet and start new transfer. */ static void tftpd_rrq(struct pbuf *p, ip_addr_t *addr, u16_t port) { struct xfer *xfer; char *s; size_t len; int has_options; int status; xfer = tftp_xfer_alloc(addr, port); if (xfer == NULL) { return; } /* skip opcode */ s = (char *)p->payload + sizeof(u16_t); len = p->len - sizeof(u16_t); /* * Parse RRQ: * filename, mode, [opt1, value1, [...] ] */ status = tftp_parse_filename(xfer, &s, &len); if (status < 0) { goto terminate; } status = tftp_parse_mode(xfer, &s, &len); if (status < 0) { goto terminate; } has_options = 0; while (len > 0) { status = tftp_parse_option(xfer, &s, &len); if (status < 0) { goto terminate; } has_options += status; } /* * Create OACK packet if necessary. */ if (has_options) { xfer->oack = pbuf_alloc(PBUF_RAW, 128, PBUF_RAM); if (xfer->oack != NULL) { struct tftp_option *o; ((u16_t *)xfer->oack->payload)[0] = PP_HTONS(TFTP_OACK); s = (char *)xfer->oack->payload + sizeof(u16_t); len = xfer->oack->len - sizeof(u16_t); for (o = &tftp_options[0]; o->name != NULL; ++o) { status = (*o->ackopt)(xfer, &s, &len); if (status < 0) { pbuf_free(xfer->oack); xfer->oack = NULL; break; } } if (xfer->oack != NULL) { pbuf_realloc(xfer->oack, xfer->oack->len - len); } } } /* * Create static pbuf that will be used for all data packets. */ xfer->pbuf = pbuf_alloc(PBUF_RAW, xfer->blksize + 4, PBUF_RAM); if (xfer->pbuf == NULL) { tftp_internal_error(xfer); goto terminate; } ((u16_t *)xfer->pbuf->payload)[0] = PP_HTONS(TFTP_DATA); /* * Finally, create PCB. Before this point any error was reported * from the server port (see tftp_error() for the reason). */ status = tftp_xfer_create_pcb(xfer); if (status < 0) { goto terminate; } if (xfer->oack) { tftp_send(xfer); } else { /* trigger send of the first data packet */ tftp_recv_ack(xfer, 0); } return; terminate: DPRINTF(("%s: terminated", __func__)); tftp_xfer_free(xfer); } static void tftp_xfer_recv(void *arg, struct udp_pcb *pcb, struct pbuf *p, ip_addr_t *addr, u16_t port) { struct xfer *xfer = (struct xfer *)arg; u16_t op; LWIP_UNUSED_ARG(pcb); /* assert only */ LWIP_UNUSED_ARG(addr); LWIP_UNUSED_ARG(port); LWIP_ASSERT1(xfer->pcb == pcb); if (p->len < 2) { tftp_error(xfer, TFTP_ENOSYS, "Short packet"); tftp_xfer_free(xfer); pbuf_free(p); return; } op = ntohs(*(u16_t *)p->payload); if (op == TFTP_ACK) { u16_t ack; if (p->len < 4) { tftp_error(xfer, TFTP_ENOSYS, "Short packet"); tftp_xfer_free(xfer); pbuf_free(p); return; } ack = ntohs(((u16_t *)p->payload)[1]); tftp_recv_ack(xfer, ack); } else if (op == TFTP_ERROR) { tftp_xfer_free(xfer); } else { tftp_error(xfer, TFTP_ENOSYS, "Unexpected opcode %d", op); tftp_xfer_free(xfer); } pbuf_free(p); } static void tftp_recv_ack(struct xfer *xfer, u16_t ack) { if (ack != (u16_t)xfer->ack) { DPRINTF2(("%s: expect %u (%u), got %u\n", __func__, (u16_t)xfer->ack, xfer->ack, ack)); return; } sys_untimeout(tftp_timeout, xfer); xfer->rexmit = 0; if (xfer->pbuf->len < xfer->blksize) { DPRINTF(("%s: got final ack %u (%u)\n", __func__, (u16_t)xfer->ack, xfer->ack)); tftp_xfer_free(xfer); return; } if (xfer->oack != NULL) { pbuf_free(xfer->oack); xfer->oack = NULL; } ++xfer->ack; tftp_fillbuf(xfer); tftp_send(xfer); } static void tftp_send(struct xfer *xfer) { struct pbuf *pbuf; pbuf = xfer->oack ? xfer->oack : xfer->pbuf; udp_send(xfer->pcb, pbuf); sys_timeout(xfer->timeout * 1000, tftp_timeout, xfer); } static void tftp_timeout(void *arg) { struct xfer *xfer = (struct xfer *)arg; int maxrexmit; maxrexmit = xfer->timeout < 60 ? 