dict_util.c

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/*
 *   This program is free software; you can redistribute it and/or modify
 *   it under the terms of the GNU General Public License as published by
 *   the Free Software Foundation; either version 2 of the License, or
 *   (at your option) any later version.
 *
 *   This program is distributed in the hope that it will be useful,
 *   but WITHOUT ANY WARRANTY; without even the implied warranty of
 *   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *   GNU General Public License for more details.
 *
 *   You should have received a copy of the GNU General Public License
 *   along with this program; if not, write to the Free Software
 *   Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA
 */
 
/** Multi-protocol AVP dictionary API
 *
 * @file src/lib/util/dict_util.c
 *
 * @copyright 2000,2006 The FreeRADIUS server project
 * @copyright 2024 Arran Cudbard-Bell (a.cudbardb@freeradius.org)
 */
RCSID("$Id: bde545a3a409544eb7a2cd0d5bb8f7619d640b72 $")
 
#define _DICT_PRIVATE 1
 
#include <freeradius-devel/util/atexit.h>
#include <freeradius-devel/util/conf.h>
#include <freeradius-devel/util/dict.h>
#include <freeradius-devel/util/dict_ext_priv.h>
#include <freeradius-devel/util/dict_fixup_priv.h>
#include <freeradius-devel/util/proto.h>
#include <freeradius-devel/util/rand.h>
#include <freeradius-devel/util/syserror.h>
 
#ifdef HAVE_SYS_STAT_H
#  include <sys/stat.h>
#endif
 
fr_dict_gctx_t *dict_gctx = NULL;       //!< Top level structure containing global dictionary state.
 
#define DICT_ATTR_ALLOWED_CHARS \
        ['-'] = true, ['/'] = true, ['_'] = true, \
        ['0'] = true, ['1'] = true, ['2'] = true, ['3'] = true, ['4'] = true, \
        ['5'] = true, ['6'] = true, ['7'] = true, ['8'] = true, ['9'] = true, \
        ['A'] = true, ['B'] = true, ['C'] = true, ['D'] = true, ['E'] = true, \
        ['F'] = true, ['G'] = true, ['H'] = true, ['I'] = true, ['J'] = true, \
        ['K'] = true, ['L'] = true, ['M'] = true, ['N'] = true, ['O'] = true, \
        ['P'] = true, ['Q'] = true, ['R'] = true, ['S'] = true, ['T'] = true, \
        ['U'] = true, ['V'] = true, ['W'] = true, ['X'] = true, ['Y'] = true, \
        ['Z'] = true, \
        ['a'] = true, ['b'] = true, ['c'] = true, ['d'] = true, ['e'] = true, \
        ['f'] = true, ['g'] = true, ['h'] = true, ['i'] = true, ['j'] = true, \
        ['k'] = true, ['l'] = true, ['m'] = true, ['n'] = true, ['o'] = true, \
        ['p'] = true, ['q'] = true, ['r'] = true, ['s'] = true, ['t'] = true, \
        ['u'] = true, ['v'] = true, ['w'] = true, ['x'] = true, ['y'] = true, \
        ['z'] = true
 
/** Characters allowed in a single dictionary attribute name
 *
 */
bool const fr_dict_attr_allowed_chars[SBUFF_CHAR_CLASS] = {
        DICT_ATTR_ALLOWED_CHARS
};
 
/** Characters allowed in a nested dictionary attribute name
 *
 */
bool const fr_dict_attr_nested_allowed_chars[SBUFF_CHAR_CLASS] = {
        DICT_ATTR_ALLOWED_CHARS,
        [ '.' ] = true
};
 
/** Characters allowed in enumeration value names
 *
 */
bool const fr_dict_enum_allowed_chars[SBUFF_CHAR_CLASS] = {
        ['+'] = true, ['-'] = true, ['.'] = true, ['/'] = true, ['_'] = true,
        ['0'] = true, ['1'] = true, ['2'] = true, ['3'] = true, ['4'] = true,
        ['5'] = true, ['6'] = true, ['7'] = true, ['8'] = true, ['9'] = true,
        ['A'] = true, ['B'] = true, ['C'] = true, ['D'] = true, ['E'] = true,
        ['F'] = true, ['G'] = true, ['H'] = true, ['I'] = true, ['J'] = true,
        ['K'] = true, ['L'] = true, ['M'] = true, ['N'] = true, ['O'] = true,
        ['P'] = true, ['Q'] = true, ['R'] = true, ['S'] = true, ['T'] = true,
        ['U'] = true, ['V'] = true, ['W'] = true, ['X'] = true, ['Y'] = true,
        ['Z'] = true,
        ['a'] = true, ['b'] = true, ['c'] = true, ['d'] = true, ['e'] = true,
        ['f'] = true, ['g'] = true, ['h'] = true, ['i'] = true, ['j'] = true,
        ['k'] = true, ['l'] = true, ['m'] = true, ['n'] = true, ['o'] = true,
        ['p'] = true, ['q'] = true, ['r'] = true, ['s'] = true, ['t'] = true,
        ['u'] = true, ['v'] = true, ['w'] = true, ['x'] = true, ['y'] = true,
        ['z'] = true
};
 
/** Default protocol rules set for every dictionary
 *
 * This is usually overriden by the public symbol from the protocol library
 * associated with the dictionary
 * e.g. libfreeradius-dhcpv6.so -> libfreeradius_dhcpv6_dict_protocol.
 */
static fr_dict_protocol_t dict_proto_default = {
        .name = "default",
        .default_type_size = 2,
        .default_type_length = 2,
};
 
/*
 *      Create the hash of the name.
 *
 *      We copy the hash function here because it's substantially faster.
 */
#define FNV_MAGIC_INIT (0x811c9dc5)
#define FNV_MAGIC_PRIME (0x01000193)
 
/** Apply a simple (case insensitive) hashing function to the name of an attribute, vendor or protocol
 *
 * @param[in] name      of the attribute, vendor or protocol.
 * @param[in] len       length of the input string.
 *
 * @return the hashed derived from the name.
 */
static uint32_t dict_hash_name(char const *name, size_t len)
{
        uint32_t hash = FNV_MAGIC_INIT;
 
        char const *p = name, *q = name + len;
 
        while (p < q) {
                int c = *(unsigned char const *)p;
                if (isalpha(c)) c = tolower(c);
 
                /* coverity[overflow_const] */
                hash *= FNV_MAGIC_PRIME;
                hash ^= (uint32_t)(c & 0xff);
                p++;
        }
 
        return hash;
}
 
/** Wrap name hash function for fr_dict_protocol_t
 *
 * @param[in]   data fr_dict_attr_t to hash.
 * @return the hash derived from the name of the attribute.
 */
static uint32_t dict_protocol_name_hash(void const *data)
{
        char const *name;
 
        name = ((fr_dict_t const *)data)->root->name;
 
        return dict_hash_name(name, strlen(name));
}
 
/** Compare two protocol names
 *
 */
static int8_t dict_protocol_name_cmp(void const *one, void const *two)
{
        fr_dict_t const *a = one;
        fr_dict_t const *b = two;
        int ret;
 
        ret = strcasecmp(a->root->name, b->root->name);
        return CMP(ret, 0);
}
 
/** Hash a protocol number
 *
 */
static uint32_t dict_protocol_num_hash(void const *data)
{
        return fr_hash(&(((fr_dict_t const *)data)->root->attr), sizeof(((fr_dict_t const *)data)->root->attr));
}
 
/** Compare two protocol numbers
 *
 */
static int8_t dict_protocol_num_cmp(void const *one, void const *two)
{
        fr_dict_t const *a = one;
        fr_dict_t const *b = two;
 
        return CMP(a->root->attr, b->root->attr);
}
 
/** Wrap name hash function for fr_dict_attr_t
 *
 * @param data          fr_dict_attr_t to hash.
 * @return the hash derived from the name of the attribute.
 */
static uint32_t dict_attr_name_hash(void const *data)
{
        char const *name;
 
        name = ((fr_dict_attr_t const *)data)->name;
 
        return dict_hash_name(name, strlen(name));
}
 
/** Compare two attribute names
 *
 */
static int8_t dict_attr_name_cmp(void const *one, void const *two)
{
        fr_dict_attr_t const *a = one, *b = two;
        int ret;
 
        ret = strcasecmp(a->name, b->name);
        return CMP(ret, 0);
}
 
/** Compare two attributes by total order.
 *
 *  This function is safe / ordered even when the attributes are in
 *  different dictionaries.  This allows it to work for local
 *  variables, as those are in a different dictionary from the
 *  protocol ones.
 *
 *  This function orders parents first, then their children.
 */
int8_t fr_dict_attr_ordered_cmp(fr_dict_attr_t const *a, fr_dict_attr_t const *b)
{
        int8_t ret;
 
        /*
         *      Order by parent first.  If the parents are different,
         *      we order by parent numbers.
         *
         *      If the attributes share the same parent at some point,
         *      then the deeper child is sorted later.
         */
        if (a->depth < b->depth) {
                ret = fr_dict_attr_ordered_cmp(a, b->parent);
                if (ret != 0) return ret;
 
                return -1;      /* order a before b */
        }
 
        if (a->depth > b->depth) {
                ret = fr_dict_attr_ordered_cmp(a->parent, b);
                if (ret != 0) return ret;
 
                return +1;      /* order b before a */
        }
 
        /*
         *      We're at the root (e.g. "RADIUS").  Compare by
         *      protocol number.
         *
         *      Or, the parents are the same.  We can then order by
         *      our (i.e. child) attribute number.
         */
        if ((a->depth == 0) || (a->parent == b->parent)) {
                /*
                 *      Order known attributes before unknown / raw ones.
                 */
                ret = CMP((a->flags.is_unknown | a->flags.is_raw), (b->flags.is_unknown | b->flags.is_raw));
                if (ret != 0) return ret;
 
                return CMP(a->attr, b->attr);
        }
 
        /*
         *      The parents are different, we don't need to order by
         *      our attribute number.  Instead, we order by the
         *      parent.
         *
         *      Note that at this point, the call below will never
         *      return 0, because the parents are different.
         */
        return fr_dict_attr_ordered_cmp(a->parent, b->parent);
}
 
/** Wrap name hash function for fr_dict_vendor_t
 *
 * @param data fr_dict_vendor_t to hash.
 * @return the hash derived from the name of the attribute.
 */
static uint32_t dict_vendor_name_hash(void const *data)
{
        char const *name;
 
        name = ((fr_dict_vendor_t const *)data)->name;
 
        return dict_hash_name(name, strlen(name));
}
 
/** Compare two attribute names
 *
 */
static int8_t dict_vendor_name_cmp(void const *one, void const *two)
{
        fr_dict_vendor_t const *a = one;
        fr_dict_vendor_t const *b = two;
        int ret;
 
        ret = strcasecmp(a->name, b->name);
        return CMP(ret, 0);
}
 
/** Hash a vendor number
 *
 */
static uint32_t dict_vendor_pen_hash(void const *data)
{
        return fr_hash(&(((fr_dict_vendor_t const *)data)->pen),
                       sizeof(((fr_dict_vendor_t const *)data)->pen));
}
 
/** Compare two vendor numbers
 *
 */
static int8_t dict_vendor_pen_cmp(void const *one, void const *two)
{
        fr_dict_vendor_t const *a = one;
        fr_dict_vendor_t const *b = two;
 
        return CMP(a->pen, b->pen);
}
 
/** Hash a enumeration name
 *
 */
static uint32_t dict_enum_name_hash(void const *data)
{
        fr_dict_enum_value_t const *enumv = data;
 
        return dict_hash_name((void const *)enumv->name, enumv->name_len);
}
 
/** Compare two dictionary attribute enum values
 *
 */
static int8_t dict_enum_name_cmp(void const *one, void const *two)
{
        fr_dict_enum_value_t const *a = one;
        fr_dict_enum_value_t const *b = two;
        int ret;
 
        ret = CMP(a->name_len, b->name_len);
        if (ret != 0) return ret;
 
        ret = strncasecmp(a->name, b->name, a->name_len);
        return CMP(ret, 0);
}
 
/** Hash a dictionary enum value
 *
 */
static uint32_t dict_enum_value_hash(void const *data)
{
        fr_dict_enum_value_t const *enumv = data;
 
        return fr_value_box_hash(enumv->value);
}
 
/** Compare two dictionary enum values
 *
 */
static int8_t dict_enum_value_cmp(void const *one, void const *two)
{
        fr_dict_enum_value_t const *a = one;
        fr_dict_enum_value_t const *b = two;
        int ret;
 
        ret = fr_value_box_cmp(a->value, b->value); /* not yet int8_t! */
        return CMP(ret, 0);
}
 
/** Resolve an alias attribute to the concrete attribute it points to
 *
 * @param[out] err      where to write the error (if any).
 * @param[in] da        to resolve.
 * @return
 *      - NULL on error.
 *      - The concrete attribute on success.
 */
static inline fr_dict_attr_t const *dict_attr_alias(fr_dict_attr_err_t *err, fr_dict_attr_t const *da)
{
        fr_dict_attr_t const *ref;
 
        if (!da->flags.is_alias) return da;
 
        ref = fr_dict_attr_ref(da);
        if (unlikely(!ref)) {
                fr_strerror_printf("ALIAS attribute '%s' missing reference", da->name);
                if (err) *err = FR_DICT_ATTR_INTERNAL_ERROR;
                return NULL;
        } else {
                if (err) *err = FR_DICT_ATTR_OK;
        }
 
        return ref;
}
 
/** Set a dictionary attribute's name
 *
 * @note This function can only be used _before_ the attribute is inserted into the dictionary.
 *
 * @param[in] da_p      to set name for.
 * @param[in] name      to set.  If NULL a name will be automatically generated.
 */
static inline CC_HINT(always_inline) int dict_attr_name_set(fr_dict_attr_t **da_p, char const *name)
{
        char            buffer[FR_DICT_ATTR_MAX_NAME_LEN + 1];
        size_t          name_len;
        char            *name_start, *name_end;
        fr_dict_attr_t  *da = *da_p;
 
        /*
         *      Generate a name if none is specified
         */
        if (!name) {
                fr_sbuff_t unknown_name = FR_SBUFF_OUT(buffer, sizeof(buffer));
 
 
                (void) fr_sbuff_in_sprintf(&unknown_name, "%u", da->attr);
 
                name = fr_sbuff_buff(&unknown_name);
                name_len = fr_sbuff_used(&unknown_name);
        } else {
                name_len = strlen(name);
        }
 
        /*
         *      Grow the structure to hold the name
         *
         *      We add the name as an extension because it makes
         *      the code less complex, and means the name value
         *      is copied automatically when if the fr_dict_attr_t
         *      is copied.
         *
         *      We do still need to fixup the da->name pointer
         *      though.
         */
        name_start = dict_attr_ext_alloc_size(da_p, FR_DICT_ATTR_EXT_NAME, name_len + 1);
        if (!name_start) return -1;
 
        name_end = name_start + name_len;
 
        memcpy(name_start, name, name_len);
        *name_end = '\0';
 
        (*da_p)->name = name_start;
        (*da_p)->name_len = name_len;
 
        return 0;
}
 
/** Add a child/nesting extension to an attribute
 *
 * @note This function can only be used _before_ the attribute is inserted into the dictionary.
 *
 * @param[in] da_p              to set a group reference for.
 */
static inline CC_HINT(always_inline) int dict_attr_children_init(fr_dict_attr_t **da_p)
{
        fr_dict_attr_ext_children_t     *ext;
 
        ext = dict_attr_ext_alloc(da_p, FR_DICT_ATTR_EXT_CHILDREN);
        if (unlikely(!ext)) return -1;
 
        return 0;
}
 
/** Cache the vendor pointer for an attribute
 *
 * @note This function can only be used _before_ the attribute is inserted into the dictionary.
 *
 * @param[in] da_p              to set a group reference for.
 * @param[in] vendor            to set.
 */
static inline CC_HINT(always_inline) int dict_attr_vendor_set(fr_dict_attr_t **da_p, fr_dict_attr_t const *vendor)
{
        fr_dict_attr_ext_vendor_t       *ext;
 
        ext = dict_attr_ext_alloc(da_p, FR_DICT_ATTR_EXT_VENDOR);
        if (unlikely(!ext)) return -1;
 
        ext->vendor = vendor;
 
        return 0;
}
 
/** Initialise a per-attribute enumeration table
 *
 * @note This function can only be used _before_ the attribute is inserted into the dictionary.
 *
 * @param[in] da_p              to set a group reference for.
 */
static inline CC_HINT(always_inline) int dict_attr_enumv_init(fr_dict_attr_t **da_p)
{
        fr_dict_attr_ext_enumv_t        *ext;
 
        ext = dict_attr_ext_alloc(da_p, FR_DICT_ATTR_EXT_ENUMV);
        if (unlikely(!ext)) return -1;
 
        return 0;
}
 
/** Initialise a per-attribute namespace
 *
 * @note This function can only be used _before_ the attribute is inserted into the dictionary.
 *
 * @param[in] da_p              to set a group reference for.
 */
static inline CC_HINT(always_inline) int dict_attr_namespace_init(fr_dict_attr_t **da_p)
{
        fr_dict_attr_ext_namespace_t    *ext;
 
        ext = dict_attr_ext_alloc(da_p, FR_DICT_ATTR_EXT_NAMESPACE);
        if (unlikely(!ext)) return -1;
 
        /*
         *      Create the table of attributes by name.
         *      There MAY NOT be multiple attributes of the same name.
         *
         *      If the attribute already has extensions
         *      then we don't want to leak the old
         *      namespace hash table.
         */
        if (!ext->namespace) {
                ext->namespace = fr_hash_table_talloc_alloc(*da_p, fr_dict_attr_t,
                                                            dict_attr_name_hash, dict_attr_name_cmp, NULL);
                if (!ext->namespace) {
                        fr_strerror_printf("Failed allocating \"namespace\" table");
                        return -1;
                }
        }
 
        return 0;
}
 
/** Initialise type specific fields within the dictionary attribute
 *
 * Call when the type of the attribute is known.
 *
 * @param[in,out] da_p  to set the type for.
 * @param[in] type      to set.
 * @return
 *      - 0 on success.
 *      - < 0 on error.
 */
int dict_attr_type_init(fr_dict_attr_t **da_p, fr_type_t type)
{
        if (unlikely(((*da_p)->type != FR_TYPE_NULL) &&
                     ((*da_p)->type != type))) {
                fr_strerror_printf("Cannot set data type to '%s' - it is already set to '%s'",
                                   fr_type_to_str(type), fr_type_to_str((*da_p)->type));
                return -1;
        }
 
        if (unlikely((*da_p)->state.finalised == true)) {
                fr_strerror_const("Can't perform type initialisation on finalised attribute");
                return -1;
        }
 
        /*
         *      Structural types can have children
         *      so add the extension for them.
         */
        switch (type) {
        case FR_TYPE_STRUCTURAL:
                /*
                 *      Groups don't have children or namespaces.  But
                 *      they always have refs.  Either to the root of
                 *      the current dictionary, or to another dictionary,
                 *      via its top-level TLV.
                 *
                 *      Note that when multiple TLVs have the same
                 *      children, the dictionary has to use "clone="
                 *      instead of "ref=".  That's because the
                 *      children of the TLVs all require the correct
                 *      parentage.  Perhaps that can be changed when
                 *      the encoders / decoders are updated.  It would be good to just reference the DAs instead of cloning an entire subtree.
                 */
                if ((type == FR_TYPE_GROUP) && !fr_dict_attr_ext(*da_p, FR_DICT_ATTR_EXT_REF)) {
                        if (dict_attr_ext_alloc(da_p, FR_DICT_ATTR_EXT_REF) == NULL) return -1;
                        break;
                }
 
                if (dict_attr_children_init(da_p) < 0) return -1;
                if (dict_attr_namespace_init(da_p) < 0) return -1;      /* Needed for all TLV style attributes */
 
                (*da_p)->last_child_attr = (1 << 24);   /* High enough not to conflict with protocol numbers */
                break;
 
        /*
         *      Leaf types
         */
        default:
                if (dict_attr_enumv_init(da_p) < 0) return -1;
                break;
        }
 
        (*da_p)->flags.is_known_width |= fr_type_fixed_size[type];
 
        /*
         *      Set default type-based flags
         */
        switch (type) {
        case FR_TYPE_DATE:
        case FR_TYPE_TIME_DELTA:
                (*da_p)->flags.length = 4;
                (*da_p)->flags.flag_time_res = FR_TIME_RES_SEC;
                break;
 
 
        case FR_TYPE_OCTETS:
        case FR_TYPE_STRING:
                (*da_p)->flags.is_known_width = ((*da_p)->flags.length != 0);
                break;
 
        default:
                break;
        }
 
        (*da_p)->type = type;
 
        return 0;
}
 
/** Initialise fields which depend on a parent attribute
 *
 * @param[in,out] da_p  to initialise.
 * @param[in] parent    of the attribute.
 * @return
 *      - 0 on success.
 *      - < 0 on error.
 */
int dict_attr_parent_init(fr_dict_attr_t **da_p, fr_dict_attr_t const *parent)
{
        fr_dict_attr_t            *da = *da_p;
        fr_dict_t const           *dict = parent->dict;
        fr_dict_attr_ext_vendor_t *ext;
 
        if (unlikely((*da_p)->type == FR_TYPE_NULL)) {
                fr_strerror_const("Attribute type must be set before initialising parent.  Use dict_attr_type_init() first");
                return -1;
        }
 
        if (unlikely(da->parent != NULL)) {
                fr_strerror_printf("Attempting to set parent for '%s' to '%s', but parent already set to '%s'",
                                   da->name, parent->name, da->parent->name);
                return -1;
        }
 
        if (unlikely((*da_p)->state.finalised == true)) {
                fr_strerror_printf("Attempting to set parent for '%s' to '%s', but attribute already finalised",
                                   da->name, parent->name);
                return -1;
        }
 
        da->parent = parent;
        da->dict = parent->dict;
        da->depth = parent->depth + 1;
        da->flags.internal |= parent->flags.internal;
 
