/* $OpenBSD: rpc_cout.c,v 1.3 1996/12/10 15:29:34 deraadt Exp $ */ /* $NetBSD: rpc_cout.c,v 1.6 1996/10/01 04:13:53 cgd 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 or with the express written consent of * Sun Microsystems, Inc. * * 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 */ #ifndef lint static char sccsid[] = "@(#)rpc_cout.c 1.13 89/02/22 (C) 1987 SMI"; #endif /* * rpc_cout.c, XDR routine outputter for the RPC protocol compiler */ #include #include #include #include #include "rpc_parse.h" #include "rpc_util.h" static findtype __P((definition *, char *)); static undefined __P((char *)); static print_generic_header __P((char *, int)); static print_header __P((definition *)); static print_prog_header __P((proc_list *)); static print_trailer __P((void)); static print_ifopen __P((int, char *)); static print_ifarg __P((char *)); static print_ifsizeof __P((char *, char *)); static print_ifclose __P((int)); static print_ifstat __P((int, char *, char *, relation, char *, char *, char *)); static emit_num __P((definition *)); static emit_program __P((definition *)); static emit_enum __P((definition *)); static emit_union __P((definition *)); static emit_struct __P((definition *)); static emit_typedef __P((definition *)); static print_stat __P((int, declaration *)); /* * Emit the C-routine for the given definition */ void emit(def) definition *def; { if (def->def_kind == DEF_CONST) { return; } if (def->def_kind == DEF_PROGRAM) { emit_program(def); return; } if (def->def_kind == DEF_TYPEDEF) { /* now we need to handle declarations like struct typedef foo * foo; since we dont want this to be expanded into 2 calls to * xdr_foo */ if (strcmp(def->def.ty.old_type, def->def_name) == 0) return; }; print_header(def); switch (def->def_kind) { case DEF_UNION: emit_union(def); break; case DEF_ENUM: emit_enum(def); break; case DEF_STRUCT: emit_struct(def); break; case DEF_TYPEDEF: emit_typedef(def); break; } print_trailer(); } static findtype(def, type) definition *def; char *type; { if (def->def_kind == DEF_PROGRAM || def->def_kind == DEF_CONST) { return (0); } else { return (streq(def->def_name, type)); } } static undefined(type) char *type; { definition *def; def = (definition *) FINDVAL(defined, type, findtype); return (def == NULL); } static print_generic_header(procname, pointerp) char *procname; int pointerp; { f_print(fout, "\n"); f_print(fout, "bool_t\n"); if (Cflag) { f_print(fout, "xdr_%s(", procname); f_print(fout, "XDR *xdrs, "); f_print(fout, "%s ", procname); if (pointerp) f_print(fout, "*"); f_print(fout, "objp)\n{\n\n"); } else { f_print(fout, "xdr_%s(xdrs, objp)\n", procname); f_print(fout, "\tXDR *xdrs;\n"); f_print(fout, "\t%s ", procname); if (pointerp) f_print(fout, "*"); f_print(fout, "objp;\n{\n\n"); } } static print_header(def) definition *def; { decl_list *dl; bas_type *ptr; int i; print_generic_header(def->def_name, def->def_kind != DEF_TYPEDEF || !isvectordef(def->def.ty.old_type, def->def.ty.rel)); /* Now add Inline support */ if (inline == 0) return; /* May cause lint to complain. but ... */ f_print(fout, "\t register int32_t *buf;\n\n"); } static print_prog_header(plist) proc_list *plist; { print_generic_header(plist->args.argname, 1); } static print_trailer() { f_print(fout, "\treturn (TRUE);\n"); f_print(fout, "}\n"); } static print_ifopen(indent, name) int indent; char *name; { tabify(fout, indent); f_print(fout, " if (!xdr_%s(xdrs", name); } static print_ifarg(arg) char *arg; { f_print(fout, ", %s", arg); } static print_ifsizeof(prefix, type) char *prefix; char *type; { if (streq(type, "bool")) { f_print(fout, ", sizeof(bool_t), (xdrproc_t)xdr_bool"); } else { f_print(fout, ", sizeof("); if (undefined(type) && prefix) { f_print(fout, "%s ", prefix); } f_print(fout, "%s), (xdrproc_t)xdr_%s", type, type); } } static print_ifclose(indent) int indent; { f_print(fout, ")) {\n"); tabify(fout, indent); f_print(fout, "\t return (FALSE);\n"); tabify(fout, indent); f_print(fout, " }\n"); } static print_ifstat(indent, prefix, type, rel, amax, objname, name) int indent; char *prefix; char *type; relation rel; char *amax; char *objname; char *name; { char *alt = NULL; switch (rel) { case REL_POINTER: print_ifopen(indent, "pointer"); print_ifarg("(char **)"); f_print(fout, "%s", objname); print_ifsizeof(prefix, type); break; case REL_VECTOR: if (streq(type, "string")) { alt = "string"; } else if (streq(type, "opaque")) { alt = "opaque"; } if (alt) { print_ifopen(indent, alt); print_ifarg(objname); } else { print_ifopen(indent, "vector"); print_ifarg("(char *)"); f_print(fout, "%s", objname); } print_ifarg(amax); if (!alt) { print_ifsizeof(prefix, type); } break; case REL_ARRAY: if (streq(type, "string")) { alt = "string"; } else if (streq(type, "opaque")) { alt = "bytes"; } if (streq(type, "string")) { print_ifopen(indent, alt); print_ifarg(objname); } else { if (alt) { print_ifopen(indent, alt); } else { print_ifopen(indent, "array"); } print_ifarg("(char **)"); if (*objname == '&') { f_print(fout, "%s.%s_val, (u_int *)%s.%s_len", objname, name, objname, name); } else { f_print(fout, "&%s->%s_val, (u_int *)&%s->%s_len", objname, name, objname, name); } } print_ifarg(amax); if (!alt) { print_ifsizeof(prefix, type); } break; case REL_ALIAS: print_ifopen(indent, type); print_ifarg(objname); break; } print_ifclose(indent); } /* ARGSUSED */ static emit_enum(def) definition *def; { print_ifopen(1, "enum"); print_ifarg("(enum_t *)objp"); print_ifclose(1); } static emit_program(def) definition *def; { decl_list *dl; version_list *vlist; proc_list *plist; for (vlist = def->def.pr.versions; vlist != NULL; vlist = vlist->next) for (plist = vlist->procs; plist != NULL; plist = plist->next) { if (!newstyle || plist->arg_num < 2) continue; /* old style, or single * argument */ print_prog_header(plist); for (dl = plist->args.decls; dl != NULL; dl = dl->next) print_stat(1, &dl->decl); print_trailer(); } } static emit_union(def) definition *def; { declaration *dflt; case_list *cl; declaration *cs; char *object; char *vecformat = "objp->%s_u.%s"; char *format = "&objp->%s_u.%s"; print_stat(1, &def->def.un.enum_decl); f_print(fout, "\tswitch (objp->%s) {\n", def->def.un.enum_decl.name); for (cl = def->def.un.cases; cl != NULL; cl = cl->next) { f_print(fout, "\tcase %s:\n", cl->case_name); if (cl->contflag == 1) /* a continued case statement */ continue; cs = &cl->case_decl; if (!streq(cs->type, "void")) { object = alloc(strlen(def->def_name) + strlen(format) + strlen(cs->name) + 1); if (isvectordef(cs->type, cs->rel)) { s_print(object, vecformat, def->def_name, cs->name); } else { s_print(object, format, def->def_name, cs->name); } print_ifstat(2, cs->prefix, cs->type, cs->rel, cs->array_max, object, cs->name); free(object); } f_print(fout, "\t\tbreak;\n"); } dflt = def->def.un.default_decl; if (dflt != NULL) { if (!streq(dflt->type, "void")) { f_print(fout, "\tdefault:\n"); object = alloc(strlen(def->def_name) + strlen(format) + strlen(dflt->name) + 1); if (isvectordef(dflt->type, dflt->rel)) { s_print(object, vecformat, def->def_name, dflt->name); } else { s_print(object, format, def->def_name, dflt->name); } print_ifstat(2, dflt->prefix, dflt->type, dflt->rel, dflt->array_max, object, dflt->name); free(object); f_print(fout, "\t\tbreak;\n"); } } else { f_print(fout, "\tdefault:\n"); f_print(fout, "\t\treturn (FALSE);\n"); } f_print(fout, "\t}\n"); } static emit_struct(def) definition *def; { decl_list *dl; int i, j, size, flag; decl_list *cur, *psav; bas_type *ptr; char *sizestr, *plus; char ptemp[256]; int can_inline; if (inline == 0) { for (dl = def->def.st.decls; dl != NULL; dl = dl->next) print_stat(1, &dl->decl); return; } for (dl = def->def.st.decls; dl != NULL; dl = dl->next) if (dl->decl.rel == REL_VECTOR) { f_print(fout, "\t int i;\n"); break; } size = 0; can_inline = 0; for (dl = def->def.st.decls; dl != NULL; dl = dl->next) if ((dl->decl.prefix == NULL) && ((ptr = find_type(dl->decl.type)) != NULL) && ((dl->decl.rel == REL_ALIAS) || (dl->decl.rel == REL_VECTOR))) { if (dl->decl.rel == REL_ALIAS) size += ptr->length; else { can_inline = 1; break; /* can be inlined */ }; } else { if (size >= inline) { can_inline = 1; break; /* can be inlined */ } size = 0; } if (size > inline) can_inline = 1; if (can_inline == 0) { /* can not inline, drop back to old mode */ for (dl = def->def.st.decls; dl != NULL; dl = dl->next) print_stat(1, &dl->decl); return; }; flag = PUT; for (j = 0; j < 2; j++) { if (flag == PUT) f_print(fout, "\n\t if (xdrs->x_op == XDR_ENCODE) {\n"); else f_print(fout, "\n \t return (TRUE);\n\t} else if (xdrs->x_op == XDR_DECODE) {\n"); i = 0; size = 0; sizestr = NULL; for (dl = def->def.st.decls; dl != NULL; dl = dl->next) { /* xxx */ /* now walk down the list and check for basic types */ if ((dl->decl.prefix == NULL) && ((ptr = find_type(dl->decl.type)) != NULL) && ((dl->decl.rel == REL_ALIAS) || (dl->decl.rel == REL_VECTOR))) { if (i == 0) cur = dl; i++; if (dl->decl.rel == REL_ALIAS) size += ptr->length; else { /* this is required to handle arrays */ if (sizestr == NULL) plus = " "; else plus = "+"; if (ptr->length != 1) s_print(ptemp, " %s %s * %d", plus, dl->decl.array_max, ptr->length); else s_print(ptemp, " %s %s ", plus, dl->decl.array_max); /* now concatenate to sizestr !!!! */ if (sizestr == NULL) sizestr = strdup(ptemp); else { sizestr = (char *)realloc(sizestr, strlen(sizestr) + strlen(ptemp) + 1); if (sizestr == NULL) { f_print(stderr, "Fatal error : no memory \n"); crash(); }; sizestr = strcat(sizestr, ptemp); /* build up length of * array */ } } } else { if (i > 0) if (sizestr == NULL && size < inline) { /* don't expand into inline * code if size < inline */ while (cur != dl) { print_stat(1, &cur->decl); cur = cur->next; } } else { /* were already looking at a * xdr_inlineable structure */ if (sizestr == NULL) f_print(fout, "\t buf = (int32_t *)XDR_INLINE(xdrs,%d * BYTES_PER_XDR_UNIT);", size); else if (size == 0) f_print(fout, "\t buf = (int32_t *)XDR_INLINE(xdrs,%s * BYTES_PER_XDR_UNIT);", sizestr); else f_print(fout, "\t buf = (int32_t *)XDR_INLINE(xdrs,(%d + %s)* BYTES_PER_XDR_UNIT);", size, sizestr); f_print(fout, "\n\t if (buf == NULL) {\n"); psav = cur; while (cur != dl) { print_stat(2, &cur->decl); cur = cur->next; } f_print(fout, "\n\t }\n\t else {\n"); cur = psav; while (cur != dl) { emit_inline(&cur->decl, flag); cur = cur->next; } f_print(fout, "\t }\n"); } size = 0; i = 0; sizestr = NULL; print_stat(1, &dl->decl); } } if (i > 0) if (sizestr == NULL && size < inline) { /* don't expand into inline code if size < * inline */ while (cur != dl) { print_stat(1, &cur->decl); cur = cur->next; } } else { /* were already looking at a xdr_inlineable * structure */ if (sizestr == NULL) f_print(fout, "\t\tbuf = (int32_t *)XDR_INLINE(xdrs,%d * BYTES_PER_XDR_UNIT);", size); else if (size == 0) f_print(fout, "\t\tbuf = (int32_t *)XDR_INLINE(xdrs,%s * BYTES_PER_XDR_UNIT);", sizestr); else f_print(fout, "\t\tbuf = (int32_t *)XDR_INLINE(xdrs,(%d + %s)* BYTES_PER_XDR_UNIT);", size, sizestr); f_print(fout, "\n\t\tif (buf == NULL) {\n"); psav = cur; while (cur != NULL) { print_stat(2, &cur->decl); cur = cur->next; } f_print(fout, "\n\t }\n\t else {\n"); cur = psav; while (cur != dl) { emit_inline(&cur->decl, flag); cur = cur->next; } f_print(fout, "\t }\n"); } flag = GET; } f_print(fout, "\t return(TRUE);\n\t}\n\n"); /* now take care of XDR_FREE case */ for (dl = def->def.st.decls; dl != NULL; dl = dl->next) print_stat(1, &dl->decl); } static emit_typedef(def) definition *def; { char *prefix = def->def.ty.old_prefix; char *type = def->def.ty.old_type; char *amax = def->def.ty.array_max; relation rel = def->def.ty.rel; print_ifstat(1, prefix, type, rel, amax, "objp", def->def_name); } static print_stat(indent, dec) declaration *dec; int indent; { char *prefix = dec->prefix; char *type = dec->type; char *amax = dec->array_max; relation rel = dec->rel; char name[256]; if (isvectordef(type, rel)) { s_print(name, "objp->%s", dec->name); } else { s_print(name, "&objp->%s", dec->name); } print_ifstat(indent, prefix, type, rel, amax, name, dec->name); } char *upcase __P((char *)); emit_inline(decl, flag) declaration *decl; int flag; { /*check whether an array or not */ switch (decl->rel) { case REL_ALIAS: emit_single_in_line(decl, flag, REL_ALIAS); break; case REL_VECTOR: f_print(fout, "\t\t{ register %s *genp; \n", decl->type); f_print(fout, "\t\t for ( i = 0,genp=objp->%s;\n \t\t\ti < %s; i++){\n\t\t", decl->name, decl->array_max); emit_single_in_line(decl, flag, REL_VECTOR); f_print(fout, "\t\t }\n\t\t };\n"); } } emit_single_in_line(decl, flag, rel) declaration *decl; int flag; relation rel; { char *upp_case; int freed = 0; if (flag == PUT) f_print(fout, "\t\t IXDR_PUT_"); else if (rel == REL_ALIAS) f_print(fout, "\t\t objp->%s = IXDR_GET_", decl->name); else f_print(fout, "\t\t *genp++ = IXDR_GET_"); upp_case = upcase(decl->type); /* hack - XX */ if (strcmp(upp_case, "INT") == 0) { free(upp_case); freed = 1; upp_case = "LONG"; } if (strcmp(upp_case, "U_INT") == 0) { free(upp_case); freed = 1; upp_case = "U_LONG"; } if (flag == PUT) if (rel == REL_ALIAS) f_print(fout, "%s(buf,objp->%s);\n", upp_case, decl->name); else f_print(fout, "%s(buf,*genp++);\n", upp_case); else f_print(fout, "%s(buf);\n", upp_case); if (!freed) free(upp_case); } char * upcase(str) char *str; { char *ptr, *hptr; ptr = (char *) malloc(strlen(str)+1); if (ptr == (char *) NULL) { f_print(stderr, "malloc failed \n"); exit(1); }; hptr = ptr; while (*str != '\0') *ptr++ = toupper(*str++); *ptr = '\0'; return (hptr); }