/* $OpenBSD: xdr_rec.c,v 1.13 2008/12/09 19:40:10 otto Exp $ */ /* * Sun RPC is a product of Sun Microsystems, Inc. and is provided for * unrestricted use provided that this legend is included on all tape * media and as a part of the software program in whole or part. Users * may copy or modify Sun RPC without charge, but are not authorized * to license or distribute it to anyone else except as part of a product or * program developed by the user. * * SUN RPC IS PROVIDED AS IS WITH NO WARRANTIES OF ANY KIND INCLUDING THE * WARRANTIES OF DESIGN, MERCHANTIBILITY AND FITNESS FOR A PARTICULAR * PURPOSE, OR ARISING FROM A COURSE OF DEALING, USAGE OR TRADE PRACTICE. * * Sun RPC is provided with no support and without any obligation on the * part of Sun Microsystems, Inc. to assist in its use, correction, * modification or enhancement. * * SUN MICROSYSTEMS, INC. SHALL HAVE NO LIABILITY WITH RESPECT TO THE * INFRINGEMENT OF COPYRIGHTS, TRADE SECRETS OR ANY PATENTS BY SUN RPC * OR ANY PART THEREOF. * * In no event will Sun Microsystems, Inc. be liable for any lost revenue * or profits or other special, indirect and consequential damages, even if * Sun has been advised of the possibility of such damages. * * Sun Microsystems, Inc. * 2550 Garcia Avenue * Mountain View, California 94043 */ /* * xdr_rec.c, Implements TCP/IP based XDR streams with a "record marking" * layer above tcp (for rpc's use). * * Copyright (C) 1984, Sun Microsystems, Inc. * * These routines interface XDRSTREAMS to a tcp/ip connection. * There is a record marking layer between the xdr stream * and the tcp transport level. A record is composed on one or more * record fragments. A record fragment is a thirty-two bit header followed * by n bytes of data, where n is contained in the header. The header * is represented as a htonl(u_int32_t). The high order bit encodes * whether or not the fragment is the last fragment of the record * (1 => fragment is last, 0 => more fragments to follow. * The other 31 bits encode the byte length of the fragment. */ #include #include #include #include #include #include #include #include #include #include #include static bool_t xdrrec_getlong(XDR *, long *); static bool_t xdrrec_putlong(XDR *, long *); static bool_t xdrrec_getbytes(XDR *, caddr_t, u_int); static bool_t xdrrec_putbytes(XDR *, caddr_t, u_int); static u_int xdrrec_getpos(XDR *); static bool_t xdrrec_setpos(XDR *, u_int); static int32_t *xdrrec_inline(XDR *, u_int); static void xdrrec_destroy(XDR *); struct ct_data; static struct xdr_ops xdrrec_ops = { xdrrec_getlong, xdrrec_putlong, xdrrec_getbytes, xdrrec_putbytes, xdrrec_getpos, xdrrec_setpos, xdrrec_inline, xdrrec_destroy, NULL, /* xdrrec_control */ }; /* * A record is composed of one or more record fragments. * A record fragment is a four-byte header followed by zero to * 2**32-1 bytes. The header is treated as a long unsigned and is * encode/decoded to the network via htonl/ntohl. The low order 31 bits * are a byte count of the fragment. The highest order bit is a boolean: * 1 => this fragment is the last fragment of the record, * 0 => this fragment is followed by more fragment(s). * * The fragment/record machinery is not general; it is constructed to * meet the needs of xdr and rpc based on tcp. */ #define LAST_FRAG ((u_int32_t)(1 << 31)) typedef struct rec_strm { caddr_t tcp_handle; /* * out-goung bits */ int (*writeit)(caddr_t, caddr_t, int); caddr_t out_base; /* output buffer (points to frag header) */ caddr_t out_finger; /* next output position */ caddr_t out_boundry; /* data cannot up to this address */ u_int32_t *frag_header; /* beginning of current fragment */ bool_t