        /*
         *      Point to the vendor definition.  Since ~90% of
         *      attributes are VSAs, caching this pointer will help.
         */
        if (da->type == FR_TYPE_VENDOR) {
                da->flags.type_size = dict->root->flags.type_size;
                da->flags.length = dict->root->flags.type_size;
 
                if ((dict->root->attr == FR_DICT_PROTO_RADIUS) && (da->depth == 2)) {
                        fr_dict_vendor_t const *dv;
 
                        dv = fr_dict_vendor_by_num(dict, da->attr);
                        if (dv) {
                                da->flags.type_size = dv->type;
                                da->flags.length = dv->length;
                        }
                }
 
        } else if (da->type == FR_TYPE_TLV) {
                da->flags.type_size = dict->root->flags.type_size;
                da->flags.length = dict->root->flags.type_size;
        }
 
        if (parent->type == FR_TYPE_VENDOR) {
                ext = dict_attr_ext_alloc(da_p, FR_DICT_ATTR_EXT_VENDOR);
                if (unlikely(!ext)) return -1;
 
                ext->vendor = parent;
 
        } else {
                ext = dict_attr_ext_copy(da_p, parent, FR_DICT_ATTR_EXT_VENDOR); /* Noop if no vendor extension */
        }
 
        da = *da_p;
 
        if (!ext || ((da->type != FR_TYPE_TLV) && (da->type != FR_TYPE_VENDOR))) return 0;
 
        da->flags.type_size = ext->vendor->flags.type_size;
        da->flags.length = ext->vendor->flags.type_size;
 
        return 0;
}
 
/** Set the attribute number (if any)
 *
 * @param[in] da                to set the attribute number for.
 * @param[in] num               to set.
 */
int dict_attr_num_init(fr_dict_attr_t *da, unsigned int num)
{
        if (da->state.attr_set) {
                fr_strerror_const("Attribute number already set");
                return -1;
        }
        da->attr = num;
        da->state.attr_set = true;
 
        return 0;
}
 
/** Set the attribute number (if any)
 *
 * @note Must have a parent set.
 *
 * @param[in] da                to set the attribute number for.
 */
int dict_attr_num_init_name_only(fr_dict_attr_t *da)
{
        if (!da->parent) {
                fr_strerror_const("Attribute must have parent set before automatically setting attribute number");
                return -1;
        }
        return dict_attr_num_init(da, ++fr_dict_attr_unconst(da->parent)->last_child_attr);
}
 
/** Set where the dictionary attribute was defined
 *
 */
void dict_attr_location_init(fr_dict_attr_t *da, char const *filename, int line)
{
        da->filename = filename;
        da->line = line;
}
 
/** Set remaining fields in a dictionary attribute before insertion
 *
 * @param[in] da_p              to finalise.
 * @param[in] name              of the attribute.
 * @return
 *      - 0 on success.
 *      - < 0 on error.
 */
int dict_attr_finalise(fr_dict_attr_t **da_p, char const *name)
{
        fr_dict_attr_t          *da;
 
        /*
        *       Finalising the attribute allocates its
        *       automatic number if its a name only attribute.
        */
        da = *da_p;
 
        /*
         *      Initialize the length field automatically if it's not been set already
         */
        if (!da->flags.length && fr_type_is_leaf(da->type) && !fr_type_is_variable_size(da->type)) {
                fr_value_box_t box;
 
                fr_value_box_init(&box, da->type, NULL, false);
                da->flags.length = fr_value_box_network_length(&box);
        }
 
        switch(da->type) {
        case FR_TYPE_STRUCT:
                da->flags.is_known_width |= da->flags.array;
                break;
 
        case FR_TYPE_GROUP:
        {
                fr_dict_attr_ext_ref_t  *ext;
                /*
                *       If it's a group attribute, the default
                *       reference goes to the root of the
                *       dictionary as that's where the default
                *       name/numberspace is.
                *
                *       This may be updated by the caller.
                */
                ext = fr_dict_attr_ext(da, FR_DICT_ATTR_EXT_REF);
                if (unlikely(ext == NULL)) {
                        fr_strerror_const("Missing ref extension");
                        return -1;
                }
 
                /*
                 *      For groups, if a ref wasn't provided then
                 *      set it to the dictionary root.
                 */
                if ((ext->type == FR_DICT_ATTR_REF_NONE) &&
                    (unlikely(dict_attr_ref_set(da, fr_dict_root(da->dict), FR_DICT_ATTR_REF_ALIAS) < 0))) {
                        return -1;
                }
        }
                break;
 
        default:
                break;
        }
 
        /*
         *      Name is a separate talloc chunk.  We allocate
         *      it last because we cache the pointer value.
         */
        if (dict_attr_name_set(da_p, name) < 0) return -1;
 
        DA_VERIFY(*da_p);
 
        (*da_p)->state.finalised = true;
 
        return 0;
}
 
static inline CC_HINT(always_inline)
int dict_attr_init_common(char const *filename, int line,
                          fr_dict_attr_t **da_p,
                          fr_dict_attr_t const *parent,
                          fr_type_t type, dict_attr_args_t const *args)
{
        dict_attr_location_init((*da_p), filename, line);
 
        if (unlikely(dict_attr_type_init(da_p, type) < 0)) return -1;
 
        if (args->flags) (*da_p)->flags = *args->flags;
 
        if (parent && (dict_attr_parent_init(da_p, parent) < 0)) return -1;
 
        if (args->ref && (dict_attr_ref_aset(da_p, args->ref, FR_DICT_ATTR_REF_ALIAS) < 0)) return -1;
 
        /*
         *      Everything should be created correctly.
         */
        if (!(*da_p)->flags.internal && !(*da_p)->flags.is_alias &&
            parent && ((parent->type == FR_TYPE_TLV) || (parent->type ==FR_TYPE_VENDOR))) {
                if (!parent->flags.type_size) {
                        fr_strerror_printf("Parent %s has zero type_size", parent->name);
                        return -1;
                }
 
                if ((uint64_t) (*da_p)->attr >= ((uint64_t) 1 << (8 * parent->flags.type_size))) {
                        fr_strerror_printf("Child of parent %s has invalid attribute number %u for type_size %u",
                                           parent->name, (*da_p)->attr, parent->flags.type_size);
                        return -1;
                }
        }
 
        return 0;
}
 
/** Initialise fields in a dictionary attribute structure
 *
 * This function is a wrapper around the other initialisation functions.
 *
 * The reason for the separation, is that sometimes we're initialising a dictionary attribute
 * by parsing an actual dictionary file, and other times we're copying attribute, or initialising
 * them programatically.
 *
 * This function should only be used for the second case, where we have a complet attribute
 * definition already.
 *
 * @note This function can only be used _before_ the attribute is inserted into the dictionary.
 *
 * @param[in] filename          file.
 * @param[in] line              number.
 * @param[in] da_p              to initialise.
 * @param[in] parent            of the attribute, if none, this attribute will
 *                              be initialised as a dictionary root.
 * @param[in] name              of attribute.  Pass NULL for auto-generated name.
 * @param[in] attr              number.
 * @param[in] type              of the attribute.
 * @param[in] args              optional initialisation arguments.
 * @return
 *      - 0 on success.
 *      - <0 on error.
 */
int _dict_attr_init(char const *filename, int line,
                    fr_dict_attr_t **da_p,
                    fr_dict_attr_t const *parent,
                    char const *name, unsigned int attr,
                    fr_type_t type, dict_attr_args_t const *args)
{
        /*
         *      We initialize the number first, as doing that doesn't have any other side effects.
         */
        if (unlikely(dict_attr_num_init(*da_p, attr) < 0)) return -1;
 
        /*
         *      This function then checks the number, for things like VSAs.
         */
        if (unlikely(dict_attr_init_common(filename, line, da_p, parent, type, args) < 0)) return -1;
 
        if (unlikely(dict_attr_finalise(da_p, name) < 0)) return -1;
 
        return 0;
}
 
/** Initialise fields in a dictionary attribute structure
 *
 * This function is a wrapper around the other initialisation functions.
 *
 * The reason for the separation, is that sometimes we're initialising a dictionary attribute
 * by parsing an actual dictionary file, and other times we're copying attribute, or initialising
 * them programatically.
 *
 * This function should only be used for the second case, where we have a complet attribute
 * definition already.
 *
 * @note This function can only be used _before_ the attribute is inserted into the dictionary.
 *
 * @param[in] filename          file.
 * @param[in] line              number.
 * @param[in] da_p              to initialise.
 * @param[in] parent            of the attribute, if none, this attribute will
 *                              be initialised as a dictionary root.
 * @param[in] name              of attribute.  Pass NULL for auto-generated name.
 *                              automatically generated.
 * @param[in] type              of the attribute.
 * @param[in] args              optional initialisation arguments.
 * @return
 *      - 0 on success.
 *      - <0 on error.
 */
int _dict_attr_init_name_only(char const *filename, int line,
                         fr_dict_attr_t **da_p,
                         fr_dict_attr_t const *parent,
                         char const *name,
                         fr_type_t type, dict_attr_args_t const *args)
{
        if (unlikely(dict_attr_init_common(filename, line, da_p, parent, type, args) < 0)) return -1;
 
        /*
         *      Automatically generate the attribute number when the attribut is added.
         */
        (*da_p)->flags.name_only = true;
 
        if (unlikely(dict_attr_finalise(da_p, name) < 0)) return -1;
 
        return 0;
}
 
static int _dict_attr_free(fr_dict_attr_t *da)
{
        fr_dict_attr_ext_enumv_t        *ext;
 
#if 0
#ifdef WITH_VERIFY_PTR
        /*
         *      Check that any attribute we reference is still valid
         *      when we're being freed.
         */
        fr_dict_attr_t const *ref = fr_dict_attr_ref(da);
 
        if (ref) (void)talloc_get_type_abort_const(ref, fr_dict_attr_t);
#endif
#endif
 
        ext = fr_dict_attr_ext(da, FR_DICT_ATTR_EXT_ENUMV);
        if (ext) talloc_free(ext->value_by_name);               /* Ensure this is freed before the enumvs */
 
        return 0;
}
 
/** Allocate a partially completed attribute
 *
 * This is useful in some instances where we need to pre-allocate the attribute
 * for talloc hierarchy reasons, but want to finish initialising it
 * with #dict_attr_init later.
 *
 * @param[in] ctx               to allocate attribute in.
 * @param[in] proto             protocol specific extensions.
 * @return
 *      - A new, partially completed, fr_dict_attr_t on success.
 *      - NULL on failure (memory allocation error).
 */
fr_dict_attr_t *dict_attr_alloc_null(TALLOC_CTX *ctx, fr_dict_protocol_t const *proto)
{
        fr_dict_attr_t *da;
 
        /*
         *      Do not use talloc zero, the caller
         *      always initialises memory allocated
         *      here.
         */
        da = talloc_zero(ctx, fr_dict_attr_t);
        if (unlikely(!da)) return NULL;
 
        /*
         *      Allocate room for the protocol specific flags
         */
        if (proto->attr.flags.len > 0) {
                if (unlikely(dict_attr_ext_alloc_size(&da, FR_DICT_ATTR_EXT_PROTOCOL_SPECIFIC,
                                                      proto->attr.flags.len) == NULL)) {
                        talloc_free(da);
                        return NULL;
                }
        }
        talloc_set_destructor(da, _dict_attr_free);
 
        return da;
}
 
/** Allocate a dictionary root attribute on the heap
 *
 * @param[in] filename          file.
 * @param[in] line              number.
 * @param[in] ctx               to allocate the attribute in.
 * @param[in] dict              the attribute will be used in.
 * @param[in] name              of the attribute.  If NULL an OID string
 *                              will be created and set as the name.
 * @param[in] proto_number              number.  This should be
 * @param[in] args              optional initialisation arguments.
 * @return
 *      - A new fr_dict_attr_t on success.
 *      - NULL on failure.
 */
fr_dict_attr_t *_dict_attr_alloc_root(char const *filename, int line,
                                      TALLOC_CTX *ctx,
                                      fr_dict_t const *dict,
                                      char const *name, int proto_number,
                                      dict_attr_args_t const *args)
{
        fr_dict_attr_t  *n;
 
        n = dict_attr_alloc_null(ctx, dict->proto);
        if (unlikely(!n)) return NULL;
 
        if (_dict_attr_init(filename, line, &n, NULL, name, proto_number, FR_TYPE_TLV, args) < 0) {
                talloc_free(n);
                return NULL;
        }
 
        return n;
}
 
/** Allocate a dictionary attribute on the heap
 *
 * @param[in] filename          file.
 * @param[in] line              number.
 * @param[in] ctx               to allocate the attribute in.
 * @param[in] parent            of the attribute.
 * @param[in] name              of the attribute.  If NULL an OID string
 *                              will be created and set as the name.
 * @param[in] attr              number.
 * @param[in] type              of the attribute.
 * @param[in] args              optional initialisation arguments.
 * @return
 *      - A new fr_dict_attr_t on success.
 *      - NULL on failure.
 */
fr_dict_attr_t *_dict_attr_alloc(char const *filename, int line,
                                 TALLOC_CTX *ctx,
                                 fr_dict_attr_t const *parent,
                                 char const *name, int attr,
                                 fr_type_t type, dict_attr_args_t const *args)
{
        fr_dict_attr_t  *n;
 
        n = dict_attr_alloc_null(ctx, parent->dict->proto);
        if (unlikely(!n)) return NULL;
 
        if (_dict_attr_init(filename, line, &n, parent, name, attr, type, args) < 0) {
                talloc_free(n);
                return NULL;
        }
 
        return n;
}
 
/** Copy a an existing attribute, possibly to a new location
 *
 * @param[in] ctx               to allocate new attribute in.
 * @param[in] parent            where to parent the copy from. If NULL, in->parent is used.
 * @param[in] in                attribute to copy.
 * @param[in] name              to assign to the attribute. If NULL, in->name is used.
 * @return
 *      - A copy of the input fr_dict_attr_t on success.
 *      - NULL on failure.
 */
fr_dict_attr_t *dict_attr_acopy(TALLOC_CTX *ctx, fr_dict_attr_t const *parent, fr_dict_attr_t const *in,
                                char const *name)
{
        fr_dict_attr_t          *n;
 
        if (in->flags.has_fixup) {
                fr_strerror_printf("Cannot copy from %s - source attribute is waiting for additional definitions",
                                   in->name);
                return NULL;
        }
 
        fr_assert(parent || name);
 
        n = dict_attr_alloc(ctx, parent ? parent : in->parent, name ? name : in->name,
                            in->attr, in->type, &(dict_attr_args_t){ .flags = &in->flags });
        if (unlikely(!n)) return NULL;
 
        /*
         *      This newly allocated attribute is not the target of a ref.
         */
        n->flags.is_ref_target = false;
 
        if (dict_attr_ext_copy_all(&n, in) < 0) {
        error:
                talloc_free(n);
                return NULL;
        }
        DA_VERIFY(n);
 
        if (fr_type_is_structural(in->type) && in->flags.has_alias) {
                if (dict_attr_acopy_aliases(n, in) < 0) goto error;
        }
 
        return n;
}
 
int fr_dict_attr_acopy_local(fr_dict_attr_t const *dst, fr_dict_attr_t const *src)
{
        if (!dst->flags.local) {
                fr_strerror_const("Cannot copy attributes to a non-local dictionary");
                return -1;
        }
 
        if (src->flags.has_fixup) {
                fr_strerror_printf("Cannot copy from %s to %s - source attribute is waiting for additional definitions",
                                   src->name, dst->name);
                return -1;
        }
 
        /*
         *      Why not?  @todo - check and fix
         */
        if (src->flags.local) {
                fr_strerror_const("Cannot copy a local attribute");
                return -1;
        }
 
        return dict_attr_acopy_children(dst->dict, UNCONST(fr_dict_attr_t *, dst), src);
}
 
static int dict_attr_acopy_child(fr_dict_t *dict, fr_dict_attr_t *dst, fr_dict_attr_t const *src,
                                 fr_dict_attr_t const *child)
{
        fr_dict_attr_t                  *copy;
 
        copy = dict_attr_acopy(dict->pool, dst, child, child->name);
        if (!copy) return -1;
 
        fr_assert(copy->parent == dst);
        copy->depth = copy->parent->depth + 1;
 
        if (dict_attr_child_add(dst, copy) < 0) return -1;
 
        if (dict_attr_add_to_namespace(dst, copy) < 0) return -1;
 
        if (!dict_attr_children(child)) return 0;
 
        if (dict_attr_acopy_children(dict, copy, child) < 0) return -1;
 
        /*
         *      Children of a UNION get an ALIAS added to the parent of the UNION.  This allows the UNION
         *      attribute to be omitted from parsing and printing.
         */
        if (src->type != FR_TYPE_UNION) return 0;
 
        return dict_attr_alias_add(dst->parent, copy->name, copy, false);
}
 
 
/** Copy the children of an existing attribute
 *
 * @param[in] dict              to allocate the children in
 * @param[in] dst               where to copy the children to
 * @param[in] src               where to copy the children from
 * @return
 *      - 0 on success
 *      - <0 on error
 */
int dict_attr_acopy_children(fr_dict_t *dict, fr_dict_attr_t *dst, fr_dict_attr_t const *src)
{
        uint                            child_num;
        fr_dict_attr_t const            *child = NULL, *src_key = NULL;
        fr_dict_attr_t                  *dst_key;
 
        fr_assert(fr_dict_attr_has_ext(dst, FR_DICT_ATTR_EXT_CHILDREN));
        fr_assert(dst->type == src->type);
        fr_assert(fr_dict_attr_is_key_field(src) == fr_dict_attr_is_key_field(dst));
 
        /*
         *      For non-struct parents, we can copy their children in any order.
         */
        if (likely(src->type != FR_TYPE_STRUCT)) {
                for (child = fr_dict_attr_iterate_children(src, &child);
                     child != NULL;
                     child = fr_dict_attr_iterate_children(src, &child)) {
                        if (dict_attr_acopy_child(dict, dst, src, child) < 0) return -1;
                }
 
                return 0;
        }
 
        /*
         *      For structs, we copy the children in order.  This allows "key" fields to be copied before
         *      fields which depend on them.
         *
         *      Note that due to the checks in the DEFINE and ATTRIBUTE parsers (but not the validate
         *      routines), STRUCTs can only have children which are MEMBERs.  And MEMBERs are allocated in
         *      order.
         */
        for (child_num = 1, child = fr_dict_attr_child_by_num(src, child_num);
             child != NULL;
             child_num++, child = fr_dict_attr_child_by_num(src, child_num)) {
                /*
                 *      If the key field has enums, then delay copying the enums until after we've copied all
                 *      of the other children.
                 *
                 *      For a UNION which is inside of a STRUCT, the UNION has a reference to the key field.
                 *      So the key field needs to be defined before we create the UNION.
                 *
                 *      But the key field also has a set of ENUMs, each of which has a key ref to the UNION
                 *      member which is associated with that key value.  This means that we have circular
                 *      dependencies.
                 *
                 *      The loop is resolved by creating the key first, and allocating room for an ENUM
                 *      extension.  This allows the UNION to reference the key.  Once the UNION is created, we
                 *      go back and copy all of the ENUMs over.  The ENUM copy routine will take care of
                 *      fixing up the refs.
                 */
                if (unlikely(fr_dict_attr_is_key_field(child) && child->flags.has_value)) {
                        src_key = child;
 
                        if (src_key->flags.has_fixup) {
                                fr_strerror_printf("Cannot copy from %s - source attribute is waiting for additional definitions",
                                                   src_key->name);
                                return -1;
                        }
 
                        dst_key = dict_attr_alloc(dict, dst, src_key->name,
                                                  src_key->attr, src_key->type, &(dict_attr_args_t){ .flags = &src_key->flags });
                        if (unlikely(!dst_key)) return -1;
 
                        if (!dict_attr_ext_alloc(&dst_key, FR_DICT_ATTR_EXT_ENUMV)) return -1;
 
                        fr_assert(dst_key->parent == dst);
                        dst_key->depth = dst->depth + 1;
 
                        if (dict_attr_child_add(dst, dst_key) < 0) return -1;
 
                        if (dict_attr_add_to_namespace(dst, dst_key) < 0) return -1;
 
                        continue;
                }
 
                if (dict_attr_acopy_child(dict, dst, src, child) < 0) return -1;
 
                DA_VERIFY(child);
        }
 
        DA_VERIFY(dst);
 
        if (!src_key) return 0;
 
        if (!dict_attr_ext_copy(&dst_key, src_key, FR_DICT_ATTR_EXT_ENUMV)) return -1;
 
        return 0;
}
 
/** Copy the VALUEs of an existing attribute, by casting them
 *
 * @param[in] dst               where to cast the VALUEs to
 * @param[in] src               where to cast the VALUEs from
 * @return
 *      - 0 on success
 *      - <0 on error
 */
int dict_attr_acopy_enumv(fr_dict_attr_t *dst, fr_dict_attr_t const *src)
{
        fr_dict_attr_ext_enumv_t        *ext;
 
        fr_assert(!fr_type_is_non_leaf(dst->type));
        fr_assert(!fr_type_is_non_leaf(src->type));
 
        fr_assert(fr_dict_attr_has_ext(dst, FR_DICT_ATTR_EXT_ENUMV));
        fr_assert(fr_dict_attr_has_ext(src, FR_DICT_ATTR_EXT_ENUMV));
 
        ext = fr_dict_attr_ext(src, FR_DICT_ATTR_EXT_ENUMV);
        if (!ext) {
                fr_assert(0);
                return -1;
        }
 
        if (!ext->name_by_value) {
                fr_strerror_printf("Reference enum %s does not have any VALUEs to copy", src->name);
                return -1;
        }
 
        if (dict_attr_ext_copy(&dst, src, FR_DICT_ATTR_EXT_ENUMV)) return fr_hash_table_num_elements(ext->name_by_value);
 
        return -1;
}
 
 
/** Copy aliases of an existing attribute to a new one.
 *
 * @param[in] dst               where to copy the children to
 * @param[in] src               where to copy the children from
 * @return
 *      - 0 on success
 *      - <0 on error
 */
int dict_attr_acopy_aliases(UNUSED fr_dict_attr_t *dst, fr_dict_attr_t const *src)
{
        fr_hash_table_t *namespace;
        fr_hash_iter_t  iter;
        fr_dict_attr_t const *da;
 
        if (!src->flags.has_alias) return 0;
 
        switch (src->type) {
        case FR_TYPE_TLV:
        case FR_TYPE_VENDOR:
        case FR_TYPE_VSA:
                break;
 
