#include "asn1fix_internal.h" static int _asn1f_check_if_tag_must_be_explicit(arg_t *arg, asn1p_expr_t *v); static int _asn1f_compare_tags(arg_t *arg, asn1p_expr_t *a, asn1p_expr_t *b); static int _asn1f_fix_type_tag(arg_t *arg, asn1p_expr_t *expr); int asn1f_pull_components_of(arg_t *arg) { TQ_HEAD(asn1p_expr_t) list; asn1p_expr_t *expr = arg->expr; asn1p_expr_t *memb; int r_value = 0; switch(expr->expr_type) { case ASN_CONSTR_SEQUENCE: case ASN_CONSTR_SET: break; default: return 0; } TQ_INIT(&list); /* * Look into */ while((memb = TQ_REMOVE(&(expr->members), next))) { asn1p_expr_t *coft; /* COMPONENTS OF thing itself */ asn1p_expr_t *terminal; /* Terminal of the referenced type */ if(memb->expr_type != A1TC_COMPONENTS_OF) { TQ_ADD(&list, memb, next); continue; } coft = TQ_FIRST(&memb->members); assert(coft); assert(!TQ_NEXT(coft, next)); /* * Find the referenced type. */ terminal = asn1f_find_terminal_type(arg, coft); if(!terminal || (terminal->expr_type != expr->expr_type)) { FATAL("COMPONENTS OF at line %d " "must reference a %s type", coft->_lineno, expr->expr_type==ASN_CONSTR_SET ? "SET" : "SEQUENCE" ); TQ_ADD(&list, memb, next); r_value = -1; continue; } /* * Clone the final structure. */ coft = asn1p_expr_clone(terminal, 1 /* Skip extensions */); if(!coft) return -1; /* ENOMEM */ if(0) { asn1p_expr_free(memb); /* Don't need it anymore*/ } else { /* Actual removal clashes with constraints... skip. */ } /* * Move all components of the cloned structure * into the current one. */ while((memb = TQ_REMOVE(&(coft->members), next))) { TQ_ADD(&list, memb, next); memb->parent_expr = expr; } asn1p_expr_free(coft); /* Remove wrapper */ } /* Move the stuff back */ TQ_MOVE(&(expr->members), &list); return r_value; } /* * Fix extensibility parts inside constructed types (SEQUENCE, SET, CHOICE). */ int asn1f_fix_constr_ext(arg_t *arg) { asn1p_expr_t *expr = arg->expr; asn1p_expr_t *v; TQ_HEAD(asn1p_expr_t) root_list; TQ_HEAD(asn1p_expr_t) ext_list; TQ_HEAD(asn1p_expr_t) *cur_list; int r_value = 0; int ext_count = 0; switch(expr->expr_type) { case ASN_CONSTR_SEQUENCE: case ASN_CONSTR_SET: case ASN_CONSTR_CHOICE: break; default: return 0; } DEBUG("(%s) for line %d", expr->Identifier, expr->_lineno); TQ_INIT(&root_list); TQ_INIT(&ext_list); cur_list = (void *)&root_list; /* * Split the set of fields into two lists, the root list * and the extensions list. */ while((v = TQ_REMOVE(&(expr->members), next))) { if(v->expr_type == A1TC_EXTENSIBLE) { ext_count++; switch(ext_count) { case 1: cur_list = (void *)&ext_list; break; case 2: cur_list = (void *)&root_list; if(v->value) { FATAL("Optional extension marker " "must not contain " "an exception mark " "at line %d", v->_lineno); r_value = -1; } asn1p_expr_free(v); continue; case 3: FATAL("Third extension marker " "is not allowed at line %d", v->_lineno); default: r_value = -1; } } TQ_ADD(cur_list, v, next); } /* * Copy the root list and extension list back into the main list. */ TQ_MOVE(&(expr->members), &root_list); while((v = TQ_REMOVE(&ext_list, next))) TQ_ADD(&(expr->members), v, next); if(arg->mod->module_flags & MSF_EXTENSIBILITY_IMPLIED && ext_count == 0) { v = asn1p_expr_new(0, arg->mod); if(v) { v->Identifier = strdup("..."); v->expr_type = A1TC_EXTENSIBLE; v->meta_type = AMT_TYPE; v->_lineno = expr->_lineno; /* The best we can do */ if(v->Identifier == NULL) { asn1p_expr_free(v); r_value = -1; } else { asn1p_expr_add(expr, v); } } else { r_value = -1; } } return r_value; } int asn1f_fix_constr_tag(arg_t *arg, int fix_top_level) { asn1p_expr_t *expr = arg->expr; asn1p_expr_t *v; int root_tagged = 0; /* The root component is manually tagged */ int ext_tagged = 0; /* The extensions are manually tagged */ int component_number = 0; int r_value = 0; DEBUG("(%s) for line %d", expr->Identifier, expr->_lineno); /* * Fix the top-level type itself first. */ if(fix_top_level) { if(expr->tag.tag_class == TC_NOCLASS) return r_value; if(_asn1f_fix_type_tag(arg, expr)) r_value = -1; return r_value; } switch(expr->expr_type) { case ASN_CONSTR_SEQUENCE: case ASN_CONSTR_SET: case ASN_CONSTR_CHOICE: break; default: return 0; } TQ_FOR(v, &(expr->members), next) { if(v->expr_type == A1TC_EXTENSIBLE) { component_number++; continue; } if(v->tag.tag_class == TC_NOCLASS) { continue; } switch(component_number) { case 0: case 2: root_tagged = 1; break; default: ext_tagged = 1; break; } if(_asn1f_fix_type_tag(arg, v)) r_value = -1; } if((arg->mod->module_flags & MSF_AUTOMATIC_TAGS) && !root_tagged) { if(ext_tagged) { /* X.690: 28.4 */ FATAL("In %s at line %d: " "extensions are tagged " "but root components are not", expr->Identifier, expr->_lineno); r_value = -1; } else { /* Make a decision on automatic tagging */ expr->auto_tags_OK = 1; } } return r_value; } static int _asn1f_fix_type_tag(arg_t *arg, asn1p_expr_t *expr) { int must_explicit = _asn1f_check_if_tag_must_be_explicit(arg, expr); int module_impl_tags = (arg->mod->module_flags & (MSF_IMPLICIT_TAGS | MSF_AUTOMATIC_TAGS)); int r_value = 0; if(expr->tag.tag_mode == TM_DEFAULT) { if(must_explicit || module_impl_tags == 0) expr->tag.tag_mode = TM_EXPLICIT; else expr->tag.tag_mode = TM_IMPLICIT; } /* * Perform a final sanity check. */ if(must_explicit) { if(expr->tag.tag_mode == TM_IMPLICIT) { FATAL("%s tagged in IMPLICIT mode " "but must be EXPLICIT at line %d", expr->Identifier, expr->_lineno); r_value = -1; } else { expr->tag.tag_mode = TM_EXPLICIT; } } return r_value; } int asn1f_fix_constr_autotag(arg_t *arg) { asn1p_expr_t *expr = arg->expr; asn1p_expr_t *v; asn1c_integer_t tag_value = 0; int r_value = 0; switch(expr->expr_type) { case ASN_CONSTR_SEQUENCE: case ASN_CONSTR_SET: case ASN_CONSTR_CHOICE: if(expr->auto_tags_OK) break; /* Automatic tagging is not applicable */ /* Fall through */ default: return 0; } DEBUG("(%s) for line %d", expr->Identifier, expr->_lineno); TQ_FOR(v, &(expr->members), next) { int must_explicit; if(v->expr_type == A1TC_EXTENSIBLE) { /* 28.5, d) */ continue; } if(0) { /* This may be not true in case COMPONENTS OF */ assert(v->tag.tag_class == TC_NOCLASS); } must_explicit = _asn1f_check_if_tag_must_be_explicit(arg, v); v->tag.tag_class = TC_CONTEXT_SPECIFIC; v->tag.tag_mode = must_explicit ? TM_EXPLICIT : TM_IMPLICIT; v->tag.tag_value = tag_value++; } return r_value; } /* * Check that tags are distinct. */ int asn1f_check_constr_tags_distinct(arg_t *arg) { asn1p_expr_t *expr = arg->expr; asn1p_expr_t *v; int r_value = 0; switch(expr->expr_type) { case ASN_CONSTR_SEQUENCE: case ASN_CONSTR_SET: case ASN_CONSTR_CHOICE: break; default: return 0; } TQ_FOR(v, &(expr->members), next) { /* * In every series of non-mandatory components, * the tags must be distinct from each other AND the * tag of the following mandatory component. * For SET and CHOICE treat everything as a big set of * non-mandatory components. */ if(expr->expr_type != ASN_CONSTR_SEQUENCE || v->marker.flags) { asn1p_expr_t *nv; for(nv = v; (nv = TQ_NEXT(nv, next));) { DEBUG("S/C comparing tags %s s. %s", v->Identifier, nv->Identifier); if(_asn1f_compare_tags(arg, v, nv)) r_value = -1; if(expr->expr_type == ASN_CONSTR_SEQUENCE && !nv->marker.flags) break; } } } return r_value; } static int _asn1f_check_if_tag_must_be_explicit(arg_t *arg, asn1p_expr_t *v) { struct asn1p_type_tag_s tag; struct asn1p_type_tag_s save_tag; asn1p_expr_t *reft; int ret; /* * Fetch the _next_ tag for this type. */ save_tag = v->tag; /* Save existing tag */ memset(&v->tag, 0, sizeof(v->tag)); /* Remove it temporarily */ ret = asn1f_fetch_outmost_tag(arg->asn, arg->mod, v, &tag, 0); v->tag = save_tag; /* Restore the tag back */ if(ret == 0) return 0; /* If found tag, it's okay */ reft = asn1f_find_terminal_type(arg, v); if(reft) { switch(reft->expr_type) { case ASN_TYPE_ANY: case ASN_CONSTR_CHOICE: return 1; default: return 0; } } return 0; } /* * Check that the tags are distinct. */ static int _asn1f_compare_tags(arg_t *arg, asn1p_expr_t *a, asn1p_expr_t *b) { struct asn1p_type_tag_s ta, tb; int ra, rb; int ret; ra = asn1f_fetch_outmost_tag(arg->asn, arg->mod, a, &ta, AFT_IMAGINARY_ANY); rb = asn1f_fetch_outmost_tag(arg->asn, arg->mod, b, &tb, AFT_IMAGINARY_ANY); /* * If both tags are explicitly or implicitly given, use them. */ DEBUG("Fetching outmost tags: %d, %d", ra, rb); if(ra == 0 && rb == 0) { /* * Simple case: fetched both tags. */ if((ta.tag_value == tb.tag_value && ta.tag_class == tb.tag_class) || ta.tag_value == -1 /* Spread IMAGINARY ANY tag... */ || tb.tag_value == -1 /* ...it is an evil virus, fear it! */ ) { char tagbuf[2][TAG2STRING_BUFFER_SIZE]; char *p = (a->expr_type == A1TC_EXTENSIBLE) ?"potentially ":""; FATAL("Processing %s at line %d: component \"%s\" at line %d %shas the same tag " "as component \"%s\" at line %d", arg->expr->Identifier, arg->expr->_lineno, a->Identifier, a->_lineno, p, b->Identifier, b->_lineno ); FATAL("Consider adding AUTOMATIC TAGS " "after module %s DEFINITIONS, " "or manually tag components", arg->expr->module->ModuleName); DEBUG("Tags: %s %s vs. %s %s", asn1p_tag2string(&ta, tagbuf[0]), a->Identifier, asn1p_tag2string(&tb, tagbuf[1]), b->Identifier ); if((arg->mod->module_flags & MSF_EXTENSIBILITY_IMPLIED) && (a->expr_type == A1TC_EXTENSIBLE) && (b->expr_type == A1TC_EXTENSIBLE)) { FATAL("The previous error is due to " "improper use of " "EXTENSIBILITY IMPLIED flag " "of module %s", arg->mod->ModuleName); } return -1; } else { /* Tags are distinct */ return 0; } } /********************************************************** * Now we must perform some very funny recursion to check * multiple components of CHOICE type, etc. */ DEBUG("Comparing tags %s:%x <-> %s:%x", a->Identifier, a->expr_type, b->Identifier, b->expr_type); if(ra && a->meta_type == AMT_TYPEREF) { DEBUG(" %s is a type reference", a->Identifier); a = asn1f_lookup_symbol(arg, a->module, a->rhs_pspecs, a->reference); if(!a) return 0; /* Already FATAL()'ed somewhere else */ WITH_MODULE(a->module, ret = _asn1f_compare_tags(arg, a, b)); return ret; } if(ra && a->expr_type == ASN_CONSTR_CHOICE) { asn1p_expr_t *v; DEBUG(" %s is a choice type (%d)", a->Identifier, a->_mark); /* * Iterate over members of CHOICE. */ //if(a->_mark & TM_RECURSION) return 0; TQ_FOR(v, &(a->members), next) { //a->_mark |= TM_RECURSION; ret = _asn1f_compare_tags(arg, v, b); //a->_mark &= ~TM_RECURSION; if(ret) return ret; } return 0; } if(rb && b->expr_type == ASN_CONSTR_CHOICE) { return _asn1f_compare_tags(arg, b, a); } if(a->_mark & TM_RECURSION) return 0; if(b->_mark & TM_RECURSION) return 0; a->_mark |= TM_RECURSION; b->_mark |= TM_RECURSION; ret = _asn1f_compare_tags(arg, b, a); a->_mark &= ~TM_RECURSION; b->_mark &= ~TM_RECURSION; return ret; }