5 : 3; if (++xfer->rexmit < maxrexmit) { tftp_send(xfer); } else { tftp_xfer_free(xfer); } } static void tftp_fillbuf(struct xfer *xfer) { ssize_t nread; DPRINTF2(("%s: reading block %u\n", __func__, xfer->ack)); ((u16_t *)xfer->pbuf->payload)[1] = htons(xfer->ack); nread = read(xfer->fd, (char *)xfer->pbuf->payload + 4, xfer->blksize); if (nread < 0) { tftp_error(xfer, TFTP_EUNDEF, "Read failed"); return; } pbuf_realloc(xfer->pbuf, nread + 4); } /** * Find a free transfer slot (without a pcb). Record peer's IP * address and port, but don't allocate a pcb yet. * * We delay creation of the pcb in response to the original request * until the request is verified and accepted. This makes using * tcpdump(8) easier, since tcpdump does not track TFTP transfers, so * an error reply from a new pcb is not recognized as such and is not * decoded as TFTP (see tftp_error()). * * If the request is rejected, the pcb remains NULL and the transfer * slot remains unallocated. Since all TFTP processing happens on the * lwIP thread, there's no concurrent processing, so we don't need to * "lock" the transfer slot until the pcb is allocated. */ static struct xfer * tftp_xfer_alloc(ip_addr_t *addr, u16_t port) { struct xfer *xfer; int i; /* Find free xfer slot */ xfer = NULL; for (i = 0; i < TFTP_MAX_XFERS; ++i) { if (tftpd.xfers[i].pcb == NULL) { xfer = &tftpd.xfers[i]; break; } } if (xfer == NULL) { if (report_transient_errors) { tftpd_error(addr, port, TFTP_EUNDEF, "Maximum number of simultaneous connections exceeded"); } return NULL; } ipX_addr_copy(0, xfer->peer_ip, *ip_2_ipX(addr)); xfer->peer_port = port; xfer->ack = 0; xfer->pbuf = NULL; xfer->oack = NULL; xfer->rexmit = 0; xfer->blksize = 512; xfer->blksize_from_opt = 0; xfer->timeout = 1; xfer->timeout_from_opt = 0; xfer->tsize = -1; xfer->tsize_from_opt = 0; return xfer; } static int tftp_xfer_create_pcb(struct xfer *xfer) { struct udp_pcb *pcb; err_t error; pcb = udp_new(); /* Bind */ if (pcb != NULL) { error = udp_bind(pcb, ipX_2_ip(&tftpd.pcb->local_ip), 0); if (error != ERR_OK) { udp_remove(pcb); pcb = NULL; } } /* Connect */ if (pcb != NULL) { error = udp_connect(pcb, ipX_2_ip(&xfer->peer_ip), xfer->peer_port); if (error != ERR_OK) { udp_remove(pcb); pcb = NULL; } } if (pcb == NULL) { if (report_transient_errors) { tftp_error(xfer, TFTP_EUNDEF, "Failed to create connection"); } return -1; } xfer->pcb = pcb; udp_recv(xfer->pcb, tftp_xfer_recv, xfer); return 0; } static void tftp_xfer_free(struct xfer *xfer) { sys_untimeout(tftp_timeout, xfer); if (xfer->pcb != NULL) { udp_remove(xfer->pcb); xfer->pcb = NULL; } if (xfer->fd > 0) { close(xfer->fd); xfer->fd = -1; } if (xfer->oack != NULL) { pbuf_free(xfer->oack); xfer->oack = NULL; } if (xfer->pbuf != NULL) { pbuf_free(xfer->pbuf); xfer->pbuf = NULL; } if (xfer->filename != NULL) { free(xfer->filename); xfer->filename = NULL; } } static int tftp_parse_filename(struct xfer *xfer, char **ps, size_t *plen) { const char *filename; struct stat st; char *pathname; char *s; size_t len; int status; filename = tftp_getstr(xfer, "filename", ps, plen); if (filename == NULL) { return -1; } DPRINTF(("%s: requested file name: %s\n", __func__, filename)); xfer->filename = strdup(filename); if (xfer->filename == NULL) { return tftp_internal_error(xfer); } /* replace backslashes with forward slashes */ s = xfer->filename; while ((s = strchr(s, '\\')) != NULL) { *s++ = '/'; } /* deny attempts to break out of tftp dir */ if (strncmp(xfer->filename, "../", 3) == 0 || strstr(xfer->filename, "/../") != NULL) { return tftp_error(xfer, TFTP_ENOENT, "Permission denied"); } len = strlen(tftpd.root) + 1 /*slash*/ + strlen(xfer->filename) + 1 /*nul*/; pathname = (char *)malloc(len); if (pathname == NULL) { return tftp_internal_error(xfer); } status = RTStrPrintf(pathname, len, "%s/%s", tftpd.root, xfer->filename); if (status < 0) { return tftp_internal_error(xfer); } DPRINTF(("%s: full pathname: %s\n", __func__, pathname)); xfer->fd = open(pathname, O_RDONLY); if (xfer->fd < 0) { if (errno == EPERM) { return tftp_error(xfer, TFTP_ENOENT, "Permission denied"); } else { return tftp_error(xfer, TFTP_ENOENT, "File not found"); } } status = fstat(xfer->fd, &st); if (status < 0) { return tftp_internal_error(xfer); } if (!S_ISREG(st.st_mode)) { return tftp_error(xfer, TFTP_ENOENT, "File not found"); } xfer->tsize = st.st_size; return 0; } static int tftp_parse_mode(struct xfer *xfer, char **ps, size_t *plen) { const char *modename; modename = tftp_getstr(xfer, "mode", ps, plen); if (modename == NULL) { return -1; } if (RTStrICmp(modename, "octet") == 0) { xfer->octet = 1; } else if (RTStrICmp(modename, "netascii") == 0) { xfer->octet = 0; /* XXX: not (yet?) */ return tftp_error(xfer, TFTP_ENOSYS, "Mode \"netascii\" not supported"); } else if (RTStrICmp(modename, "mail") == 0) { return tftp_error(xfer, TFTP_ENOSYS, "Mode \"mail\" not supported"); } else { return tftp_error(xfer, TFTP_ENOSYS, "Unknown mode \"%s\"", modename); } return 0; } static int tftp_parse_option(struct xfer *xfer, char **ps, size_t *plen) { const char *opt; const char *val; struct tftp_option *o; opt = tftp_getstr(xfer, "option name", ps, plen); if (opt == NULL) { return -1; } if (*plen == 0) { return tftp_error(xfer, TFTP_EUNDEF, "Missing option value"); } val = tftp_getstr(xfer, "option value", ps, plen); if (val == NULL) { return -1; } /* handle option if known, ignore otherwise */ for (o = &tftp_options[0]; o->name != NULL; ++o) { if (RTStrICmp(o->name, opt) == 0) { return (*o->getopt)(xfer, val); } } return 0; /* unknown option */ } static int tftp_opt_blksize(struct xfer *xfer, const char *optval) { char *end; long blksize; errno = 0; blksize = strtol(optval, &end, 10); if (errno != 0 || *end != '\0') { return 0; } if (blksize < 8) { return 0; } if (blksize > 1428) { /* exceeds ethernet mtu */ blksize = 1428; } xfer->blksize = blksize; xfer->blksize_from_opt = 1; return 1; } static int tftp_opt_timeout(struct xfer *xfer, const char *optval) { LWIP_UNUSED_ARG(xfer); LWIP_UNUSED_ARG(optval); return 0; } static int tftp_opt_tsize(struct xfer *xfer, const char *optval) { LWIP_UNUSED_ARG(optval); /* must be "0", but we don't check it */ if (xfer->tsize < 0) { return 0; } xfer->tsize_from_opt = 1; return 1; } static char * tftp_getstr(struct xfer *xfer, const char *msg, char **ps, size_t *plen) { char *s; ssize_t slen; s = *ps; slen = tftp_strnlen(s, *plen); if (slen < 0) { tftp_error(xfer, TFTP_EUNDEF, "Unterminated %s", msg); return NULL; } *ps += slen + 1; *plen -= slen + 1; return s; } static int tftp_ack_blksize(struct