                /*
                 *      Automatically added aliases are copied in dict_attr_acopy_child().
                 */
        case FR_TYPE_STRUCT:
                return 0;
 
        default:
                fr_strerror_printf("Cannot add ALIAS to parent attribute %s of data type '%s'", src->name, fr_type_to_str(src->type));
                return -1;
 
        }
 
        namespace = dict_attr_namespace(src);
        fr_assert(namespace != NULL);
 
        for (da = fr_hash_table_iter_init(namespace, &iter);
             da != NULL;
             da = fr_hash_table_iter_next(namespace, &iter)) {
                if (!da->flags.is_alias) continue;
 
#if 1
                fr_strerror_printf("Cannot clone ALIAS %s.%s to %s.%s", src->name, da->name, dst->name, da->name);
                return -1;
 
#else
                fr_dict_attr_t const *parent, *ref;
                fr_dict_attr_t const *new_ref;
 
                ref = fr_dict_attr_ref(da);
                fr_assert(ref != NULL);
 
                /*
                 *      ALIASes are normally down the tree, to shorten sibling relationships.
                 *      e.g. Cisco-AVPAir -> Vendor-Specific.Cisco.AV-Pair.
                 *
                 *      The question is to we want to allow aliases to create cross-tree links?  I suspect
                 *      not.
                 */
                parent = fr_dict_attr_common_parent(src, ref, true);
                if (!parent) {
                        fr_strerror_printf("Cannot clone ALIAS %s.%s to %s.%s, the alias reference %s is outside of the shared tree",
                                           src->name, da->name, dst->name, da->name, ref->name);
                        return -1;
                }
 
                fr_assert(parent == src);
 
                new_ref = fr_dict_attr_by_name(NULL, dst, da->name);
                fr_assert(new_ref == NULL);
 
                /*
                 *      This function needs to walk back up from "ref" to "src", finding the intermediate DAs.
                 *      Once that's done, it needs to walk down from "dst" to create a new "ref".
                 */
                new_ref = dict_alias_reref(dst, src, ref);
                fr_assert(new_ref != NULL);
 
                if (dict_attr_alias_add(dst, da->name, new_ref, false) < 0) return -1;
#endif
        }
 
        return 0;
}
 
/** Add an alias to an existing attribute
 *
 */
int dict_attr_alias_add(fr_dict_attr_t const *parent, char const *alias, fr_dict_attr_t const *ref, bool from_public)
{
        fr_dict_attr_t const *da;
        fr_dict_attr_t *self;
        fr_hash_table_t *namespace;
 
        switch (parent->type) {
        case FR_TYPE_STRUCT:
                /*
                 *      If we are a STRUCT, the reference an only be to children of a UNION.
                 */
                fr_assert(ref->parent->type == FR_TYPE_UNION);
 
                /*
                 *      And the UNION must be a MEMBER of the STRUCT.
                 */
                fr_assert(ref->parent->parent == parent);
                break;
 
        case FR_TYPE_TLV:
        case FR_TYPE_VENDOR:
        case FR_TYPE_VSA:
        case FR_TYPE_GROUP:
                break;
 
        default:
                fr_strerror_printf("Cannot add ALIAS to parent attribute %s of data type '%s'",
                                   parent->name, fr_type_to_str(parent->type));
                return -1;
        }
 
        if ((ref->type == FR_TYPE_UNION) || fr_dict_attr_is_key_field(ref)) {
                fr_strerror_printf("Cannot add ALIAS to target attribute %s of data type '%s'",
                                   ref->name, fr_type_to_str(ref->type));
                return -1;
        }
 
        da = dict_attr_by_name(NULL, parent, alias);
        if (da) {
                fr_strerror_printf("ALIAS '%s' conflicts with another attribute in namespace %s",
                                   alias, parent->name);
                return -1;
        }
 
        /*
         *      ALIASes from the dictionaries, need to point to a child of the same parent.  ALIASes cannot go
         *      back up the tree.
         *
         *      ALIASes added internally, they can break this restriction.
         *
         *      This restriction is here to prevent people from creating loops of ALIASes.
         */
        if (from_public && !fr_dict_attr_common_parent(parent, ref, true)) {
                fr_strerror_printf("Invalid ALIAS to target attribute %s of data type '%s' - the attributes do not share a parent",
                                   ref->name, fr_type_to_str(ref->type));
                return -1;
        }
 
        /*
         *      Note that we do NOT call fr_dict_attr_add() here.
         *
         *      When that function adds two equivalent attributes, the
         *      second one is prioritized for printing.  For ALIASes,
         *      we want the pre-existing one to be prioritized.
         *
         *      i.e. you can lookup the ALIAS by "name", but you
         *      actually get returned "ref".
         */
        {
                fr_dict_attr_flags_t flags = ref->flags;
 
                flags.is_alias = 1;     /* These get followed automatically by public functions */
 
                self = dict_attr_alloc(parent->dict->pool, parent, alias, ref->attr, FR_TYPE_VOID, (&(dict_attr_args_t){ .flags = &flags, .ref = ref }));
                if (unlikely(!self)) return -1;
        }
 
        self->dict = parent->dict;
        UNCONST(fr_dict_attr_t *, parent)->flags.has_alias = true;
 
        fr_assert(fr_dict_attr_ref(self) == ref);
 
        namespace = dict_attr_namespace(parent);
        if (!namespace) {
                fr_strerror_printf("Attribute '%s' does not contain a namespace", parent->name);
        error:
                talloc_free(self);
                return -1;
        }
 
        if (!fr_hash_table_insert(namespace, self)) {
                fr_strerror_const("Internal error storing attribute");
                goto error;
        }
 
        return 0;
}
 
/** Add a protocol to the global protocol table
 *
 * Inserts a protocol into the global protocol table.  Uses the root attributes
 * of the dictionary for comparisons.
 *
 * @param[in] dict of protocol we're inserting.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int dict_protocol_add(fr_dict_t *dict)
{
        if (!dict->root) return -1;     /* Should always have root */
 
        if (!fr_hash_table_insert(dict_gctx->protocol_by_name, dict)) {
                fr_dict_t *old_proto;
 
                old_proto = fr_hash_table_find(dict_gctx->protocol_by_name, dict);
                if (!old_proto) {
                        fr_strerror_printf("%s: Failed inserting protocol name %s", __FUNCTION__, dict->root->name);
                        return -1;
                }
 
                if ((strcmp(old_proto->root->name, dict->root->name) == 0) &&
                    (old_proto->root->name == dict->root->name)) {
                        fr_strerror_printf("%s: Duplicate protocol name %s", __FUNCTION__, dict->root->name);
                        return -1;
                }
 
                return 0;
        }
        dict->in_protocol_by_name = true;
 
        if (!fr_hash_table_insert(dict_gctx->protocol_by_num, dict)) {
                fr_strerror_printf("%s: Duplicate protocol number %u", __FUNCTION__, dict->root->attr);
                return -1;
        }
        dict->in_protocol_by_num = true;
 
        dict_dependent_add(dict, "global");
 
        /*
         *      Create and add sub-attributes which allow other
         *      protocols to be encapsulated in the internal
         *      namespace.
         */
        if (dict_gctx->internal && (dict != dict_gctx->internal)) {
                fr_dict_attr_t const *da;
                fr_dict_attr_flags_t flags = { 0 };
 
                if (!dict_gctx->attr_protocol_encapsulation) dict_gctx->attr_protocol_encapsulation = fr_dict_attr_by_name(NULL, dict_gctx->internal->root, "Proto");
                fr_assert(dict_gctx->attr_protocol_encapsulation != NULL);
 
                da = fr_dict_attr_child_by_num(dict_gctx->attr_protocol_encapsulation, dict->root->attr);
                if (!da) {
                        if (fr_dict_attr_add(dict_gctx->internal, dict_gctx->attr_protocol_encapsulation,
                                             dict->root->name, dict->root->attr, FR_TYPE_GROUP, &flags) < 0) {
                                return -1;
                        }
 
                        da = fr_dict_attr_child_by_num(dict_gctx->attr_protocol_encapsulation, dict->root->attr);
                        fr_assert(da != NULL);
                }
 
                dict_attr_ref_set(da, dict->root, FR_DICT_ATTR_REF_ALIAS);
        }
 
        return 0;
}
 
/** Add a vendor to the dictionary
 *
 * Inserts a vendor entry into the vendor hash table.  This must be done before adding
 * attributes under a VSA.
 *
 * @param[in] dict              of protocol context we're operating in.
 *                              If NULL the internal dictionary will be used.
 * @param[in] name              of the vendor.
 * @param[in] num               Vendor's Private Enterprise Number.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int dict_vendor_add(fr_dict_t *dict, char const *name, unsigned int num)
{
        size_t                  len;
        fr_dict_vendor_t        *vendor;
 
        INTERNAL_IF_NULL(dict, -1);
 
        len = strlen(name);
        if (len >= FR_DICT_VENDOR_MAX_NAME_LEN) {
                fr_strerror_printf("%s: Vendor name too long", __FUNCTION__);
                return -1;
        }
 
        vendor = talloc_zero(dict, fr_dict_vendor_t);
        if (!vendor) {
        oom:
                fr_strerror_const("Out of memory");
                return -1;
        }
 
        vendor->name = talloc_strdup(vendor, name);
        if (!vendor->name) {
                talloc_free(vendor);
                goto oom;
        }
        vendor->pen = num;
        vendor->type = vendor->length = 1; /* defaults */
 
        if (!fr_hash_table_insert(dict->vendors_by_name, vendor)) {
                fr_dict_vendor_t const *old_vendor;
 
                old_vendor = fr_hash_table_find(dict->vendors_by_name, vendor);
                if (!old_vendor) {
                        fr_strerror_printf("%s: Failed inserting vendor name %s", __FUNCTION__, name);
                        return -1;
                }
                if ((strcmp(old_vendor->name, vendor->name) == 0) && (old_vendor->pen != vendor->pen)) {
                        fr_strerror_printf("%s: Duplicate vendor name %s", __FUNCTION__, name);
                        return -1;
                }
 
                /*
                 *      Already inserted.  Discard the duplicate entry.
                 */
                talloc_free(vendor);
 
                return 0;
        }
 
        /*
         *      Insert the SAME pointer (not free'd when this table is
         *      deleted), into another table.
         *
         *      We want this behaviour because we want OLD names for
         *      the attributes to be read from the configuration
         *      files, but when we're printing them, (and looking up
         *      by value) we want to use the NEW name.
         */
        if (fr_hash_table_replace(NULL, dict->vendors_by_num, vendor) < 0) {
                fr_strerror_printf("%s: Failed inserting vendor %s", __FUNCTION__, name);
                return -1;
        }
 
        return 0;
}
 
/** See if a #fr_dict_attr_t can have children
 *
 * @param da the dictionary attribute to check.
 */
bool dict_attr_can_have_children(fr_dict_attr_t const *da)
{
        switch (da->type) {
        case FR_TYPE_TLV:
        case FR_TYPE_VENDOR:
        case FR_TYPE_VSA:
        case FR_TYPE_STRUCT:
        case FR_TYPE_UNION:
                return true;
 
        default:
                break;
        }
 
        return false;
}
 
/** Add a child to a parent.
 *
 * @param[in] parent    we're adding a child to.
 * @param[in] child     to add to parent.
 * @return
 *      - 0 on success.
 *      - -1 on failure (memory allocation error).
 */
int dict_attr_child_add(fr_dict_attr_t *parent, fr_dict_attr_t *child)
{
        fr_dict_attr_t const * const *bin;
        fr_dict_attr_t **this;
        fr_dict_attr_t const **children;
 
        /*
         *      Setup fields in the child
         */
        fr_assert(child->parent == parent);
 
        DA_VERIFY(child);
 
        if (fr_dict_attr_ref(parent)) {
                fr_strerror_printf("Cannot add children to attribute '%s' which has 'ref=%s'",
                                   parent->name, fr_dict_attr_ref(parent)->name);
                return -1;
        }
 
        if (!dict_attr_can_have_children(parent)) {
                fr_strerror_printf("Cannot add children to attribute '%s' of type %s",
                                   parent->name,
                                   fr_type_to_str(parent->type));
                return -1;
        }
 
        if ((parent->type == FR_TYPE_VSA) && (child->type != FR_TYPE_VENDOR)) {
                fr_strerror_printf("Cannot add non-vendor children to attribute '%s' of type %s",
                                   parent->name,
                                   fr_type_to_str(parent->type));
                return -1;
        }
 
        /*
         *      The parent has children by name only, not by number.  Don't even bother trying to track
         *      numbers, except for VENDOR in root, and MEMBER of a struct.
         */
        if (!parent->flags.is_root && parent->flags.name_only &&
            (parent->type != FR_TYPE_STRUCT) && (parent->type != FR_TYPE_TLV)) {
                return 0;
        }
 
        /*
         *      We only allocate the pointer array *if* the parent has children.
         */
        children = dict_attr_children(parent);
        if (!children) {
                children = talloc_zero_array(parent, fr_dict_attr_t const *, UINT8_MAX + 1);
                if (!children) {
                        fr_strerror_const("Out of memory");
                        return -1;
                }
                if (dict_attr_children_set(parent, children) < 0) return -1;
        }
 
        /*
         *      Treat the array as a hash of 255 bins, with attributes
         *      sorted into bins using num % 255.
         *
         *      Although the various protocols may define numbers higher than 255:
         *
         *      RADIUS/DHCPv4     - 1-255
         *      Diameter/Internal - 1-4294967295
         *      DHCPv6            - 1-65535
         *
         *      In reality very few will ever use attribute numbers > 500, so for
         *      the majority of lookups we get O(1) performance.
         *
         *      Attributes are inserted into the bin in order of their attribute
         *      numbers to allow slightly more efficient lookups.
         */
        for (bin = &children[child->attr & 0xff]; *bin; bin = &(*bin)->next) {
                /*
                 *      Workaround for vendors that overload the RFC space.
                 *      Structural attributes always take priority.
                 */
                bool child_is_struct = fr_type_is_structural(child->type);
                bool bin_is_struct = fr_type_is_structural((*bin)->type);
 
                if (child_is_struct && !bin_is_struct) break;
                if (fr_dict_vendor_num_by_da(child) <= fr_dict_vendor_num_by_da(*bin)) break;   /* Prioritise RFC attributes */
                if (child->attr <= (*bin)->attr) break;
        }
 
        memcpy(&this, &bin, sizeof(this));
        child->next = *this;
        *this = child;
 
        return 0;
}
 
/** Add an attribute to the name table for an attribute
 *
 * @param[in] parent            containing the namespace to add this attribute to.
 * @param[in] da                to add to the name lookup tables.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int dict_attr_add_to_namespace(fr_dict_attr_t const *parent, fr_dict_attr_t *da)
{
        fr_hash_table_t         *namespace;
 
        namespace = dict_attr_namespace(parent);
        if (unlikely(!namespace)) {
                fr_strerror_printf("Parent \"%s\" has no namespace", parent->name);
        error:
                return -1;
        }
 
        /*
         *      Sanity check to stop children of vendors ending
         *      up in the Vendor-Specific or root namespace.
         */
        if ((fr_dict_vendor_num_by_da(da) != 0) && (da->type != FR_TYPE_VENDOR) &&
            ((parent->type == FR_TYPE_VSA) || parent->flags.is_root)) {
                fr_strerror_printf("Cannot insert attribute '%s' of type %s into %s",
                                   da->name,
                                   fr_type_to_str(da->type),
                                   parent->name);
                goto error;
        }
 
        /*
         *      Insert the attribute, only if it's not a duplicate.
         */
        if (!fr_hash_table_insert(namespace, da)) {
                fr_dict_attr_t *a;
 
                /*
                 *      Find the old name.  If it's the same name and
                 *      but the parent, or number, or type are
                 *      different, that's an error.
                 */
                a = fr_hash_table_find(namespace, da);
                if (a && (strcasecmp(a->name, da->name) == 0)) {
                        if ((a->attr != da->attr) || (a->type != da->type) || (a->parent != da->parent)) {
                                fr_strerror_printf("Duplicate attribute name '%s' in namespace '%s'.  "
                                                   "Originally defined %s[%d]",
                                                   da->name, parent->name,
                                                   a->filename, a->line);
                                goto error;
                        }
                }
 
                /*
                 *      Otherwise the attribute has been redefined later
                 *      in the dictionary.
                 *
                 *      The original fr_dict_attr_t remains in the
                 *      dictionary but entry in the name hash table is
                 *      updated to point to the new definition.
                 */
                if (fr_hash_table_replace(NULL, namespace, da) < 0) {
                        fr_strerror_const("Internal error storing attribute");
                        goto error;
                }
        }
 
        return 0;
}
 
/** A variant of fr_dict_attr_t that allows a pre-allocated, populated fr_dict_attr_t to be added
 *
 */
int fr_dict_attr_add_initialised(fr_dict_attr_t *da)
{
        fr_dict_attr_t const    *exists;
 
        if (unlikely(da->dict->read_only)) {
                fr_strerror_printf("%s dictionary has been marked as read only", fr_dict_root(da->dict)->name);
                return -1;
        }
 
        if (unlikely(da->state.finalised == false)) {
                fr_strerror_const("Attribute has not been finalised");
                return -1;
        }
 
        /*
         *      Check that the definition is valid.
         */
        if (!dict_attr_valid(da)) return -1;
 
        /*
         *      Don't allow duplicate names
         *
         *      Previously we allowed duplicate names, but only if the
         *      attributes were compatible (we'd just ignore the operation).
         *
         *      But as attribute parsing may have generated fixups, which
         *      we'd now need to unpick, it's easier just to error out
         *      and have the user fix the duplicate.
         */
        exists = fr_dict_attr_by_name(NULL, da->parent, da->name);
        if (exists) {
                fr_strerror_printf("Duplicate attribute name '%s' in namespace '%s'.  "
                                   "Originally defined %s[%d]", da->name, da->parent->name,
                                   exists->filename, exists->line);
                return -1;
        }
 
        /*
         *      In some cases name_only attributes may have explicitly
         *      assigned numbers. Ensure that there are no conflicts
         *      between auto-assigned and explkicitly assigned.
         */
        if (da->flags.name_only) {
                if (da->state.attr_set) {
                        fr_dict_attr_t *parent = fr_dict_attr_unconst(da->parent);
 
                        if (da->attr > da->parent->last_child_attr) {
                                parent->last_child_attr = da->attr;
 
                                /*
                                *       If the attribute is outside of the bounds of
                                *       the type size, then it MUST be an internal
                                *       attribute.  Set the flag in this attribute, so
                                *       that the encoder doesn't have to do complex
                                *       checks.
                                */
                                if ((da->attr >= (((uint64_t)1) << (8 * parent->flags.type_size)))) da->flags.internal = true;
                        }
                } else if (unlikely(dict_attr_num_init_name_only(da)) < 0) {
                        return -1;
                }
        }
 
        /*
         *      Attributes can also be indexed by number.  Ensure that
         *      all attributes of the same number have the same
         *      properties.
         */
        exists = fr_dict_attr_child_by_num(da->parent, da->attr);
        if (exists) {
                fr_strerror_printf("Duplicate attribute number %u in namespace '%s'.  "
                                   "Originally defined by '%s' at %s[%d]",
                                   da->attr, da->parent->name, exists->name, exists->filename, exists->line);
                return -1;
        }
 
        /*
         *      Add in by number
         */
        if (dict_attr_child_add(UNCONST(fr_dict_attr_t *, da->parent), da) < 0) return -1;
 
        /*
         *      Add in by name
         */
        if (dict_attr_add_to_namespace(da->parent, da) < 0) return -1;
 
#ifndef NDEBUG
        {
                fr_dict_attr_t const *found;
 
                /*
                 *      Check if we added the attribute
                 */
                found = dict_attr_child_by_num(da->parent, da->attr);
                if (!found) {
                        fr_strerror_printf("FATAL - Failed to find attribute number %u we just added to namespace '%s'", da->attr, da->parent->name);
                        return -1;
                }
 
                if (!dict_attr_by_name(NULL, da->parent, da->name)) {
                        fr_strerror_printf("FATAL - Failed to find attribute '%s' we just added to namespace '%s'", da->name, da->parent->name);
                        return -1;
                }
        }
#endif
 
        return 0;
}
 
/** Add an attribute to the dictionary
 *
 * @param[in] dict              of protocol context we're operating in.
 *                              If NULL the internal dictionary will be used.
 * @param[in] parent            to add attribute under.
 * @param[in] name              of the attribute.
 * @param[in] attr              number.
 * @param[in] type              of attribute.
 * @param[in] flags             to set in the attribute.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int fr_dict_attr_add(fr_dict_t *dict, fr_dict_attr_t const *parent,
                     char const *name, unsigned int attr, fr_type_t type, fr_dict_attr_flags_t const *flags)
{
        fr_dict_attr_t *da;
 
        if (fr_dict_attr_ref(parent)) {
                fr_strerror_printf("Cannot add children to attribute '%s' which has 'ref=%s'",
                                   parent->name, fr_dict_attr_ref(parent)->name);
                return -1;
        }
 
        if (!dict_attr_can_have_children(parent)) {
                fr_strerror_printf("Cannot add children to attribute '%s' of type %s",
                                   parent->name,
                                   fr_type_to_str(parent->type));
                return -1;
        }
 
        da = dict_attr_alloc_null(dict->pool, dict->proto);
        if (unlikely(!da)) return -1;
 
        if (dict_attr_init(&da, parent, name,
                           attr, type, &(dict_attr_args_t){ .flags = flags}) < 0) return -1;
 
        return fr_dict_attr_add_initialised(da);
}
 
/** Add an attribute to the dictionary
 *
 * @param[in] dict              of protocol context we're operating in.
 *                              If NULL the internal dictionary will be used.
 * @param[in] parent            to add attribute under.
 * @param[in] name              of the attribute.
 * @param[in] type              of attribute.
 * @param[in] flags             to set in the attribute.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int fr_dict_attr_add_name_only(fr_dict_t *dict, fr_dict_attr_t const *parent,
                               char const *name, fr_type_t type, fr_dict_attr_flags_t const *flags)
{
        fr_dict_attr_t *da;
 
        da = dict_attr_alloc_null(dict->pool, dict->proto);
        if (unlikely(!da)) return -1;
 
        if (dict_attr_init_name_only(&da, parent, name,type, &(dict_attr_args_t){ .flags = flags}) < 0) return -1;
 
        return fr_dict_attr_add_initialised(da);
}
 
 
int dict_attr_enum_add_name(fr_dict_attr_t *da, char const *name,
                            fr_value_box_t const *value,
                            bool coerce, bool takes_precedence,
                            fr_dict_attr_t const *key_child_ref)
{
        size_t                          len;
        fr_dict_enum_value_t            *enumv = NULL;
        fr_value_box_t                  *enum_value = NULL;
        fr_dict_attr_ext_enumv_t        *ext;
 
        if (!da) {
                fr_strerror_printf("%s: Dictionary attribute not specified", __FUNCTION__);
                return -1;
        }
 
        if (!*name) {
                fr_strerror_printf("%s: Empty names are not permitted", __FUNCTION__);
                return -1;
        }
 
        len = strlen(name);
        if (len >= FR_DICT_ENUM_MAX_NAME_LEN) {
                fr_strerror_printf("VALUE name is too long");
                return -1;
        }
 