frag_sent; /* true if buffer sent in middle of record */ /* * in-coming bits */ int (*readit)(caddr_t, caddr_t, int); u_long in_size; /* fixed size of the input buffer */ caddr_t in_base; caddr_t in_finger; /* location of next byte to be had */ caddr_t in_boundry; /* can read up to this location */ long fbtbc; /* fragment bytes to be consumed */ bool_t last_frag; u_int sendsize; u_int recvsize; bool_t nonblock; bool_t in_haveheader; u_int32_t in_header; char *in_hdrp; int in_hdrlen; int in_reclen; int in_received; int in_maxrec; } RECSTREAM; static u_int fix_buf_size(u_int); static bool_t flush_out(RECSTREAM *, bool_t); static bool_t fill_input_buf(RECSTREAM *); static bool_t get_input_bytes(RECSTREAM *, caddr_t, int); static bool_t set_input_fragment(RECSTREAM *); static bool_t skip_input_bytes(RECSTREAM *, long); static bool_t realloc_stream(RECSTREAM *, int); /* * Create an xdr handle for xdrrec * xdrrec_create fills in xdrs. Sendsize and recvsize are * send and recv buffer sizes (0 => use default). * tcp_handle is an opaque handle that is passed as the first parameter to * the procedures readit and writeit. Readit and writeit are read and * write respectively. They are like the system * calls expect that they take an opaque handle rather than an fd. */ void xdrrec_create(XDR *xdrs, u_int sendsize, u_int recvsize, caddr_t tcp_handle, int (*readit)(caddr_t, caddr_t, int), /* like read, but pass it a tcp_handle, not sock */ int (*writeit)(caddr_t, caddr_t, int)) /* like write, but pass it a tcp_handle, not sock */ { RECSTREAM *rstrm = (RECSTREAM *)mem_alloc(sizeof(RECSTREAM)); if (rstrm == NULL) { (void)fprintf(stderr, "xdrrec_create: out of memory\n"); /* * This is bad. Should rework xdrrec_create to * return a handle, and in this case return NULL */ return; } rstrm->sendsize = sendsize = fix_buf_size(sendsize); rstrm->out_base = malloc(rstrm->sendsize); if (rstrm->out_base == NULL) { (void)fprintf(stderr, "xdrrec_create: out of memory\n"); mem_free(rstrm, sizeof(RECSTREAM)); return; } rstrm->recvsize = recvsize = fix_buf_size(recvsize); rstrm->in_base = malloc(recvsize); if (rstrm->in_base == NULL) { (void)fprintf(stderr, "xdrrec_create: out of memory\n"); mem_free(rstrm->out_base, sendsize); mem_free(rstrm, sizeof(RECSTREAM)); return; } /* * now the rest ... */ xdrs->x_ops = &xdrrec_ops; xdrs->x_private = (caddr_t)rstrm; rstrm->tcp_handle = tcp_handle; rstrm->readit = readit; rstrm->writeit = writeit; rstrm->out_finger = rstrm->out_boundry = rstrm->out_base; rstrm->frag_header = (u_int32_t *)rstrm->out_base; rstrm->out_finger += sizeof(u_int32_t); rstrm->out_boundry += sendsize; rstrm->frag_sent = FALSE; rstrm->in_size = recvsize; rstrm->in_boundry = rstrm->in_base; rstrm->in_finger = (rstrm->in_boundry += recvsize); rstrm->fbtbc = 0; rstrm->last_frag = TRUE; rstrm->in_haveheader = FALSE; rstrm->in_hdrlen = 0; rstrm->in_hdrp = (char *)(void *)&rstrm->in_header; rstrm->nonblock = FALSE; rstrm->in_reclen = 0; rstrm->in_received = 0; } /* * The reoutines defined below are the xdr ops which will go into the * xdr handle filled in by xdrrec_create. */ static bool_t xdrrec_getlong(XDR *xdrs, long int *lp) { RECSTREAM *rstrm = (RECSTREAM *)(xdrs->x_private); int32_t *buflp = (int32_t *)(rstrm->in_finger); int32_t mylong; /* first try the inline, fast case */ if ((rstrm->fbtbc >= sizeof(int32_t)) && (((long)rstrm->in_boundry - (long)buflp) >= sizeof(int32_t))) { *lp = (long)ntohl((u_int32_t)(*buflp)); rstrm->fbtbc -= sizeof(int32_t); rstrm->in_finger += sizeof(int32_t); } else { if (! xdrrec_getbytes(xdrs, (caddr_t)(void *)&mylong, sizeof(int32_t))) return (FALSE); *lp = (long)ntohl((u_int32_t)mylong); } return (TRUE); } static bool_t xdrrec_putlong(XDR *xdrs, long int *lp) { RECSTREAM *rstrm = (RECSTREAM *)(xdrs->x_private); int32_t *dest_lp = ((int32_t *)(rstrm->out_finger)); if ((rstrm->out_finger += sizeof(int32_t)) > rstrm->out_boundry) { /* * this case should almost never happen so the code is * inefficient */ rstrm->out_finger -= sizeof(int32_t); rstrm->frag_sent = TRUE; if (! flush_out(rstrm, FALSE)) return (FALSE); dest_lp = ((int32_t *)(void *)(rstrm->out_finger)); rstrm->out_finger += sizeof(int32_t); } *dest_lp = (int32_t)htonl((u_int32_t)(*lp)); return (TRUE); } static bool_t /* must manage buffers, fragments, and records */ xdrrec_getbytes(XDR *xdrs, caddr_t addr, u_int len) { RECSTREAM *rstrm = (RECSTREAM *)(xdrs->x_private); int current; while (len > 0) { current = rstrm->fbtbc; if (current == 0) { if (rstrm->last_frag) return (FALSE); if (! set_input_fragment(rstrm)) return (FALSE); continue; } current = (len < current) ? len : current; if (! get_input_bytes(rstrm, addr, current)) return (FALSE); addr += current; rstrm->fbtbc -= current; len -= current; } return (TRUE); } static bool_t xdrrec_putbytes(XDR *xdrs, caddr_t addr, u_int len) { RECSTREAM *rstrm = (RECSTREAM *)(xdrs->x_private); long current; while (len > 0) { current = (u_long)rstrm->out_boundry - (u_long)rstrm->out_finger; current = (len < current) ? len : current; memcpy(rstrm->out_finger, addr, current); rstrm->out_finger += current; addr += current; len -= current; if (rstrm->out_finger == rstrm->out_boundry) { rstrm->frag_sent = TRUE; if (! flush_out(rstrm, FALSE)) return (FALSE); } } return (TRUE); } static u_int xdrrec_getpos(XDR *xdrs) { RECSTREAM *rstrm = (RECSTREAM *)xdrs->x_private; off_t pos; pos = lseek((int)(long)rstrm->tcp_handle, (off_t)0, SEEK_CUR); if (pos != (off_t)-1) switch (xdrs->x_op) { case XDR_ENCODE: pos += rstrm->out_finger - rstrm->out_base; break; case XDR_DECODE: pos -= rstrm->in_boundry - rstrm->in_finger; break; default: pos = -1; break; } return ((u_int) pos); } static bool_t xdrrec_setpos(XDR *xdrs, u_int pos) { RECSTREAM *rstrm = (RECSTREAM *)xdrs->x_private; u_int currpos = xdrrec_getpos(xdrs); int delta = currpos - pos; caddr_t newpos; if ((int)currpos != -1) switch (xdrs->x_op) { case XDR_ENCODE: newpos = rstrm->out_finger - delta; if ((newpos > (caddr_t)(rstrm->frag_header)) && (newpos < rstrm->out_boundry)) { rstrm->out_finger = newpos; return (TRUE); } break; case XDR_DECODE: newpos = rstrm->in_finger - delta; if ((delta < (int)(rstrm->fbtbc)) && (newpos <= rstrm->in_boundry) && (newpos >= rstrm->in_base)) { rstrm->in_finger = newpos; rstrm->fbtbc -= delta; return (TRUE); } break; case XDR_FREE: break; } return (FALSE); } static int32_t * xdrrec_inline(XDR *xdrs, u_int len) { RECSTREAM *rstrm = (RECSTREAM *)xdrs->x_private; int32_t *buf = NULL; switch (xdrs->x_op) { case XDR_ENCODE: if ((rstrm->out_finger + len) <= rstrm->out_boundry) { buf = (int32_t *) rstrm->out_finger; rstrm->out_finger += len; } break; case XDR_DECODE: if ((len <= rstrm->fbtbc) && ((rstrm->in_finger + len) <= rstrm->in_boundry)) { buf = (int32_t *) rstrm->in_finger; rstrm->fbtbc -= len; rstrm->in_finger += len; } break; case XDR_FREE: break; } return (buf); } static void xdrrec_destroy(XDR *xdrs) { RECSTREAM *rstrm = (RECSTREAM *)xdrs->x_private; mem_free(rstrm->out_base, rstrm->sendsize); mem_free(rstrm->in_base, rstrm->recvsize); mem_free(rstrm, sizeof(RECSTREAM)); } /* * Exported routines to manage xdr records */ /* * Before reading (deserializing from the stream, one should always call * this procedure to guarantee proper record alignment. */ bool_t xdrrec_skiprecord(XDR *xdrs) { RECSTREAM *rstrm = (RECSTREAM *)(xdrs->x_private); enum xprt_stat xstat; if (rstrm->nonblock) { if (__xdrrec_getrec(xdrs, &xstat, FALSE)) { rstrm->fbtbc = 0; return (TRUE); } if (rstrm->in_finger == rstrm->in_boundry && xstat == XPRT_MOREREQS) { rstrm->fbtbc = 0; return (TRUE); } return (FALSE); } while (rstrm->fbtbc > 0 || (! rstrm->last_frag)) { if (! skip_input_bytes(rstrm, rstrm->fbtbc)) return (FALSE); rstrm->fbtbc = 0; if ((! rstrm->last_frag) && (! set_input_fragment(rstrm))) return (FALSE); } rstrm->last_frag = FALSE; return (TRUE); } /* * Look ahead fuction. * Returns TRUE iff there is no more input in the buffer * after consuming the rest of the current record. */ bool_t xdrrec_eof(XDR *xdrs) { RECSTREAM *rstrm = (RECSTREAM *)(xdrs->x_private); while (rstrm->fbtbc > 0 || (! rstrm->last_frag)) { if (! skip_input_bytes(rstrm, rstrm->fbtbc)) return (TRUE); rstrm->fbtbc = 0; if ((! rstrm->last_frag) && (! set_input_fragment(rstrm))) return (TRUE); } if (rstrm->in_finger == rstrm->in_boundry) return (TRUE); return (FALSE); } /* * The client must tell the package when an end-of-record has occurred. * The second paraemters tells whether the record should be flushed to the * (output) tcp stream. (This let's the package support batched or * pipelined procedure calls.) TRUE => immmediate flush to tcp connection. */ bool_t xdrrec_endofrecord(XDR *xdrs, int32_t sendnow) { RECSTREAM *rstrm = (RECSTREAM *)(xdrs->x_private); u_long len; /* fragment length */ if (sendnow || rstrm->frag_sent || ((u_long)rstrm->out_finger + sizeof(u_int32_t) >= (u_long)rstrm->out_boundry)) { rstrm->frag_sent = FALSE; return (flush_out(rstrm, TRUE)); } len = (u_long)(rstrm->out_finger) - (u_long)(rstrm->frag_header) - sizeof(u_int32_t); *(rstrm->frag_header) = htonl((u_long)len | LAST_FRAG); rstrm->frag_header = (u_int32_t *)rstrm->out_finger; rstrm->out_finger += sizeof(u_int32_t); return (TRUE); } /* * Fill the stream buffer with a record for a non-blocking connection. * Return true if a record is available in the buffer, false if not. */ bool_t __xdrrec_getrec(XDR *xdrs, enum xprt_stat *statp, bool_t expectdata) { RECSTREAM *rstrm = (RECSTREAM *)(xdrs->x_private); ssize_t n; int fraglen; if (!rstrm->in_haveheader) { n = rstrm->readit(rstrm->tcp_handle, rstrm->in_hdrp, (int)sizeof (rstrm->in_header) - rstrm->in_hdrlen); if (n == 0) { *statp = expectdata ? XPRT_DIED : XPRT_IDLE; return (FALSE); } if (n < 0) { *statp = XPRT_DIED; return (FALSE); } rstrm->in_hdrp += n; rstrm->in_hdrlen += n; if (rstrm->in_hdrlen < sizeof (rstrm->in_header)) { *statp = XPRT_MOREREQS; return (FALSE); } rstrm->in_header = ntohl(rstrm->in_header); fraglen = (int)(rstrm->in_header & ~LAST_FRAG); if (fraglen == 0 || fraglen > rstrm->in_maxrec || (rstrm->in_reclen + fraglen) > rstrm->in_maxrec) { *statp = XPRT_DIED; return (FALSE); } rstrm->in_reclen += fraglen; if (rstrm->in_reclen > rstrm->recvsize) realloc_stream(rstrm, rstrm->in_reclen); if (rstrm->in_header & LAST_FRAG) { rstrm->in_header &= ~LAST_FRAG; rstrm->last_frag = TRUE; } } n = rstrm->readit(rstrm->tcp_handle, rstrm->in_base + rstrm->in_received, (rstrm->in_reclen - rstrm->in_received)); if (n < 0) { *statp = XPRT_DIED; return (FALSE); } if (n == 0) { *statp = expectdata ? XPRT_DIED : XPRT_IDLE; return (FALSE); } rstrm->in_received += n; if (rstrm->in_received == rstrm->in_reclen) { rstrm->in_haveheader = (FALSE); rstrm->in_hdrp = (char *)(void *)&rstrm->in_header; rstrm->in_hdrlen = 0; if (rstrm->last_frag) { rstrm->fbtbc = rstrm->in_reclen; rstrm->in_boundry = rstrm->in_base + rstrm->in_reclen; rstrm->in_finger = rstrm->in_base; rstrm->in_reclen = rstrm->in_received = 0; *statp = XPRT_MOREREQS; return (TRUE); } } *statp = XPRT_MOREREQS; return (FALSE); } bool_t __xdrrec_setnonblock(XDR *xdrs, int maxrec) { RECSTREAM *rstrm = (RECSTREAM *)(xdrs->x_private); rstrm->nonblock = TRUE; if (maxrec == 0) maxrec = rstrm->recvsize; rstrm->in_maxrec = maxrec; return (TRUE); } /* * Internal useful routines */ static bool_t flush_out(RECSTREAM *rstrm, int32_t eor) { u_long eormask = (eor == TRUE) ? LAST_FRAG : 0; u_int32_t len = (u_long)(rstrm->out_finger) - (u_long)(rstrm->frag_header) - sizeof(u_int32_t); *(rstrm->frag_header) = htonl(len | eormask); len = (u_long)(rstrm->out_finger) - (u_long)(rstrm->out_base); if ((*(rstrm->writeit))(rstrm->tcp_handle, rstrm->out_base, (int)len) != (int)len) return (FALSE); rstrm->frag_header = (u_int32_t *)rstrm->out_base; rstrm->out_finger = (caddr_t)rstrm->out_base + sizeof(u_int32_t); return (TRUE); } static bool_t /* knows nothing about records! Only about input buffers */ fill_input_buf(RECSTREAM *rstrm) { caddr_t where; u_long i; long len; if (rstrm->nonblock) return FALSE; where = rstrm->in_base; i = (u_long)rstrm->in_boundry % BYTES_PER_XDR_UNIT; where += i; len = rstrm->in_size - i; if ((len = (*(rstrm->readit))(rstrm->tcp_handle, where, len)) == -1) return (FALSE); rstrm->in_finger = where; where += len; rstrm->in_boundry = where; return (TRUE); } static bool_t /* knows nothing about records! Only about input buffers */ get_input_bytes(RECSTREAM *rstrm, caddr_t addr, int len) { long current; if (rstrm->nonblock) { if (len > (int)(rstrm->in_boundry - rstrm->in_finger)) return FALSE; memcpy(addr, rstrm->in_finger, (size_t)len); rstrm->in_finger += len; return (TRUE); } while (len > 0) { current = (long)rstrm->in_boundry - (long)rstrm->in_finger; if (current == 0) { if (! fill_input_buf(rstrm)) return (FALSE); continue; } current = (len < current) ? len : current; memcpy(addr, rstrm->in_finger, current); rstrm->in_finger += current; addr += current; len -= current; } return (TRUE); } static bool_t /* next four bytes of the input stream are treated as a header */ set_input_fragment(RECSTREAM *rstrm) { u_int32_t header; if (rstrm->nonblock) return (FALSE); if (! get_input_bytes(rstrm, (caddr_t)&header, sizeof(header))) return (FALSE); header = (long)ntohl(header); rstrm->last_frag = ((header & LAST_FRAG) == 0) ? FALSE : TRUE; /* * Sanity check. Try not to accept wildly incorrect * record sizes. Unfortunately, the only record size * we can positively identify as being 'wildly incorrect' * is zero. Ridiculously large record sizes may look wrong, * but we don't have any way to be certain that they aren't * what the client actually intended to send us. */ if (header == 0) return(FALSE); rstrm->fbtbc = header & (~LAST_FRAG); return (TRUE); } static bool_t /* consumes input bytes; knows nothing about records! */ skip_input_bytes(RECSTREAM *rstrm, long int cnt) { long current; while (cnt > 0) { current = (long)rstrm->in_boundry - (long)rstrm->in_finger; if (current == 0) { if (! fill_input_buf(rstrm)) return (FALSE); continue; } current = (cnt < current) ? cnt : current; rstrm->in_finger += current; cnt -= current; } return (TRUE); } static u_int fix_buf_size(u_int s) { if (s < 100) s = 4000; return (RNDUP(s)); } /* * Reallocate the input buffer for a non-block stream. */ static bool_t realloc_stream(RECSTREAM *rstrm, int size) { ptrdiff_t diff; char *buf; if (size > rstrm->recvsize) { buf = realloc(rstrm->in_base, (size_t)size); if (buf == NULL) return (FALSE); diff = buf - rstrm->in_base; rstrm->in_finger += diff; rstrm->in_base = buf; rstrm->in_boundry = buf + size; rstrm->recvsize = size; rstrm->in_size = size; } return (TRUE); }