xfer *xfer, char **ps, size_t *plen) { if (!xfer->blksize_from_opt) { return 0; } return tftp_add_oack(ps, plen, "blksize", "%u", xfer->blksize); } static int tftp_ack_timeout(struct xfer *xfer, char **ps, size_t *plen) { if (!xfer->timeout_from_opt) { return 0; } return tftp_add_oack(ps, plen, "timeout", "%u", xfer->timeout); } static int tftp_ack_tsize(struct xfer *xfer, char **ps, size_t *plen) { if (!xfer->tsize_from_opt) { return 0; } LWIP_ASSERT1(xfer->tsize >= 0); return tftp_add_oack(ps, plen, "tsize", /* XXX: FIXME: want 64 bit */ "%lu", (unsigned long)xfer->tsize); } static int tftp_add_oack(char **ps, size_t *plen, const char *optname, const char *fmt, ...) { va_list ap; int sz; sz = RTStrPrintf(*ps, *plen, "%s", optname); if (sz < 0 || (size_t)sz >= *plen) { return -1; } ++sz; /* for nul byte */ *ps += sz; *plen -= sz; va_start(ap, fmt); sz = vsnprintf(*ps, *plen, fmt, ap); va_end(ap); if (sz < 0 || (size_t)sz >= *plen) { return -1; } ++sz; /* for nul byte */ *ps += sz; *plen -= sz; return 0; } static ssize_t tftp_strnlen(char *buf, size_t bufsize) { void *end; end = memchr(buf, '\0', bufsize); if (end == NULL) { return -1; } return (char *)end - buf; } static int tftp_internal_error(struct xfer *xfer) { if (report_transient_errors) { tftp_error(xfer, TFTP_EUNDEF, "Internal error"); } return -1; } /** * Send an error packet to the peer. * * PCB may not be created yet in which case send the error packet from * the TFTP server port (*). * * (*) We delay creation of the PCB in response to the original * request until the request is verified and accepted. This makes * using tcpdump(8) easier, since tcpdump does not track TFTP * transfers, so an error reply from a new PCB is not recognized as * such and is not decoded as TFTP. * * Always returns -1 for callers to reuse. */ static int tftp_error(struct xfer *xfer, u16_t error, const char *fmt, ...) { va_list ap; struct pbuf *q; LWIP_ASSERT1(xfer != NULL); va_start(ap, fmt); q = tftp_verror(error, fmt, ap); va_end(ap); if (q == NULL) { return -1; } if (xfer->pcb != NULL) { udp_send(xfer->pcb, q); } else { udp_sendto(tftpd.pcb, q, ipX_2_ip(&xfer->peer_ip), xfer->peer_port); } pbuf_free(q); return -1; } /** * Send an error packet from TFTP server port to the specified peer. */ static void tftpd_error(ip_addr_t *addr, u16_t port, u16_t error, const char *fmt, ...) { va_list ap; struct pbuf *q; va_start(ap, fmt); q = tftp_verror(error, fmt, ap); va_end(ap); if (q != NULL) { udp_sendto(tftpd.pcb, q, addr, port); pbuf_free(q); } } /** * Create ERROR pbuf with formatted error message. */ static struct pbuf * tftp_verror(u16_t error, const char *fmt, va_list ap) { struct tftp_error { u16_t opcode; /* TFTP_ERROR */ u16_t errcode; char errmsg[512]; }; struct pbuf *p; struct tftp_error *errpkt; int msgsz; p = pbuf_alloc(PBUF_TRANSPORT, sizeof(*errpkt), PBUF_RAM); if (p == NULL) { return NULL; } errpkt = (struct tftp_error *)p->payload; errpkt->opcode = PP_HTONS(TFTP_ERROR); errpkt->errcode = htons(error); msgsz = vsnprintf(errpkt->errmsg, sizeof(errpkt->errmsg), fmt, ap); if (msgsz < 0) { errpkt->errmsg[0] = '\0'; msgsz = 1; } else if ((size_t)msgsz < sizeof(errpkt->errmsg)) { ++msgsz; /* for nul byte */ } else { msgsz = sizeof(errpkt->errmsg); /* truncated, includes nul byte */ } pbuf_realloc(p, sizeof(*errpkt) - sizeof(errpkt->errmsg) + msgsz); return p; }