        /*
         *      If the parent isn't a key field, then we CANNOT add a child struct.
         */
        if (!fr_dict_attr_is_key_field(da) && key_child_ref) {
                fr_strerror_const("Child attributes cannot be defined for VALUEs which are not 'key' attributes");
                return -1;
        }
 
        if (fr_type_is_structural(da->type) || (da->type == FR_TYPE_STRING)) {
                fr_strerror_printf("Enumeration names cannot be added for data type '%s'", fr_type_to_str(da->type));
                return -1;
        }
 
        if (da->flags.is_alias) {
                fr_strerror_printf("Enumeration names cannot be added for ALIAS '%s'", da->name);
                return -1;
        }
 
        ext = fr_dict_attr_ext(da, FR_DICT_ATTR_EXT_ENUMV);
        if (!ext) {
                fr_strerror_printf("VALUE cannot be defined for %s", da->name);
                return -1;
        }
 
        /*
         *      Initialise enumv hash tables
         */
        if (!ext->value_by_name || !ext->name_by_value) {
                ext->value_by_name = fr_hash_table_talloc_alloc(da, fr_dict_enum_value_t, dict_enum_name_hash,
                                                                dict_enum_name_cmp, NULL);
                if (!ext->value_by_name) {
                        fr_strerror_printf("Failed allocating \"value_by_name\" table");
                        return -1;
                }
 
                ext->name_by_value = fr_hash_table_talloc_alloc(da, fr_dict_enum_value_t, dict_enum_value_hash,
                                                                dict_enum_value_cmp, NULL);
                if (!ext->name_by_value) {
                        fr_strerror_printf("Failed allocating \"name_by_value\" table");
                        return -1;
                }
        }
 
        /*
         *      Allocate a structure to map between
         *      the name and value.
         */
        enumv = talloc_zero(da, fr_dict_enum_value_t);
        if (!enumv) {
        oom:
                fr_strerror_printf("%s: Out of memory", __FUNCTION__);
                return -1;
        }
 
        enumv->name = talloc_strdup(enumv, name);
        enumv->name_len = len;
 
        if (key_child_ref) {
                fr_dict_enum_ext_attr_ref_t *ref;
 
                ref = dict_enum_ext_alloc(&enumv, FR_DICT_ENUM_EXT_ATTR_REF);
                if (!ref) goto oom;
 
                ref->da = key_child_ref;
        }
 
        enum_value = fr_value_box_alloc(enumv, da->type, NULL);
        if (!enum_value) goto oom;
 
        if (da->type != value->type) {
                if (!coerce) {
                        fr_strerror_printf("Type mismatch between attribute (%s) and enum (%s)",
                                           fr_type_to_str(da->type),
                                           fr_type_to_str(value->type));
                        return -1;
                }
 
                if (fr_value_box_cast(enumv, enum_value, da->type, NULL, value) < 0) {
                        fr_strerror_printf_push("Failed coercing enum type (%s) to attribute type (%s)",
                                                fr_type_to_str(value->type),
                                                fr_type_to_str(da->type));
 
                        return -1;
                }
        } else {
                if (unlikely(fr_value_box_copy(enum_value, enum_value, value) < 0)) {
                        fr_strerror_printf_push("%s: Failed copying value into enum", __FUNCTION__);
                        return -1;
                }
        }
 
        enumv->value = enum_value;
 
        /*
         *      Add the value into the dictionary.
         */
        {
                fr_dict_attr_t *tmp;
                memcpy(&tmp, &enumv, sizeof(tmp));
 
                if (!fr_hash_table_insert(ext->value_by_name, tmp)) {
                        fr_dict_enum_value_t const *old;
 
                        /*
                         *      Suppress duplicates with the same
                         *      name and value.  There are lots in
                         *      dictionary.ascend.
                         */
                        old = fr_dict_enum_by_name(da, name, -1);
                        if (!fr_cond_assert(old)) return -1;
 
                        if (fr_value_box_cmp(old->value, enumv->value) == 0) {
                                talloc_free(enumv);
                                return 0;
                        }
 
                        fr_strerror_printf("Duplicate VALUE name \"%s\" for Attribute '%s'. "
                                           "Old value was \"%pV\", new value was \"%pV\"", name, da->name,
                                           old->value, enumv->value);
                        talloc_free(enumv);
                        return -1;
                }
 
                if (enumv->name_len > ext->max_name_len) ext->max_name_len = enumv->name_len;
        }
 
        /*
         *      There are multiple VALUE's, keyed by attribute, so we
         *      take care of that here.
         */
        if (takes_precedence) {
                if (fr_hash_table_replace(NULL, ext->name_by_value, enumv) < 0) {
                        fr_strerror_printf("%s: Failed inserting value %s", __FUNCTION__, name);
                        return -1;
                }
        } else {
                (void) fr_hash_table_insert(ext->name_by_value, enumv);
        }
 
        /*
         *      Mark the attribute up as having an enumv
         */
        UNCONST(fr_dict_attr_t *, da)->flags.has_value = 1;
 
        return 0;
}
 
/** Add a value name
 *
 * Aliases are textual (string) names for a given value.
 *
 * Value names are not limited to integers, and may be added for any non-structural
 * attribute type.
 *
 * @param[in] da                to add enumeration value to.
 * @param[in] name              Name of value name.
 * @param[in] value             to associate with name.
 * @param[in] coerce            if the type of the value does not match the
 *                              type of the da, attempt to cast it to match
 *                              the type of the da.  If this is false and there's
 *                              a type mismatch, we fail.
 *                              We also fail if the value cannot be coerced to
 *                              the attribute type.
 * @param[in] takes_precedence  This name should take precedence over previous
 *                              names for the same value, when resolving value
 *                              to name.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int fr_dict_enum_add_name(fr_dict_attr_t *da, char const *name,
                               fr_value_box_t const *value,
                               bool coerce, bool takes_precedence)
{
        return dict_attr_enum_add_name(da, name, value, coerce, takes_precedence, NULL);
}
 
/** Add an name to an integer attribute hashing the name for the integer value
 *
 * If the integer value conflicts with an existing name, it's incremented
 * until we find a free value.
 */
int fr_dict_enum_add_name_next(fr_dict_attr_t *da, char const *name)
{
        fr_value_box_t  v = {
                                .type = da->type
                        };
        fr_value_box_t  s = {
                                .type = da->type
                        };
 
        if (fr_dict_enum_by_name(da, name, -1)) return 0;
 
        switch (da->type) {
        case FR_TYPE_INT8:
                v.vb_int8 = s.vb_int8 = fr_hash_string(name) & INT8_MAX;
                break;
 
        case FR_TYPE_INT16:
                v.vb_int16 = s.vb_int16 = fr_hash_string(name) & INT16_MAX;
                break;
 
        case FR_TYPE_INT32:
                v.vb_int32 = s.vb_int32 = fr_hash_string(name) & INT32_MAX;
                break;
 
        case FR_TYPE_INT64:
                v.vb_int64 = s.vb_int64 = fr_hash_string(name) & INT64_MAX;
                break;
 
        case FR_TYPE_UINT8:
                v.vb_uint8 = s.vb_uint8 = fr_hash_string(name) & UINT8_MAX;
                break;
 
        case FR_TYPE_UINT16:
                v.vb_uint16 = s.vb_uint16 = fr_hash_string(name) & UINT16_MAX;
                break;
 
        case FR_TYPE_UINT32:
                v.vb_uint32 = s.vb_uint32 = fr_hash_string(name) & UINT32_MAX;
                break;
 
        case FR_TYPE_UINT64:
                v.vb_uint64 = s.vb_uint64 = fr_hash_string(name) & UINT64_MAX;
                break;
 
        default:
                fr_strerror_printf("Attribute is wrong type for auto-numbering, expected numeric type, got %s",
                                   fr_type_to_str(da->type));
                return -1;
        }
 
        /*
         *      If there's no existing value, add an enum
         *      with the hash value of the name.
         *
         *      This helps with debugging as the values
         *      are consistent.
         */
        if (!fr_dict_enum_by_value(da, &v)) {
        add:
                return fr_dict_enum_add_name(da, name, &v, false, false);
        }
 
        for (;;) {
                fr_value_box_increment(&v);
 
                if (fr_value_box_cmp_op(T_OP_CMP_EQ, &v, &s) == 0) {
                        fr_strerror_const("No free integer values for enumeration");
                        return -1;
                }
 
                if (!fr_dict_enum_by_value(da, &v)) goto add;
        }
        /* NEVER REACHED */
}
 
/** Find a common ancestor that two TLV type attributes share
 *
 * @param[in] a                 first TLV attribute.
 * @param[in] b                 second TLV attribute.
 * @param[in] is_ancestor       Enforce a->b relationship (a is parent or ancestor of b).
 * @return
 *      - Common ancestor if one exists.
 *      - NULL if no common ancestor exists.
 */
fr_dict_attr_t const *fr_dict_attr_common_parent(fr_dict_attr_t const *a, fr_dict_attr_t const *b, bool is_ancestor)
{
        unsigned int i;
        fr_dict_attr_t const *p_a, *p_b;
 
        if (!a || !b) return NULL;
 
        if (is_ancestor && (b->depth <= a->depth)) return NULL; /* fast_path */
 
        /*
         *      Find a common depth to work back from
         */
        if (a->depth > b->depth) {
                p_b = b;
                for (p_a = a, i = a->depth - b->depth; p_a && (i > 0); p_a = p_a->parent, i--);
                if (is_ancestor && (p_a != p_b)) return NULL;
        } else if (a->depth < b->depth) {
                p_a = a;
                for (p_b = b, i = b->depth - a->depth; p_b && (i > 0); p_b = p_b->parent, i--);
                if (is_ancestor && (p_a != p_b)) return NULL;
        } else {
                p_a = a;
                p_b = b;
        }
 
        while (p_a && p_b) {
                if (p_a == p_b) return p_a;
 
                p_a = p_a->parent;
                p_b = p_b->parent;
        }
 
        return NULL;
}
 
/** Process a single OID component
 *
 * @param[out] out              Value of component.
 * @param[in] oid               string to parse.
 * @return
 *      - 0 on success.
 *      - -1 on format error.
 */
int fr_dict_oid_component_legacy(unsigned int *out, char const **oid)
{
        char const *p = *oid;
        char *q;
        unsigned long num;
 
        *out = 0;
 
        num = strtoul(p, &q, 10);
        if ((p == q) || (num == ULONG_MAX)) {
                fr_strerror_printf("Invalid OID component \"%s\" (%lu)", p, num);
                return -1;
        }
 
        switch (*q) {
        case '\0':
        case '.':
                *oid = q;
                *out = (unsigned int)num;
 
                return 0;
 
        default:
                fr_strerror_const("Unexpected text after OID component");
                *out = 0;
                return -1;
        }
}
 
/** Get the leaf attribute of an OID string
 *
 * @note On error, vendor will be set (if present), parent will be the
 *      maximum depth we managed to resolve to, and attr will be the child
 *      we failed to resolve.
 *
 * @param[out] attr             Number we parsed.
 * @param[in,out] parent        attribute (or root of dictionary).
 *                              Will be updated to the parent directly beneath the leaf.
 * @param[in] oid               string to parse.
 * @return
 *      - > 0 on success (number of bytes parsed).
 *      - <= 0 on parse error (negative offset of parse error).
 */
ssize_t fr_dict_attr_by_oid_legacy(fr_dict_attr_t const **parent, unsigned int *attr, char const *oid)
{
        char const              *p = oid;
        unsigned int            num = 0;
        ssize_t                 slen;
 
        if (!*parent) return -1;
 
        /*
         *      It's a partial OID.  Grab it, and skip to the next bit.
         */
        if (p[0] == '.') {
                p++;
        }
 
        *attr = 0;
 
        if (fr_dict_oid_component_legacy(&num, &p) < 0) return oid - p;
 
        /*
         *      Record progress even if we error out.
         *
         *      Don't change this, you will break things.
         */
        *attr = num;
 
        /*
         *      Only a limited number of structural types can have children.  Specifically, groups cannot.
         */
        if (!dict_attr_can_have_children(*parent)) {
                fr_strerror_printf("Attribute %s (%u) cannot contain a child attribute.  "
                                   "Error at sub OID \"%s\"", (*parent)->name, (*parent)->attr, oid);
                return 0;       /* We parsed nothing */
        }
 
        switch (p[0]) {
        /*
         *      We've not hit the leaf yet, so the attribute must be
         *      defined already.
         */
        case '.':
        {
                fr_dict_attr_t const *child;
                p++;
 
                child = dict_attr_child_by_num(*parent, num);
                if (!child) {
                        fr_strerror_printf("Unknown attribute '%u' in OID string \"%s\" for parent %s",
                                           num, oid, (*parent)->name);
                        return 0;       /* We parsed nothing */
                }
 
                /*
                 *      Record progress even if we error out.
                 *
                 *      Don't change this, you will break things.
                 */
                *parent = child;
 
                slen = fr_dict_attr_by_oid_legacy(parent, attr, p);
                if (slen <= 0) return slen - (p - oid);
                return slen + (p - oid);
        }
 
        /*
         *      Hit the leaf, this is the attribute we need to define.
         */
        case '\0':
                *attr = num;
                return p - oid;
 
        default:
                fr_strerror_printf("Malformed OID string, got trailing garbage '%s'", p);
                return oid - p;
        }
}
 
/** Parse an OID component, resolving it to a defined attribute
 *
 * @note Will leave the sbuff pointing at the component the error occurred at
 *       so that the caller can attempt to process the component in another way.
 *
 * @param[out] err              The parsing error that occurred.
 * @param[out] out              The deepest attribute we resolved.
 * @param[in] parent            Where to resolve relative attributes from.
 * @param[in] in                string to parse.
 * @param[in] tt                Terminal strings.
 * @return
 *      - >0 the number of bytes consumed.
 *      - <0 Parse error occurred here.
 */
fr_slen_t fr_dict_oid_component(fr_dict_attr_err_t *err,
                                fr_dict_attr_t const **out, fr_dict_attr_t const *parent,
                                fr_sbuff_t *in, fr_sbuff_term_t const *tt)
{
        fr_sbuff_t              our_in = FR_SBUFF(in);
        uint32_t                num = 0;
        fr_sbuff_parse_error_t  sberr;
        fr_dict_attr_t const    *child;
 
        if (err) *err = FR_DICT_ATTR_OK;
 
        *out = NULL;
 
        if (!dict_attr_can_have_children(parent)) {
                fr_strerror_printf("Attribute '%s' is type %s and cannot contain child attributes.  "
                                   "Error at OID \"%.*s\"",
                                   parent->name,
                                   fr_type_to_str(parent->type),
                                   (int)fr_sbuff_remaining(&our_in),
                                   fr_sbuff_current(&our_in));
                if (err) *err = FR_DICT_ATTR_NO_CHILDREN;
                FR_SBUFF_ERROR_RETURN(&our_in);
        }
 
        if (fr_dict_attr_by_name_substr(err, &child, parent, &our_in, tt) > 0) goto done;
 
        fr_sbuff_out(&sberr, &num, &our_in);
        switch (sberr) {
        /*
         *      Lookup by number
         */
        case FR_SBUFF_PARSE_OK:
                if (!fr_sbuff_is_char(&our_in, '.') && !fr_sbuff_is_terminal(&our_in, tt)) {
                        if (err) *err = FR_DICT_ATTR_PARSE_ERROR;
                        fr_strerror_printf("Invalid OID component (%s) \"%.*s\"",
                                           fr_table_str_by_value(sbuff_parse_error_table, sberr, "<INVALID>"),
                                           (int)fr_sbuff_remaining(&our_in), fr_sbuff_current(&our_in));
                        goto fail;
                }
 
                child = dict_attr_child_by_num(parent, num);
                if (!child) {
                        fr_sbuff_set_to_start(&our_in);
                        fr_strerror_printf("Failed resolving child %u in namespace '%s'",
                                           num, parent->name);
                        if (err) *err = FR_DICT_ATTR_NOTFOUND;
                        FR_SBUFF_ERROR_RETURN(&our_in);
                }
 
                if (err) *err = FR_DICT_ATTR_OK;
                break;
 
        case FR_SBUFF_PARSE_ERROR_NUM_OVERFLOW:
                if (err) *err = FR_DICT_ATTR_PARSE_ERROR;
 
                fr_sbuff_set_to_start(&our_in);
 
                {
                        fr_sbuff_marker_t c_start;
 
                        fr_sbuff_marker(&c_start, &our_in);
                        fr_sbuff_adv_past_allowed(&our_in, FR_DICT_ATTR_MAX_NAME_LEN, fr_dict_attr_allowed_chars, NULL);
                        fr_strerror_printf("Invalid value \"%.*s\" - attribute numbers must be less than 2^32",
                                           (int)fr_sbuff_behind(&c_start), fr_sbuff_current(&c_start));
                }
                FR_SBUFF_ERROR_RETURN(&our_in);
 
        default:
        fail:
                /*
                 *      Leave *err from the call to fr_dict_attr_by_name_substr().
                 */
                fr_sbuff_set_to_start(&our_in);
                FR_SBUFF_ERROR_RETURN(&our_in);
        }
 
done:
        child = dict_attr_alias(err, child);
        if (unlikely(!child)) FR_SBUFF_ERROR_RETURN(&our_in);
 
        *out = child;
 
        FR_SBUFF_SET_RETURN(in, &our_in);
}
 
/** Resolve an attribute using an OID string
 *
 * @note Will leave the sbuff pointing at the component the error occurred at
 *       so that the caller can attempt to process the component in another way.
 *       An err pointer should be provided in order to determine if an error
 *       occurred.
 *
 * @param[out] err              The parsing error that occurred.
 * @param[out] out              The deepest attribute we resolved.
 * @param[in] parent            Where to resolve relative attributes from.
 * @param[in] in                string to parse.
 * @param[in] tt                Terminal strings.
 * @return The number of bytes of name consumed.
 */
fr_slen_t fr_dict_attr_by_oid_substr(fr_dict_attr_err_t *err,
                                     fr_dict_attr_t const **out, fr_dict_attr_t const *parent,
                                     fr_sbuff_t *in, fr_sbuff_term_t const *tt)
{
        fr_sbuff_t              our_in = FR_SBUFF(in);
        fr_sbuff_marker_t       m_c;
        fr_dict_attr_t const    *our_parent = parent;
 
        fr_sbuff_marker(&m_c, &our_in);
 
        /*
         *      If the OID doesn't begin with '.' we
         *      resolve it from the root.
         */
#if 0
        if (!fr_sbuff_next_if_char(&our_in, '.')) our_parent = fr_dict_root(fr_dict_by_da(parent));
#else
        (void) fr_sbuff_next_if_char(&our_in, '.');
#endif
        *out = NULL;
 
        for (;;) {
                fr_dict_attr_t const    *child;
 
                if ((fr_dict_oid_component(err, &child, our_parent, &our_in, tt) < 0) || !child) {
                        *out = our_parent;
                        fr_sbuff_set(&our_in, &m_c);    /* Reset to the start of the last component */
                        break;  /* Resolved as much as we can */
                }
 
                our_parent = child;
                *out = child;
 
                fr_sbuff_set(&m_c, &our_in);
                if (!fr_sbuff_next_if_char(&our_in, '.')) break;
        }
 
        FR_SBUFF_SET_RETURN(in, &our_in);
}
 
/** Resolve an attribute using an OID string
 *
 * @param[out] err              The parsing error that occurred.
 * @param[in] parent            Where to resolve relative attributes from.
 * @param[in] oid               string to parse.
 * @return
 *      - NULL if we couldn't resolve the attribute.
 *      - The resolved attribute.
 */
fr_dict_attr_t const *fr_dict_attr_by_oid(fr_dict_attr_err_t *err, fr_dict_attr_t const *parent, char const *oid)
{
        fr_sbuff_t              sbuff = FR_SBUFF_IN(oid, strlen(oid));
        fr_dict_attr_t const    *da;
 
        if (fr_dict_attr_by_oid_substr(err, &da, parent, &sbuff, NULL) <= 0) return NULL;
        if (err && *err != FR_DICT_ATTR_OK) return NULL;
 
        /*
         *      If we didn't parse the entire string, then the parsing stopped at an unknown child.
         *      e.g. Vendor-Specific.Cisco.Foo.  In that case, the full attribute wasn't found.
         */
        if (fr_sbuff_remaining(&sbuff) > 0) {
                if (err) *err = FR_DICT_ATTR_NOTFOUND;
                return NULL;
        }
 
        return da;
}
 
/** Return the root attribute of a dictionary
 *
 * @param dict                  to return root for.
 * @return the root attribute of the dictionary.
 *
 * @hidecallergraph
 */
fr_dict_attr_t const *fr_dict_root(fr_dict_t const *dict)
{
        return dict->root;
}
 
bool fr_dict_is_read_only(fr_dict_t const *dict)
{
        return dict->read_only;
}
 
dl_t *fr_dict_dl(fr_dict_t const *dict)
{
        return dict->dl;
}
 
fr_slen_t dict_by_protocol_substr(fr_dict_attr_err_t *err,
                                  fr_dict_t **out, fr_sbuff_t *name, fr_dict_t const *dict_def)
{
        fr_dict_attr_t          root;
 
        fr_sbuff_t              our_name;
        fr_dict_t               *dict;
        fr_slen_t               slen;
        char                    buffer[FR_DICT_ATTR_MAX_NAME_LEN + 1 + 1];      /* +1 \0 +1 for "too long" */
 
        if (!dict_gctx || !name || !out) {
                if (err) *err = FR_DICT_ATTR_EINVAL;
                if (name) FR_SBUFF_ERROR_RETURN(name);
                return 0;
        }
 
        our_name = FR_SBUFF(name);
        memset(&root, 0, sizeof(root));
 
        /*
         *      Advance p until we get something that's not part of
         *      the dictionary attribute name.
         */
        slen = fr_sbuff_out_bstrncpy_allowed(&FR_SBUFF_OUT(buffer, sizeof(buffer)),
                                             &our_name, SIZE_MAX,
                                             fr_dict_attr_allowed_chars);
        if (slen == 0) {
                fr_strerror_const("Zero length attribute name");
                if (err) *err = FR_DICT_ATTR_PARSE_ERROR;
                FR_SBUFF_ERROR_RETURN(&our_name);
        }
        if (slen > FR_DICT_ATTR_MAX_NAME_LEN) {
                fr_strerror_const("Attribute name too long");
                if (err) *err = FR_DICT_ATTR_PARSE_ERROR;
                FR_SBUFF_ERROR_RETURN(&our_name);
        }
 
        /*
         *      The remaining operations don't generate errors
         */
        if (err) *err = FR_DICT_ATTR_OK;
 
        /*
         *      If what we stopped at wasn't a '.', then there
         *      can't be a protocol name in this string.
         */
        if (*(our_name.p) && (*(our_name.p) != '.')) {
                memcpy(out, &dict_def, sizeof(*out));
                return 0;
        }
 
        root.name = buffer;
        dict = fr_hash_table_find(dict_gctx->protocol_by_name, &(fr_dict_t){ .root = &root });
 
        if (!dict) {
                if (strcasecmp(root.name, "internal") != 0) {
                        fr_strerror_printf("Unknown protocol '%s'", root.name);
                        memcpy(out, &dict_def, sizeof(*out));
                        fr_sbuff_set_to_start(&our_name);
                        FR_SBUFF_ERROR_RETURN(&our_name);
                }
 
                dict = dict_gctx->internal;
        }
 
        *out = dict;
 
        FR_SBUFF_SET_RETURN(name, &our_name);
}
 
/** Look up a protocol name embedded in another string
 *
 * @param[out] err              Parsing error.
 * @param[out] out              the resolve dictionary or NULL if the dictionary
 *                              couldn't be resolved.
 * @param[in] name              string start.
 * @param[in] dict_def          The dictionary to return if no dictionary qualifier was found.
 * @return
 *      - 0 and *out != NULL.  Couldn't find a dictionary qualifier, so returned dict_def.
 *      - < 0 on error and (*out == NULL) (offset as negative integer)
 *      - > 0 on success (number of bytes parsed).
 */
fr_slen_t fr_dict_by_protocol_substr(fr_dict_attr_err_t *err, fr_dict_t const **out, fr_sbuff_t *name, fr_dict_t const *dict_def)
{
        return dict_by_protocol_substr(err, UNCONST(fr_dict_t **, out), name, dict_def);
}
 
/** Internal version of #fr_dict_by_protocol_name
 *
 * @note For internal use by the dictionary API only.
 *
 * @copybrief fr_dict_by_protocol_name
 */
fr_dict_t *dict_by_protocol_name(char const *name)
{
        if (!dict_gctx || !name) return NULL;
 
        return fr_hash_table_find(dict_gctx->protocol_by_name,
                                  &(fr_dict_t){ .root = &(fr_dict_attr_t){ .name = name } });
}
 
/** Internal version of #fr_dict_by_protocol_num
 *
 * @note For internal use by the dictionary API only.
 *
 * @copybrief fr_dict_by_protocol_num
 */
fr_dict_t *dict_by_protocol_num(unsigned int num)
{
        if (!dict_gctx) return NULL;
 
        return fr_hash_table_find(dict_gctx->protocol_by_num,
                                  &(fr_dict_t) { .root = &(fr_dict_attr_t){ .attr = num } });
}
 
/** Internal version of #fr_dict_by_da
 *
 * @note For internal use by the dictionary API only.
 *
 * @copybrief fr_dict_by_da
 */
fr_dict_t *dict_by_da(fr_dict_attr_t const *da)
{
#ifndef NDEBUG
        {
                fr_dict_attr_t const    *da_p = da;
                fr_dict_t const         *dict;
 
                dict = da->dict;
                while (da_p->parent) {
                        da_p = da_p->parent;
                        fr_cond_assert_msg(da_p->dict == dict, "Inconsistent dict membership.  "
                                           "Expected %s, got %s",
                                           !da_p->dict ? "(null)" : fr_dict_root(da_p->dict)->name,
                                           !dict ? "(null)" : fr_dict_root(dict)->name);
                        DA_VERIFY(da_p);
                }
 
                if (!da_p->flags.is_root) {
                        fr_strerror_printf("%s: Attribute %s has not been inserted into a dictionary",
                                           __FUNCTION__, da->name);
                        return NULL;
                }
        }
#endif
 
        /*
         *      Parent of the root attribute must
         *      be the dictionary.
         */
        return talloc_get_type_abort(da->dict, fr_dict_t);
}
 
/** Lookup a protocol by its name
 *
 * @note For internal use by the dictionary API only.
 *
 * @param[in] name of the protocol to locate.
 * @return
 *      - Attribute matching name.
 *      - NULL if no matching protocol could be found.
 */
fr_dict_t const *fr_dict_by_protocol_name(char const *name)
{
        return dict_by_protocol_name(name);
}
 
/** Lookup a protocol by its number
 *
 * Returns the #fr_dict_t belonging to the protocol with the specified number
 * if any have been registered.
 *
 * @param[in] num to search for.
 * @return dictionary representing the protocol (if it exists).
 */
fr_dict_t const *fr_dict_by_protocol_num(unsigned int num)
{
        return dict_by_protocol_num(num);
}
 
/** Attempt to locate the protocol dictionary containing an attribute
 *
 * @note Unlike fr_dict_by_attr_name, doesn't search through all the dictionaries,
 *      just uses the fr_dict_attr_t hierarchy and the talloc hierarchy to locate
 *      the dictionary (much much faster and more scalable).
 *
 * @param[in] da                To get the containing dictionary for.
 * @return
 *      - The dictionary containing da.
 *      - NULL.
 */
fr_dict_t const *fr_dict_by_da(fr_dict_attr_t const *da)
{
        return dict_by_da(da);
}
 
/** See if two dictionaries have the same end parent
 *
 * @param[in] dict1 one dictionary
 * @param[in] dict2 two dictionary
 * @return
 *      - true the dictionaries have the same end parent
 *      - false the dictionaries do not have the same end parent.
 */
bool fr_dict_compatible(fr_dict_t const *dict1, fr_dict_t const *dict2)
{
        while (dict1->next) dict1 = dict1->next;
 
        while (dict2->next) dict2 = dict2->next;
 
        return (dict1 == dict2);
}
 
/** Look up a vendor by one of its child attributes
 *
 * @param[in] da        The vendor attribute.
 * @return
 *      - The vendor.
 *      - NULL if no vendor with that number was registered for this protocol.
 */
fr_dict_vendor_t const *fr_dict_vendor_by_da(fr_dict_attr_t const *da)
{
        fr_dict_t               *dict;
        fr_dict_vendor_t        dv;
 
        dv.pen = fr_dict_vendor_num_by_da(da);
        if (!dv.pen) return NULL;
 
        dict = dict_by_da(da);
 
        return fr_hash_table_find(dict->vendors_by_num, &dv);
}
 
/** Look up a vendor by its name
 *
 * @param[in] dict              of protocol context we're operating in.
 *                              If NULL the internal dictionary will be used.
 * @param[in] name              to search for.
 * @return
 *      - The vendor.
 *      - NULL if no vendor with that name was registered for this protocol.
 */
fr_dict_vendor_t const *fr_dict_vendor_by_name(fr_dict_t const *dict, char const *name)
{
        fr_dict_vendor_t        *found;
 
        INTERNAL_IF_NULL(dict, NULL);
 
        if (!name) return NULL;
 
        found = fr_hash_table_find(dict->vendors_by_name, &(fr_dict_vendor_t) { .name = name });
        if (!found) return NULL;
 
        return found;
}
 
/** Look up a vendor by its PEN
 *
 * @param[in] dict              of protocol context we're operating in.
 *                              If NULL the internal dictionary will be used.
 * @param[in] vendor_pen        to search for.
 * @return
 *      - The vendor.
 *      - NULL if no vendor with that number was registered for this protocol.
 */
fr_dict_vendor_t const *fr_dict_vendor_by_num(fr_dict_t const *dict, uint32_t vendor_pen)
{
        INTERNAL_IF_NULL(dict, NULL);
 
        return fr_hash_table_find(dict->vendors_by_num, &(fr_dict_vendor_t) { .pen = vendor_pen });
}
 
/** Return vendor attribute for the specified dictionary and pen
 *
 * @param[in] vendor_root       of the vendor root attribute.  Could be 26 (for example) in RADIUS.
 * @param[in] vendor_pen        to find.
 * @return
 *      - NULL if vendor does not exist.
 *      - A fr_dict_attr_t representing the vendor in the dictionary hierarchy.
 */
fr_dict_attr_t const *fr_dict_vendor_da_by_num(fr_dict_attr_t const *vendor_root, uint32_t vendor_pen)
{
        fr_dict_attr_t const *vendor;
 
        switch (vendor_root->type) {
        case FR_TYPE_VSA:       /* Vendor specific attribute */
                break;
 
        default:
                fr_strerror_printf("Wrong type for vendor root, expected '%s', got '%s'",
                                   fr_type_to_str(FR_TYPE_VSA),
                                   fr_type_to_str(vendor_root->type));
                return NULL;
        }
 
        vendor = dict_attr_child_by_num(vendor_root, vendor_pen);
        if (!vendor) {
                fr_strerror_printf("Vendor %u not defined", vendor_pen);
                return NULL;
        }
 
        if (vendor->type != FR_TYPE_VENDOR) {
                fr_strerror_printf("Wrong type for vendor, expected '%s' got '%s'",
                                   fr_type_to_str(vendor->type),
                                   fr_type_to_str(FR_TYPE_VENDOR));
                return NULL;
        }
 
        return vendor;
}
 
/** Callback function for resolving dictionary attributes
 *
 * @param[out] err      Where to write error codes.  Any error
 *                      other than FR_DICT_ATTR_NOTFOUND will
 *                      prevent resolution from continuing.
 * @param[out] out      Where to write resolved DA.
 * @param[in] parent    The dictionary root or other attribute to search from.
 * @param[in] in        Contains the string to resolve.
 * @param[in] tt        Terminal sequences to use to determine the portion
 *                      of in to search.
 * @return
 *      - < 0 on failure.
 *      - The number of bytes of name consumed on success.
 */
typedef fr_slen_t (*dict_attr_resolve_func_t)(fr_dict_attr_err_t *err,
                                              fr_dict_attr_t const **out, fr_dict_attr_t const *parent,
                                              fr_sbuff_t *in, fr_sbuff_term_t const *tt);
 
/** Internal function for searching for attributes in multiple dictionaries
 *
 * @param[out] err              Any errors that occurred searching.
 * @param[out] out              The attribute we found.
 * @param[in] dict_def          The default dictionary to search in.
 * @param[in] in                string to resolve to an attribute.
 * @param[in] tt                terminals that indicate the end of the string.
 * @param[in] internal          Resolve the attribute in the internal dictionary.
 * @param[in] foreign           Resolve attribute in a foreign dictionary,
 *                              i.e. one other than dict_def.
 * @param[in] func              to use for resolution.
 * @return
 *      - <=0 on error (the offset of the error).
 *      - >0 on success.
 */
static inline CC_HINT(always_inline)
fr_slen_t dict_attr_search(fr_dict_attr_err_t *err, fr_dict_attr_t const **out,
                           fr_dict_t const *dict_def,
                           fr_sbuff_t *in, fr_sbuff_term_t const *tt,
                           bool internal, bool foreign,
                           dict_attr_resolve_func_t func)
{
        fr_dict_attr_err_t      our_err = FR_DICT_ATTR_OK;
        fr_hash_iter_t          iter;
        fr_dict_t               *dict = NULL;
        fr_sbuff_t              our_in = FR_SBUFF(in);
 
        if (internal && !dict_gctx->internal) internal = false;
 
        /*
         *      Always going to fail...
         */
        if (unlikely(!internal && !foreign && !dict_def)) {
                if (err) *err = FR_DICT_ATTR_EINVAL;
                *out = NULL;
                return 0;
        }
 
        /*
         *      dict_def search in the specified dictionary
         */
        if (dict_def) {
                (void)func(&our_err, out, fr_dict_root(dict_def), &our_in, tt);
                switch (our_err) {
                case FR_DICT_ATTR_OK:
                        FR_SBUFF_SET_RETURN(in, &our_in);
 
                case FR_DICT_ATTR_NOTFOUND:
                        if (!internal && !foreign) goto error;
                        break;
 
                default:
                        goto error;
                }
        }
 
        /*
         *      Next in the internal dictionary
         */
        if (internal) {
                (void)func(&our_err, out, fr_dict_root(dict_gctx->internal), &our_in, tt);
                switch (our_err) {
                case FR_DICT_ATTR_OK:
                        FR_SBUFF_SET_RETURN(in, &our_in);
 
                case FR_DICT_ATTR_NOTFOUND:
                        if (!foreign) goto error;
                        break;
 
                default:
                        goto error;
                }
        }
 
        /*
         *      Now loop over the protocol dictionaries
         */
        for (dict = fr_hash_table_iter_init(dict_gctx->protocol_by_num, &iter);
             dict;
             dict = fr_hash_table_iter_next(dict_gctx->protocol_by_num, &iter)) {
                if (dict == dict_def) continue;
                if (dict == dict_gctx->internal) continue;
 
                (void)func(&our_err, out, fr_dict_root(dict), &our_in, tt);
                switch (our_err) {
                case FR_DICT_ATTR_OK:
                        FR_SBUFF_SET_RETURN(in, &our_in);
 
                case FR_DICT_ATTR_NOTFOUND:
                        continue;
 
                default:
                        break;
                }
        }
 
error:
        /*
         *      Add a more helpful error message about
         *      which dictionaries we tried to locate
         *      the attribute in.
         */
        if (our_err == FR_DICT_ATTR_NOTFOUND) {
                fr_sbuff_marker_t       start;
                char                    *list = NULL;
 
#define DICT_NAME_APPEND(_in, _dict) \
do { \
        char *_n; \
        _n = talloc_strdup_append_buffer(_in, fr_dict_root(_dict)->name); \
        if (unlikely(!_n)) { \
                talloc_free(_in); \
                goto done; \
        } \
        _in = _n; \
        _n = talloc_strdup_append_buffer(_in, ", "); \
        if (unlikely(!_n)) { \
                talloc_free(_in); \
                goto done; \
        } \
        _in = _n; \
} while (0)
 
                our_in = FR_SBUFF(in);
                fr_sbuff_marker(&start, &our_in);
 
                list = talloc_strdup(NULL, "");
                if (unlikely(!list)) goto done;
 
                if (dict_def) DICT_NAME_APPEND(list, dict_def);
                if (internal) DICT_NAME_APPEND(list, dict_gctx->internal);
 
                if (foreign) {
                        for (dict = fr_hash_table_iter_init(dict_gctx->protocol_by_num, &iter);
                             dict;
                             dict = fr_hash_table_iter_next(dict_gctx->protocol_by_num, &iter)) {
                                if (dict == dict_def) continue;
                                if (dict == dict_gctx->internal) continue;
 
                                if (internal) DICT_NAME_APPEND(list, dict);
                        }
                }
 
                fr_strerror_printf("Attribute '%pV' not found.  Searched in: %pV",
                                   fr_box_strvalue_len(fr_sbuff_current(&start),
                                                       fr_sbuff_adv_until(&our_in, SIZE_MAX, tt, '\0')),
                                   fr_box_strvalue_len(list, talloc_array_length(list) - 3));
 
                talloc_free(list);
        }
 
done:
        if (err) *err = our_err;
        *out = NULL;
 
        FR_SBUFF_ERROR_RETURN(&our_in);
}
 
/** Internal function for searching for attributes in multiple dictionaries
 *
 * Unlike #dict_attr_search this function searches for a protocol name preceding
 * the attribute identifier.
 */
static inline CC_HINT(always_inline)
fr_slen_t dict_attr_search_qualified(fr_dict_attr_err_t *err, fr_dict_attr_t const **out,
                                     fr_dict_t const *dict_def,
                                     fr_sbuff_t *in, fr_sbuff_term_t const *tt,
                                     bool internal, bool foreign,
                                     dict_attr_resolve_func_t func)
{
        fr_sbuff_t              our_in = FR_SBUFF(in);
        fr_dict_attr_err_t      our_err;
        fr_dict_t               *initial;
        fr_slen_t               slen;
 
        /*
         *      Check for dictionary prefix
         */
        slen = dict_by_protocol_substr(&our_err, &initial, &our_in, dict_def);
        if (our_err != FR_DICT_ATTR_OK) {
        error:
                if (err) *err = our_err;
                *out = NULL;
                FR_SBUFF_ERROR_RETURN(&our_in);
        }
 
        /*
         *      Has dictionary qualifier, can't fallback
         */
        if (slen > 0) {
                /*
                 *      Next thing SHOULD be a '.'
                 */
                if (!fr_sbuff_next_if_char(&our_in, '.')) {
                        if (err) *err = FR_DICT_ATTR_PARSE_ERROR;
                        *out = NULL;
                        FR_SBUFF_ERROR_RETURN(&our_in);
                }
 
                internal = foreign = false;
        }
 
        if (dict_attr_search(&our_err, out, initial, &our_in, tt, internal, foreign, func) < 0) goto error;
        if (err) *err = FR_DICT_ATTR_OK;
 
        FR_SBUFF_SET_RETURN(in, &our_in);
}
 
/** Locate a qualified #fr_dict_attr_t by its name and a dictionary qualifier
 *
 * This function will search through all loaded dictionaries, or a subset of
 * loaded dictionaries, for a matching attribute in the top level namespace.
 *
 * This attribute may be qualified with `<protocol>.` to selection an attribute
 * in a specific case.
 *
 * @note If calling this function from the server any list or request qualifiers
 *  should be stripped first.
 *
 * @param[out] err              Why parsing failed. May be NULL.
 *                              @see fr_dict_attr_err_t
 * @param[out] out              Dictionary found attribute.
 * @param[in] dict_def          Default dictionary for non-qualified dictionaries.
 * @param[in] name              Dictionary/Attribute name.
 * @param[in] tt                Terminal strings.
 * @param[in] internal          If true, fallback to the internal dictionary.
 * @param[in] foreign           If true, fallback to foreign dictionaries.
 * @return
 *      - < 0 on failure.
 *      - The number of bytes of name consumed on success.
 */
fr_slen_t fr_dict_attr_search_by_qualified_name_substr(fr_dict_attr_err_t *err, fr_dict_attr_t const **out,
                                                       fr_dict_t const *dict_def,
                                                       fr_sbuff_t *name, fr_sbuff_term_t const *tt,
                                                       bool internal, bool foreign)
{
        return dict_attr_search_qualified(err, out, dict_def, name, tt,
                                          internal, foreign, fr_dict_attr_by_name_substr);
}
 
/** Locate a #fr_dict_attr_t by its name in the top level namespace of a dictionary
 *
 * This function will search through all loaded dictionaries, or a subset of
 * loaded dictionaries, for a matching attribute in the top level namespace.
 *
 * @note If calling this function from the server any list or request qualifiers
 *  should be stripped first.
 *
 * @param[out] err              Why parsing failed. May be NULL.
 *                              @see fr_dict_attr_err_t
 * @param[out] out              Dictionary found attribute.
 * @param[in] dict_def          Default dictionary for non-qualified dictionaries.
 * @param[in] name              Dictionary/Attribute name.
 * @param[in] tt                Terminal strings.
 * @param[in] internal          If true, fallback to the internal dictionary.
 * @param[in] foreign           If true, fallback to foreign dictionaries.
 * @return
 *      - < 0 on failure.
 *      - The number of bytes of name consumed on success.
 */
fr_slen_t fr_dict_attr_search_by_name_substr(fr_dict_attr_err_t *err, fr_dict_attr_t const **out,
                                             fr_dict_t const *dict_def,
                                             fr_sbuff_t *name, fr_sbuff_term_t const *tt,
                                             bool internal, bool foreign)
{
        return dict_attr_search_qualified(err, out, dict_def, name, tt,
                                          internal, foreign, fr_dict_attr_by_name_substr);
}
 
/** Locate a qualified #fr_dict_attr_t by a dictionary qualified OID string
 *
 * This function will search through all loaded dictionaries, or a subset of
 * loaded dictionaries, for a matching attribute.
 *
 * @note If calling this function from the server any list or request qualifiers
 *  should be stripped first.
 *
 * @note err should be checked to determine if a parse error occurred.
 *
 * @param[out] err              Why parsing failed. May be NULL.
 *                              @see fr_dict_attr_err_t
 * @param[out] out              Dictionary found attribute.
 * @param[in] dict_def          Default dictionary for non-qualified dictionaries.
 * @param[in] in                Dictionary/Attribute name.
 * @param[in] tt                Terminal strings.
 * @param[in] internal          If true, fallback to the internal dictionary.
 * @param[in] foreign           If true, fallback to foreign dictionaries.
 * @return The number of bytes of name consumed.
 */
fr_slen_t fr_dict_attr_search_by_qualified_oid_substr(fr_dict_attr_err_t *err, fr_dict_attr_t const **out,
                                                      fr_dict_t const *dict_def,
                                                      fr_sbuff_t *in, fr_sbuff_term_t const *tt,
                                                      bool internal, bool foreign)
{
        return dict_attr_search_qualified(err, out, dict_def, in, tt,
                                          internal, foreign, fr_dict_attr_by_oid_substr);
}
 
/** Locate a qualified #fr_dict_attr_t by a dictionary using a non-qualified OID string
 *
 * This function will search through all loaded dictionaries, or a subset of
 * loaded dictionaries, for a matching attribute.
 *
 * @note If calling this function from the server any list or request qualifiers
 *  should be stripped first.
 *
 * @note err should be checked to determine if a parse error occurred.
 *
 * @param[out] err              Why parsing failed. May be NULL.
 *                              @see fr_dict_attr_err_t
 * @param[out] out              Dictionary found attribute.
 * @param[in] dict_def          Default dictionary for non-qualified dictionaries.
 * @param[in] in                Dictionary/Attribute name.
 * @param[in] tt                Terminal strings.
 * @param[in] internal          If true, fallback to the internal dictionary.
 * @param[in] foreign           If true, fallback to foreign dictionaries.
 * @return The number of bytes of name consumed.
 */
fr_slen_t fr_dict_attr_search_by_oid_substr(fr_dict_attr_err_t *err, fr_dict_attr_t const **out,
                                            fr_dict_t const *dict_def,
                                            fr_sbuff_t *in, fr_sbuff_term_t const *tt,
                                            bool internal, bool foreign)
{
        return dict_attr_search_qualified(err, out, dict_def, in, tt,
                                          internal, foreign, fr_dict_attr_by_oid_substr);
}
 
/** Locate a qualified #fr_dict_attr_t by its name and a dictionary qualifier
 *
 * @param[out] err              Why parsing failed. May be NULL.
 *                              @see fr_dict_attr_err_t.
 * @param[in] dict_def          Default dictionary for non-qualified dictionaries.
 * @param[in] name              Dictionary/Attribute name.
 * @param[in] internal          If true, fallback to the internal dictionary.
 * @param[in] foreign           If true, fallback to foreign dictionaries.
 * @return an #fr_dict_attr_err_t value.
 */
fr_dict_attr_t const *fr_dict_attr_search_by_qualified_oid(fr_dict_attr_err_t *err, fr_dict_t const *dict_def,
                                                           char const *name,
                                                           bool internal, bool foreign)
{
        ssize_t                 slen;
        fr_sbuff_t              our_name;
        fr_dict_attr_t const    *da;
        fr_dict_attr_err_t      our_err;
 
        fr_sbuff_init_in(&our_name, name, strlen(name));
 
        slen = fr_dict_attr_search_by_qualified_oid_substr(&our_err, &da, dict_def, &our_name, NULL, internal, foreign);
        if (our_err != FR_DICT_ATTR_OK) {
                if (err) *err = our_err;
                return NULL;
        }
        if ((size_t)slen != fr_sbuff_len(&our_name)) {
                fr_strerror_printf("Trailing garbage after attr string \"%s\"", name);
                if (err) *err = FR_DICT_ATTR_PARSE_ERROR;
                return NULL;
        }
 
        return da;
}
 
/** Look up a dictionary attribute by a name embedded in another string
 *
 * Find the first invalid attribute name char in the string pointed
 * to by name.
 *
 * Copy the characters between the start of the name string and the first
 * none #fr_dict_attr_allowed_chars char to a buffer and perform a dictionary lookup
 * using that value.
 *
 * If the attribute exists, advance the pointer pointed to by name
 * to the first none #fr_dict_attr_allowed_chars char, and return the DA.
 *
 * If the attribute does not exist, don't advance the pointer and return
 * NULL.
 *
 * @param[out] err              Why parsing failed. May be NULL.
 *                              @see fr_dict_attr_err_t
 * @param[out] out              Where to store the resolve attribute.
 * @param[in] parent            containing the namespace to search in.
 * @param[in] name              string start.
 * @param[in] tt                Terminal sequences to use to determine the portion
 *                              of in to search.
 * @return
 *      - <= 0 on failure.
 *      - The number of bytes of name consumed on success.
 */
fr_slen_t fr_dict_attr_by_name_substr(fr_dict_attr_err_t *err, fr_dict_attr_t const **out,
                                      fr_dict_attr_t const *parent, fr_sbuff_t *name, UNUSED fr_sbuff_term_t const *tt)
{
        fr_dict_attr_t const    *da;
        size_t                  len;
        fr_dict_attr_t const    *ref;
        char const              *p;
        char                    buffer[FR_DICT_ATTR_MAX_NAME_LEN + 1 + 1];      /* +1 \0 +1 for "too long" */
        fr_sbuff_t              our_name = FR_SBUFF(name);
        fr_hash_table_t         *namespace;
 
        *out = NULL;
 
#ifdef STATIC_ANALYZER
        memset(buffer, 0, sizeof(buffer));
#endif
 
        len = fr_sbuff_out_bstrncpy_allowed(&FR_SBUFF_OUT(buffer, sizeof(buffer)),
                                            &our_name, SIZE_MAX,
                                            fr_dict_attr_allowed_chars);
        if (len == 0) {
                fr_strerror_const("Zero length attribute name");
                if (err) *err = FR_DICT_ATTR_PARSE_ERROR;
                FR_SBUFF_ERROR_RETURN(&our_name);
        }
        if (len > FR_DICT_ATTR_MAX_NAME_LEN) {
                fr_strerror_const("Attribute name too long");
                if (err) *err = FR_DICT_ATTR_PARSE_ERROR;
                FR_SBUFF_ERROR_RETURN(&our_name);
        }
 
        /*
         *      Do a second pass, ensuring that the name has at least one alphanumeric character.
         */
        for (p = buffer; p < (buffer + len); p++) {
                if (sbuff_char_alpha_num[(uint8_t) *p]) break;
        }
 
        if ((size_t) (p - buffer) == len) {
                fr_strerror_const("Invalid attribute name");
                if (err) *err = FR_DICT_ATTR_PARSE_ERROR;
                FR_SBUFF_ERROR_RETURN(&our_name);
        }
 
        ref = fr_dict_attr_ref(parent);
        if (ref) parent = ref;
 
redo:
        namespace = dict_attr_namespace(parent);
        if (!namespace) {
                fr_strerror_printf("Attribute '%s' does not contain a namespace", parent->name);
                if (err) *err = FR_DICT_ATTR_NO_CHILDREN;
                fr_sbuff_set_to_start(&our_name);
                FR_SBUFF_ERROR_RETURN(&our_name);
        }
 
        da = fr_hash_table_find(namespace, &(fr_dict_attr_t){ .name = buffer });
        if (!da) {
                if (parent->flags.is_root) {
                        fr_dict_t const *dict = fr_dict_by_da(parent);
 
                        if (dict->next) {
                                parent = dict->next->root;
                                goto redo;
                        }
                }
 
                if (err) *err = FR_DICT_ATTR_NOTFOUND;
                fr_strerror_printf("Attribute '%s' not found in namespace '%s'", buffer, parent->name);
                fr_sbuff_set_to_start(&our_name);
                FR_SBUFF_ERROR_RETURN(&our_name);
        }
 
        da = dict_attr_alias(err, da);
        if (unlikely(!da)) FR_SBUFF_ERROR_RETURN(&our_name);
 
        *out = da;
        if (err) *err = FR_DICT_ATTR_OK;
 
        FR_SBUFF_SET_RETURN(name, &our_name);
}
 
/* Internal version of fr_dict_attr_by_name
 *
 */
fr_dict_attr_t *dict_attr_by_name(fr_dict_attr_err_t *err, fr_dict_attr_t const *parent, char const *name)
{
        fr_hash_table_t         *namespace;
        fr_dict_attr_t          *da;
 
        DA_VERIFY(parent);
 
redo:
        namespace = dict_attr_namespace(parent);
        if (!namespace) {
                fr_strerror_printf("Attribute '%s' does not contain a namespace", parent->name);
                if (err) *err = FR_DICT_ATTR_NO_CHILDREN;
                return NULL;
        }
 
        da = fr_hash_table_find(namespace, &(fr_dict_attr_t) { .name = name });
        if (!da) {
                if (parent->flags.is_root) {
                        fr_dict_t const *dict = fr_dict_by_da(parent);
 
                        if (dict->next) {
                                parent = dict->next->root;
                                goto redo;
                        }
                }
 
                if (err) *err = FR_DICT_ATTR_NOTFOUND;
                fr_strerror_printf("Attribute '%s' not found in namespace '%s'", name, parent->name);
                return NULL;
        }
 
        if (err) *err = FR_DICT_ATTR_OK;
 
        return da;
}
 
/** Locate a #fr_dict_attr_t by its name
 *
 * @param[out] err              Why the lookup failed. May be NULL.
 *                              @see fr_dict_attr_err_t.
 * @param[in] parent            containing the namespace we're searching in.
 * @param[in] name              of the attribute to locate.
 * @return
 *      - Attribute matching name.
 *      - NULL if no matching attribute could be found.
 */
fr_dict_attr_t const *fr_dict_attr_by_name(fr_dict_attr_err_t *err, fr_dict_attr_t const *parent, char const *name)
{
        fr_dict_attr_t const *da;
 
        DA_VERIFY(parent);
 
        da = dict_attr_by_name(err, parent, name);
        if (!da) return NULL;
 
        da = dict_attr_alias(err, da);
        if (unlikely(!da)) return NULL;
 
        return da;
}
 
/** Internal version of fr_dict_attr_child_by_num
 *
 */
fr_dict_attr_t *dict_attr_child_by_num(fr_dict_attr_t const *parent, unsigned int attr)
{
        fr_dict_attr_t const *bin;
        fr_dict_attr_t const **children;
        fr_dict_attr_t const *ref;
 
        DA_VERIFY(parent);
 
        /*
         *      Do any necessary dereferencing
         */
        ref = fr_dict_attr_ref(parent);
        if (ref) parent = ref;
 
        children = dict_attr_children(parent);
        if (!children) return NULL;
 
        /*
         *      Child arrays may be trimmed back to save memory.
         *      Check that so we don't SEGV.
         */
        if ((attr & 0xff) >= talloc_array_length(children)) return NULL;
 
        bin = children[attr & 0xff];
        for (;;) {
                if (!bin) return NULL;
                if (bin->attr == attr) {
                        fr_dict_attr_t *out;
 
                        memcpy(&out, &bin, sizeof(bin));
 
                        return out;
                }
                bin = bin->next;
        }
 
        return NULL;
}
 
/** Check if a child attribute exists in a parent using an attribute number
 *
 * @param[in] parent            to check for child in.
 * @param[in] attr              number to look for.
 * @return
 *      - The child attribute on success.
 *      - NULL if the child attribute does not exist.
 */
fr_dict_attr_t const *fr_dict_attr_child_by_num(fr_dict_attr_t const *parent, unsigned int attr)
{
        fr_dict_attr_t const *da;
 
        da = dict_attr_child_by_num(parent, attr);
        if (!da) return NULL;
 
        da = dict_attr_alias(NULL, da);
        if (unlikely(!da)) return NULL;
 
        return da;
}
 
/** Iterate over all enumeration values for an attribute
 *
 * @param[in] da                to iterate over.
 * @param[in] iter              to use for iteration.
 * @return
 *      - First #fr_dict_enum_value_t in the attribute.
 *      - NULL if no enumeration values exist.
 */
fr_dict_enum_value_t const *fr_dict_enum_iter_init(fr_dict_attr_t const *da, fr_dict_enum_iter_t *iter)
{
        fr_dict_attr_ext_enumv_t        *ext;
 
        ext = fr_dict_attr_ext(da, FR_DICT_ATTR_EXT_ENUMV);
        if (!ext) {
                fr_strerror_printf("%s has no enumeration values to iterate over", da->name);
                return NULL;
        }
 
        return fr_hash_table_iter_init(ext->value_by_name, iter);
}
 
/* Iterate over next enumeration value for an attribute
 *
 * @param[in] da                to iterate over.
 * @param[in] iter              to use for iteration.
 * @return
 *      - Next #fr_dict_enum_value_t in the attribute.
 *      - NULL if no more enumeration values exist.
 */
fr_dict_enum_value_t const *fr_dict_enum_iter_next(fr_dict_attr_t const *da, fr_dict_enum_iter_t *iter)
{
        fr_dict_attr_ext_enumv_t        *ext;
        ext = fr_dict_attr_ext(da, FR_DICT_ATTR_EXT_ENUMV);
        if (!ext) {
                fr_strerror_printf("%s has no enumeration values to iterate over", da->name);
                return NULL;
        }
 
        return fr_hash_table_iter_next(ext->value_by_name, iter);;
}
 
/** Lookup the structure representing an enum value in a #fr_dict_attr_t
 *
 * @param[in] da                to search in.
 * @param[in] value             to search for.
 * @return
 *      - Matching #fr_dict_enum_value_t.
 *      - NULL if no matching #fr_dict_enum_value_t could be found.
 */
fr_dict_enum_value_t const *fr_dict_enum_by_value(fr_dict_attr_t const *da, fr_value_box_t const *value)
{
        fr_dict_attr_ext_enumv_t        *ext;
 
        ext = fr_dict_attr_ext(da, FR_DICT_ATTR_EXT_ENUMV);
        if (!ext) {
                fr_strerror_printf("VALUE cannot be defined for %s attributes",
                                   fr_type_to_str(da->type));
                return NULL;
        }
 
        /*
         *      No values associated with this attribute
         */
        if (!ext->name_by_value) return NULL;
 
        /*
         *      Could be NULL or an unknown attribute, in which case
         *      we want to avoid the lookup gracefully...
         */
        if (value->type != da->type) return NULL;
 
        return fr_hash_table_find(ext->name_by_value, &(fr_dict_enum_value_t){ .value = value });
}
 
/** Lookup the name of an enum value in a #fr_dict_attr_t
 *
 * @param[in] da                to search in.
 * @param[in] value             number to search for.
 * @return
 *      - Name of value.
 *      - NULL if no matching value could be found.
 */
char const *fr_dict_enum_name_by_value(fr_dict_attr_t const *da, fr_value_box_t const *value)
{
        fr_dict_enum_value_t const *dv;
 
        dv = fr_dict_enum_by_value(da, value);
        if (!dv) return NULL;
 
        return dv->name;
}
 
/*
 *      Get a value by its name, keyed off of an attribute.
 */
fr_dict_enum_value_t const *fr_dict_enum_by_name(fr_dict_attr_t const *da, char const *name, ssize_t len)
{
        fr_dict_attr_ext_enumv_t        *ext;
 
        if (!name) return NULL;
 
        ext = fr_dict_attr_ext(da, FR_DICT_ATTR_EXT_ENUMV);
        if (!ext) {
                fr_strerror_printf("VALUE cannot be defined for %s attributes",
                                   fr_type_to_str(da->type));
                return NULL;
        }
 
        /*
         *      No values associated with this attribute
         */
        if (!ext->value_by_name) return NULL;
 
        if (len < 0) len = strlen(name);
 
        return fr_hash_table_find(ext->value_by_name, &(fr_dict_enum_value_t){ .name = name, .name_len = len});
}
 
/*
 *      Get a value by its name, keyed off of an attribute, from an sbuff
 */
fr_slen_t fr_dict_enum_by_name_substr(fr_dict_enum_value_t **out, fr_dict_attr_t const *da, fr_sbuff_t *in)
{
        fr_dict_attr_ext_enumv_t        *ext;
        fr_sbuff_t      our_in = FR_SBUFF(in);
        fr_dict_enum_value_t *found = NULL;
        size_t          found_len = 0;
        uint8_t         *p;
        uint8_t         name[FR_DICT_ENUM_MAX_NAME_LEN + 1];
 
        /*
         *      No values associated with this attribute, do nothing.
         */
        ext = fr_dict_attr_ext(da, FR_DICT_ATTR_EXT_ENUMV);
        if (!ext || !ext->value_by_name) return 0;
 
        /*
         *      Loop until we exhaust all of the possibilities.
         */
        for (p = name; (size_t) (p - name) < ext->max_name_len; p++) {
                int len = (p - name) + 1;
                fr_dict_enum_value_t *enumv;
 
                *p = fr_sbuff_char(&our_in, '\0');
                if (!fr_dict_enum_allowed_chars[*p]) {
                        break;
                }
                fr_sbuff_next(&our_in);
 
                enumv = fr_hash_table_find(ext->value_by_name, &(fr_dict_enum_value_t){ .name = (char const *) name,
                                                                                        .name_len = len});
 
                /*
                 *      Return the LONGEST match, as there may be
                 *      overlaps.  e.g. "Framed", and "Framed-User".
                 */
                if (enumv) {
                        found = enumv;
                        found_len = len;
                }
        }
 
        if (found) {
                *out = found;
                FR_SBUFF_SET_RETURN(in, found_len);
        }
 
        return 0;
}
 
/** Extract an enumeration name from a string
 *
 * This function defines the canonical format for an enumeration name.
 *
 * An enumeration name is made up of one or more fr_dict_attr_allowed_chars
 * with at least one character in the sequence not being a special character
 * i.e. [-+/_] or a number.
 *
 * This disambiguates enumeration identifiers from mathematical expressions.
 *
 * If we allowed enumeration names consisting of sequences of numbers separated
 * by special characters it would not be possible to determine if the special
 * character were an operator in a subexpression.
 *
 * For example take:
 *
 *    &My-Enum-Attr == 01234-5678
 *
 * Without having access to the enumeration values of My-Enum-Attr (which we
 * might not have during tokenisation), we cannot tell if this is:
 *
 * (&My-Enum-Attr == 01234-5678)
 *
 * OR
 *
 * ((&My-Enum-Attr == 01234) - 5678)
 *
 * If an alpha character occurs anywhere in the string i.e:
 *
 *    (&My-Enum-Attr == 01234-A5678)
 *
 * we know 01234-A5678 can't be a mathematical sub-expression because the
 * second potential operand can no longer be parsed as an integer constant.
 *
 * @param[out] out      The name string we managed to extract.
 *                      May be NULL in which case only the length of the name
 *                      will be returned.
 * @param[out] err      Type of parsing error which occurred.  May be NULL.
 * @param[in] in        The string containing the enum identifier.
 * @param[in] tt        If non-null verify that a terminal sequence occurs
 *                      after the enumeration name.
 * @return
 *      - <0 the offset at which the parse error occurred.
 *      - >1 the number of bytes parsed.
 */
fr_slen_t fr_dict_enum_name_from_substr(fr_sbuff_t *out, fr_sbuff_parse_error_t *err,
                                        fr_sbuff_t *in, fr_sbuff_term_t const *tt)
{
        fr_sbuff_t our_in = FR_SBUFF(in);
        bool seen_alpha = false;
 
        while (fr_sbuff_is_in_charset(&our_in, fr_dict_enum_allowed_chars)) {
                if (fr_sbuff_is_alpha(&our_in)) seen_alpha = true;
                fr_sbuff_next(&our_in);
        }
 
        if (!seen_alpha) {
                if (fr_sbuff_used(&our_in) == 0) {
                        fr_strerror_const("VALUE name is empty");
                        if (err) *err = FR_SBUFF_PARSE_ERROR_NOT_FOUND;
                        FR_SBUFF_ERROR_RETURN(&our_in);
                }
 
                fr_strerror_const("VALUE name must contain at least one alpha character");
                if (err) *err = FR_SBUFF_PARSE_ERROR_FORMAT;
                fr_sbuff_set_to_start(&our_in); /* Marker should be at the start of the enum */
                FR_SBUFF_ERROR_RETURN(&our_in);
        }
 
        /*
         *      Check that the sequence is correctly terminated
         */
        if (tt && !fr_sbuff_is_terminal(&our_in, tt)) {
                fr_strerror_const("VALUE name has trailing text");
                if (err) *err = FR_SBUFF_PARSE_ERROR_TRAILING;
                FR_SBUFF_ERROR_RETURN(&our_in);
        }
 
        if (out) return fr_sbuff_out_bstrncpy_exact(out, in, fr_sbuff_used(&our_in));
 
        if (err) *err = FR_SBUFF_PARSE_OK;
 
        FR_SBUFF_SET_RETURN(in, &our_in);
}
 
int dict_dlopen(fr_dict_t *dict, char const *name)
{
        char                    *lib_name;
        char                    *sym_name;
        fr_dict_protocol_t      *proto;
 
        if (!name) return 0;
 
        lib_name = talloc_typed_asprintf(NULL, "libfreeradius-%s", name);
        if (unlikely(lib_name == NULL)) {
        oom:
                fr_strerror_const("Out of memory");
                return -1;
        }
        talloc_bstr_tolower(lib_name);
 
        dict->dl = dl_by_name(dict_gctx->dict_loader, lib_name, NULL, false);
        if (!dict->dl) {
                fr_strerror_printf_push("Failed loading dictionary validation library \"%s\"", lib_name);
                talloc_free(lib_name);
                return -1;
        }
        talloc_free(lib_name);
 
        /*
         *      The public symbol that contains per-protocol rules
         *      and extensions.
         *
         *      It ends up being easier to do this using dlsym to
         *      resolve the symbol and not use the autoloader
         *      callbacks as theoretically multiple dictionaries
         *      could use the same protocol library, and then the
         *      autoloader callback would only run for the first
         *      dictionary which loaded the protocol.
         */
        sym_name = talloc_typed_asprintf(NULL, "libfreeradius_%s_dict_protocol", name);
        if (unlikely(sym_name == NULL)) {
                goto oom;
        }
        talloc_bstr_tolower(sym_name);
 
        /*
         *      De-hyphenate the symbol name
         */
        {
                char *p, *q;
 
                for (p = sym_name, q = p + (talloc_strlen(sym_name)); p < q; p++) *p = *p == '-' ? '_' : *p;
        }
 
        proto = dlsym(dict->dl->handle, sym_name);
        talloc_free(sym_name);
 
        /*
         *      Soft failure, not all protocol libraires provide
         *      custom validation functions or flats.
         */
        if (!proto) return 0;
 
        /*
         *      Replace the default protocol with the custom one
         *      if we have it...
         */
        dict->proto = proto;
 
        return 0;
}
 
/** Find a dependent in the tree of dependents
 *
 */
static int8_t _dict_dependent_cmp(void const *a, void const *b)
{
        fr_dict_dependent_t const *dep_a = a;
        fr_dict_dependent_t const *dep_b = b;
        int ret;
 
        ret = strcmp(dep_a->dependent, dep_b->dependent);
        return CMP(ret, 0);
}
 
/** Record a new dependency on a dictionary
 *
 * These are used to determine what is currently depending on a dictionary.
 *
 * @param[in] dict      to record dependency on.
 * @param[in] dependent Either C src file, or another dictionary.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int dict_dependent_add(fr_dict_t *dict, char const *dependent)
{
        fr_dict_dependent_t *found;
 
        found = fr_rb_find(dict->dependents, &(fr_dict_dependent_t){ .dependent = dependent } );
        if (!found) {
                fr_dict_dependent_t *new;
 
                new = talloc_zero(dict->dependents, fr_dict_dependent_t);
                if (unlikely(!new)) return -1;
 
                /*
                 *      If the dependent is in a module that gets
                 *      unloaded, any strings in the text area also
                 *      get unloaded (including dependent locations).
                 *
                 *      Strdup the string here so we don't get
                 *      random segfaults if a module forgets to unload
                 *      a dictionary.
                 */
                new->dependent = talloc_strdup(new, dependent);
                fr_rb_insert(dict->dependents, new);
 
                new->count = 1;
 
                return 0;
        }
 
        found->count++; /* Increase ref count */
 
        return 0;
}
 
/** Manually increase the reference count for a dictionary
 *
 * This is useful if a previously loaded dictionary needs to
 * be bound to the lifetime of an additional object.
 *
 * @param[in] dict      to increase the reference count for.
 * @param[in] dependent requesting the loading of the dictionary.
 * @return
 *      - 0 on success.
 *      - -1 on error.
 */
int fr_dict_dependent_add(fr_dict_t const *dict, char const *dependent)
{
        fr_dict_t *m_dict = fr_dict_unconst(dict);
 
        if (unlikely(!m_dict)) return -1;
 
        return dict_dependent_add(m_dict, dependent);
}
 
/** Decrement ref count for a dependent in a dictionary
 *
 * @param[in] dict      to remove dependency from.
 * @param[in] dependent Either C src, or another dictionary dependent.
 *                      What depends on this dictionary.
 */
int dict_dependent_remove(fr_dict_t *dict, char const *dependent)
{
        fr_dict_dependent_t *found;
 
        found = fr_rb_find(dict->dependents, &(fr_dict_dependent_t){ .dependent = dependent } );
        if (!found) {
                fr_strerror_printf("Dependent \"%s\" not found in dictionary \"%s\"", dependent, dict->root->name);
                return -1;
        }
 
        if (found->count == 0) {
                fr_strerror_printf("Zero ref count invalid for dependent \"%s\", dictionary \"%s\"",
                                   dependent, dict->root->name);
                return -1;
        }
 
        if (--found->count == 0) {
                fr_rb_delete(dict->dependents, found);
                talloc_free(found);
                return 0;
        }
 
        return 1;
}
 
/** Check if a dictionary still has dependents
 *
 * @param[in] dict      to check
 * @return
 *      - true if there's still at least one dependent.
 *      - false if there are no dependents.
 */
bool dict_has_dependents(fr_dict_t *dict)
{
        return (fr_rb_num_elements(dict->dependents) > 0);
}
 
#ifndef NDEBUG
static void dependent_debug(fr_dict_t *dict)
{
        fr_rb_iter_inorder_t    iter;
        fr_dict_dependent_t     *dep;
 
        if (!dict_has_dependents(dict)) return;
 
        fprintf(stderr, "DEPENDENTS FOR %s\n", dict->root->name);
 
        for (dep = fr_rb_iter_init_inorder(dict->dependents, &iter);
             dep;
             dep = fr_rb_iter_next_inorder(dict->dependents, &iter)) {
                fprintf(stderr, "\t<- %s (%d)\n", dep->dependent, dep->count);
        }
}
#endif
 
 
static int dict_autoref_free(fr_dict_t *dict)
{
        fr_dict_t **refd_list;
        unsigned int i;
 
        if (!dict->autoref) return 0;
 
        if (fr_hash_table_flatten(dict->autoref, (void ***)&refd_list, dict->autoref) < 0) {
                fr_strerror_const("failed flattening autoref hash table");
                return -1;
        }
 
        /*
         *      Free the dictionary.  It will call proto->free() if there's nothing more to do.
         */
        for (i = 0; i < talloc_array_length(refd_list); i++) {
                if (fr_dict_free(&refd_list[i], dict->root->name) < 0) {
                        fr_strerror_printf("failed freeing autoloaded protocol %s", refd_list[i]->root->name);
                        return -1;
                }
        }
 
        TALLOC_FREE(dict->autoref);
 
        return 0;
}
 
static int _dict_free(fr_dict_t *dict)
{
        /*
         *      We don't necessarily control the order of freeing
         *      children.
         */
        if (dict != dict->gctx->internal) {
                fr_dict_attr_t const *da;
 
                if (dict->gctx->attr_protocol_encapsulation && dict->root) {
                        da = fr_dict_attr_child_by_num(dict->gctx->attr_protocol_encapsulation, dict->root->attr);
                        if (da && fr_dict_attr_ref(da)) dict_attr_ref_null(da);
                }
        }
 
#ifdef STATIC_ANALYZER
        if (!dict->root) {
                fr_strerror_const("dict root is missing");
                return -1;
        }
#endif
 
        /*
         *      If we called init(), then call free()
         */
        if (dict->proto && dict->proto->free) {
                dict->proto->free();
        }
 
        if (!fr_cond_assert(!dict->in_protocol_by_name || fr_hash_table_delete(dict->gctx->protocol_by_name, dict))) {
                fr_strerror_printf("Failed removing dictionary from protocol hash \"%s\"", dict->root->name);
                return -1;
        }
        dict->in_protocol_by_name = false;
 
        if (!fr_cond_assert(!dict->in_protocol_by_num || fr_hash_table_delete(dict->gctx->protocol_by_num, dict))) {
                fr_strerror_printf("Failed removing dictionary from protocol number_hash \"%s\"", dict->root->name);
                return -1;
        }
        dict->in_protocol_by_num = false;
 
        if (dict_has_dependents(dict)) {
                fr_rb_iter_inorder_t    iter;
                fr_dict_dependent_t     *dep;
 
                fr_strerror_printf("Refusing to free dictionary \"%s\", still has dependents", dict->root->name);
 
                for (dep = fr_rb_iter_init_inorder(dict->dependents, &iter);
                     dep;
                     dep = fr_rb_iter_next_inorder(dict->dependents, &iter)) {
                        fr_strerror_printf_push("%s (%d)", dep->dependent, dep->count);
                }
 
                return -1;
        }
 
        /*
         *      Free the hash tables with free functions first
         *      so that the things the hash tables reference
         *      are still there.
         */
        talloc_free(dict->vendors_by_name);
 
        /*
         *      Decrease the reference count on the validation
         *      library we loaded.
         */
        dl_free(dict->dl);
 
        if (dict == dict->gctx->internal) {
                dict->gctx->internal = NULL;
                dict->gctx->attr_protocol_encapsulation = NULL;
        }
 
        return 0;
}
 
/** Allocate a new dictionary
 *
 * @param[in] ctx to allocate dictionary in.
 * @return
 *      - NULL on memory allocation error.
 */
fr_dict_t *dict_alloc(TALLOC_CTX *ctx)
{
        fr_dict_t *dict;
 
        if (!dict_gctx) {
                fr_strerror_const("Initialise global dictionary ctx with fr_dict_global_ctx_init()");
                return NULL;
        }
 
        dict = talloc_zero(ctx, fr_dict_t);
        if (!dict) {
                fr_strerror_const("Failed allocating memory for dictionary");
        error:
                talloc_free(dict);
                return NULL;
        }
        dict->gctx = dict_gctx; /* Record which global context this was allocated in */
        talloc_set_destructor(dict, _dict_free);
 
        /*
         *      A list of all the files that constitute this dictionary
         */
        fr_dlist_talloc_init(&dict->filenames, fr_dict_filename_t, entry);
 
        /*
         *      Pre-Allocate pool memory for rapid startup
         *      As that's the working memory required during
         *      dictionary initialisation.
         */
        dict->pool = talloc_pool(dict, DICT_POOL_SIZE);
        if (!dict->pool) {
                fr_strerror_const("Failed allocating talloc pool for dictionary");
                goto error;
        }
 
        /*
         *      Create the table of vendor by name.   There MAY NOT
         *      be multiple vendors of the same name.
         */
        dict->vendors_by_name = fr_hash_table_alloc(dict, dict_vendor_name_hash, dict_vendor_name_cmp, NULL);
        if (!dict->vendors_by_name) {
                fr_strerror_printf("Failed allocating \"vendors_by_name\" table");
                goto error;
        }
        /*
         *      Create the table of vendors by value.  There MAY
         *      be vendors of the same value.  If there are, we
         *      pick the latest one.
         */
        dict->vendors_by_num = fr_hash_table_alloc(dict, dict_vendor_pen_hash, dict_vendor_pen_cmp, NULL);
        if (!dict->vendors_by_num) {
                fr_strerror_printf("Failed allocating \"vendors_by_num\" table");
                goto error;
        }
 
        /*
         *      Inter-dictionary reference caching
         */
        dict->autoref = fr_hash_table_alloc(dict, dict_protocol_name_hash, dict_protocol_name_cmp, NULL);
        if (!dict->autoref) {
                fr_strerror_printf("Failed allocating \"autoref\" table");
                goto error;
        }
 
        /*
         *      Who/what depends on this dictionary
         */
        dict->dependents = fr_rb_inline_alloc(dict, fr_dict_dependent_t, node, _dict_dependent_cmp, NULL);
 
        /*
         *      Set the default dictionary protocol, this can
         *      be overriden by the protocol library.
         */
        dict->proto = &dict_proto_default;
 
        return dict;
}
 
/** Allocate a new local dictionary
 *
 * @param[in] parent parent dictionary and talloc ctx
 * @return
 *      - NULL on memory allocation error.
 *
 *  This dictionary cannot define vendors, or inter-dictionary
 *  dependencies.  However, we initialize the relevant fields just in
 *  case.  We should arguably just skip initializing those fields, and
 *  just allow the server to crash if programmers do something stupid with it.
 */
fr_dict_t *fr_dict_protocol_alloc(fr_dict_t const *parent)
{
        fr_dict_t *dict;
        fr_dict_attr_t *da;
 
        fr_dict_attr_flags_t flags = {
                .is_root = true,
                .local = true,
                .internal = true,
                .type_size = parent->root->flags.type_size,
                .length = parent->root->flags.length,
        };
 
        dict = dict_alloc(UNCONST(fr_dict_t *, parent));
        if (!dict) return NULL;
 
        /*
         *      Allocate the root attribute.  This dictionary is
         *      always protocol "local", and number "0".
         */
        da = dict_attr_alloc_root(dict->pool, parent, "local", 0,
                                  &(dict_attr_args_t){ .flags = &flags });
        if (unlikely(!da)) {
                talloc_free(dict);
                return NULL;
        }
 
        da->last_child_attr = fr_dict_root(parent)->last_child_attr;
 
        dict->root = da;
        dict->root->dict = dict;
        dict->next = parent;
 
        DA_VERIFY(dict->root);
 
        return dict;
}
 
/** Decrement the reference count on a previously loaded dictionary
 *
 * @param[in] dict      to free.
 * @param[in] dependent that originally allocated this dictionary.
 * @return
 *      - 0 on success (dictionary freed).
 *      - 1 if other things still depend on the dictionary.
 *      - -1 on error (dependent doesn't exist)
 */
int fr_dict_const_free(fr_dict_t const **dict, char const *dependent)
{
        fr_dict_t **our_dict = UNCONST(fr_dict_t **, dict);
 
        return fr_dict_free(our_dict, dependent);
}
 
/** Decrement the reference count on a previously loaded dictionary
 *
 * @param[in] dict      to free.
 * @param[in] dependent that originally allocated this dictionary.
 * @return
 *      - 0 on success (dictionary freed).
 *      - 1 if other things still depend on the dictionary.
 *      - -1 on error (dependent doesn't exist)
 */
int fr_dict_free(fr_dict_t **dict, char const *dependent)
{
        if (!*dict) return 0;
 
        switch (dict_dependent_remove(*dict, dependent)) {
        case 0:         /* dependent has no more refs */
                if (!dict_has_dependents(*dict)) {
                        talloc_free(*dict);
                        return 0;
                }
                FALL_THROUGH;
 
        case 1:         /* dependent has more refs */
                return 1;
 
        default:        /* error */
                return -1;
        }
}
 
/** Process a dict_attr_autoload element to load/verify a dictionary attribute
 *
 * @param[in] to_load   attribute definition
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int fr_dict_enum_autoload(fr_dict_enum_autoload_t const *to_load)
{
        fr_dict_enum_autoload_t const   *p = to_load;
        fr_dict_enum_value_t const              *enumv;
 
        for (p = to_load; p->out; p++) {
                if (unlikely(!p->attr)) {
                        fr_strerror_printf("Invalid attribute autoload entry for \"%s\", missing attribute pointer", p->name);
                        return -1;
                }
 
                if (unlikely(!*p->attr)) {
                        fr_strerror_printf("Can't resolve value \"%s\", attribute not loaded", p->name);
                        fr_strerror_printf_push("Check fr_dict_attr_autoload_t struct has "
                                                "an entry to load the attribute \"%s\" is located in, and that "
                                                "the fr_dict_autoload_attr_t symbol name is correct", p->name);
                        return -1;
                }
 
                enumv = fr_dict_enum_by_name(*(p->attr), p->name, -1);
                if (!enumv) {
                        fr_strerror_printf("Value '%s' not found in \"%s\" attribute",
                                           p->name, (*(p->attr))->name);
                        return -1;
                }
 
                if (p->out) *(p->out) = enumv->value;
        }
 
        return 0;
}
 
/** Process a dict_attr_autoload element to load/verify a dictionary attribute
 *
 * @param[in] to_load   attribute definition
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int fr_dict_attr_autoload(fr_dict_attr_autoload_t const *to_load)
{
        fr_dict_attr_t const            *da;
        fr_dict_attr_autoload_t const   *p = to_load;
        fr_dict_attr_t const            *root = NULL;
 
        for (p = to_load; p->out; p++) {
                if (!p->dict) {
                        fr_strerror_printf("Invalid attribute autoload entry for \"%s\", missing dictionary pointer", p->name);
                        return -1;
                }
 
                if (!*p->dict) {
                        fr_strerror_printf("Autoloader autoloader can't resolve attribute \"%s\", dictionary not loaded", p->name);
                        fr_strerror_printf_push("Check fr_dict_autoload_t struct has "
                                                "an entry to load the dictionary \"%s\" is located in, and that "
                                                "the fr_dict_autoload_t symbol name is correct", p->name);
                        return -1;
                }
 
                if (!root || (root->dict != *p->dict) || (p->name[0] != '.')) {
                        root = (*p->dict)->root;
                }
 
                if (p->name[0] == '.') {
                        da = fr_dict_attr_by_oid(NULL, root, p->name + 1);
                        if (!da) {
                                fr_strerror_printf("Autoloader attribute \"%s\" not found in \"%s\" dictionary under attribute %s", p->name,
                                                   *p->dict ? (*p->dict)->root->name : "internal", root->name);
                                return -1;
                        }
                } else {
                        da = fr_dict_attr_by_oid(NULL, fr_dict_root(*p->dict), p->name);
                        if (!da) {
                                fr_strerror_printf("Autoloader attribute \"%s\" not found in \"%s\" dictionary", p->name,
                                                   *p->dict ? (*p->dict)->root->name : "internal");
                                return -1;
                        }
 
                        if (fr_type_is_structural(da->type)) root = da;
                }
 
                if (da->type != p->type) {
                        fr_strerror_printf("Autoloader attribute \"%s\" should be type %s, but defined as type %s", da->name,
                                           fr_type_to_str(p->type),
                                           fr_type_to_str(da->type));
                        return -1;
                }
 
                DA_VERIFY(da);
 
                if (p->out) *(p->out) = da;
        }
 
        return 0;
}
 
/** Process a dict_autoload element to load a protocol
 *
 * @param[in] to_load   dictionary definition.
 * @param[in] dependent that is loading this dictionary.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int _fr_dict_autoload(fr_dict_autoload_t const *to_load, char const *dependent)
{
        fr_dict_autoload_t const        *p;
 
        for (p = to_load; p->out; p++) {
                fr_dict_t *dict = NULL;
 
                if (unlikely(!p->proto)) {
                        fr_strerror_const("autoload missing parameter proto");
                        return -1;
                }
 
                /*
                 *      Load the internal dictionary
                 */
                if (strcmp(p->proto, "freeradius") == 0) {
                        if (fr_dict_internal_afrom_file(&dict, p->proto, dependent) < 0) return -1;
                } else {
                        if (fr_dict_protocol_afrom_file(&dict, p->proto, p->base_dir, dependent) < 0) return -1;
                }
 
                *(p->out) = dict;
        }
 
        return 0;
}
 
 
/** Decrement the reference count on a previously loaded dictionary
 *
 * @param[in] to_free   previously loaded dictionary to free.
 * @param[in] dependent that originally allocated this dictionary
 */
int _fr_dict_autofree(fr_dict_autoload_t const *to_free, char const *dependent)
{
        fr_dict_autoload_t const *p;
 
        for (p = to_free; p->out; p++) {
                int ret;
 
                if (!*p->out) continue;
                ret = fr_dict_const_free(p->out, dependent);
 
                if (ret == 0) *p->out = NULL;
                if (ret < 0) return -1;
        }
 
        return 0;
}
 
/** Structure used to managed the lifetime of a dictionary
 *
 * This should only be used when dictionaries are being dynamically loaded during
 * compilation.  It should not be used to load dictionaries at runtime, or if
 * modules need to load dictionaries (use static fr_dict_autoload_t defs).
 
 */
struct fr_dict_autoload_talloc_s {
        fr_dict_autoload_t load[2];             //!< Autoloader def.
        char const *dependent;                  //!< Dependent that loaded the dictionary.
};
 
/** Talloc destructor to automatically free dictionaries
 *
 * @param[in] to_free   dictionary autoloader definition describing the dictionary to free.
 */
static int _fr_dict_autoload_talloc_free(fr_dict_autoload_talloc_t const *to_free)
{
        return _fr_dict_autofree(to_free->load, to_free->dependent);
}
 
/** Autoload a dictionary and bind the lifetime to a talloc chunk
 *
 * Mainly useful for resolving "forward" references from unlang immediately.
 *
 * @note If the talloc chunk is freed it does not mean the dictionary will
 *       be immediately freed.  It will be freed when all other references
 *       to the dictionary are gone.
 *
 * @param[in] ctx       to bind the dictionary lifetime to.
 * @param[out] out      pointer to the loaded dictionary.
 * @param[in] proto     to load.
 * @param[in] dependent to register this reference to.  Will be dupd.
 */
fr_dict_autoload_talloc_t *_fr_dict_autoload_talloc(TALLOC_CTX *ctx, fr_dict_t const **out, char const *proto, char const *dependent)
{
        fr_dict_autoload_talloc_t *dict_ref;
        int ret;
 
        dict_ref = talloc(ctx, fr_dict_autoload_talloc_t);
        if (unlikely(dict_ref == NULL)) {
        oom:
                fr_strerror_const("Out of memory");
                return NULL;
        }
 
        dict_ref->load[0] = (fr_dict_autoload_t){ .proto = proto, .out = out};
        dict_ref->load[1] = (fr_dict_autoload_t) DICT_AUTOLOAD_TERMINATOR;
        dict_ref->dependent = talloc_strdup(dict_ref, dependent);
        if (unlikely(dict_ref->dependent == NULL)) {
                talloc_free(dict_ref);
                goto oom;
        }
 
        ret = _fr_dict_autoload(dict_ref->load, dependent);
        if (ret < 0) {
                talloc_free(dict_ref);
                return NULL;
        }
 
        return dict_ref;
}
 
/** Callback to automatically resolve enum values
 *
 * @param[in] module    being loaded.
 * @param[in] symbol    An array of fr_dict_enum_autoload_t to load.
 * @param[in] user_ctx  unused.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int fr_dl_dict_enum_autoload(UNUSED dl_t const *module, void *symbol, UNUSED void *user_ctx)
{
        if (fr_dict_enum_autoload((fr_dict_enum_autoload_t *)symbol) < 0) return -1;
 
        return 0;
}
 
/** Callback to automatically resolve attributes and check the types are correct
 *
 * @param[in] module    being loaded.
 * @param[in] symbol    An array of fr_dict_attr_autoload_t to load.
 * @param[in] user_ctx  unused.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int fr_dl_dict_attr_autoload(UNUSED dl_t const *module, void *symbol, UNUSED void *user_ctx)
{
        if (fr_dict_attr_autoload((fr_dict_attr_autoload_t *)symbol) < 0) return -1;
 
        return 0;
}
 
/** Callback to automatically load dictionaries required by modules
 *
 * @param[in] module    being loaded.
 * @param[in] symbol    An array of fr_dict_autoload_t to load.
 * @param[in] user_ctx  unused.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int fr_dl_dict_autoload(UNUSED dl_t const *module, void *symbol, UNUSED void *user_ctx)
{
        if (fr_dict_autoload((fr_dict_autoload_t const *)symbol) < 0) return -1;
 
        return 0;
}
 
/** Callback to automatically free a dictionary when the module is unloaded
 *
 * @param[in] module    being loaded.
 * @param[in] symbol    An array of fr_dict_autoload_t to load.
 * @param[in] user_ctx  unused.
 */
void fr_dl_dict_autofree(UNUSED dl_t const *module, void *symbol, UNUSED void *user_ctx)
{
        fr_dict_autofree(((fr_dict_autoload_t *)symbol));
}
 
static int _dict_global_free_at_exit(void *uctx)
{
        return talloc_free(uctx);
}
 
static int _dict_global_free(fr_dict_gctx_t *gctx)
{
        fr_hash_iter_t  iter;
        fr_dict_t       *dict;
        bool            still_loaded = false;
 
        /*
         *      Make sure this doesn't fire later and mess
         *      things up...
         */
        if (gctx->free_at_exit) fr_atexit_global_disarm(true, _dict_global_free_at_exit, gctx);
 
        /*
         *      Free up autorefs first, which will free up inter-dictionary dependencies.
         */
        for (dict = fr_hash_table_iter_init(gctx->protocol_by_name, &iter);
             dict;
             dict = fr_hash_table_iter_next(gctx->protocol_by_name, &iter)) {
                (void)talloc_get_type_abort(dict, fr_dict_t);
 
                if (dict_autoref_free(dict) < 0) return -1;
        }
 
        for (dict = fr_hash_table_iter_init(gctx->protocol_by_name, &iter);
             dict;
             dict = fr_hash_table_iter_next(gctx->protocol_by_name, &iter)) {
                (void)talloc_get_type_abort(dict, fr_dict_t);
                dict_dependent_remove(dict, "global");                  /* remove our dependency */
 
                if (talloc_free(dict) < 0) {
#ifndef NDEBUG
                        FR_FAULT_LOG("gctx failed to free dictionary %s - %s", dict->root->name, fr_strerror());
#endif
                        still_loaded = true;
                }
        }
 
        /*
         *      Free the internal dictionary as the last step, after all of the protocol dictionaries and
         *      libraries have freed their references to it.
         */
        if (gctx->internal) {
                dict_dependent_remove(gctx->internal, "global");        /* remove our dependency */
 
                if (talloc_free(gctx->internal) < 0) still_loaded = true;
        }
 
        if (still_loaded) {
#ifndef NDEBUG
                fr_dict_gctx_debug(stderr, gctx);
#endif
                return -1;
        }
 
        /*
         *      Set this to NULL just in case the caller tries to use
         *      dict_global_init() again.
         */
        if (gctx == dict_gctx) dict_gctx = NULL;        /* In case the active context isn't this one */
 
        return 0;
}
 
/** Initialise the global protocol hashes
 *
 * @note Must be called before any other dictionary functions.
 *
 * @param[in] ctx               to allocate global resources in.
 * @param[in] free_at_exit      Install an at_exit handler to free the global ctx.
 *                              This is useful when dictionaries are held by other
 *                              libraries which free them using atexit handlers.
 * @param[in] dict_dir          the default location for the dictionaries.
 * @return
 *      - A pointer to the new global context on success.
 *      - NULL on failure.
 */
fr_dict_gctx_t *fr_dict_global_ctx_init(TALLOC_CTX *ctx, bool free_at_exit, char const *dict_dir)
{
        fr_dict_gctx_t *new_ctx;
 
        new_ctx = talloc_zero(ctx, fr_dict_gctx_t);
        if (!new_ctx) {
                fr_strerror_const("Out of Memory");
                return NULL;
        }
        new_ctx->perm_check = true;     /* Check file permissions by default */
 
        new_ctx->protocol_by_name = fr_hash_table_alloc(new_ctx, dict_protocol_name_hash, dict_protocol_name_cmp, NULL);
        if (!new_ctx->protocol_by_name) {
                fr_strerror_const("Failed initializing protocol_by_name hash");
        error:
                talloc_free(new_ctx);
                return NULL;
        }
 
        new_ctx->protocol_by_num = fr_hash_table_alloc(new_ctx, dict_protocol_num_hash, dict_protocol_num_cmp, NULL);
        if (!new_ctx->protocol_by_num) {
                fr_strerror_const("Failed initializing protocol_by_num hash");
                goto error;
        }
 
        new_ctx->dict_dir_default = talloc_strdup(new_ctx, dict_dir);
        if (!new_ctx->dict_dir_default) goto error;
 
        new_ctx->dict_loader = dl_loader_init(new_ctx, NULL, false, false);
        if (!new_ctx->dict_loader) goto error;
 
        new_ctx->free_at_exit = free_at_exit;
 
        talloc_set_destructor(new_ctx, _dict_global_free);
 
        if (!dict_gctx) dict_gctx = new_ctx;    /* Set as the default */
 
        if (free_at_exit) fr_atexit_global(_dict_global_free_at_exit, new_ctx);
 
        return new_ctx;
}
 
/** Set whether we check dictionary file permissions
 *
 * @param[in] gctx      to alter.
 * @param[in] enable    Whether we should check file permissions as they're loaded.
 */
void fr_dict_global_ctx_perm_check(fr_dict_gctx_t *gctx, bool enable)
{
        gctx->perm_check = enable;
}
 
/** Set a new, active, global dictionary context
 *
 * @param[in] gctx      To set.
 */
void fr_dict_global_ctx_set(fr_dict_gctx_t const *gctx)
{
        memcpy(&dict_gctx, &gctx, sizeof(dict_gctx));
}
 
/** Explicitly free all data associated with a global dictionary context
 *
 * @note You should *NOT* ignore the return code of this function.
 *       You should use perror() or PERROR() to print out the reason
 *       why freeing failed.
 *
 * @param[in] gctx      To set.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int fr_dict_global_ctx_free(fr_dict_gctx_t const *gctx)
{
        if (dict_gctx == gctx) dict_gctx = NULL;
 
        return talloc_const_free(gctx);
}
 
/** Allow the default dict dir to be changed after initialisation
 *
 * @param[in] dict_dir  New default dict dir to use.
 * @return
 *      - 0 on success.
 *      - -1 on failure.
 */
int fr_dict_global_ctx_dir_set(char const *dict_dir)
{
        if (!dict_gctx) return -1;
 
        talloc_free(dict_gctx->dict_dir_default);               /* Free previous value */
        dict_gctx->dict_dir_default = talloc_strdup(dict_gctx, dict_dir);
        if (!dict_gctx->dict_dir_default) return -1;
 
        return 0;
}
 
char const *fr_dict_global_ctx_dir(void)
{
        return dict_gctx->dict_dir_default;
}
 
/** Mark all dictionaries and the global dictionary ctx as read only
 *
 * Any attempts to add new attributes will now fail.
 */
void fr_dict_global_ctx_read_only(void)
{
        fr_hash_iter_t  iter;
        fr_dict_t       *dict;
 
        if (!dict_gctx) return;
 
        /*
         *      Set everything to read only
         */
        for (dict = fr_hash_table_iter_init(dict_gctx->protocol_by_num, &iter);
             dict;
             dict = fr_hash_table_iter_next(dict_gctx->protocol_by_num, &iter)) {
                dict_hash_tables_finalise(dict);
                dict->read_only = true;
        }
 
        dict = dict_gctx->internal;
        dict_hash_tables_finalise(dict);
        dict->read_only = true;
        dict_gctx->read_only = true;
}
 
/** Dump information about currently loaded dictionaries
 *
 * Intended to be called from a debugger
 */
void fr_dict_gctx_debug(FILE *fp, fr_dict_gctx_t const *gctx)
{
        fr_hash_iter_t                  dict_iter;
        fr_dict_t                       *dict;
        fr_rb_iter_inorder_t            dep_iter;
        fr_dict_dependent_t             *dep;
 
        if (gctx == NULL) gctx = dict_gctx;
 
        if (!gctx) {
                fprintf(fp, "gctx not initialised\n");
                return;
        }
 
        fprintf(fp, "gctx %p report\n", dict_gctx);
        for (dict = fr_hash_table_iter_init(gctx->protocol_by_num, &dict_iter);
             dict;
             dict = fr_hash_table_iter_next(gctx->protocol_by_num, &dict_iter)) {
                for (dep = fr_rb_iter_init_inorder(dict->dependents, &dep_iter);
                     dep;
                     dep = fr_rb_iter_next_inorder(dict->dependents, &dep_iter)) {
                        fprintf(fp, "\t%s is referenced from %s count (%d)\n",
                                dict->root->name, dep->dependent, dep->count);
                }
        }
 
        if (gctx->internal) {
                for (dep = fr_rb_iter_init_inorder(gctx->internal->dependents, &dep_iter);
                     dep;
                     dep = fr_rb_iter_next_inorder(gctx->internal->dependents, &dep_iter)) {
                        fprintf(fp, "\t%s is referenced from %s count (%d)\n",
                                gctx->internal->root->name, dep->dependent, dep->count);
                }
        }
}
 
/** Iterate protocols by name
 *
 */
fr_dict_t *fr_dict_global_ctx_iter_init(fr_dict_global_ctx_iter_t *iter)
{
        if (!dict_gctx) return NULL;
 
        return fr_hash_table_iter_init(dict_gctx->protocol_by_name, iter);
}
 
fr_dict_t *fr_dict_global_ctx_iter_next(fr_dict_global_ctx_iter_t *iter)
{
        if (!dict_gctx) return NULL;
 
        return fr_hash_table_iter_next(dict_gctx->protocol_by_name, iter);
}
 
 
/** Coerce to non-const
 *
 */
fr_dict_t *fr_dict_unconst(fr_dict_t const *dict)
{
        if (unlikely(dict->read_only)) {
                fr_strerror_printf("%s dictionary has been marked as read only", fr_dict_root(dict)->name);
                return NULL;
        }
        return UNCONST(fr_dict_t *, dict);
}
 
/** Coerce to non-const
 *
 */
fr_dict_attr_t *fr_dict_attr_unconst(fr_dict_attr_t const *da)
{
        fr_dict_t *dict;
 
        dict = dict_by_da(da);
        if (unlikely(dict->read_only)) {
                fr_strerror_printf("%s dictionary has been marked as read only", fr_dict_root(dict)->name);
                return NULL;
        }
 
        return UNCONST(fr_dict_attr_t *, da);
}
 
fr_dict_t const *fr_dict_internal(void)
{
        if (!dict_gctx) return NULL;
 
        return dict_gctx->internal;
}
 
/*
 *      Check for the allowed characters.
 */
ssize_t fr_dict_valid_name(char const *name, ssize_t len)
{
        char const *p = name, *end;
        bool unknown = false;
        bool alnum = false;
 
        if (len < 0) len = strlen(name);
 
        if (len > FR_DICT_ATTR_MAX_NAME_LEN) {
                fr_strerror_const("Attribute name is too long");
                return -1;
        }
 
        end = p + len;
 
        /*
         *      Unknown attributes can have '.' in their name.
         */
        if ((len > 5) && (memcmp(name, "Attr-", 5) == 0)) unknown = true;
 
        while (p < end) {
                if ((*p == '.') && unknown) p++;
 
                if (!fr_dict_attr_allowed_chars[(uint8_t)*p]) {
                        fr_strerror_printf("Invalid character '%pV' in attribute name \"%pV\"",
                                           fr_box_strvalue_len(p, 1), fr_box_strvalue_len(name, len));
 
                        return -(p - name);
                }
 
                alnum |= sbuff_char_alpha_num[(uint8_t)*p];
 
                p++;
        }
 
        if (!alnum) {
                fr_strerror_const("Invalid attribute name");
                return -1;
        }
 
        return len;
}
 
ssize_t fr_dict_valid_oid_str(char const *name, ssize_t len)
{
        char const *p = name, *end;
        bool alnum = false;
 
        if (len < 0) len = strlen(name);
        end = p + len;
 
        do {
                if (!fr_dict_attr_allowed_chars[(uint8_t)*p] && (*p != '.')) {
                        fr_strerror_printf("Invalid character '%pV' in oid string \"%pV\"",
                                           fr_box_strvalue_len(p, 1), fr_box_strvalue_len(name, len));
 
                        return -(p - name);
                }
 
                alnum |= sbuff_char_alpha_num[(uint8_t)*p];
                p++;
        } while (p < end);
 
        if (!alnum) return 0;
 
        return len;
}
 
/** Iterate over children of a DA.
 *
 *  @param[in] parent   the parent da to iterate over
 *  @param[in,out] prev pointer to NULL to start, otherwise pointer to the previously returned child
 *  @return
 *     - NULL for end of iteration
 *     - !NULL for a valid child.  This child MUST be passed to the next loop.
 */
fr_dict_attr_t const *fr_dict_attr_iterate_children(fr_dict_attr_t const *parent, fr_dict_attr_t const **prev)
{
        fr_dict_attr_t const * const *bin;
        fr_dict_attr_t const **children;
        fr_dict_attr_t const *ref;
        size_t len, i, start;
 
        ref = fr_dict_attr_ref(parent);
        if (ref) parent = ref;
 
        children = dict_attr_children(parent);
        if (!children) return NULL;
 
        if (!*prev) {
                start = 0;
 
        } else if ((*prev)->next) {
                /*
                 *      There are more children in this bin, return
                 *      the next one.
                 */
                return (*prev)->next;
 
        } else {
                /*
                 *      Figure out which bin we were in.  If it was
                 *      the last one, we're done.
                 */
                start = (*prev)->attr & 0xff;
                if (start == 255) return NULL;
 
                /*
                 *      Start at the next bin.
                 */
                start++;
        }
 
        /*
         *      Look for a non-empty bin, and return the first child
         *      from there.
         */
        len = talloc_array_length(children);
        for (i = start; i < len; i++) {
                bin = &children[i & 0xff];
 
                if (*bin) return *bin;
        }
 
        return NULL;
}
 
/** Call the specified callback for da and then for all its children
 *
 */
static int dict_walk(fr_dict_attr_t const *da, fr_dict_walk_t callback, void *uctx)
{
        size_t i, len;
        fr_dict_attr_t const **children;
 
        children = dict_attr_children(da);
 
        if (fr_dict_attr_ref(da) || !children) return callback(da, uctx);
 
        len = talloc_array_length(children);
        for (i = 0; i < len; i++) {
                int ret;
                fr_dict_attr_t const *bin;
 
                if (!children[i]) continue;
 
                for (bin = children[i]; bin; bin = bin->next) {
                        ret = dict_walk(bin, callback, uctx);
                        if (ret < 0) return ret;
                }
        }
 
        return 0;
}
 
int fr_dict_walk(fr_dict_attr_t const *da, fr_dict_walk_t callback, void *uctx)
{
        return dict_walk(da, callback, uctx);
}
 
 
void fr_dict_attr_verify(char const *file, int line, fr_dict_attr_t const *da)
{
        int i;
        fr_dict_attr_t const *da_p;
 
        (void) talloc_get_type_abort_const(da, fr_dict_attr_t);
 
        if ((!da->flags.is_root) && (da->depth == 0)) {
                fr_fatal_assert_fail("CONSISTENCY CHECK FAILED %s[%d]: fr_dict_attr_t %s vendor: %u, attr %u: "
                                     "Is not root, but depth is 0",
                                     file, line, da->name, fr_dict_vendor_num_by_da(da), da->attr);
        }
 
        if (da->depth > FR_DICT_MAX_TLV_STACK) {
                fr_fatal_assert_fail("CONSISTENCY CHECK FAILED %s[%d]: fr_dict_attr_t %s vendor: %u, attr %u: "
                                     "Indicated depth (%u) greater than TLV stack depth (%d)",
                                     file, line, da->name, fr_dict_vendor_num_by_da(da), da->attr,
                                     da->depth, FR_DICT_MAX_TLV_STACK);
        }
 
        for (da_p = da; da_p; da_p = da_p->next) {
                (void) talloc_get_type_abort_const(da_p, fr_dict_attr_t);
        }
 
        for (i = da->depth, da_p = da; i >= 0; i--, da_p = da_p->parent) {
                if (!da_p) {
                        fr_fatal_assert_fail("CONSISTENCY CHECK FAILED %s[%d]: fr_dict_attr_t %s vendor: %u, attr %u: "
                                             "Depth indicated there should be a parent, but parent is NULL",
                                             file, line, da->name, fr_dict_vendor_num_by_da(da), da->attr);
                }
                if (i != (int)da_p->depth) {
                        fr_fatal_assert_fail("CONSISTENCY CHECK FAILED %s[%d]: fr_dict_attr_t %s vendor: %u, attr %u: "
                                             "Depth out of sequence, expected %i, got %u",
                                             file, line, da->name, fr_dict_vendor_num_by_da(da), da->attr, i, da_p->depth);
                }
 
        }
 
        if ((i + 1) < 0) {
                fr_fatal_assert_fail("CONSISTENCY CHECK FAILED %s[%d]: fr_dict_attr_t top of hierarchy was not at depth 0",
                                     file, line);
        }
 
        if (da->parent && (da->parent->type == FR_TYPE_VENDOR) && !fr_dict_attr_has_ext(da, FR_DICT_ATTR_EXT_VENDOR)) {
                fr_fatal_assert_fail("CONSISTENCY CHECK FAILED %s[%d]: VSA missing 'vendor' extension", file, line);
        }
 
        switch (da->type) {
        case FR_TYPE_STRUCTURAL:
        {
                fr_hash_table_t *ht;
 
                if (da->type == FR_TYPE_GROUP) break;
 
                fr_assert_msg(fr_dict_attr_has_ext(da, FR_DICT_ATTR_EXT_CHILDREN),
                              "CONSISTENCY CHECK FAILED %s[%d]: %s missing 'children' extension",
                              file, line,
                              fr_type_to_str(da->type));
 
                fr_assert_msg(fr_dict_attr_has_ext(da, FR_DICT_ATTR_EXT_NAMESPACE),
                              "CONSISTENCY CHECK FAILED %s[%d]: %s missing 'namespace' extension",
                              file, line,
                              fr_type_to_str(da->type));
 
                /*
                 *      Check the namespace hash table is ok
                 */
                ht = dict_attr_namespace(da);
                if (unlikely(!ht)) break;
                fr_hash_table_verify(ht);
        }
                break;
 
        default:
                break;
        }
}
 
/** See if a structural da is allowed to contain another da
 *
 *  We have some complex rules with different structural types,
 *  different protocol dictionaries, references to other protocols,
 *  etc.
 *
 *  @param[in] parent   The parent da, must be structural
 *  @param[in] child    The alleged child
 *  @return
 *      - false - the child is not allowed to be contained by the parent
 *      - true - the child is allowed to be contained by the parent
 */
bool fr_dict_attr_can_contain(fr_dict_attr_t const *parent, fr_dict_attr_t const *child)
{
        /*
         *      This is the common case: child is from the parent.
         */
        if (child->parent == parent) return true;
 
        if (child->flags.is_raw) return true; /* let people do stupid things */
 
        /*
         *      Only structural types can have children.
         */
        if (!fr_type_structural[parent->type]) return false;
 
        /*
         *      An internal attribute can go into any other container.
         *
         *      Any other attribute can go into an internal structural
         *      attribute, because why not?
         */
        if (dict_gctx) {
                if (child->dict == dict_gctx->internal) return true;
 
                if (parent->dict == dict_gctx->internal) return true;
        }
 
        /*
         *      Anything can go into internal groups.
         */
        if ((parent->type == FR_TYPE_GROUP) && parent->flags.internal) return true;
 
        /*
         *      Protocol attributes have to be in the same dictionary.
         *
         *      Unless they're a cross-protocol grouping attribute.
         *      In which case we check if the ref is the same.
         */
        if (child->dict != parent->dict) {
                fr_dict_attr_t const *ref;
 
                ref = fr_dict_attr_ref(parent);
 
                return (ref && (ref->dict == child->dict));
        }
 
        /*
         *      Key fields can have children, but everyone else thinks
         *      that the struct is the parent.  <sigh>
         */
        if ((parent->type == FR_TYPE_STRUCT) && child->parent->parent == parent) return true;
 
        /*
         *      We're in the same protocol dictionary, but the child
         *      isn't directly from the parent.  Therefore the only
         *      type of same-protocol structure it can go into is a
         *      group.
         */
        return (parent->type == FR_TYPE_GROUP);
}
 
/** Return the protocol descriptor for the dictionary.
 *
 */
fr_dict_protocol_t const *fr_dict_protocol(fr_dict_t const *dict)
{
        return dict->proto;
}
 
/*
 *      Get the real protocol namespace behind a local one.
 */
fr_dict_attr_t const *fr_dict_unlocal(fr_dict_attr_t const *da)
{
        if (!da->flags.local) return da;
 
        fr_assert(da->dict->root == da);
 
        while (da->dict->next) {
                da = da->dict->next->root;
        }
 
        return da;
}
 
/*
 *      Get the real protocol dictionary behind a local one.
 */
fr_dict_t const *fr_dict_proto_dict(fr_dict_t const *dict)
{
        while (dict->next) dict = dict->next;
 
        return dict;
}
 
int fr_dict_attr_set_group(fr_dict_attr_t **da_p, fr_dict_attr_t const *ref)
{
        if ((*da_p)->type == FR_TYPE_GROUP) {
                fr_assert(fr_dict_attr_ext(*da_p, FR_DICT_ATTR_EXT_REF) != NULL);
                return 0;
        }
 
        (*da_p)->type = FR_TYPE_GROUP;
        (*da_p)->flags.type_size = 0;
        (*da_p)->flags.length = 0;
 
        fr_assert(fr_dict_attr_ext(*da_p, FR_DICT_ATTR_EXT_REF) == NULL);
 
        return dict_attr_ref_aset(da_p, ref, FR_DICT_ATTR_REF_ALIAS);
}